Patent Abstract:
The present invention relates to novel iturin biosynthesis genes, and uses thereof. More specifically, the present invention provides novel iturin biosynthesis genes, wherein the iturin biosynthesis genes were cloned from  Bacillus subtilis  subsp.  krictiensis  ATCC 55079, the base sequence was determined after checking whether the cloned genes are iturin biosynthesis genes or not, and it was ascertained that the identified genes are novel genes different from the reported gene by comparing the base sequences with that of the reported gene, and uses thereof.

Full Description:
BACKGROUND OF THE INVENTION 
       [0001]    1. Field of the Invention 
         [0002]    The present disclosure relates to novel iturin biosynthesis genes, and more particularly, to novel iturin biosynthesis genes derived from  Bacillus subtilis  subsp.  krictiensis  ATCC 55079 and uses thereof. 
         [0003]    2. Description of the Related Art 
         [0004]    Biological control is a means of controlling pathogenic microorganisms that cause disease injuries in plants through the use of other microorganisms that have antagonistic actions. Most representative biopesticides have been primarily used for controlling various plant pathogens, insects harming crops, insect pests such as mites, nematodes, and weeds through direct or indirect use of microorganisms themselves. Studies on this biological control started in early 1990s, and since then, many efforts have been made to inhibit plant pathogens by using various kinds of bacteria and fungi. However, since the soil ecosystems are complex and complicated interactions are associated between plants and microorganisms, the results of studies were very unsatisfying. Recently, interactions between plants and microorganisms have been gradually identified and outstanding results have been reported thanks to developments in biotechnology, such as molecular biology. Currently, about 40 kinds of biological control agents have been developed all around the world (H. D. Burges, Formulation of microbial biopesticides, Kluwer Academic Publisher, Dordrecht, The Netherlands, p. 187-202, 1998) and 25 kinds of biological control agents are registered and commercially available only in the U.S. (B. B. McSpadden Gardener, et al., Plant Health Progress [Internet], May 10, 2002 [cited Aug. 13, 2010], Available from: http://www.plantmanagementnetwork.org/pub/php/review/biocontrol/). 
         [0005]    Registered products are mainly for the control of soil borne plant diseases by  Fusarium, Pythium, Rhizoctonia , and  Sclerotinia  ( Phytophthora ), but, these products have not yet captured a large share of the market. So far, one of the most successful examples of biological control is the control of crown gall, a disease of roots in fruit trees, caused by  Agrobacterium tumefaciens  (A. Kerr, Plant Dis., 64: 25-30, 1980). Controlling this plant disease cannot be carried out with chemosynthetic pesticides. However, it has been known that an antibiotic agrocin produced by  Agrobacterium  radiobacter inhibits the invasion of  A. tumefaciens , and then, several products that improved  A. radiobacter  by using genetic engineering techniques have been developed and thought to have a considerable worldwide market share (names of products: Nogall, Norbac, Galltrol-A, etc.). Another successful example is the study on the control of root rots of wheat using  Pseudomonas fluorescens , and research teams at the USDA and Washington State University succeeded in isolating  P. fluorescens  which exhibits strong antagonistic activity against  Gaeumannomyces graminis  var.  tritici  causing the root rots of wheat from soil through 10-year researches (D. M. Weller, Annu. Rev. Phytopathol., 26: 379-407, 1988; D. M. Weller, et al., Can. J. Plant Pathol., 8: 328-334, 1986; R. J. Cook, Can. J. Plant. Pathol., 14: 76-85, 1992). When wheat seeds were treated with this antagonistic microorganism and sown, the yield of wheat increased by 10 to 20% and it was concluded that this effect was caused by phenazine antibiotics (L. S. Thomashow, et al., Appl. Environ. Microbiol., 56: 908-912, 1990; C. Keel, et al., Mol. Plant-Microbe Interact., 5: 4-13, 1992) and 2,4-diacetyl phloroglucinol antibiotic produced by  Pseudomonas  (C. Keel, et al., Mol. Plant-Microbe Interact., 5: 4-13, 1992). To overcome the differences in control activities depending on application time and region, revealed through a field experiment over 8 years, research teams introduced genetic engineering techniques to maximize the gene expression of  Pseudomonas  sp. related with the production of phenazine antibiotics and succeeded in overcoming the irregularity of the control effect of root rots of wheat (M. H. Ryder, et al., Improving plant productivity with  Rhizobacteria , CSIRO Divisions of soils, Adelaide, South Australia, p. 247-249, 1994). 
         [0006]      Bacillus subtilis  ( B. subtilis ) has been received attention of many researchers due to not only many kinds of antibiotics but also its characteristic to produce various enzymes, and along with  Saccharomyces cerevisiae  ( S. cerevisiae ), and  Lactobacillus  sp., it is recognized as a harmless strain to a human body and the environment by the U.S. Food and Drug Administration. Examples of formulations of microbial pesticides developed by using  B. subtilis  include Epic, Kodiak, Companion, HiStick, Serenade, etc. and these are largely widely used for seed treatment or post-harvest application, and for protecting putrefaction of vegetables and the like (B. B. McSpadden Gardener, et al., Plant Health Progress [Internet], May 10, 2002 [cited Aug. 13, 2010], Available from: http://www.plantmanagementnetwork.org/pub/php/review/biocontrol/). Especially, Serenade which was registered in early 2,000s by AgraQuest Co. has been produced by using  B. subtilis  QST713 and is registered as a fungicide and a bactericide in 25 countries, and currently, various products depending on their uses are commercially available. In addition, a research team at the USDA found that iturin antibiotics produced by  B. subtilis  inhibited  Monilinia fructicola , the pathogen of peach brown rot, and attempted a study to develop  B. subtilis  as a preservative during storage of tree fruits (R. C. Gueldner, et al., J. Agric. Food Chem., 36: 366-370, 1988). 
         [0007]    Besides, a research team lead by Dr. Pusey at the USDA found that  B. subtilis  has an inhibitory effect on many plant diseases (P. L. Pusey, et al., Pesticide Sci., 27: 133-140, 1989) and Phae et al. also isolated  B. subtilis  NB22 having a wide inhibitory effect on plant pathogens from decomposed soil for compost and proved that its active components are iturin-based materials (C. G. Phae, et al., J. Ferment. Bioeng., 69: 1-7, 1990). Like these, iturin, a cyclic peptide antibiotic, has long been widely used as a biological control agent, but, study on iturin biosynthesis genes at the molecular level has hardly been made, except for one published in J. Ferment. Bioeng. by a Japanese research team in 1990. 
         [0008]    The complete genome sequence of  B. subtilis  168 strain having a gene responsible for biosynthesis of surfactin, another cyclic peptide other than iturin was published in 1997 (Kunst, F., et al., Nature, 390: 249-256, 1997), and the result of study on a gene responsible for biosynthesis of mycosubtilin from  B. subtilis  ATCC 6633 was reported by a German research team in late 1990s (E. H. Duitman, et al., Proc. Natl. Acad. Sci., 96: 13294-13299, 1999). Since then, cloning, base sequence, and characteristics of iturin A gene from  B. subtilis  RB14 was published by a Japanese research team in 2000s (K. Tsuge, et al., J. Bacteriol., 183: 6265-6273, 2001). Furthermore, a German research team found that  B. amyloliquefaciens  FZB42 which promotes plant growth and suppresses plant pathogens at the same time produced cyclic peptides, surfactin, fengycin, and bacillomycin D as secondary metabolites, and investigated and reported genetic structures and functional characteristics of produced secondary metabolites at the molecular level (A. Koumoutsi, et al., J. Bacteriol., 186: 1084-1096, 2004). Besides, the above German research team reported that  B. amyloliquefaciens  FZB42 produces polyketide-based antibiotics, macrolactin, bacillaene, and difficidin, in addition to the above three cyclic peptides (Chen, et al., Nature Biotechnol., 25: 1007-1014, 2007). Likewise, while reports on various cyclic peptide antibiotics have been made intermittently, there is hardly a report on various kinds of iturin biosynthesis genes. 
         [0009]    Thus, the present inventors cloned iturin biosynthesis genes from  B. subtilis  subsp.  krictiensis  ATCC 55079 (S. H. Bok, et al., U.S. Pat. No. 5,155,041, 1992. 10. 13) which is effective for various plant pathogens isolated from domestic soils and produces six kinds of iturins (iturin A to F) and obtained the U.S. patent in 1992, identified iturin biosynthesis genes by determining base sequences of the genes, analyzed their characteristics, and found that the above iturin biosynthesis genes are novel iturin biosynthesis genes that show many differences in base sequences, compared to conventional iturin genes, thereby leading to completion of the present invention. 
       SUMMARY OF THE INVENTION 
       [0010]    One object of the present invention is to provide novel iturin biosynthesis genes, proteins encoded by the genes, and uses thereof. 
         [0011]    In order to achieve the objects, the present invention provides an iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:6 or an iturin biosynthesis gene having 95% or more sequence identity to the gene. 
         [0012]    The present invention also provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:5. 
         [0013]    Furthermore, the present invention provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:3. 
         [0014]    The present invention also provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:7. 
         [0015]    Furthermore, the present invention provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:8. 
         [0016]    The present invention also provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6, SEQ ID NO:3, and SEQ ID NO:7. 
         [0017]    Furthermore, the present invention provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6, SEQ ID NO:3, and SEQ ID NO:8. 
         [0018]    The present invention also provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6, SEQ ID NO:7, and SEQ ID NO:8. 
         [0019]    Furthermore, the present invention provides an iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:1. 
         [0020]    The present invention also provides an iturin protein encoded by the gene in accordance with the present invention. 
         [0021]    Furthermore, the present invention provides a vector comprising nucleotide sequence of the gene in accordance with the present invention. 
         [0022]    The present invention also provides a transformant transformed with the vector comprising nucleotide sequence of the gene in accordance with the present invention. 
         [0023]    Furthermore, the present invention provides iturin protein produced by the transformant in accordance with the present invention. 
         [0024]    The present invention also provides a biological control agent comprising the transformant producing the iturin protein in accordance with the present invention or its culture medium. 
         [0025]    Furthermore, the present invention provides the transformant of the present invention or its culture medium for use as a biological control agent, or the iturin protein produced by the transformant of the present invention for use as a biological control agent. 
         [0026]    Hereinafter, the present invention will be described in detail. 
         [0027]    The present invention provides an iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:6 or an iturin biosynthesis gene having 95% or more sequence identity to the gene, or iturin protein encoded by the gene. 
         [0028]    In the iturin biosynthesis gene, the nucleotide sequence of SEQ ID NO:6 may comprise ORF 3 of the iturin biosynthesis gene, and the protein encoded by the iturin gene may be, but not limited to, conventionally known iturin biosynthesis protein. 
         [0029]    In a specific example of the present invention, first, the present inventors used  B. subtilis  168, which is known that produces surfactin, but does not produce iturin, to identify the novel iturin biosynthesis gene. Surfactin and iturin are cyclic lipopeptide antibiotics composed of seven amino acids and a fatty acid. They are different from each other only in amino acid composition and sequences, and are known to be very similar in their molecular weights. Since surfactin gene is as large enough to be 32 kb in size, the size of iturin gene is thought to be similar to that. It is also assumed that the biosynthetic pathways of these two antibiotics are not distinct from the beginning, but the same pathway is utilized up to established steps, and then, two antibiotics are synthesized using separate biosynthetic pathways. Since some  B. subtilis  strains are known that produce both iturin and surfactin, the present inventors assumed that each gene is less likely to exist separately in consideration of the size of two genes. That is, cyclization of peptides and acylation process of connecting peptides and fatty acids during the biosynthetic process of two antibiotics are assumed to utilize the same pathway for biosynthesis of surfactin and iturin, considering each gene size. On the basis of these assumptions, the present inventors obtained surfactin biosynthetic genes from the database of  B. subtilis  168 which was used in the  Bacillus  genome project and tried the cloning of iturin biosynthetic genes of  B. subtilis  subsp.  krictiensis  with a DNA homology based method. In a specific example of the present invention, PCR and electrophoresis were conducted using the chromosomal DNAs of B, subtilis 168 and  B. subtilis  subsp.  krictiensis  as the template. Among gene products obtained from  B. subtilis  subsp.  krictiensis , about 1.8 kb of a DNA fragment, the same size with the gene product from  B. subtilis  168, was obtained ( FIG. 1 ). 
         [0030]    Also in a specific example of the present invention, when the amino acid sequence of the DNA fragment obtained from  B. subtilis  subsp.  krictiensis  was compared to amino acid sequences of other peptide biosynthesis genes using NCBI database, it showed 82 to 85% homology with three different surfactin biosynthesis genes and 80% homology with lichenysin biosynthesis gene produced by  B. licheniformis.    
         [0031]    Also in a specific example of the present invention, to clone genes responsible for acylation process of connecting peptides and fatty acids, PCR was conducted using designed 20 primers and about 0.4 kb of a DNA fragment was obtained and the sequence was determined ( FIG. 3 ). As a result of NCBI database search to compare amino acids, this gene product had 56 to 83% homology with acyl carrier protein reductases derived from other microorganisms ( FIG. 4 ). Especially, it showed 83% homology with acyl carrier protein reductases derived from other  B. subtilis  and it was thought to be usable for genomic library screening of  B. subtilis  subsp.  krictiensis.    
         [0032]    Also in a specific example of the present invention, to clone the iturin biosynthetic genes from genomic library of  B. subtilis  subsp.  krictiensis , the genomic DNAs of  B. subtilis  subsp.  krictiensis  were partially digested with Sau3A. Then, to 30 kb of a DNA fragment was inserted into the cosmid vector pLAFR3 and  E. coli  HB101 was transformed with the vector to construct the genomic library. Colony hybridization and Southern hybridization were conducted using the constructed genomic library of  B. subtilis  subsp.  krictiensis  and 1.8 kb of peptide biosynthesis gene, which was already cloned in Example &lt;3-1&gt; as a probe. Consequently, two clones that showed homology with the probe DNA at 27 kb and 32 kb positions were observed and named as pJJ815 and pJJ121, respectively ( FIG. 5 ). 
         [0033]    Also in a specific example of the present invention, a restriction enzyme map was constructed by digesting cosmid clones with various kinds of restriction enzymes and leaving out the regions which were overlapped each other. Base sequences of some fragments were investigated. As a result, some fragment of pJJ121 showed 57 to 90% homology with surfactin synthetase I, tyrocidine synthetase II, gramicidine S synthetase I, and peptide synthetase 2. From the result, the present inventors assumed that two cosmid clones include some genes related with peptide synthesis of iturin biosynthetic process. 
         [0034]    Also in a specific example of the present invention, Southern hybridization was conducted at 50° C. and 65° C. using chromosomal DNAs of  B. subtilis  subsp.  krictiensis  and  B. subtilis  168 to determine whether the genes in the cosmid clones are responsible for iturin or surfactin biosynthesis. Six EcoRI fragments which were obtained by digesting cosmid clones pJJ121 and pJJ815 with EcoRI were subcloned and the fragments were prepared as probe DNAs. Consequently, at 65° C., while  B. subtilis  subsp.  krictiensis  showed homologies with all probe DNAs of six EcoRI fragments,  B. subtilis  168 did not show homology with any probe DNAs of six EcoRI fragments. The result of Southern hybridization at 50° C. was the same as above, but,  B. subtilis  168 showed only weak homology for pJJ121E3 fragment. Accordingly, the genes in the cosmid clones hardly showed similarity with surfactin biosynthesis genes and it was assumed that the genes are likely to be responsible for iturin biosynthesis ( FIG. 7  and  FIG. 8 ). 
         [0035]    In a specific example of the present invention, bidirectional sequence was determined with EcoRI fragments cloned from those two cosmid clones to obtain 21,253 bp. However, the present inventors found that some genes were missing. To further obtain the missing sequence, the present inventors obtained the genes through a genomic library screening and determined sequence to obtain a total of 37,682 bp of sequence. Seven ORFs which were assumed to be responsible for iturin biosynthesis were found within the sequence ( FIG. 9 ). When each of seven ORFs which were assumed to be responsible for iturin biosynthesis of cosmid clones was compared with other cyclic lipopeptide biosynthetic genes, they showed 76 to 86% similarity to surfactin genes derived from  B. subtilis , but they showed 92 to 100% similarity to surfactin genes derived from  B. amyloliquefaciens . Especially, ORF 2-1 (543 bp), ORF 2-2 (9,927 bp), and ORF 3 (10,757 bp) which were assumed to be directly engaged in iturin biosynthesis showed 92 to 98% similarity to surfactin genes derived from  B. amyloliquefaciens , respectively (Table 1). While ORF 2-1 showed 94% similarity to  B. amyloliquefaciens  FZB42 of which number starts with CP000560.1 among strains listed in Table 1, it showed 98% similarity to the entire sequence (37,682 bp). However, since the strain was reported to produce cyclic peptides, surfactin, fengycin, and bacillomycin D (Chen, et al., Nature Biotechnol., 25: 1007-1014, 2007), but not iturin, the present inventors assumed that ORF 2-1, ORF 2-2, and ORF 3 of the cosmid clones were novel iturin biosynthesis genes. 
         [0036]    In a specific example of the present invention, antifungal activities of iturin and surfactin were examined against three kinds of test microorganisms, the rice blast fungus  Magnaporthe grisea , the fungus causing athlete&#39;s foot  Trichophyton mentagrophytes , and the fungus causing wilt disease of the family Solanaceae  Fusarium oxysporum . Consequently, as shown in  FIG. 10 , standard compounds iturin A and surfactin showed antifungal activities against  Magnaporthe grisea  and  Trichophyton mentagrophytes . Iturin showed antifungal activity against  Fusarium oxysporum , whereas surfactin did not show antifungal activity against  Fusarium oxysporum  ( FIG. 10 ). 
         [0037]    Also in a specific example of the present invention, when antifungal activity was examined using the supernatant of culture broth of  Bacillus  producing iturin or surfactin,  B. subtilis  subsp.  krictiensis  producing iturin showed antifungal activities against  Magnaporthe grisea, Trichophyton mentagrophytes , and  Fusarium oxysporum , just like the examination result for antifungal activities using standard compounds. On the other hand,  B. subtilis  JH642 and  B. subtilis  168 which do not produce antibiotics did not showed antifungal activities against the above test microorganisms.  B. subtilis  C9 which is assumed to produce both surfactin and iturin showed antifungal activities against  Fusarium oxysporum  against which iturin showed antifungal activity. Based on these results, the present inventors decided to use  Fusarium oxysporum  as a test microorganism for selecting iturin mutants ( FIG. 11 ). 
         [0038]    Also in a specific example of the present invention, the present inventors transformed fragments of cosmid clones into  B. subtilis  subsp.  krictiensis  ( FIG. 12 ), and then observed antifungal activity against  Fusarium oxysporum . Consequently, pBT6 fragment (including ORF 2-2 and ORF 3) showed the strongest antifungal activity against  Fusarium oxysporum  in the transformed  B. subtilis  subsp.  krictiensis  ( FIG. 13 ). 
