The invention is related to the area of mismatch repair genes. In particular it is related to the field of in situ mutagenesis of single celled organisms.
Within the past four years, the genetic cause of the Hereditary Nonpolyposis Colorectal Cancer Syndrome (HNPCC), also known as Lynch syndrome II, has been ascertained for the majority of kindred""s affected with the disease (Liu, B., Parsons, R., Papadopoulos, N., Nicolaides, N. C., Lynch, H. T., Watson, P., Jass, J. R., Dunlop, M., Wyllie, A., Peltomaki, P., de la Chapelle, A., Hamilton, S. R., Vogelstein, B., and Kinzler, K. W. 1996. Analysis of mismatch repair genes in hereditary non-polyposis colorectal cancer patients. Nat. Med. 2:169-174). The molecular basis of HNPCC involves genetic instability resulting from defective mismatch repair (MMR). To date, six genes have been identified in humans that encode for proteins and appear to participate in the MMR process, including the mutS homologs GTBP, hMSH2, and hMSH3 and the mutL homologs hALH1, hPMS1, and hPMS2 (Bronner, C. E., Baker, S. M., Morrison, P. T., Warren, G., Smith, L. G., Lescoe, M. K., Kane, M., Earabino, C., Lipford, J., Lindblom, A., Tannergard, P., Bollag, R. J., Godwin, A., R., Ward, D. C., Nordenskjold, M., Fishel, R., Kolodner, R., and Liskay, R. M. 1994. Mutation in the DNA mismatch repair gene homologue hMLH1 is associated with hereditary non-polyposis colon cancer. Nature 368:258-261; Fishel, R., Lescoe, M., Rao, M. R. S., Copeland, N. J., Jenkins, N. A., Garber, J., Kane, M., and Kolodner, R. 1993. The human mutator gene homolog MSH2 and its association with hereditary nonpolyposis colon cancer. Cell 7:1027-1038; Leach, F. S., Nicolaides, N. C, Papadopoulos, N., Liu, B., Jen, J., Parsons, R., Peltomaki, P., Sistonen, P., Aaltonen, L. A., Nystrom-Lahti, M., Guan, X. Y., Zhang, J., Meltzer, P. S., Yu, J. W., Kao, F. T., Chen, D. J., Cerosaletti, K. M., Fournier, R. E. K., Todd, S., Lewis, T., Leach R. J., Naylor, S. L., Weissenbach, J., Mecklin, J. P., Jarvinen, J. A., Petersen, G. M., Hamilton, S. R., Green, J., Jass, J., Watson, P., Lynch, H. T., Trent, J. M., de la Chapelle, A., Kinzler, K. W., and Vogelstein, B. 1993. Mutations of a mutS homolog in hereditary non-polyposis colorectal cancer. Cell 75:1215-1225; Nicolaides, N. C., Papadopoulos, N., Liu, B., Wei, Y. F., Carter, K. C., Ruben, S. M., Rosen, C. A., Haseltine, W. A., Fleischmann, R. D., Fraser, C. M., Adams, M. D., Venter, C. J., Dunlop, M. G., Hamilton, S. R., Petersen, G. M., de la Chapelle, A., Vogelstein, B., and kinzler, K. W. 1994. Mutations of two PMS homologs in hereditary nonpolyposis colon cancer. Nature 371: 75-80; Nicolaides, N. C., Palombo, F., Kinzler, K. W., Vogelstein, B., and Jiricny, J. 1996. Molecular cloning of the N-terminus of GTBP. Genomics 31:395-397; Palombo, F., Hughes, M., Jiricny, J., Truong, O., Hsuan, J. 1994. Mismatch repair and cancer. Nature 36:417; Palombo, F., Gallinari, P., laccarino, I., Lettieri, T., Hughes, M. A., Truong, O., Hsuan, J. J., and Jiricny, J. 1995. GTBP, a 160-kilodalton protein essential for mismatch-binding activity in human cells. Science 268:1912-1914; Papadopoulos, N., Nicolaides, N. C., Wei, Y. F., Carter, K. C., Ruben, S. M., Rosen, C. A., Haseltine, W. A., Fleischmann, R. D., Fraser, C. M., Adams, M. D., Venter, C. J., Dunlop, M. G., Hamilton, S. R., Petersen, G. M., de la Chapelle, A., Vogelstein, B., and Kinzler, K. W. 1994. Mutation of a mutL homolog is associated with hereditary colon cancer. Science 263:1625-1629). Germline mutations in four of these genes (hMSH2, hMLH1, hPMS1, and hPMS2) have been identified in HNPCC kindred""s (Bronner, C. E., Baker, S. M., Morrison, P. T., Warren, G., Smith, L. G., Lescoe, M. K., Kane, M., Earabino, C., Lipford, J., Lindblom, A., Tannergard, P., Bollag, R. J., Godwin, A., R., Ward, D. C., Nordenskjold, M., Fishel, R., Kolodner, R., and Liskay, R. M. 1994. Mutation in the DNA mismatch repair gene homologue hMLH1 is associated with hereditary non-polyposis colon cancer. Nature 368:258-261; Leach, F. S., Nicolaides, N. C, Papadopoulos, N., Liu, B., Jen, J., Parsons, R., Peltomaki, P., Sistonen, P., Aaltonen, L. A., Nystrom-Lahti, M., Guan, X. Y., Zhang, J., Meltzer, P. S., Yu, J. W., Kao, F. T., Chen, D. J., Cerosaletti, K. M., Fournier, R. E. K., Todd, S., Lewis, T., Leach