         [0039]    Also in a specific example of the present invention, to confirm that among fragments of cosmid clones responsible for iturin biosynthesis, pBT6 is the region related to iturin biosynthesis, pJJ121E2 fragment containing pBT6 fragment was cloned into pTZ18 vector, and p121E3 vector having a spectinomycin-resistant gene was digested with BamHI and XbaI, and a ClaI site was attached thereto by PCR, and then, the fragment was digested with ClaI. Again, the ClaI-digested spectinomycin-resistant gene-containing fragment was inserted into the ClaI site of the pTZ18 vector into which pJJ121E2 fragment was inserted, and a SalI site was removed to prepare pJJ121E2-1 vector. Then,  B. subtilis  subsp.  krictiensis  was transformed with pJJ121E2-1 vector ( B. subtilis  subsp.  krictiensis  mutant-10) and whether the ability for iturin biosynthesis is lost or not was examined ( FIG. 14 ). Consequently,  B. subtilis  subsp.  krictiensis  showed a strong antifungal activity against  Fusarium oxysporum , whereas  B. subtilis  subsp.  krictiensis  mutant-10 showed significantly decreased antifungal activity ( FIG. 15 ). In addition, as shown in  FIG. 16 , it was confirmed that the spectinomycin-resistant gene was inserted into the chromosome of  B. subtilis  subsp.  krictiensis  mutant-10 strain through Southern hybridization ( FIG. 16 ). 
         [0040]    Also in a specific example of the present invention, metabolites of  B. subtilis  subsp.  krictiensis  and  B. subtilis  subsp.  krictiensis  mutant-10 strain were analyzed by HPLC. Consequently, peaks observed in both  B. subtilis  subsp.  krictiensis  and the commercially available standard compound iturin A were identical, whereas the peak of iturin A was not observed in  B. subtilis  subsp.  krictiensis  mutant-10 strain ( FIG. 17 ). The molecular weights for these peaks were determined by LC-Mass, and consequently, it was confirmed that peaks which were observed in  B. subtilis  subsp.  krictiensis , but not in  B. subtilis  subsp.  krictiensis  mutant-10 corresponded exactly to iturins A to F ( FIG. 18  to  FIG. 20 ). 
         [0041]    That is, the present inventors cloned iturin biosynthesis genes derived from  B. subtilis  subsp.  krictiensis , analyzed the cloned gene sequences, and confirmed that these are novel iturin biosynthetic genes of which sequences are different from those of the previously known cyclic lipopeptide biosynthetic genes. 
         [0042]    The present invention also provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:5, or iturin protein encoded by the iturin biosynthesis gene. 
         [0043]    Furthermore, the present invention provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:3, or iturin protein encoded by the iturin biosynthesis gene. 
         [0044]    The present invention also provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:7, or iturin protein encoded by the iturin biosynthesis gene. 
         [0045]    Furthermore, the present invention provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:8, or iturin protein encoded by the iturin biosynthesis gene. 
         [0046]    In the iturin biosynthesis gene, the nucleotide sequence of SEQ ID NO:6 may comprise ORF 3 of the iturin biosynthesis gene, the nucleotide sequence of SEQ ID NO:3 may comprise ORF 2 of the iturin biosynthesis gene, and the nucleotide sequence of SEQ ID NO:5 may comprise ORF 2-2, one part of ORF 2 of the iturin biosynthesis gene, but the present invention is not limited to such. In addition, the protein encoded by the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:6 may have nucleotide sequence of SEQ ID NO:14, the protein encoded by the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:3 may have nucleotide sequence of SEQ ID NO:11, and the protein encoded by the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:5 may have nucleotide sequence of SEQ ID NO:13, but the present invention is not limited to such. 
         [0047]    Also, in the iturin biosynthesis gene, the nucleotide sequence of SEQ ID NO:7 may comprise ORF 4 of the iturin biosynthesis gene, and the nucleotide sequence of SEQ ID NO:8 may comprise ORF 5 of the iturin biosynthesis gene, but the present invention is not limited to such. In addition, the protein encoded by the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:7 may have nucleotide sequence of SEQ ID NO:15, and the protein encoded by the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:8 may have nucleotide sequence of SEQ ID NO:16, but the present invention is not limited to such. 
         [0048]    The nucleotide sequence of SEQ ID NO:3 is characterized by the entire nucleotide sequence of ORF 2 of the iturin biosynthesis gene, and in order to determine a specific region encoding the iturin biosynthesis gene, the present inventors divided ORF 2 region into ORF 2-1 (SEQ ID NO:4) and ORF 2-2 (SEQ ID NO:5) to use in Examples. 
         [0049]    In a specific example, when the iturin biosynthetic genes were compared to amino acids of other cyclic lipopeptide biosynthetic genes, there was a significant difference in the size of the entire iturin gene. Thus, the present inventors prepared fragments including ORFs which compose the iturin biosynthesis gene and experimented to identify regions responsible for iturin biosynthesis protein. Consequently, the present inventors confirmed that when the vector comprising nucleotide sequences of ORF 2-2 and ORF 3 was used, antifungal activity of iturin protein was elevated, thereby identifying the gene responsible for iturin biosynthesis. 
         [0050]    The present invention also provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6, SEQ ID NO:3, and SEQ ID NO:7, or iturin protein encoded by the iturin biosynthesis gene. 
         [0051]    Furthermore, the present invention provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6, SEQ ID NO:3, and SEQ ID NO:8, or iturin protein encoded by the iturin biosynthesis gene. 
         [0052]    The present invention also provides an iturin biosynthesis gene having nucleotide sequences of SEQ ID NO:6, SEQ ID NO:7, and SEQ ID NO:8, or iturin protein encoded by the iturin biosynthesis gene. 
         [0053]    The nucleotide sequence of SEQ ID NO:6 of the iturin biosynthesis gene may comprise ORF 3 of the iturin biosynthesis gene, the nucleotide sequence of SEQ ID NO:3 may comprise ORF 2 of the iturin biosynthesis gene, the nucleotide sequence of SEQ ID NO:7 may comprise ORF 4 of the iturin biosynthesis gene, and the nucleotide sequence of SEQ ID NO:8 may comprise ORF 5 of the iturin biosynthesis gene. But the present invention is not limited to such and any nucleotide sequence which can produce iturin proteins in iturin biosynthesis genes may be included. 
         [0054]    For the protein encoded by the iturin biosynthesis gene, the protein encoded by the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:6 may have nucleotide sequence of SEQ ID NO:14, the protein encoded by the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:3 may have nucleotide sequence of SEQ ID NO:11, the protein encoded by the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:7 may have nucleotide sequence of SEQ ID NO:15, and the protein encoded by the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:8 may have nucleotide sequence of SEQ ID NO:16. But the present invention is not limited to such and any nucleotide sequence which can produce iturin proteins in iturin biosynthesis genes may be included. 
         [0055]    Furthermore, the present invention provides an iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:1, or iturin protein encoded by the iturin biosynthesis gene. 
         [0056]    In the iturin biosynthesis gene, the nucleotide sequence of SEQ ID NO:1 may comprise seven nucleotide sequences of ORFs 1 to 6 included in the iturin biosynthesis gene shown in  FIG. 9 , but the present invention is not limited to such. 
         [0057]    In a specific example, the nucleotide sequence exhibited a significant difference, compared to conventional genes responsible for iturin biosynthesis, and thereby, the present inventors found that the nucleotide sequence is the novel iturin biosynthesis gene. Among ORFs composing the iturin biosynthesis gene, antifungal activity of the transformant comprising the fragment which comprises a part of ORF 2 (ORF 2-2) and ORF 3 was the most increased. Antifungal activity of transformant comprising the fragment which comprises other ORFs was confirmed. 
         [0058]    Therefore, the present inventors identified the novel iturin biosynthesis gene having the nucleotide sequence of SEQ ID NO:1. 
         [0059]    Furthermore, the present invention provides a vector comprising nucleotide sequence of the iturin biosynthesis gene in accordance with the present invention. 
         [0060]    The nucleotide sequence of iturin biosynthesis gene which is included in the vector may comprise the iturin biosynthesis gene having nucleotide sequence of SEQ ID NO:1, preferably the gene having nucleotide sequences of SEQ ID NO:6, SEQ ID NO:3, and SEQ ID NO:7, the gene having nucleotide sequences of SEQ ID NO:6, SEQ ID NO:3, and SEQ ID NO:8, or the gene having nucleotide sequences of SEQ ID NO:6, SEQ ID NO:7, and SEQ ID NO:8, preferably the gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:5, the gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:3, the gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:7, or the gene having nucleotide sequences of SEQ ID NO:6 and SEQ ID NO:8, and more preferably, the gene having nucleotide sequence of SEQ ID NO:6, or the iturin biosynthesis gene having 95% or more sequence identity to the gene having nucleotide sequence of SEQ ID NO:6. But, the present invention is not limited to such. 
         [0061]    The present invention also provides a transformant transformed with the vector comprising nucleotide sequence of the iturin biosynthesis gene in accordance with the present invention. 
         [0062]    Furthermore, the present invention provides iturin protein produced by the transformant in accordance with the present invention. 
         [0063]      Bacillus subtilis, Saccharomyces cerevisiae , and  Bacillus amyloliquefaciens  may be used for the transformant, but the present invention is not limited to such. In addition, methods for introducing the recombinant vector into the strain may be heat-shock method, electroporation method, and preferably Spizizen method, but they are not limited to such. Known techniques may be used for introduction. 
         [0064]    In the iturin protein encoded by the iturin biosynthesis gene in accordance with the present invention, iturin proteins may be encoded by the vector comprising the gene or the transformant, but the present invention is not limited to such. 
         [0065]    In a specific example, it was confirmed that antifungal activity of the strain which was transformed with the vector comprising nucleotide sequences in accordance with the present invention was increased. Therefore, culture broth of the transformed strain may be used as a biological control agent and such transformant itself may be efficiently used as a biological control agent. By using the transformant itself, it may be possible to reduce processes, transportation, and storage that are required for obtainment of iturin proteins. 
         [0066]    The present invention also provides a biological control agent comprising the transformant producing the iturin in accordance with the present invention or its culture broth. 
         [0067]    Furthermore, the present invention provides the transformant of the present invention or its culture broth for use as a biological control agent, or the iturin protein produced by the transformant of the present invention for use as a biological control agent. 
         [0068]    The iturin protein, the transformant producing iturin protein, and its culture broth in accordance with the present invention may have control effect against rice blast pathogen  Magnaporthe grisea , wilt pathogen  Fusarium oxysporum , gray mold rot pathogen  Botrytis cinerea , barley powdery mildew pathogen  Erysiphe graminis  f. sp.  hordei , tomato leaf mold pathogen  Fulvia fulva , anthracnose pathogen  Colletotrichum gloeosporioides , Ginseng root rot pathogen  Cylindrocarpon destructans , the pathogen of damping-off of ginseng  Rhizoctonia solani , the pathogen of  Alternaria  leaf spot of green onions  Alternaria porri , the pathogen of  Alternaria  leaf spot of apples  Alternaria mali , the pathogen of  Alternaria  blight of ginseng  Alternaria panax , the pathogen of damping-off of ginseng  Pythium  sp. or  Salmonella typhimurium , and preferably against rice blast pathogen  Magnaporthe grisea  and wilt pathogen  Fusarium oxysporum , but the present invention is not limited to such. 
         [0069]    In a specific example, the present inventors transformed  B. subtilis  subsp.  krictiensis  with the fragments of cosmid clones and observed antifungal activity against  Fusarium oxysporum . As a result, the present inventors observed that the pBT6 fragment-transformed  B. subtilis  subsp.  krictiensis  showed remarkably increased antifungal activity, compared to untransformed control  B. subtilis  subsp.  krictiensis.    
         [0070]    Therefore, the iturin protein encoded by novel iturin biosynthesis genes identified in the present invention, the transformant producing thereof, and culture broth thereof may be used effectively as biological control agents. 
         [0071]    As stated above, through gene cloning, base sequence determination, and antifungal activity examination, the present inventors identified iturin biosynthesis genes from  B. subtilis  strain producing six kinds of iturins described in the present invention. In addition, through mutants and instrumental analyses, the present inventors reconfirmed that metabolites are iturins and confirmed that the genes are novel genes which are different from the genes reported up to date. Based on these, it is considered that with the use of iturin biosynthesis genes, strains may be modified to antifungal activity-enhanced strains to use as a biological control agent. On the other hand, it is considered that the gene may be transformed into bacteria showing other biological control activities, and thus, be applied to novel strain development. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0072]    The above and other objects, features and other advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which: 
           [0073]      FIG. 1  is an electrophoresis photo for verifying PCR products obtained from  B. subtilis  subsp.  krictiensis  ATCC 55079 and  B. subtilis  168 strain: 
           [0074]    Lane 1:1 kb ladder; 
           [0075]    Lane 2: PCR products obtained from  B. subtilis  168 strain by using SrfB7 and SrfB8 primers (products of surfactin gene); 
           [0076]    Lane 3: PCR products obtained from  B. subtilis  subsp.  krictiensis  strain by using SrfB7 and SrfBB primers (products of putative iturin gene); 
           [0077]    Lane 4: PCR products obtained from  B. subtilis  168 strain by using SrfB9 and SrfB10 primers (products of surfactin gene); and 
           [0078]    Lane 5: PCR products obtained from  B. subtilis  subsp.  krictiensis  strain by using SrfB9 and SrfB10 primers (products of putative iturin gene). 
           [0079]      FIG. 2  is a figure showing comparative analysis of the amino acid sequence obtained from  B. subtilis  subsp.  krictiensis  strain by using SrfB9 and SrfB10 primers with the amino acid sequence of surfactin biosynthesis gene and the amino acid sequence of lichenysin biosynthesis gene using CLUSTAL W: 
           [0080]    1: amino acid sequence of the PCR product obtained from  B. subtilis  subsp.  krictiensis  strain by using SrfB9 and SrfB10 primers (amino acid sequence of product of putative iturin gene); 
           [0081]    2, 3, 4: amino acid sequence of three different domains of the surfactin biosynthesis gene; and 
           [0082]    5: amino acid sequence of the lichenysin biosynthesis gene. 
           [0083]      FIG. 3  is a figure showing nucleotide and peptide sequences of 0.4 kb PCR product obtained from  B. subtilis  subsp.  krictiensis  strain by using SrfA5 and SrfA6 primers. 
           [0084]      FIG. 4  is a figure showing comparative analysis of the amino acid sequence of PCR product obtained from  B. subtilis  subsp.  krictiensis  strain by using SrfA5 and SrfA6 primers with amino acid sequences of other strains using CLUSTAL W: 
           [0085]    1: amino acid sequence of an acyl carrier protein reductase of  Cuphea lanceolata  plant; 
           [0086]    2: amino acid sequence of an acyl carrier protein reductase of  Bacillus subtilis  strain; 
           [0087]    3: amino acid sequence of an acyl carrier protein reductase of  Salmonella typhimurium  strain; 
           [0088]    4: amino acid sequence of an acyl carrier protein reductase of  Deinococcus radiodurans  strain; and 
           [0089]    5: amino acid sequence of PCR product obtained from  B. subtilis  subsp.  krictiensis  strain using SrfA5 and SrfA6 primers. 
           [0090]      FIG. 5  is a figure showing the result of genomic library screening of  B. subtilis  subsp.  krictiensis:    
           [0091]      FIG. 5A  is a figure showing the result of colony hybridization; 
           [0092]      FIG. 5B  is the result of agarose electrophoresis after digesting the DNAs of cosmid clones obtained by colony hybridization with EcoRI; and 
           [0093]      FIG. 5C  is a figure showing the result of Southern hybridization, in which two clones exhibited homology with radioisotope-labeled probe DNA. 
           [0094]      FIG. 6  is a restriction enzyme map of cosmid clones obtained by genomic library screening. 
           [0095]      FIG. 7A  to  FIG. 7F  are figures showing the results of hybridization at 65° C. of EcoRI-digested fragments of pJJ815 and pJJ121 clones obtained by genomic library screening from  B. subtilis  subsp.  krictiensis  and  B. subtilis  168 strain: 
           [0096]    Lane 1: lambda DNA digested with HindIII; 
           [0097]    Lane 2: genomic DNA of  B. subtilis  subsp.  krictiensis;    
           [0098]    Lane 3: genomic DNA of  B. subtilis  168; and 
           [0099]    Lane 4: probe DNA. 
           [0100]      FIG. 8A  to  FIG. 5F  are figures showing the results of hybridization at 50° C. of EcoRI-digested fragments of pJJ815 and pJJ121 clones obtained by genomic library screening from  B. subtilis  subsp.  krictiensis  and  B. subtilis  168: 
           [0101]    Lane 1: lambda DNA digested with HindIII; 
           [0102]    Lane 2: genomic DNA of  B. subtilis  subsp.  krictiensis;    
           [0103]    Lane 3: genomic DNA of  B. subtilis  168; and 
           [0104]    Lane 4: probe DNA. 
           [0105]      FIG. 9  shows genetic organization of iturin biosynthesis gene obtained by genomic library screening from  B. subtilis  subsp.  krictiensis  strain: 
           [0106]    ORF1: transcriptional regulator; 
           [0107]    ORF2-1: Itu A-1; 
           [0108]    ORF2-2: Itu A-2; 
           [0109]    ORF3: Itu B; 
           [0110]    ORF4: Itu C; 
           [0111]    ORF5: Itu D; and 
           [0112]    OFR6: asparate transaminase-like protein. 
           [0113]      FIG. 10  is a figure showing comparison of antifungal activity of standard compounds, iturin and surfactin. 
           [0114]      FIG. 11  is a figure showing comparison of antifungal activity of  B. subtilis  subsp.  krictiensis, B. subtilis  168,  B. subtilis  JH642, and  B. subtilis  C9 against three kinds of test microorganisms: 
           [0115]    Wild type:  B. subtilis  subsp.  krictiensis  producing iturin; 
           [0116]      B. subtilis  168:  B. subtilis  strain having surfactin gene but not producing surfactin; 
           [0117]      B. subtilis  JH642:  B. subtilis  strain producing neither iturin nor surfactin; and 
           [0118]      B. subtilis  C9: putative  B. subtilis  strain producing both surfactin and iturin. 
           [0119]      FIG. 12  shows EcoRI fragments of cosmid clones and construction of the vector comprising the fragments. 
           [0120]      FIG. 13  is a figure showing comparison of antifungal activity of  B. subtilis  subsp.  krictiensis  transformants containing various EcoRI fragments derived from cosmid clones: 
           [0121]    1: pBT1 fragments; fragments of cosmid pJJ121 digested with SmaI and EcoRI 
           [0122]    2: pBT3 fragments; EcoRI fragments of cosmid pJJ815 
           [0123]    3: pBT6 fragments; EcoRI fragments of cosmid pJJ121 
           [0124]    4: untransformed  B. subtilis  subsp.  krictiensis  strain. 
           [0125]      FIG. 14  is a schematic diagram of construction of a vector for preparing an iturin-less mutant. 
           [0126]      FIG. 15  is a figure showing comparison of antifungal activity of  B. subtilis  subsp.  krictiensis  producing iturin and the iturin-less mutant against  Fusarium oxysporum.    
           [0127]      FIG. 16  shows the result of Southern hybridization for examining whether spectinomycin which was inserted within the mutant was inserted into chromosomes or not: 
           [0128]    Lane 1:1 kb ladder; 
           [0129]    Lane 2: fragments of genomic DNA of B, subtilis subsp.  krictiensis  strain digested with ClaI; 
           [0130]    Lane 3: fragments of genomic DNA of  B. subtilis  subsp.  krictiensis  mutant-10 strain digested with ClaI; and 
           [0131]    Lane 4: p121E3 vector digested with BamHI and XbaI. 
           [0132]      FIG. 17  is a HPLC chromatogram for examining whether iturin was produced or not from  B. subtilis  subsp.  krictiensis  and the iturin-less mutant. 
           [0133]      FIG. 18  is HPLC chromatograms for analyzing six kinds of iturins produced by  B. subtilis  subsp.  krictiensis:    
           [0134]    A: Iturin A; 
           [0135]    B: Iturin B; 
           [0136]    C: Iturin C; 
           [0137]    D: Iturin D; 
           [0138]    E: Iturin E; and 
           [0139]    F: Iturin F. 
           [0140]      FIG. 19  shows the result of LC-Mass analysis for examining whether iturin A, B, and C among six iturins were produced from  B. subtilis  subsp.  krictiensis.    
           [0141]      FIG. 20  shows the result of LC-Mass analysis for examining whether iturin D, E, and F among six iturins were produced from  B. subtilis  subsp.  krictiensis.    
       
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       [0142]    Hereinafter, the present invention will be described in more detail with reference to examples. 
         [0143]    However, the following examples and experimental examples are provided for illustrative purposes only, and the scope of the present invention is not limited thereto. 
       Example 1 
       [0144]    Culture of  Bacillus  Strains 
         [0145]      B. subtilis  subsp.  krictiensis  ATCC 55079 was a strain isolated by the present inventors, and the strain was described in U.S. patent. The strain was also deposited in American Type Culture Collection (ATCC).  B. subtilis  168,  B. subtilis  JH642, and  B. subtilis  C9 used in examples of the present invention were provided from Bio-Chemical Research Center at Korea Research Institute of Bioscience and Biotechnology. 
         [0146]      Bacillus subtilis  and  E. coli  were cultured in an LB medium (Bacto-tryptone 10 g, Bacto-yeast extract 5 g, sodium chloride 10 g/L). For a medium of  Bacillus subtilis  strains for producing active materials, a complex medium (sucrose 30 g, soytone 10 g, yeast extract 5 g, K 2 HPO 4  0.5 g, MgSO 4  2 g, MnCl 2  4 mg, CaCl 2  5 mg, FeSO 4 .7H 2 O 25 mg, pH 7.0/L) was used. 
         [0147]    For transformation, Spizizen&#39;s medium (50% glucose 10 mL, 2% casein hydrolysate 10 mL, 10% yeast extract 10 mL, 1 M MgCl 2  2.25 mL, KH 2 PO 4  6 g, K 2 HPO 4  14 g, (NH 4 ) 2 SO 4  2 g, Sodium citrate 1 g, MgSO 4  0.2 g/L) was used. 
       Example 2 
       [0148]    Construction of Genomic Library of  B. subtilis  Subsp.  krictiensis    
         [0149]    &lt;2-1&gt; Extraction of Chromosomal DNA from  B. subtilis  subsp.  krictiensis    
         [0150]    Since surfactin and iturin, which are cyclic lipopeptide antibiotics, are similar in molecular weights and different from each other only in amino acid composition and sequences, and surfactin gene is as large enough to be 32 kb in size, the present inventors thought that the size of iturin gene is similar to that of surfactin gene, and assumed that these two antibiotics are synthesized using the same biosynthetic pathway up to some steps, and then, from the established step, two antibiotics are synthesized using different biosynthetic pathways. 
         [0000]    
       