R. J., Naylor, S. L., Weissenbach, J., Mecklin, J. P., Jarvinen, J. A., Petersen, G. M., Hamilton, S. R., Green, J., Jass, J., Watson, P., Lynch, H. T., Trent, J. M., de la Chapelle, A., Kinzler, K. W., and Vogelstein, B. 1993. Mutations of a mutS homolog in hereditary non-polyposis colorectal cancer. Cell 75:1215-1225; Liu, B., Parsons, R., Papadopoulos, N., Nicolaides, N. C., Lynch, H. T., Watson, P., Jass, J. R., Dunlop, M., Wyllie, A., Peltomaki, P., de la Chapelle, A., Hamilton, S. R., Vogelstein, B., and Kinzler, K. W. 1996. Analysis of mismatch repair genes in hereditary non-polyposis colorectal cancer patients. Nat. Med. 2:169-174; Nicolaides, N. C., Papadopoulos, N., Liu, B., Wei, Y. F., Carter, K. C., Ruben, S. M., Rosen, C. A., Haseltine, W. A., Fleischmann, R. D., Fraser, C. M., Adams, M. D., Venter, C. J., Dunlop, M. G., Hamilton, S. R., Petersen, G. M., de la Chapelle, A., Vogelstein, B., and kinzler, K. W. 1994. Mutations of two PMS homologs in hereditary nonpolyposis colon cancer. Nature 371: 75-80; Papadopoulos, N., Nicolaides, N. C., Wei, Y. F., Carter, K. C., Ruben, S. M., Rosen, C. A., Haseltine, W. A., Fleischmann, R. D., Fraser, C. M., Adams, M. D., Venter, C. J., Dunlop, M. G., Hamilton, S. R., Petersen, G. M., de la Chapelle, A., Vogelstein, B., and kinzler, K. W. 1994. Mutation of a mutL homolog is associated with hereditary colon cancer. Science 263:1625-1629). Though the mutator defect that arises from the MMR deficiency can affect any DNA sequence, microsatellite sequences are particularly sensitive to MMR abnormalities (Modrich, P. 1994. Mismatch repair, genetic stability, and cancer. Science 266:1959-1960). Microsatellite instability (MI) is therefore a useful indicator of defective MMR. In addition to its occurrence in virtually all tumors arising in HNPCC patients, MI is found in a small fraction of sporadic tumors with distinctive molecular and phenotypic properties (Perucho, M. 1996. Cancer of the microsattelite mutator phenotype. Biol Chem. 377:675-684).
HNPCC is inherited in an autosomal dominant fashion, so that the normal cells of affected family members contain one mutant allele of the relevant MMR gene (inherited from an affected parent) and one wild-type allele (inherited from the unaffected parent). During the early stages of tumor development, however, the wild-type allele is inactivated through a somatic mutation, leaving the cell with no functional MMR gene and resulting in a profound defect in MMR activity. Because a somatic mutation in addition to a germ-line mutation is required to generate defective MMR in the tumor cells, this mechanism is generally referred to as one involving two hits, analogous to the biallelic inactivation of tumor suppressor genes that initiate other hereditary cancers (Leach, F. S., Nicolaides, N. C, Papadopoulos, N., Liu, B., Jen, J., Parsons, R., Peltomaki, P., Sistonen, P., Aaltonen, L. A., Nystrom-Lahti, M., Guan, X. Y., Zhang, J., Meltzer, P. S., Yu, J. W., Kao, F. T., Chen, D. J., Cerosaletti, K. M., Fournier, R. E. K., Todd, S., Lewis, T., Leach R. J., Naylor, S. L., Weissenbach, J., Mecklin, J. P., Jarvinen, J. A., Petersen, G. M., Hamilton, S. R., Green, J., Jass, J., Watson, P., Lynch, H. T., Trent, J. M., de la Chapelle, A., Kinzler, K. W., and Vogelstein, B. 1993. Mutations of a mutS homolog in hereditary non-polyposis colorectal cancer. Cell 75:1215-1225; Liu, B., Parsons, R., Papadopoulos, N., Nicolaides, N. C., Lynch, H. T., Watson, P., Jass, J. R., Dunlop, M., Wyllie, A., Peltomaki, P., de la Chapelle, A., Hamilton, S. R., Vogelstein, B., and Kinzler, K. W. 1996. Analysis of mismatch repair genes in hereditary non-polyposis colorectal cancer patients. Nat. Med. 2:169-174; Parsons, R., Li, G. M., Longley, M. J., Fang, W. H., Papadopolous, N., Jen, J., de la Chapelle, A., Kinzler, K. W., Vogelstein, B., and Modrich, P. 1993. Hypermutability and mismatch repair deficiency in RER+ tumor cells. Cell 75:1227-1236). In line with this two-hit mechanism, the non-neoplastic cells of HNPCC patients generally retain near normal levels of MMR activity due to the presence of the wild-type allele.
The ability to alter the signal transduction pathways by manipulation of a gene products function, either by over-expression of the wild type protein or a fragment thereof, or by introduction of mutations into specific protein domains of the protein, the so-called dominant-negative inhibitory mutant, were described over a decade in the yeast system Saccharomyces cerevisiae by Herskowitz (Nature 329(6136):219-222, 1987). It has been demonstrated that over-expression of wild type gene products can result in a similar, dominant-negative inhibitory phenotype due most likely to the xe2x80x9csaturating-outxe2x80x9d of a factor, such as a protein, that is present at low levels and necessary for activity; removal of the protein by binding to a high level of its cognate partner results in the same net effect, leading to inactivation of the protein and the associated signal transduction pathway. Recently, work done by Nicolaides et. al. (Nicolaides N C, Littman S J, Modrich P, Kinzler K W, Vogelstein B 1998. A naturally occurring hPMS2 mutation can confer a dominant negative mutator phenotype. Mol Cell Biol 18:1635-1641) has demonstrated the utility of introducing dominant negative inhibitory mismatch repair mutants into mammalian cells to confer global DNA hypermutability. The ability to manipulate the MMR process and therefore increase the mutability of the target host genome at will, in this example a mammalian cell, allows for the generation of innovative cell subtypes or variants of the original wild type cells. These variants can be placed under a specified, desired selective process, the result of which is a novel organism that expresses an altered biological molecule(s) and has a new trait. The concept of creating and introducing dominant negative alleles of a gene, including the MMR alleles, in bacterial cells has been documented to result in genetically altered prokaryotic mismatch repair genes (Aronshtam A, Marinus M G. 1996. Dominant negative mutator mutations in the mutL gene of Escherichia coli. Nucleic Acids Res 24:2498-2504; Wu T H, Marinus M G. 1994. Dominant negative mutator mutations in the mutS gene of Escherichia coli. J Bacteriol 176:5393-400; Brosh R M Jr, Matson S W. 1995. Mutations in motif II of Escherichia coli DNA helicase II render the enzyme nonfunctional in both mismatch repair and excision repair with differential effects on the unwinding reaction. J Bacteriol 177:5612-5621). Furthermore, altered MMR activity has been demonstrated when MMR genes from different species including yeast, mammalian cells, and plants are over-expressed (Fishel, R., Lescoe, M., Rao, M. R. S., Copeland, N. J., Jenkins, N. A., Garber, J., Kane, M., and Kolodner, R. 1993. The human mutator gene homolog MSH2 and its association with hereditary nonpolyposis colon cancer. Cell 7:1027-1038; Studamire B, Quach T, Alani, E. 1998. Saccharomyces cerevisiae Msh2p and Msh6p ATPase activities are both required during mismatch repair. Mol Cell Biol 18:7590-7601; Alani E, Sokolsky T, Studamire B, Miret J J, Lahue R S. 1997. Genetic and biochemical analysis of Msh2p-Msh6p: role of ATP hydrolysis and Msh2p-Msh6p subunit interactions in mismatch base pair recognition. Mol Cell Biol 17:2436-2447; Lipkin S M, Wang V, Jacoby R, Banerjee-Basu S, Baxevanis A D, Lynch H T, Elliott R M, and Collins F S. 2000. MLH3: a DNA mismatch repair gene associated with mammalian microsatellite instability. Nat. Genet. 24:27-35).
There is a continuing need in the art for methods of genetically manipulating useful strains of yeast to increase their performance characteristics and abilities.
It is an object of the present invention to provide a method for rendering yeast cells hypermutable.
It is another object of the invention to provide hypermutable yeast cells.
It is a further object of the invention to provide a method of mutating a gene of interest in a yeast.
It is yet another object of the present invention to provide a method to produce yeast that are hypermutable.
It is an object of the invention to provide a method to restore normal mismatch repair activity to hypermutable cells following strain selection.
These and other objects of the invention are provided by one or more of the following embodiments. In one embodiment a method is provided for making a hypermutable yeast. A polynucleotide comprising a dominant negative allele of a mismatch repair gene is introduced into a yeast cell. The cell thus becomes hypermutable.
According to another embodiment a homogeneous composition of cultured, hypermutable yeast cells is provided. The yeast cells comprise a dominant negative allele of a mismatch repair gene.
According to still another embodiment of the invention a method is provided for generating a mutation in a gene of interest. A yeast cell culture comprising the gene of interest and a dominant negative allele of a mismatch repair gene is cultivated. The yeast cell is hypermutable. Cells of the culture are tested to determine whether the gene of interest harbors a mutation.
In yet another embodiment of the invention a method is provided for generating a mutation in a gene of interest. A yeast cell comprising the gene of interest and a polynucleotide encoding a dominant negative allele of a mismatch repair gene is grown to create a population of mutated, hypermutable yeast cells. The population of mutated, hypermutable yeast cells is cultivated under trait selection conditions. Yeast cells which grow under trait selection conditions are tested to determine whether the gene of interest harbors a mutation.
Also provided by the present invention is a method for generating enhanced hypermutable yeast. A yeast cell is exposed to a mutagen. The yeast cell is defective in mismatch repair (MMR) due to the presence of a dominant negative allele of at least one MMR gene. An enhanced rate of mutation of the yeast cell is achieved due to the exposure to the mutagen.
According to still another aspect of the invention a method is provided for generating mismatch repair (MMR)-proficient yeast with new output traits. A yeast cell comprising a gene of interest and a polynucleotide encoding a dominant negative allele of a mismatch repair gene is grown to create a population of mutated, hypermutable yeast cells. The population of mutated, hypermutable yeast cells is cultivated under trait selection conditions. The yeast cells which grow under trait selection conditions are tested to determine whether the gene of interest harbors a mutation. Normal mismatch repair activity is restored to the yeast cells.
These and other embodiments of the invention provide the art with methods that can generate enhanced mutability in yeast as well as providing single-celled eukaryotic organisms harboring potentially useful mutations to generate novel output traits for commercial applications.