                 
         
             
             
         
       
     
         [0151]    Especially, cyclization of peptides and acylation process of connecting peptides and fatty acids during the biosynthetic process of two antibiotics are assumed to utilize the same pathway for biosynthesis of surfactin and iturin. Various kinds of primers were designed from nucleotide sequence of  B. subtilis  168 which is known to produce surfactin, and PCR was conducted. By conducting PCR with the chromosomal DNAs of  B. subtilis  168 strain and  B. subtilis  subsp.  krictiensis  strain as the template, a 1.8 kb PCR product which was produced from both two strains was obtained. The sequence of the gene product was determined and whether the gene product is associated with a peptide synthetase or not was examined. Then, the present inventors tried to clone iturin biosynthetic genes by colony hybridization and Southern hybridization. 
         [0152]    First, in order to extract DNAs from  B. subtilis  subsp.  krictiensis  and  B. subtilis  168, each single colony of two strains was inoculated into 250 mL of LB medium, and cultured at 30° C., 250 rpm, until late logarithmic phase (A 600nm =1.0-2.0), and then centrifuged (8,000×g, 10 min, RT). The pellets were washed with 100 mL of lysis buffer [100 mM Tris-HCl, 1 mM EDTA, 10% SDS, pH 8.0] and suspended into 40 mL of lysis buffer. 100 mg of lysozyme was added thereto, and stationary culture was performed for 10 min. After stationary culture, 3 mL of 20% SDS was added thereto, and culture was performed for min. Then, 40 mL of TE-saturated phenol was added and mixed. A DNA layer was separated by centrifugation (10,000×g, 10 min, 4° C.). The DNA layer was extracted with phenol/chloroform and was isolated. 0.1 volume of 3 M sodium acetate (pH 5.2) and 2.5 volume of cooled ethanol were added to precipitate DNAs. DNAs were washed with 70% ethanol and air-dried to obtain DNA pellets. The obtained DNA pellets were dissolved in TE buffer. 
         [0153]    &lt;2-2&gt; Partial Digestion 
         [0154]    In order to determine the partial digestion condition, 10 μg of isolated DNA and buffer solution were mixed and adjusted to 150 μL, and then, 15 μL aliquots were dispensed into nine eppendorf tubes, and a 30 μL aliquot was dispensed into No. 1 tube and allowed to stand in ice. 4 unit of restriction enzyme was added to No. 1 tube and mixed well, and then, a 15 μL aliquot was transferred into No. 2 tube and mixed well. Again, a 15 μL aliquot was sequentially transferred and mixed well into each tube until No. 8 tube. No. 9 tube was used as untreated. No. 1 to No. 8 tubes were cultured at 30° C. for 1 hr, and the reaction was stopped by adding EDTA to a final concentration of 20 mM. 3 μL of gel-loading dye was added to each tube and the amount of Sau3A to obtain 20 to 30 kb DNA was determined by performing electrophoresis on 0.5% agarose gel. The cosmid vector pLAFR3 was digested with BamHI and treated with phosphatase. 
         [0155]    &lt;2-3&gt; Construction of Genomic Library of  B. subtilis  subsp.  krictiensis  in  E. coli    
         [0156]    To clone the iturin biosynthetic gene from genomic library of  B. subtilis  subsp.  krictiensis  strain, the chromosomal DNA of  B. subtilis  subsp.  krictiensis  strain extracted in Example &lt;2-1&gt; was partially digested with Sau3A. Then, 20 to 30 kb DNA fragments were inserted into cosmid vector pLAFR3 (obtained from Department of Applied Biology and Chemistry, College of Agriculture and Life Science, Seoul National University).  E. coli  HB101 was transformed with the DNA fragment-inserted cosmid vector pLAFR3 to construct the genomic library. 
       Example 3 
       [0157]    Screening of Iturin Biosynthesis Gene from  B. subtilis  subsp.  krictiensis    
         [0158]    &lt;3-1&gt; Preparation of DNA Probe 
         [0159]    Since iturin and surfactin genes are similar in their molecular weights, and their seven peptides form a cyclic ring, and it was reported that the size of surfactin gene is as large enough to be 32 kb in size, the present inventors assumed that iturin biosynthesis gene is equal to surfactin gene in size. Since some  B. subtilis  strains are reported that produce both iturin and surfactin, cyclization of peptides and acylation process of connecting fatty acids are assumed to utilize the same pathway for biosynthesis, considering each gene size. On the basis of these assumptions, primers were prepared using DNA base sequence information of surfactin gene. PCR with primer pair for surfactin gene were conducted using the genomic DNAs obtained in Example &lt;2-1&gt; from  B. subtilis  168 having surfactin gene and  B. subtilis  subsp.  krictiensis  producing iturin as the template. PCR condition was 30 cycles at 94° C. for 30 sec, 50° C. for 30 sec, 72° C. for 60 sec; and 72° C. for 5 min. The used primers are as follows: 
         [0000]    
       
         
               
             
           
               
                 SrfA1 (SEQ ID NO: 18): 
               
               
                 5′-CGG GAA AGC GCT GGG GAA TAA CCG C-3′; 
               
               
                   
               
               
                 SrfA2 (SEQ ID NO: 19): 
               
               
                 5′-CCT TCA AAG CTT TGA ACA GGT GGT C-3′; 
               
               
                   
               
               
                 SrfA3 (SEQ ID NO: 20): 
               
               
                 5′-CTC GCT TGG CGG AGA TTC CAT CAA AG-3′; 
               
               
                   
               
               
                 SrfA4 (SEQ ID NO: 21): 
               
               
                 5′-GTT CTG TCT CTT CAG CAG TCA GCG AG-3′; 
               
               
                   
               
               
                 SrfA5 (SEQ ID NO: 22): 
               
               
                 5′-GCG ATT GAT TAT GCG CTT GTT GAG-3′; 
               
               
                   
               
               
                 SrfA6 (SEQ ID NO: 23): 
               
               
                 5′-TCG GCA CAT ACG CTG ATT GAA CTG C-3′; 
               
               
                   
               
               
                 SrfA7 (SEQ ID NO: 24): 
               
               
                 5′-GGG TAA AGG ATC GCC TCA ATC GTT-3′; 
               
               
                   
               
               
                 SrfA8 (SEQ ID NO: 25): 
               
               
                 5′-CGA AAT AGG CTA TCT CGC ACT CAG-3′; 
               
               
                   
               
               
                 SrfA9 (SEQ ID NO: 26): 
               
               
                 5′-TTC AGA ATA GGG CTT ATC AAG CA-3′; 
               
               
                   
               
               
                 SrfA10 (SEQ ID NO: 27): 
               
               
                 5′-GCT GTG TTG CCG CCT TTA TCT TTG A-3′; 
               
               
                   
               
               
                 SrfB1 (SEQ ID NO: 28): 
               
               
                 5′-ATG TCT CAG ATG CAT GGA GC-3′; 
               
               
                   
               
               
                 SrfB2 (SEQ ID NO: 29): 
               
               
                 5′-CTG GCA ACT AAT AGG CTG AC-3′; 
               
               
                   
               
               
                 SrfB3 (SEQ ID NO: 30): 
               
               
                 5′-ATT GAA GCT TGT GCC GCC TG-3′; 
               
               
                   
               
               
                 SrfB4 (SEQ ID NO: 31): 
               
               
                 5′-TCC TTT AAA GCT TTG CAC AG-3′; 
               
               
                   
               
               
                 SrfB5 (SEQ ID NO: 32): 
               
               
                 5′-GAA ACA GCA GCG ATT ATG AAC GAC-3′; 
               
               
                   
               
               
                 SrfB6 (SEQ ID NO: 33): 
               
               
                 5′-AGA CAT CGA GCC AGT ATT CCT CAT C-3′; 
               
               
                   
               
               
                 SrfB7 (SEQ ID NO: 34): 
               
               
                 5′-ATT TCG AGC GGC CAG CTG AAC G-3′; 
               
               
                   
               
               
                 SrfB8 (SEQ ID NO: 35): 
               
               
                 5′-TTT CAT CCG GCG CCG TAT AGG TTT-3′; 
               
               
                   
               
               
                 SrfB9 (SEQ ID NO: 36): 
               
               
                 5′- GCA AAA TTT CCG GAC AGC GGG ATA T-3′; 
               
               
                 and 
               
               
                   
               
               
                 SrfB10 (SEQ ID NO: 37): 
               
               
                 5′- TCG ATC CGG CCG ATG TAT TCA AT-3′. 
               