It is a discovery of the present invention that hypermutable yeast can be made by altering the activity of endogenous mismatch repair activity of host cells. Dominant negative alleles of mismatch repair genes, when introduced and expressed in yeast, increase the rate of spontaneous mutations by reducing the effectiveness of endogenous mismatch repair-mediated DNA repair activity, thereby rendering the yeast highly susceptible to genetic alterations, i.e., hypermutable. Hypermutable yeast can then be utilized to screen for mutations in a gene or a set of genes in variant siblings that exhibit an output trait(s) not found in the wild-type cells.
The process of mismatch repair, also called mismatch proofreading, is an evolutionarily highly conserved process that is carried out by protein complexes described in cells as disparate as prokaryotic cells such as bacteria to more complex mammalian cells (Modrich, P. 1994. Mismatch repair, genetic stability, and cancer. Science 266:1959-1960; Parsons, R., Li, G. M., Longley, M., Modrich, P., Liu, B., Berk, T., Hamilton, S. R., Kinzler, K. W., and Vogelstein, B. 1995. Mismatch repair deficiency in phenotypically normal human cells. Science 268:738-740; Perucho, M. 1996. Cancer of the microsattelite mutator phenotype. Biol Chem. 377:675-684). A mismatch repair gene is a gene that encodes one of the proteins of such a mismatch repair complex. Although not wanting to be bound by any particular theory of mechanism of action, a mismatch repair complex is believed to detect distortions of the DNA helix resulting from non-complementary pairing of nucleotide bases. The non-complementary base on the newer DNA strand is excised, and the excised base is replaced with the appropriate base that is complementary to the older DNA strand. In this way, cells eliminate many mutations that occur as a result of mistakes in DNA replication, resulting in genetic stability of the sibling cells derived from the parental cell.
Some wild type alleles as well as dominant negative alleles cause a mismatch repair defective phenotype even in the presence of a wild-type allele in the same cell. An example of a dominant negative allele of a mismatch repair gene is the human gene hPMS2-134, which carries a truncation mutation at codon 134 (Parsons, R., Li, G. M., Longley, M., Modrich, P., Liu, B., Berk, T., Hamilton, S. R., Kinzler, K. W., and Vogelstein, B. 1995. Mismatch repair deficiency in phenotypically normal human cells. Science 268:738-740; Nicolaides N C, Littman S J, Modrich P, Kinzler K W, Vogelstein B 1998. A naturally occurring hPMS2 mutation can confer a dominant negative mutator phenotype. Mol Cell Biol 18:1635-1641). The mutation causes the product of this gene to abnormally terminate at the position of the 134th amino acid, resulting in a shortened polypeptide containing the N-terminal 133 amino acids. Such a mutation causes an increase in the rate of mutations, which accumulate in cells after DNA replication. Expression of a dominant negative allele of a mismatch repair gene results in impairment of mismatch repair activity, even in the presence of the wild-type allele. Any mismatch repair allele, which produces such effect, can be used in this invention, whether it is wild-type or altered, whether it derives from mammalian, yeast, fungal, amphibian, insect, plant, or bacteria. In addition, the use of over-expressed wild type MMR gene alleles from human, mouse, plants, and yeast in bacteria has been shown to cause a dominant negative effect on the bacterial hosts MMR activity (Aronshtam A, Marinus M G. 1996. Dominant negative mutator mutations in the mutL gene of Escherichia coli. Nucleic Acids Res 24:2498-2504; Wu T H, Marinus M G. 1994. Dominant negative mutator mutations in the mutS gene of Escherichia coli. J Bacteriol 176:5393-400; Brosh R M Jr, Matson S W. 1995. Mutations in motif II of Escherichia coli DNA helicase II render the enzyme nonfunctional in both mismatch repair and excision repair with differential effects on the unwinding reaction. J Bacteriol 177:5612-5621; Lipkin S M, Wang V, Jacoby R, Banerjee-Basu S, Baxevanis A D, Lynch H T, Elliott R M, and Collins F S. 2000. MLH3: a DNA mismatch repair gene associated with mammalian microsatellite instability. Nat Genet 24:27-35). This suggests that perturbation of the multi-component MMR protein complex can be accomplished by introduction of MMR components from other species into yeast.
Dominant negative alleles of a mismatch repair gene can be obtained from the cells of humans, animals, yeast, bacteria, plants or other organisms. Screening cells for defective mismatch repair activity can identify such alleles. Mismatch repair genes may be mutant or wild type. Yeast host MMR may be mutated or not. The term yeast used in this application comprises any organism from the eukaryotic kingdom, including but not limited to Saccharomyces sp., Pichia sp., Schizosaccharomyces sp., Kluyveromyces sp., and other fungi (Gellissen, G. and Hollenberg, C P. Gene 190(1):87-97, 1997). These organisms can be exposed to chemical mutagens or radiation, for example, and can be screened for defective mismatch repair. Genomic DNA, cDNA, mRNA, or protein from any cell encoding a mismatch repair protein can be analyzed for variations from the wild-type sequence. Dominant negative alleles of a mismatch repair gene can also be created artificially, for example, by producing variants of the hPMS2-134 allele or other mismatch repair genes (Nicolaides N C, Littman S J, Modrich P, Kinzler K W, Vogelstein B 1998. A naturally occurring hPMS2 mutation can confer a dominant negative mutator phenotype. Mol Cell Biol 18:1635-1641). Various techniques of site-directed mutagenesis can be used. The suitability of such alleles, whether natural or artificial, for use in generating hypermutable yeast can be evaluated by testing the mismatch repair activity (using methods described in Nicolaides N C, Littman S J, Modrich P, Kinzler K W, Vogelstein B 1998. A naturally occurring hPMS2 mutation can confer a dominant negative mutator phenotype. Mol Cell Biol 18:1635-1641) caused by the allele in the presence of one or more wild-type alleles to determine if it is a dominant negative allele.
A yeast that over-expresses a wild type mismatch repair allele or a dominant negative allele of a mismatch repair gene will become hypermutable. This means that the spontaneous mutation rate of such yeast is elevated compared to yeast without such alleles. The degree of elevation of the spontaneous mutation rate can be at least 2-fold, 5-fold, 10-fold, 20-fold, 50-fold, 100-fold, 200-fold, 500-fold, or 1 000-fold that of the normal yeast as measured as a function of yeast doubling/hour.
According to one aspect of the invention, a polynucleotide encoding either a wild type or a dominant negative form of a mismatch repair protein is introduced into yeast. The gene can be any dominant negative allele encoding a protein which is part of a mismatch repair complex, for example, mutS, mutL, mutH, or mutY homologs of the bacterial, yeast, plant or mammalian genes (Modrich, P. 1994. Mismatch repair, genetic stability, and cancer. Science 266:1959-1960; Prolla, T. A, Pang, Q., Alani, E., Kolodner, R. A., and Liskay, R. M. 1994. MLH1, PMS1, and MSH2 Interaction during the initiation of DNA mismatch repair in yeast. Science 264:1091-1093). The gene may also be a PMSR gene such as hPMSR, PMSR2 and PMSR3, or a PMSL gene. The gene may also be MSH6. The dominant negative allele can be naturally occurring or made in the laboratory. The polynucleotide can be in the form of genomic DNA, cDNA, RNA, or a chemically synthesized polynucleotide or polypeptide. The molecule can be introduced into the cell by transformation, electroporation, mating, particle bombardment, or other method described in the literature.
Transformation is used herein as any process whereby a polynucleotide or polypeptide is introduced into a cell. The process of transformation can be carried out in a yeast culture using a suspension of cells. The yeast can be any type classified under the eukayotic kingdom as by international convention.
In general, transformation will be carried out using a suspension of cells but other methods can also be employed as long as a sufficient fraction of the treated cells incorporate the polynucleotide or polypeptide so as to allow transfected cells to be grown and utilized. The protein product of the polynucleotide may be transiently or stably expressed in the cell. Techniques for transformation are well known to those skilled in the art. Available techniques to introduce a polynucleotide or polypeptide into a yeast cell include but are not limited to electroporation, viral transduction, cell fusion, the use of spheroplasts or chemically competent cells (e.g., calcium chloride), and packaging of the polynucleotide together with lipid for fusion with the cells of interest. Once a cell has been transformed with the mismatch repair gene or protein, the cell can be propagated and manipulated in either liquid culture or on a solid agar matrix, such as a petri dish. If the transfected cell is stable, the gene will be expressed at a consistent level for many cell generations, and a stable, hypermutable yeast strain results.
An isolated yeast cell can be obtained from a yeast culture by chemically selecting strains using antibiotic selection of an expression vector. If the yeast cell is derived from a single cell, it is defined as a clone. Techniques for single-cell cloning of microorganisms such as yeast are well known in the art.
A polynucleotide encoding a dominant negative form of a mismatch repair protein can be introduced into the genome of yeast or propagated on an extra-chromosomal plasmid, such as the 2-micron plasmid. Selection of clones harboring a mismatch repair gene expression vector can be accomplished by plating cells on synthetic complete medium lacking the appropriate amino acid or other essential nutrient as described (J. C. Schneider and L. Guarente, Methods in Enzymology 194:373,1991). The yeast can be any species for which suitable techniques are available to produce transgenic microorganisms, such as but not limited to genera including Saccharomyces, Schizosaccharomyces, Pichia, Hansenula, Kluyveromyces and others.
Any method for making transgenic yeast known in the art can be used. According to one process of producing a transgenic microorganism, the polynucleotide is introduced into the yeast by one of the methods well known to those in the art. Next, the yeast culture is grown under conditions that select for cells in which the polynucleotide encoding the mismatch repair gene is either incorporated into the host genome as a stable entity or propagated on a self-replicating extra-chromosomal plasmid, and the protein encoded by the polynucleotide fragment transcribed and subsequently translated into a functional protein within the cell. Once transgenic yeast is engineered to harbor the expression construct, it is then propagated to generate and sustain a culture of transgenic yeast indefinitely.
Once a stable, transgenic yeast cell has been engineered to express a defective mismatch repair (MMR) protein, the yeast can be cultivated to create novel mutations in one or more target gene(s) of interest harbored within the same yeast cell. A gene of interest can be any gene naturally possessed by the yeast or one introduced into the yeast host by standard recombinant DNA techniques. The target gene(s) may be known prior to the selection or unknown. One advantage of employing such transgenic yeast cells to induce mutations in resident or extra-chromosomal genes within the yeast is that it is unnecessary to expose the cells to mutagenic insult, whether it is chemical or radiation, to produce a series of random gene alterations in the target gene(s). This is due to the highly efficient nature and the spectrum of naturally occurring mutations that result as a consequence of the altered mismatch repair process. However, it is possible to increase the spectrum and frequency of mutations by the concomitant use of either chemical and/or radiation together with MMR defective cells. The net effect of the combination treatment is an increase in mutation rate in the genetically altered yeast that are useful for producing new output traits. The rate of the combination treatment is higher than the rate using only the MMR-defective cells or only the mutagen with wild-type MMR cells.