             
          
         
       
     
         [0160]    Electrophoresis of PCR products was conducted, and each gene product obtained from  B. subtilis  168 and  B. subtilis  subsp.  krictiensis  was investigated. When PCR was conducted using SrfB9 and SrfB10 primer pair, about 1.8 kb of a DNA fragment, which has the same size as gene products of  B. subtilis  168, derived from  B. subtilis  subsp.  krictiensis  was observed ( FIG. 1 ). The present inventors used the DNA fragment as the probe for screening the genomic library constructed in Example 2. 
         [0161]    &lt;3-2&gt; Sequence Comparison Between the Screened Iturin Biosynthesis Gene and Peptide Biosynthesis Genes 
         [0162]    Amino acid sequence of the putative probe for iturin biosynthesis gene obtained from  B. subtilis  subsp.  krictiensis  in Example &lt;3-1&gt; was compared to amino acid sequences of other peptide biosynthesis genes. 
         [0163]    Amino acid sequences of surfactin and lichenysin biosynthesis genes obtained by using NCBI database were compared by using CLUSTAL W program, and as shown in  FIG. 2 , the amino acid sequence obtained from  B. subtilis  subsp.  krictiensis  showed 82 to 85% homology with three different surfactin biosynthesis genes and 80% homology with the lichenysin biosynthesis gene from  B. licheniformis  ( FIG. 2 ). 
         [0164]    &lt;3-3&gt; Screening of Genes Responsible for Acylation Process of Peptides and Fatty Acids of Iturin 
         [0165]    To clone the genes responsible for acylation process of connecting peptides and fatty acids, PCR with 20 primers designed in Example &lt;3-1&gt; were performed to obtain about 0.4 kb DNA fragment. Then, nucleotide sequence for the DNA fragment was analyzed. 
         [0166]    Nucleotide and peptide sequences of 0.4 kb PCR product obtained from  B. subtilis  subsp.  krictiensis  strain by using SrfA 5 and SrfA 6 primers were shown in  FIG. 3 . 
         [0167]    To comparatively analyze amino acids shown in  FIG. 3 , the NCBI database was searched. Consequently, this gene product showed 56 to 83% homology with acyl carrier protein reductase derived from other microorganisms, and especially, it showed 83% homology with acyl carrier protein derived from other  B. subtilis  ( FIG. 4 ). 
         [0168]    &lt;3-4&gt; Screening of Iturin Biosynthesis Genes Using Colony Hybridization 
         [0169]    To search for iturin biosynthesis genes, colony hybridization was performed using the genomic library of  B. subtilis  subsp.  krictiensis  constructed in Example &lt;2-3&gt;. 
         [0170]    To use the 1.8 kb DNA fragment obtained from  B. subtilis  subsp.  krictiensis  in Example &lt;3-1&gt; as a probe for colony hybridization, the 1.8 kb DNA fragment was boiled at 100° C. for min for denaturation and cooled rapidly in ice. Reaction solution was prepared with 5 μL of a labeling buffer (5×), 2 μL of dNTP mixed solution, 7 μL of denatured DNA template, 2 μL of BSA (10 mg/mL), 5 μL of  32 P-CTP, 1 μL of Klenow enzyme, and 3 μL of D.W. and allowed to react with the 1.8 kb DNA fragment at 37° C. for 1 hr. Then, the reaction was stopped with 0.5 M EDTA. 2.5 μL of 3 N NaOH was added thereto, allowed to react again at 37° C. for 1 hr, and then, the reactant was used as a probe. 
         [0171]    First, the genomic library of  B. subtilis  subsp.  krictiensis  constructed in &lt;Example 2&gt; was spread to produce 100 to 200 colonies per plate onto LB plate medium to which tetracycline was added to a final concentration of 10 μg and cultured overnight at 37° C. until the colony size becomes about 1 mm in diameter. Colonies were transferred to a nylon membrane, and the membrane was cultured in 10% SDS for 5 min, a denaturing solution [0.5 N NaOH, 1.5 M NaCl] for 5 min, and a neutralizing solution [1.5 N NaCl, 0.5 M Tris-HCl, pH 7.4] for 5 min, and then washed with 2×SSC solution [20×SSC solution was 10-fold diluted to use; 20×SSC solution consists of 0.15 M NaCl, 0.01 M sodium citrate, and 0.001 M EDTA.] and dried, and then baked in a vacuum oven at 80° C. for 1 to 2 hrs. Then, the membrane was treated with a prehydridization solution [1 mM EDTA, 250 mM Na 2 HPO 4 , 1% casein hydrolysate, 7% SDS, pH 7.4] and allowed to react at 80° C. for 2 hrs. Labeled probe mix [14 μL of template DNA, 5 μL of 5×labeling buffer solution (Promega), 1 μL of dNTP (ATP, TTP, GTP), 1 μL of Klenow enzyme, 2 μL of  32 P-dCTP] was added to the membrane and allowed to react for overnight. After reaction, the membrane was washed with washing solutions [Washing solution I: 20×SSC 10 mL, 10% SDS 1 mL, distilled water 89 mL; Washing solution II: 20×SSC 10 mL, 10% SDS 10 mL, distilled water 80 mL; Washing solution III: 20×SSC 0.5 mL, 10% SDS 1 mL, distilled water 98.5 mL], and exposed to X-ray film. Then, the exposed positive colonies were selected. 
         [0172]    Consequently, as shown in  FIG. 5A , it was observed that colonies showing homology with the DNA fragment obtained from  B. subtilis  subsp.  krictiensis  appeared ( FIG. 5A ). 
         [0173]    &lt;3-5&gt; Screening of Iturin Biosynthesis Genes Using Southern Hybridization 
         [0174]    To clone iturin biosynthesis genes from genomic library of wild type  B. subtilis  subsp.  krictiensis , the genomic DNA of wild type  B. subtilis  was partially digested with Sau3A to obtain DNA fragments with various sizes. Among them, various kinds of DNA fragments with 20 to 30 kb were inserted into cosmid vector pLAFR3 to construct the genomic library in  E. coli  HB01. Then, the obtained various kinds of colonies were digested with EcoRI and each clone was analyzed using Southern hybridization. 
         [0175]    As shown in  FIG. 5B , clones digested with EcoRI restriction enzyme were electrophoresed on 0.7% agarose gel, and dyed with ethidium bromide, and allowed to react with Solution I [Tris-HCl 100 mM, NaCl 150 mM, pH 7.5] for 15 min, and then allowed to react with Solution II [Tris-HCl 100 mM, NaCl 150 mM, blocking reagent 0.5%, pH 7.5] for 30 min. After reaction, the gel was allowed to react with Solution III [Tris-HCl 100 mM, NaCl 100 mM/L, MgCl 2  100 mM, pH 9.5] for 30 min, and a nylon membrane was put on the gel, and DNA fragments were transferred to the membrane. The DNA fragments-transferred membrane was dried and hybridization was performed. During hybridization, the membrane was washed with a hybridization buffer solution containing no probe [1 mM EDTA, 250 mM Na 2 HPO 4 , 1% casein hydrolysate, 7% SDS, pH 7.4] for 2 hrs, and then washed twice with each solution, in order of Solution I, Solution II, and Solution III, 15 mL per each wash and solution was removed. Then, labeled probe mix [14 μL of template DNA, 5 μL of 5×labeling buffer solution (Promega), 1 μL of dNTP (ATP, TTP, GTP), 1 μL of Klenow enzyme, 2 μL of  32 P-dCTP] was added to the membrane and allowed to react for overnight. After reaction, probe DNA was removed and the membrane was dried, put on a X-ray film, allowed to stand at −70° C. for overnight, and the X-ray film was developed ( FIG. 5C ). 
         [0176]    Consequently, as shown in  FIG. 5B  and  FIG. 5C , it was confirmed that sequence of the DNA probe obtained from  B. subtilis  subsp.  krictiensis  existed in two lanes, and these two clones were named as pJJ815 and pJJ121, respectively. 
       Example 4 
       [0177]    Construction of Restriction Enzyme Map of pJJ815 and pJJ121 Clones 
         [0178]    Restriction enzyme map of pJJ815 and pJJ121 clones obtained in &lt;Example 3&gt; was constructed. When the above two clones were digested with SmaI and EcoRI, and their restriction enzyme maps were constructed, the clone pJJ121 was divided into pJJ121E2 (the part of ORF 2-2 to ORF 3, 8,020˜2,3480 bp in SEQ ID NO:1), pJJ121E3 (the part of ORF 3˜ORF 4), pJ815E4 (the part of ORF 4), pJJ815E6 (the part of ORF 4˜yczE, 29,167 bp˜32,819 bp in SEQ ID NO:1) and the clone pJJ815 was divided into pJJ121E2, pJJ121E3, pJJ815E4, pJJ815E6, pJJ815E5, pJJ815E2 (the part of yczE˜ycyA) ( FIG. 9 ). 
       Example 5 
       [0179]    Southern Hybridization Using the Clones pJJ815 and pJJ121 
         [0180]    To examine whether the cosmid clones pJJ815 and pJJ121 obtained by screening the genomic library of  B. subtilis  subsp.  krictiensis  are genes associated with iturin biosynthesis or not, the cosmid clones pJJ815 and pJJ121 were digested with EcoRI and genomic Southern hybridization was performed using  B. subtilis  168 which is known to produce surfactin and  B. subtilis  subsp.  krictiensis.    
         [0181]    &lt;5-1&gt; Construction of Probes Required for Southern Hybridization 
         [0182]    To perform genomic Southern hybridization, six fragments (pJJ121E2, pJJ121E3, pJJ815E4, pJJ815E5, pJJ815E6, and pJJ815E2) by digesting the clones with EcoRI were constructed as probes. Specifically, six fragments obtained by cloning cosmid clones pJJ121 and pJJ815 stated in Example &lt;2-3&gt; in  E. coli  HB101 and digesting with EcoRI were used as probes and each fragment was labeled with  32 P-dCTP isotope by the same method described in Example &lt;3-4&gt; and used for hybridization experiment. 
         [0183]    &lt;5-2&gt; Southern Hybridization Reaction Depending on Temperature 
         [0184]    Using six fragments (pJJ121E2, pJJ121E3, pJJ815E4, pJJ815E5, pJJ815E6, and pJJ815E2) prepared in Example &lt;5-1&gt; as probes, Southern hybridization was performed with chromosomal DNAs of  B. subtilis  subsp.  krictiensis  and  B. subtilis  168. In addition, Southern hybridization was performed at 50° C. and 65° C. to examine the effect of Southern hybridization temperature on the reaction. 
         [0185]    First, clones in which genomic DNAs of  B. subtilis  subsp.  krictiensis  and  B. subtilis  168 were digested with EcoRI were electrophoresed on 0.7% agarose gel, and dyed with ethidium bromide, and allowed to react with Solution I [Tris-HCl 100 mM, NaCl 150 mM, pH 7.5] for 15 min, and then allowed to react with Solution II [Tris-HCl 100 mM, NaCl 150 mM, blocking reagent 0.5%, pH 7.5] for 30 min. After reaction, the gel was allowed to react with Solution III [Tris-HCl 100 mM, NaCl 100 mM/L, MgCl 2  100 mM, pH 9.5] for 30 min, and a nylon membrane was put on the gel, and DNA fragments were transferred to the membrane. The DNA fragments-transferred membrane was dried and hybridization was performed. During hybridization reaction, the membrane was washed with a hybridization buffer solution containing no probe [1 mM EDTA, 250 mM Na 2 HPO 4 , 1% casein hydrolysate, 7% SDS, pH 7.4] for 2 hrs, and then washed twice with each solution, in order of Solution I, Solution II, and Solution III, 15 mL per each wash and solution was removed. Then, each  32 P-dCTP isotope-labeled probe DNA was added to the membrane and allowed to react for overnight. After reaction, probe DNA was removed and the membrane was dried, put on a X-ray film, allowed to stand at −70° C. for overnight, and the X-ray film was developed. 
         [0186]    As shown in  FIG. 7 , when Southern hybridization was performed at 65° C., it was observed that the probe DNA sequences existed in  B. subtilis  subsp.  krictiensis . However, no of six EcoRI fragments used as probes existed in the genomic DNA of  B. subtilis  168 containing the surfactin biosynthesis gene ( FIG. 7 ). 
         [0187]    In addition, when Southern hybridization was performed at 50° C., genomic DNA of  B. subtilis  168 showed only weak homology for pJJ121E3 fragment probe, but it showed the same results for other fragments as in Southern hybridization at 65° C. ( FIG. 8 ). Therefore, from the results of  FIG. 7  and  FIG. 8 , it was concluded that temperature did not affect Southern hybridization reaction. In addition, the above results taken together, six EcoRI fragments hardly showed any similarities with the surfactin biosynthesis gene isolated from  B. subtilis  168, except pJJ121E3 fragment which exhibited weak response at 50° C., whereas they showed similarities in  B. subtilis  subsp.  krictiensis , suggesting that six fragments (pJJ121E2, pJJ121E3, pJJ815E4, pJJ815E5, pJJ815E6, and pJJ815E2) which were obtained by digesting cosmid clones pJJ815 and pJJ121 are likely to be genes responsible for iturin biosynthesis. 
       Example 6 
       [0188]    Nucleotide Sequence Determination and Characterization of Iturin Biosynthesis Genes (Clones pJJ815 and pJJ121) 
         [0189]    &lt;6-1&gt; Nucleotide Sequence Determination of Iturin Biosynthesis Genes (pJJ815 and pJJ121) 
         [0190]    Bidirectional sequence was determined with EcoRI fragments cloned from the cosmid clones pJJ815 and pJJ121 to obtain 21,253 bp and to further obtain some missing gene nucleotide sequence, the present inventors obtained the genes through a genomic library screening and determined sequence to obtain a total of 37,682 bp of sequence and seven ORFs which are associated with iturin biosynthesis were found within the sequence ( FIG. 9 ). 
         [0191]    ORF 1 includes the nucleotide sequence at positions 2868 to 3219 of SEQ ID NO:1 (SEQ ID NO:2), ORF 2-1 includes the nucleotide sequence at positions 3810 to 4353 of SEQ ID NO:1 (SEQ ID NO:4), and ORF 2-2 includes the nucleotide sequence at positions 4632 to 14559 of SEQ ID NO:1 (SEQ ID NO:5). ORF 3 includes the nucleotide sequence at positions 14583 to 25341 of SEQ ID NO:1 (SEQ ID NO:6), ORF 4 includes the nucleotide sequence at positions 25378 to 29209 of SEQ ID NO:1 (SEQ ID NO:7), ORF 5 includes the nucleotide sequence at positions 29231 to 29960 of SEQ ID NO:1 (SEQ ID NO:8), and ORF 6 includes the nucleotide sequence at positions 30084 to 31392 of SEQ ID NO:1 (SEQ ID NO:9). 
         [0192]    &lt;6-2&gt; Comparison of Nucleotide Sequences Between Iturin Biosynthesis Gene ORF and Cyclic Peptide Biosynthesis Genes 
         [0193]    Each of seven ORFs which were assumed to be responsible for iturin biosynthesis was compared with other cyclic lipopeptide biosynthetic genes. 
         [0194]    Consequently, ORFs showed 76 to 86% similarity to surfactin genes derived from  B. subtilis , but they showed 92 to 100% similarity to surfactin genes derived from  B. amyloliquefaciens . Especially, ORF 2-1 (543 bp), ORF 2-2 (9,927 bp), and ORF 3 (10,757 bp) which were assumed to be directly engaged in iturin biosynthesis showed 92 to 98% similarity to surfactin genes derived from  B. amyloliquefaciens , respectively (Table 1). 
         [0195]    However, among these  B. amyloliquefaciens strains, B. amyloliquefaciens  FZB42 which shows 98% similarity is known that produce cyclic peptides surfactin, fengycin, and bacillomycin D (Chen, et al., Nature Biotechnol., 25: 1007-1014, 2007), but it has been reported that  B. amyloliquefaciens  FZB42 does not produce iturin. Accordingly, the present inventors compared homology of entire genes between  B. subtilis  subsp.  krictiensis  with  B. amyloliquefaciens  FZB42 (Table 2). 
         [0196]    Consequently, when the entire gene sequences of the above two strains were compared, they showed 98% homology, however, considering the entire size of the gene, 37,682 bp, two strains showed 2% difference, that is about 753 bp or more, and especially,  B. amyloliquefaciens  FZB42 has already been reported not to produce iturin (J. Bacteriol., 186: 1084-1096, 2004; Nature Biotechnol., 25: 1007-1014, 2007). Therefore, there is a great difference between  B. amyloliquefaciens  FZB42 and  B. subtilis  subsp.  krictiensis  producing iturin. 
         [0197]    Especially, though  B. amyloliquefaciens  FZB42 showed 92%, 98%, and 98% homology with ORF 2-1, ORF 2-2, and ORF-3, respectively, which are assumed to play a key role in iturin synthesis, there is a great difference in cyclic lipopeptide antibiotics produced by  B. amyloliquefaciens  FZB42 and  B. subtilis  subsp.  krictiensis , suggesting that iturin and surfactin are likely to share significant part of the biosynthesis pathways (Table 2, Table 3, and Table 4). 
         [0198]    In addition, the iturin biosynthesis genes derived from  B. subtilis  subsp.  krictiensis  showed 41% similarity with iturin A gene published in 2001 by the Japanese research team (K. Tsuge, et al., J. Bacteriol., 183: 6265-6273, 2001) and they showed 40% similarity with iturin A gene published by the German research team. Therefore, it was thought that the iturin biosynthesis genes derived from  B. subtilis  are likely to be novel genes (Table 5). 
         [0000]    
       