MMR-defective yeast of the invention can be used in genetic screens for the direct selection of variant sub-clones that exhibit new output traits with commercially desirable applications. This permits one to bypass the tedious and time consuming steps of gene identification, isolation and characterization.
Mutations can be detected by analyzing the internally and/or externally mutagenized yeast for alterations in its genotype and/or phenotype. Genes that produce altered phenotypes in MMR-defective microbial cells can be discerned by any of a variety of molecular techniques well known to those in the art. For example, the yeast genome can be isolated and a library of restriction fragments of the yeast genome can be cloned into a plasmid vector. The library can be introduced into a xe2x80x9cnormalxe2x80x9d cell and the cells exhibiting the novel phenotype screened. A plasmid can be isolated from those normal cells that exhibit the novel phenotype and the gene(s) characterized by DNA sequence analysis. Alternatively, differential messenger RNA screen can be employed utilizing driver and tester RNA (derived from wild type and novel mutant, respectively) followed by cloning the differential transcripts and characterizing them by standard molecular biology methods well known to those skilled in the art. Furthermore, if the mutant sought is encoded by an extra-chromosomal plasmid, then following co-expression of the dominant negative MMR gene and the gene of interest, and following phenotypic selection, the plasmid can be isolated from mutant clones and analyzed by DNA sequence analysis using methods well known to those in the art. Phenotypic screening for output traits in MMR-defective mutants can be by biochemical activity and/or a readily observable phenotype of the altered gene product. A mutant phenotype can also be detected by identifying alterations in electrophoretic mobility, DNA binding in the case of transcription factors, spectroscopic properties such as IR, CD, X-ray crystallography or high field NMR analysis, or other physical or structural characteristics of a protein encoded by a mutant gene. It is also possible to screen for altered novel function of a protein in situ, in isolated form, or in model systems. One can screen for alteration of any property of the yeast associated with the function of the gene of interest, whether the gene is known prior to the selection or unknown.
The screening and selection methods discussed are meant to illustrate the potential means of obtaining novel mutants with commercially valuable output traits, but they are not meant to limit the many possible ways in which screening and selection can be carried out by those of skill in the art.
Plasmid expression vectors that harbor a mismatch repair (MMR) gene insert can be used in combination with a number of commercially available regulatory sequences to control both the temporal and quantitative biochemical expression level of the dominant negative MMR protein. The regulatory sequences can be comprised of a promoter, enhancer or promoter/enhancer combination and can be inserted either upstream or downstream of the MMR gene to control the expression level. The regulatory sequences can be any of those well known to those in the art, including but not limited to the AOX1, GAP, GAL1, GAL10, PHO5, and PGK promoters harbored on high or low copy number extra-chromosomal expression vectors or on constructs that are integrated into the genome via homologous recombination. These types of regulatory systems have been disclosed in scientific publications and are familiar to those skilled in the art.
Once a microorganism with a novel, desired output trait of interest is created, the activity of the aberrant MMR activity is desirably attenuated or eliminated by any means known in the art. These include but are not limited to removing an inducer from the culture medium that is responsible for promoter activation, curing a plasmid from a transformed yeast cell, and addition of chemicals, such as 5-fluoro-orotic acid to xe2x80x9cloop-outxe2x80x9d the gene of interest.
In the case of an inducibly controlled dominant negative MMR allele, expression of the dominant negative MMR gene will be turned on (induced) to generate a population of hypermutable yeast cells with new output traits. Expression of the dominant negative MMR allele can be rapidly turned off to reconstitute a genetically stable strain that displays a new output trait of commercial interest. The resulting yeast strain is now useful as a stable strain that can be applied to various commercial applications, depending upon the selection process placed upon it.
In cases where genetically deficient mismatch repair yeast [strains such as but not limited to: EC2416 (mutS delta umuDC), and mutL or mutY strains] are used to derive new output traits, transgenic constructs can be used that express wild type mismatch repair genes sufficient to complement the genetic defect and therefore restore mismatch repair activity of the host after trait selection [Grzesiuk, E. et.al. (Mutagenesis 13;127-132, 1998); Bridges, B. A., et.al. (EMBO J. 16:3349-3356, 1997); LeClerc, J. E., Science 15:1208-1211, 1996); Jaworski, A. et.al. (Proc. Nati. Acad. Sci USA 92:11019-11023, 1995)]. The resulting yeast is genetically stable and can be employed for various commercial applications.
The use of over-expression of foreign (exogenous, transgenic) mismatch repair genes from human and yeast such as MSH2, MLH1, MLH3, etc. have been previously demonstrated to produce a dominant negative mutator phenotype in yeast hosts (Shcherbakova, P. V., Hall, M. C., Lewis, M. S., Bennett, S. E., Martin, K. J., Bushel, P. R., Afshari, C. A., and Kunkel, T. A. Mol. Cell Biol. 21(3):940-951; Studamire B, Quach T, Alani, E. 1998. Saccharomyces cerevisiae Msh2p and Msh6p ATPase activities are both required during mismatch repair. Mol Cell Biol 18:7590-7601; Alani E, Sokolsky T, Studamire B, Miret J J, Lahue R S. 1997. Genetic and biochemical analysis of Msh2p-Msh6p: role of ATP hydrolysis and Msh2p-Msh6p subunit interactions in mismatch base pair recognition. Mol Cell Biol 17:2436-2447; Lipkin S M, Wang V, Jacoby R, Banerjee-Basu S, Baxevanis A D, Lynch H T, Elliott R M, and Collins F S. 2000. MLH3: a DNA mismatch repair gene associated with mammalian microsatellite instability. Nat Genet 24:27-35). In addition, the use of yeast strains expressing prokaryotic dominant negative MMR genes as well as hosts that have genomic defects in endogenous MMR proteins have also been previously shown to result in a dominant negative mutator phenotype (Evans, E., Sugawara, N., Haber, J. E., and Alani, E. Mol. Cell. 5(5):789-799, 2000; Aronshtam A, Marinus M G. 1996. Dominant negative mutator mutations in the mutL gene of Escherichia coli. Nucleic Acids Res 24:2498-2504; Wu T H, Marinus M G. 1994. Dominant negative mutator mutations in the mutS gene of Escherichia coli. J Bacteriol 176:5393-400; Brosh R M Jr, Matson S W. 1995. Mutations in motif II of Escherichia coli DNA helicase II render the enzyme nonfunctional in both mismatch repair and excision repair with differential effects on the unwinding reaction. J Bacteriol 177:5612-5621). However, the findings disclosed here teach the use of MMR genes, including the human PMSR2 gene (Nicolaides, N. C., Carter, K. C., Shell, B. K., Papadopoulos, N., Vogelstein, B., and Kinzler, K. W. 1995. Genomic organization of the human PMS2 gene family. Genomics 30:195-206), the related PMS134 truncated MMR gene (Nicolaides N. C., Kinzler, K. W., and Vogelstein, B. 1995. Analysis of the 5xe2x80x2 region of PMS2 reveals heterogenous transcripts and a novel overlapping gene. Genomics 29:329-334), the plant mismatch repair genes (U.S. patent application Ser. No. 09/749,601) and those genes that are homologous to the 134 N-terminal amino acids of the PMS2 gene to create hypermutable yeast.
DNA mutagens can be used in combination with MMR defective yeast hosts to enhance the hypermutable production of genetic alterations. This further reduces MMR activity and is useful for generation of microorganisms with commercially relevant output traits.
The ability to create hypermutable organisms using dominant negative alleles can be used to generate innovative yeast strains that display new output features useful for a variety of applications, including but not limited to the manufacturing industry, for the generation of new biochemicals, for detoxifying noxious chemicals, either by-products of manufacturing processes or those used as catalysts, as well as helping in remediation of toxins present in the environment, including but not limited to polychlorobenzenes (PCBs), heavy metals and other environmental hazards. Novel yeast strains can be selected for enhanced activity to either produce increased quantity or quality of a protein or non-protein therapeutic molecule by means of biotransformation. Biotransformation is the enzymatic conversion of one chemical intermediate to the next intermediate or product in a pathway or scheme by a microbe or an extract derived from the microbe. There are many examples of biotransformation in use for the commercial manufacturing of important biological and chemical products, including penicillin G, erythromycin, and clavulanic acid. Organisms that are efficient at conversion of xe2x80x9crawxe2x80x9d materials to advanced intermediates and/or final products also can perform biotransformation (Beny, A. Trends Biotechnol. 14(7):250-256). The ability to control DNA hypermutability in host yeast strains using a dominant negative MMR (as described above) allows for the generation of variant subtypes that can be selected for new phenotypes of commercial interest, including but not limited to organisms that are toxin-resistant, have the capacity to degrade a toxin in situ or the ability to convert a molecule from an intermediate to either an advanced intermediate or a final product. Other applications using dominant negative MMR genes to produce genetic alteration of yeast hosts for new output traits include but are not limited to recombinant production strains that produce higher quantities of a recombinant polypeptide as well as the use of altered endogenous genes that can transform chemical or catalyze manufacturing downstream processes. A regulatable dominant negative MMR phenotype can be used to produce a yeast strain with a commercially beneficial output trait. Using this process, single-celled yeast cells expressing a dominant negative MMR can be directly selected for the phenotype of interest. Once a selected yeast with a specified output trait is isolated, the hypermutable activity of the dominant negative MMR allele can be turned-off by several methods well known to those skilled in the art. For example, if the dominant-negative allele is expressed by an inducible promoter system, the inducer can be removed or depleted. Such systems include but are not limited to promoters such as: lactose inducible GALi-GAL10 promoter (M. Johnston and R. W. Davis, Mol. Cell Biol. 4:1440, 1984); the phosphate inducible PHO5 promoter (A. Miyanohara, A. Toh-e, C. Nosaki, F. Nosaki, F. Hamada, N. Ohtomo, and K. Matsubara. Proc. Nati. Acad. Sci. U.S.A. 80:1, 1983); the alcohol dehydrogenase I (ADH) and 3-phosphoglycerate