         
               
               
               
             
               
               
               
             
           
               
                 TABLE 1 
               
               
                   
               
               
                   
                   
                 Max. 
               
               
                   
                   
                 Identity 
               
               
                 ORFs 
                 Significant alignment 
                 (%) 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 ORF1 
                 (CBI41437) transcriptional regulator [ Bacillus   
                 97 
               
               
                   
                   amyloliquefaciens ] 
               
               
                   
                 (YP01419994) transcriptional regulator [ Bacillus   
                 96 
               
               
                   
                   amyloliquefaciens ] 
               
               
                 ORF2-1 
                 (CP00560) surfactin synthetase AA [ Bacillus   
                 94 
               
               
                   
                   amyloliquefaciens ] 
               
               
                   
                 (FN597644) surfactin synthetase AA [ Bacillus   
                 92 
               
               
                   
                   subtilis ] 
               
               
                 ORF2-2 
                 (CP000560) surfactin synthetases AA, AB [ Bacillus   
                 97 
               
               
                   
                   amyloliquefaciens ] 
               
               
                   
                 (AJ575642) surfactin synthetases AA, AB [ Bacillus   
                 97 
               
               
                   
                   amyloliquefaciens ] 
               
               
                   
                 (FN597644) surfactin synthetases AA, AB [ Bacillus   
                 93 
               
               
                   
                   amyloliquefaciens ] 
               
               
                 ORF3 
                 (YP0141996) surfactin synthetase AB [ Bacillus   
                 98 
               
               
                   
                   amyloliquefaciens ] 
               
               
                   
                 (CBI41439) surfactin synthetase AB [ Bacillus   
                 95 
               
               
                   
                   amyloliquefaciens ] 
               
               
                   
                 (ZP06875171) surfactin synthetase AB [ Bacillus   
                 76 
               
               
                   
                   subtilis ] 
               
               
                 ORF4 
                 (YP01419998) surfactin synthetase AC [ Bacillus   
                 96 
               
               
                   
                   amyloliquefaciens ] 
               
               
                   
                 (ZP06875172) surfactin synthetase [ Bacillus   
                 86 
               
               
                   
                   subtilis ] 
               
               
                 ORF5 
                 (AC099323) surfactin synthetase AD [ Bacillus   
                 100 
               
               
                   
                   amyloliquefaciens ] 
               
               
                   
                 (YP0141999) surfactin synthetase AD [ Bacillus   
                 99 
               
               
                   
                   amyloliquefaciens ] 
               
               
                 ORF6 
                 (ACX10665)aspartate transaminase-like protein 
                 99 
               
               
                   
                 [ Bacillus amyloliquefaciens ] 
               
               
                   
                 (CAE02535) amino transferase [ Bacillus   
                 99 
               
               
                   
                   amyloliquefaciens ] 
               
               
                   
               
             
          
         
       
     
         [0199]    The following Table 2 showed the comparative results of the entire nucleotide sequence, 37,682 bp, of the iturin biosynthesis gene and other strains including  B. subtilis  subsp.  krictiensis , using Blast N. 
         [0000]    
       
         
               
             
               
               
               
               
               
               
               
               
             
               
               
               
               
               
               
               
               
             
           
               
                 TABLE 2 
               
             
             
               
                   
               
               
                 Sequences producing significant alignments: 
               
             
          
           
               
                   
                   
                   
                   
                 Query 
                   
                 Max 
                   
               
               
                 Accession 
                 Description 
                 Max score 
                 Total score 
                 coverage 
                 E value 
                 ident 
                 Links 
               
               
                   
               
             
          
           
               
                 CP000560.1 
                   Bacillus amyloliquefaciens  FZB42, complete genome 
                 5.353e+04 
                 6.687e+04 
                 99% 
                 0.0 
                 98% 
                   
               
               
                 AJ575642.1 
                   Bacillus amyloliquefaciens  yciC gene, yx01 gene, yckc gene, yckD           
                 5.358e+04 
                 6.485e+04 
                 96% 
                 0.0 
                 98% 
                   
               
               
                 AF534916.1 
                   Bacillus  sp. CY22 surfactin synthetase gene cluster, partial sequenc 
                 7969 
                 7969 
                 13% 
                 0.0 
                 97% 
                   
               
               
                 AF233756.1 
                   Bacillus subtilis  putative surfactin synthetase (srfC) gene, partial cd 
                 7594 
                 7594 
                 12% 
                 0.0 
                 97% 
                   
               
               
                 AL009126.3 
                   Bacillus subtilis  subsp,  subtilis  str. 168 complete genome 
                 6455 
                 2.931e+04 
                 68% 
                 0.0 
                 100% 
                   
               
               
                 AY040867.1 
                   Bacillus subtilis  strain B3 putative thioesterase (srfDB3), aspartate            
                 6368 
                 6368 
                 10% 
                 0.0 
                 98% 
                   
               
               
                 X70356.1 
                   B. subtilis  srfA-sfp gene region for surfactin synthetase 
                 6346 
                 2.214e+04 
                 62% 
                 0.0 
                 85% 
                   
               
               
                 D50453.1 
                   Bacillus subtilis  DNA, 25-36 degree region 
                 6346 
                 2.394e+04 
                 67% 
                 0.0 
                 84% 
                   
               
               
                 X72672.1 
                   B. subtilis  ORF1, ORF2 and ORF3 for surfactin synthetases 
                 5053 
                 9303 
                 44% 
                 0.0 
                 79% 
                   
               
               
                 GO931469.1 
                   Bacillus amyloliquefaciens  strain B55 Sfp gene, partial cds; Asp gen           
                 4159 
                 4159 
                 6% 
                 0.0 
                 99% 
                   
               
               
                 D13262.1 
                   Bacillus subtilis  srfAA and srfAB genes for surfactin synthetase, co           
                 4048 
                 1.513e+04 
                 45% 
                 0.0 
                 79% 
                   
               
               
                 GO981471.1 
                   Bacillus amyloliquefaciens  strain B76 Sfp gene, partial cds; Asp gen           
                 3958 
                 3958 
                 6% 
                 0.0 
                 98% 
                   
               
               
                 A8062550.1 
                   Bacillus subtilis  sfp-8 gene for biosurfactants production protein of            
                 2998 
                 2998 
                 4% 
                 0.0 
                 98% 
                   
               
               
                 X77636.1 
                   B. subtilis  putative amino acid transporter gene 
                 2281 
                 2281 
                 6% 
                 0.0 
                 84% 
                   
               
               
                 GU013559.1 
                   Bacillus  sp. CS93 SrfAA gene, partial cds 
                 2037 
                 2037 
                 3% 
                 0.0 
                 98% 
                   
               
               
                 FJ904932.1 
                   Bacillus amyloliquefaciens  strain C31 SrfAD (srfAD) gene, complete 
                 1873 
                 1873 
                 2% 
                 0.0 
                 99% 
                   
               
               
                 AY009114.1 
                   Bacillus subtilis  YckJ (yckJ), Yckl (yckl), YczE(yczE), and phosphoo 
                 1829 
                 1829 
                 4% 
                 0.0 
                 86% 
                   
               
               
                 AF520863.1 
                   Bacillus subtilis  clone Tn3 1 srfAB surfactin synthetase (srfAB) and 
                 1482 
                 1482 
                 2% 
                 0.0 
                 98% 
                   
               
               
                 AF520865.1 
                   Bacillus subtilis  clone F148r SrfAA surfactin synthetase (srfAA) gene 
                 1282 
                 2456 
                 4% 
                 0.0 
                 95% 
                   
               
               
                 EU382344.1 
                   Bacillus amyloliquefaciens  strain 96-79 Sfp (sfp) gene, complete cd           
                 1184 
                 1184 
                 1% 
                 0.0 
                 98% 
                   
               
               
                 EU882347.1 
                   Bacillus amyloliquefaciens  strain 96-82 Sfp (sfp) gene, complete cd           
                 1179 
                 1179 
                 1% 
                 0.0 
                 98% 
                   
               
               
                 D21876.1 
                   Bacillus subtilis  Ipa-14 gene encoding lipopeptide antibiotics itunin A 
                 1175 
                 1175 
                 1% 
                 0.0 
                 98% 
                   
               
               
                 L17438.1 
                   Bacillus subtilis  surfactin (sfpo) gene, complete cds 
                 1136 
                 1136 
                 3% 
                 0.0 
                 85% 
                   
               
               
                 FJ919233.1 
                   Bacillus subtilis  strain 916 phosphopantetheinyl transferase (Ipa-91           
                 1134 
                 1134 
                 1% 
                 0.0 
                 97% 
                   
               
               
                 EU797520.1 
                   Bacillus subtilis  strain RP24 lipopetide antibiotic iturin A (Ipa-14) ge           
                 1083 
                 1083 
                 1% 
                 0.0 
                 97% 
                   
               
               
                 EU797521.1 
                   Bacillus subtilis  strain mutant RP24 nonfunctional lipopeptide antibio 
                 1059 
                 1059 
                 1% 
                 0.0 
                 95% 
               
               
                   
               
               
                             indicates data missing or illegible when filed 
               
             
          
         
       
     
         [0200]    The following Table 3 showed the comparative results of the nucleotide sequence of ORF 2-1 (550 bp) of  B. subtilis  subsp.  krictiensis  and other strains, using Blast X. 

 
         [0201]    The following Table 4 showed the comparative results of the nucleotide sequence of ORF 2-2 (9,940 bp) of  B. subtilis  subsp.  krictiensis  and other strains, using Blast X. 

 
         [0202]    The following Table 5 showed the comparative results of the nucleotide sequence of ORE 3 (10,770 bp) of  B. subtilis  subsp.  krictiensis  and other strains, using Blast X. 

 
       Example 7 
       [0203]    Preparation of Assay Plates 
         [0204]    &lt;7-1&gt; Preparation of Plate for  Magnaporthe grisea    
         [0205]    For preparation of spore suspension, the rice blast pathogen  Magnaporthe grisea  was slant-cultured on a potato dextrose agar medium for 12 to 15 days, and 5 mL of distilled water was added thereto, and then spores were suspended with a Pasteur pipette, allowed to stand for an appropriate time, and the absorbance of the supernatant at 550 nm wavelength was adjusted to 1.5. The bioassay plate for  Magnaporthe grisea  was used an overlaid plate. First, rice leaf extract was added with 0.15% sucrose and 1.5% agar, and sterilized, and mixed with citrate phosphate buffer (pH 5.0) at a ratio of 1:1. 25 mL of the mixture was dispensed into each plate. After the dispensed medium was hardened, rice extract was added again with 0.15% sucrose and 1.5% agar, and sterilized, and mixed with citrate phosphate buffer (pH 5.0) at a ratio of 1:1, and maintained at 45° C. to make the overlaid medium. 5 mL of the prepared spore suspension was added to and mixed well with 50 mL of the sterilized overlaid medium, and then, each 5 to 10 mL of the mixture was overlaid onto the previously solidified base layer depending on the plate size to make a bioassay plate. 
         [0206]    &lt;7-2&gt; Preparation of Plate for  Trichophyton mentagrophytes    
         [0207]    Mycelium slant-cultured in Sabouraud&#39;s dextrose agar medium for 10 to 14 days were used, and Sabouraud&#39;s dextrose agar was used as a basic medium for the plate for  Trichophyton mentagrophytes . The fungus causing athlete&#39;s foot  Trichophyton mentagrophytes  was inoculated into Sabouraud&#39;s dextrose broth, shaking-cultured for 2 to 3 days, and homogenized with a sterilized waring blender. The absorbance of inoculum at 550 nm wavelength was adjusted to 1.5. 5 mL of inoculum was added to and mixed well with 50 mL of the Sabouraud&#39;s dextrose agar which was sterilized and adjusted to 50° C., and then each 5 to mL of the mixture was overlaid onto a base layer wherein Sabouraud&#39;s dextrose agar was dispensed and solidified in advance depending on the plate size to make a bioassay plate. 
         [0208]    &lt;7-3&gt; Preparation of Plate for  Fusarium oxysporum    
         [0209]      Fusarium oxysporum  grown on a potato dextrose agar medium was inoculated into a potato dextrose broth, shaking-cultured for 2 to 3 days, and homogenized with a sterilized waring blender. The absorbance of inoculum at 550 nm wavelength was adjusted to 1.5. 10 mL of inoculum was added to and mixed uniformly with 50 mL of the potato dextrose agar which was sterilized and adjusted to 50° C., and then each 5 to 10 mL of the mixture was overlaid onto a base layer wherein a potato dextrose agar was dispensed and solidified in advance depending on the plate size to make a bioassay plate. 
       Example 8 
       [0210]    Measurement of Antifungal Activity of  Bacillus    
         [0211]    &lt;8-1&gt; Measurement of Antifungal Activity by Standard Compounds 
         [0212]    To assay whether iturin is produced or not from iturin-producing strains obtained through mutation or recombination of them, it should depend on instrumental analysis, but it requires time and efforts. Accordingly, the present inventors tried to establish a simple method of examining whether iturin is produced or not in a laboratory. First, in order to compare antifungal activities between  B. subtilis  subsp.  krictiensis  producing iturin and  B. subtilis  168 containing surfactin genes, the present inventors purchased standard compounds, surfactin and iturin A from Sigma Co. and Wako Co. For test microorganisms, three kinds of microorganism, the rice blast fungus  Magnaporthe grisea , the fungus causing athlete&#39;s foot  Trichophyton mentagrophytes , and the fungus causing wilt disease of the family Solanaceae  Fusarium oxysporum  were used to investigate antifungal activity of standard compounds, iturin A and surfactin. 
         [0213]    Four different concentrations of surfactin or iturin A were prepared by two-fold serial dilution on the  Magnaporthe grisea  plate,  Trichophyton mentagrophytes  plate, and  Fusarium oxysporum  plate prepared in Example 7, and the range of surfactin or iturin A concentration was 1.56 to 12.56 μg/mL against the rice blast fungus, 3.12 to 25 μg/mL against the fungus causing athlete&#39;s foot, and 6.25 to 50 μg/mL against the fungus causing wilt disease of the family Solanaceae. 100 μL of each compound of four different concentrations was dispensed to sterilized cups (external diameter 6.6 mm, height 8.6 mm, stainless, Fisher Co.) placed onto the plates containing test microorganisms and the test microorganisms were cultured at 25° C. for 1 to 3 days. Growth inhibition of test microorganisms was observed to investigate antifungal activity. 
         [0214]    Consequently, iturin A showed strong antifungal activities against  Magnaporthe grisea  and  Trichophyton mentagrophytes , whereas surfactin showed weaker than iturin A, but slight inhibitory activities against them. There was a difference in antifungal activities between iturin A and surfactin, but there was no significant difference in antifungal spectrum. However, while iturin A showed a strong antifungal activity against the test microorganism  Fusarium oxysporum , surfactin did not show antifungal activity. Two compounds showed obvious difference in antifungal activity against  Fusarium oxysporum  ( FIG. 10 ). 
         [0215]    &lt;8-2&gt; Measurement of Antifungal Activity by the Supernatant of Culture Broth of  Bacillus    
         [0216]    Since analysis of iturin production or selection of iturin-less mutants, using wild type  B. subtilis  through instrumental analysis requires great time and efforts, the present inventors tried to develop a simple bioassay system using test microorganisms. First, when antifungal activity was examined using authentic iturin and surfactin, the present inventors found that only iturin showed antifungal activity against  Fusarium  strain. Then, the present inventors used various kinds of  B. subtilis  strains associated with iturin and surfactin production kept in the relevant laboratory and Bio-Chemical Research Center at Korea Research Institute of Bioscience and Biotechnology to examine antifungal activity. In order to use strains as various as possible, the present inventors collected strains that are known to produce iturin and surfactin from various researchers and in this context,  B. subtilis  C9 was also collected and used.  Bacillus  strains were liquid-cultured and their antifungal activities against three test microorganisms were investigated. 
         [0217]      B. subtilis  subsp.  krictiensis  producing iturin and  B. subtilis  JH642 producing neither iturin nor surfactin were used as control.  B. subtilis  168 which has a surfactin gene but does not produce surfactin due to natural mutation of sfp gene and  B. subtilis  C9 which is assumed to produce both surfactin and iturin were used. 
         [0218]    Single colonies of the above  Bacillus  strains grown freshly in LB agar medium were collected and inoculated into a complex medium for producing bioactive substances [sucrose 30 g, soytone 10 g, yeast extract 5 g, K 2 HPO 4  0.5 g, MgSO 4  2 g, MnCl 2  4 mg, CaCl 2  5 mg, FeSO 4 .7H 2 0 25 mg, pH 7.0, distilled water 1 L] and cultured at 30° C., 200 rpm, for 48 hr. The culture broth was centrifuged at 8,000×g, for 10 min to remove bacterial cell. 100 μL of supernatant filtered through a 0.2 μm membrane filter was added to a paper disk. The paper disks were placed on the bioassay plates prepared in &lt;Example 7&gt;, and cultured at 25° C. for 1 to 3 days. Growth inhibition of test microorganisms ( Magnaporthe grisea, Trichophyton mentagrophytes , and  Fusarium oxysporum ) was investigated. 
         [0219]    Consequently, as shown in  FIG. 11 ,  B. subtilis  subsp.  krictiensis  strain showed strong antifungal activities against all the test microorganisms,  Magnaporthe grisea, Trichophyton mentagrophytes , and  Fusarium oxysporum , just like the examination result of using the standard compound iturin A. However,  B. subtilis  JH642 and  B. subtilis  168 in which sfp gene is naturally mutated did not showed antifungal activities against three test microorganisms. But,  B. subtilis  C9 strain showed antifungal activities against three test microorganisms. Accordingly, the present inventors assumed that the antifungal activity of  B. subtilis  C9 shown in the above result was due to the production of iturin, in addition to surfactin. Based on these results, the present inventors used  Fusarium oxysporum  as a test microorganism for selecting iturin mutants ( FIG. 11 ). 
       Example 9 
       [0220]    Measurement of Antifungal Activity of Transformed  B. subtilis  subsp.  krictiensis  Mutants 
         [0221]    &lt;9-1&gt; Transformation of  B. subtilis  subsp.  krictiensis    
         [0222]    Each of four fragments (pBT6, pBT1, pBT2 and pBT3,  FIG. 12 ) which were obtained by digesting DNA fragments of cosmid clones pJJ121 and pJJ815 obtained from  B. subtilis  subsp.  krictiensis  in Example &lt;2-2&gt; with EcoRI and the fragment of HCE promoter of pT(II)PLK digested with NdeI were cloned into  Bacillus - E. coli  shuttle vector, pHPS9 (provided from Bio-Chemical Research Center at Korea Research Institute of Bioscience and Biotechnology) and introduced to  B. subtilis  subsp.  krictiensis . The strain was spread onto a plate containing chloramphenicol antibiotic (5 μg/mL) and colonies were selected as mutant strains. 
         [0223]    Specifically, a single colony of  Bacillus subtilis  subsp.  krictiensis  cultured freshly in LB agar medium was inoculated into 2 mL of Spizizen&#39;s medium (50% glucose 10 mL, 2% casein hydrolysate 10 mL, 10% yeast extract 10 mL, 1M MgCl 2  2.25 mL, KH 2 PO 4  6 g, K 2 HPO 4  14 g, (NH 4 ) 2 SO 4  2 g, Sodium citrate 1 g, MgSO 4 0.2 g, distilled water 1 L) and cultured at 37° C., 200 rpm, for 16 to 18 hr. Again, the inoculum was inoculated into fresh medium to achieve 1% and cultured under the same condition. When the absorbance of culture broth at 580 nm wavelength was 1.0, 0.5 mL of the culture broth and about 1 μg of DNA (pBT6, pBT1, pBT2, and pBT3) were mixed and shaking-cultured for 1 hr. After shaking culture, an aliquot of culture broth was spread onto a plate containing 5 μg/mL of chloramphenicol and incubated at 37° C. for 24 hr. 
         [0224]    Mutants containing fragments pBT6, pBT1, pBT2 and pBT3 were named as  B. subtilis  subsp.  krictiensis  (pBT6),  B. subtilis  subsp.  krictiensis  (pBT1),  B. subtilis  subsp.  krictiensis  (pBT2) and  B. subtilis  subsp.  krictiensis  (pBT3), respectively ( FIG. 10 ). 
         [0225]    &lt;9-2&gt; Measurement of Antifungal Activity of  B. subtilis  subsp.  krictiensis    
         [0226]    The present inventors tried to measure antifungal activities of  B. subtilis  subsp.  krictiensis  which was not transformed as control, grown freshly in LB agar medium, and  B. subtilis  subsp.  krictiensis  strains (pBT1, pBT3, and pBT6) in which fragments containing ORFs prepared in Example &lt;8-1&gt; were transformed. 
         [0227]    Single colonies of  B. subtilis  subsp.  krictiensis  strains (pBT1, pBT3, and pBT6) were collected, inoculated into a complex medium for producing bioactive substances [sucrose 30 g, soytone 10 g, yeast extract 5 g, K 2 HPO 4  0.5 g, MgSO 4  2 g, MnCl 2  4 mg, CaCl 2  5 mg, FeSO 4 .7H 2 0 25 mg, pH 7.0, distilled water 1 L], and cultured at 30° C., 200 rpm, for 48 hrs. The culture medium was centrifuged at 8,000×g, for 10 min to remove bacterial cell. 100 μL of the supernatant filtered through a 0.2 μm membrane filter was added to a paper disk (thick, diameter 8 mm, Toyo Roshi Co.). The paper disks were placed on the bioassay plates prepared in &lt;Example 7&gt;, and incubated at 25° C. for 1 to 3 days. Growth inhibition of the test microorganism  Fusarium oxysporum  was investigated. 
         [0228]    Consequently, as shown in  FIG. 13 , it was observed that the antifungal activity of  B. subtilis  subsp.  krictiensis  (pBT6) containing the clone pBT6 was increased two to three-fold over untransformed control  B. subtilis  subsp.  krictiensis . In addition, it was observed that the potency of antifungal activities of transformed strains was increased in order of pBT3, pBT1, and pBT6. These results corresponded with the above result that surfactin did not show the antifungal activity, but iturin showed the antifungal activity against  Fusarium oxysporum . That is, since the antifungal activity of  B. subtilis  subsp.  krictiensis  (pBT6) was increased due to transformation of the clone pBT6, compared to control  B. subtilis  subsp.  krictiensis , the present inventors assumed that the clone pBT6 included the iturin biosynthesis gene ( FIG. 13 ). 
       Example 10 
       [0229]    Preparation of Iturin-Less Mutants and Assay of Antifungal Activity 
         [0230]    &lt;10-1&gt; Preparation of Iturin-Less Mutants 
         [0231]    In order to confirm again that iturin biosynthesis genes exist in the cosmid clone pJJ121E2, the present inventors tried to prepare an iturin-less mutant by inserting genes into the chromosome through homologous recombination using mini-Tn100. First, the clone pJJ121E2-2, in which pJJ121 fragment digested with EcoRI was inserted into the vector pBC KS(+/−) (Stratagene), was digested with EcoRI and cloned into the vector pTZ18 (Promega), and the SalI site was removed. 
         [0232]    In addition, from the clone p121E3 ( FIG. 14 ) in which pIC333 vector was contained in a ClaI site of this vector, the spectinomycin gene-containing region was digested with BamHI and XbaI, and a ClaI site was attached thereto by PCR based on the nucleotide sequence of pTZ18 vector, and then, the fragment was digested with ClaI and the spectinomycin gene was inserted to prepare pJJ121E2-1 vector. Then,  B. subtilis  subsp.  krictiensis  strain was transformed with pJJ121E2-1 vector. Since the spectinomycin gene region containing mini-Tn100 which was inserted into  B. subtilis  subsp.  krictiensis  does not have  Bacillus  replication origin, cloning could not be done any more, but only gene insertion was done through homologous recombination of similar parts and host chromosome. Accordingly, chromosomal insertion mutants were selected from a spectinomycin-containing medium. 
         [0233]    Specifically, 7,940 bp from 16,430 bp to 24,370 bp of ORF 3 was inserted in  B. subtilis  mutant-10, and it was thought that iturin biosynthesis did not occur since among the inserted region, spectinomycin was inserted in the ClaI site, 21,046 bp. In order to improve the efficiency of transformation, the SalI site of pJJ121E2-1 vector was digested and removed. The lost region of ORF 3 which was inserted in  B. subtilis  mutant-10 was the SalI-EcoRI-SalI site, as described in  FIG. 14 . The EcoRI-SalI site was derived from pJJ121E2 fragment. The lost nucleotide sequences were 8.41 kb (8,020˜16,430 bp) and the SalI site (33 bp) derived from the vector, on the left of the EcoRI site, and the total size was 8.443 kb. 
         [0234]    &lt;10-2&gt; Measurement of Antifungal Activity of  B. subtilis  Mutant-10 
         [0235]    The mutant selected from the spectinomycin-containing medium was named as  B. subtilis  mutant-10. In order to examine antifungal activity, an aliquot of the culture broth of  B. subtilis  subsp.  krictiensis  or the culture broth of  B. subtilis  mutant-10 was loaded onto the plate for the test microorganism  Fusarium oxysporum  by the same method as &lt;Example 9&gt; for examining antifungal activities. 
         [0236]    Consequently,  B. subtilis  mutant-10 which lost the function of iturin biosynthesis gene showed so weak antifungal activity to be barely detectable, whereas  B. subtilis  subsp.  krictiensis  showed strong antifungal activity. It seemed certain that the obtained gene would be an iturin biosynthesis gene and it was confirmed that the gene was directly associated with the antifungal activity exhibited by  B. subtilis  subsp.  krictiensis  ( FIG. 15 ). 
         [0237]    &lt;10-3&gt; Confirmation of Spectinomycin Gene Insertion Using Southern Hybridization 
         [0238]    In order to confirm whether the spectinomycin gene was inserted into the chromosome of  B. subtilis  mutant-10 prepared in Example &lt;9-1&gt; or not, the spectinomycin-containing fragment, which was obtained by digesting the clone p121E3 containing pIC333 vector with mini-Tn10 by BamHI and XbaI, was labeled with  32 P isotope to prepare a probe, and Southern hybridization was conducted. Genomic DNAs were extracted from  B. subtilis  subsp,  krictiensis  and  B. subtilis  mutant-10 and digested with ClaI. Southern hybridization was conducted using the genomic DNAs of  B. subtilis  subsp.  krictiensis  and iturin-less mutant-10 digested with ClaI and the probe wherein the spectinomycin fragment which contained the spectinomycin gene derived from the clone p121E3 by digesting with BamHI and XbaI, was labeled with isotope. 
         [0239]    Consequently, as shown in  FIG. 16 , it was confirmed that the spectinomycin gene existed in the 1.5 kb position of the fragment, in which the clone p121E3 containing the spectinomycin gene was digested with BamHI and XbaI, used as the probe. It was confirmed that the spectinomycin gene existed in the same position as the spectinomycin fragment derived from the clone p121E3 also in  B. subtilis  mutant-10. On the other hand, the spectinomycin gene did not exist in  B. subtilis  subsp.  krictiensis  ( FIG. 16 ). From these results, it was confirmed that the reason  B. subtilis  mutant-10 did not show antifungal activity in Example &lt;10-2&gt; was that the spectinomycin gene was inserted into the chromosome, so that iturin was not produced. 
       Example 11 
       [0240]    Metabolite Analysis of  B. subtilis  Subsp.  krictiensis  and  B. subtilis  Mutant-10 
         [0241]    &lt;11-1&gt; Metabolite Analysis by HPLC 
         [0242]    The present inventors investigated whether there was a difference in iturin antibiotic production between the culture broth of  B. subtilis  subsp.  krictiensis  and the culture broth of  B. subtilis  mutant-10. The culture broth of  B. subtilis  subsp.  krictiensis  and the culture broth of  B. subtilis  mutant-10 were developed by thin-layer chromatography (TLC) with solvent condition of CHC 3 /MeOH/D.W.=75/25/5. Corresponding regions of each spot from the  B. subtilis  subsp.  krictiensis  and  B. subtilis  mutant-10 were collected and separated by high performance liquid chromatography (HPLC). Iturin production between  B. subtilis  subsp.  krictiensis  and  B. subtilis  mutant-10 was compared and commercially available standard compound iturin A was used as a control. 
         [0243]    Consequently, HPLC chromatogram of  B. subtilis  subsp.  krictiensis  and HPLC chromatogram of standard compound iturin A showed considerably similar peak pattern, whereas peaks corresponding iturin A were not observed in  B. subtilis  mutant-10 ( FIG. 17 ). It was confirmed that the reason  B. subtilis  mutant-10 did not show antifungal activity against the test microorganism  Fusarium oxysporum  in Example &lt;10-2&gt; was that the spectinomycin gene was inserted into the chromosome, so that iturin was not synthesized. 
         [0244]    &lt;11-2&gt; Metabolite Analysis by LC-Mass 
         [0245]    In order to investigate whether chromatogram from  B. subtilis  subsp.  krictiensis  observed by HPLC means six kinds of iturins, iturin A to F, the molecular weight of these peaks were determined by LC-Mass. As a result of HPLC analysis, through the chromatogram, it was confirmed that six kinds of iturins, iturin A to F were produced from  B. subtilis  subsp.  krictiensis  ( FIG. 18 ). When the molecular weights of the produced iturin compounds A to F were determined as [M+Na] +  using Mass spectrometry, peaks corresponding to the molecular weights of iturin A to F (A: 1043, B: 1057, C: 1057, D: 1071, E: 1071, F: 1085) were detected. From the LC-Mass result, peaks which were present in  B. subtilis  subsp.  krictiensis , but were not present in  B. subtilis  mutant-10 corresponded precisely with iturins A to F ( FIG. 19  and  FIG. 20 ), and thus, it was reconfirmed that  B. subtilis  mutant-10 did not show the antifungal activity on the bioassay plate against  F. oxysporum  because of the inhibition of production of iturin compounds. 
         [0246]    The above results taken together, ORF 2-1, ORF 2-2, and ORF 3 verified in this study showed 74 to 98% similarity with surfactin genes. However, real product encoded by the genes was not surfactin but iturin, and these genes showed low similarity, 41%, with other iturin A biosynthesis genes that have been known until now. Accordingly, the iturin biosynthesis genes of  B. subtilis  subsp.  krictiensis  used in this experiment are thought to be novel genes which are different from the genes reported up to date.

Technology Classification (CPC): 2