kinase (PGK) promoters, that are considered to be constitutive but can be repressed/de-repressed when yeast cells are grown in non-fermentable carbon sources such as but not limited to lactate (G. Ammerer, Methods in Enzymology 194:192, 1991; J. Mellor, M. J. Dobson, N. A. Roberts, M. F. Tuite, J. S. Emtage, S. White, D. A. Lowe, T. Patel, A. J. Kingsman, and S. M. Kingsman, Gene 24:563, 1982); S. Hahn and L. Guarente, Science 240:317, 1988); Alcohol oxidase (AOX) in Pichia vastoris (Tschopp, J F, Brust, P F, Cregg, J M, Stillman, C A, and Gingeras, T R. Nucleic Acids Res. 15(9):3859-76, 1987; and the thiamine repressible expression promoter nmt1 in Schizosaccharomyces pombe (Moreno, M B, Duran, A., and Ribas, J C. Yeast 16(9):861-72, 2000). Yeast cells can be transformed by any means known to those skilled in the art, including chemical transformation with LiC1 (Mount, R. C., Jordan, B. E., and Hadfield, C. Methods Mol. Biol. 53:139-145,1996) and electroporation (Thompson, J R, Register, E., Curotto, J., Kurtz, M. and Kelly, R. Yeast 14(6):565-71, 1998). Yeast cells that have been transformed with DNA can be selected for growth by a variety of methods, including but not restricted to selectable markers (URA3; Rose, M., Grisafi, P., and Botstein, D. Gene 29:113,1984; LEU2; A. Andreadis, Y., Hsu, M., Hermodson, G., Kohihaw, and P. Schimmel. J. Biol. Chem. 259:8059,1984; ARG4; G. Tschumper and J. Carbon. Gene 10:157, 1980; and HIS3; K. Struhl, D. T. Stinchcomb, S., Scherer, and R. W. Davis Proc. Natl. Acad. Sci. U.S.A. 76:1035,1979) and drugs that inhibit growth of yeast cells (tunicamycin, TUN; S. Hahn, J., Pinkham, R. Wei, R., Miller, and L. Guarente. Mol. Cell Biol. 8:655,1988). Recombinant DNA can be introduced into yeast as described above and the yeast vectors can be harbored within the yeast cell either extra-chromosomally or integrated into a specific locus. Extra-chromosomal based yeast expression vectors can be either high copy based (such as the 2-.mu.m vector Yep13; A. B. Rose and J. R. Broach, Methods in Enzymology 185:234,1991), low copy centromeric vectors that contain autonomously replicating sequences (ARS) such as YRp7 (M. Fitzgerald-Hayes, L. Clarke, and J. Carbon, Cell 29:235,1982) and well as integration vectors that permit the gene of interest to be introduced into specified locus within the host genome and propagated in a stable maimer (R. J. Rothstein, Methods in Enzymology 101:202, 1991). Ectopic expression of MMR genes in yeast can be attenuated or completely eliminated at will by a variety of methods, including but not limited to removal from the medium of the specific chemical inducer (e.g., deplete galactose that drives expression of the GAL10 promoter in Saccharomyces cerevisiae or methanol that drives expression of the AOX1 promoter in Pichia pastoris), extra-chromosomally replicating plasmids can be xe2x80x9ccuredxe2x80x9d of expression plasmid by growth of cells under non-selective conditions (e.g. YEp13 harboring cells can be propagated in the presence of leucine) and cells that have genes inserted into the genome can be grown with chemicals that force the inserted locus to xe2x80x9cloop-outxe2x80x9d (e.g., integrants that have URA3 can be selected for loss of the inserted gene by growth of integrants on 5-fluoro-orotic acid (J. D. Boeke, F. LaCroute and G. R. Fink. Mol. Gen. Genet. 197:345-346,1984). Whether by withdrawal of inducer or treatment of yeast cells with chemicals, removal of MMR expression results in the re-establishment of a genetically stable yeast cell-line. Thereafter, the lack of mutant MMR allows the endogenous, wild type MMR activity in the host cell to function normally to repair DNA. The newly generated mutant yeast strains that exhibit novel, selected output traits are suitable for a wide range of commercial processes or for gene/protein discovery to identify new biomolecules that are involved in generating a particular output trait. While it has been documented that MMR deficiency can lead to as much as a 1000-fold increase in the endogenous DNA mutation rate of a host, there is no assurance that MMR deficiency alone will be sufficient to alter every gene within the DNA of the host bacterium to create altered biochemicals with new activity(s). Therefore, the use of chemical mutagens and their respective analogues such as ethidium bromide, EMS, MNNG, MNu, Tamoxifen, 8-Hydroxyguanine, as well as others such as those taught in: Khromov-Borisov, N. N., et al. (Mutat. Res. 43 0:55-74, 1999); Ohe, T., et al. (Mutat. Res. 429:189-199, 1999); Hour, T. C. et al. (Food Chem. Toxicol. 37:569-579, 1999); Hrelia, P., et al. (Chem. Biol. Interact. 118:99-111, 1999); Garganta, F., et al. (Environ. Mol. Mutagen. 33:75-85, 1999); Ukawa-Ishikawa S., et al. (Mutat. Res. 412:99-107, 1998); the website having the URL address: www host server, ehs.utah.edu domain name, ohh directory, mutagens subdirectory, etc. can be used to further enhance the spectrum of mutations and increase the likelihood of obtaining alterations in one or more genes that can in turn generate host yeast with a desired new output trait(s). Mismatch repair deficiency leads to hosts with an increased resistance to toxicity by chemicals with DNA damaging activity. This feature allows for the creation of additional genetically diverse hosts when mismatch defective yeast are exposed to such agents, which would be otherwise impossible due to the toxic effects of such chemical mutagens [Colella, G., et al. (Br. J. Cancer 80:338-343, 1999); Moreland, N. J., et al. (Cancer Res. 59:2102-2106, 1999); Humbert, O., et. al. (Carcinogenesis 20:205-214, 1999); Glaab, W. E., et al. (Mutat. Res. 398:197-207, 1998)]. Moreover, mismatch repair is responsible for repairing chemically-induced DNA adducts, therefore blocking this process could theoretically increase the number, types, mutation rate and genomic alterations of a yeast1 [Rasmussen, L. J. et al. (Carcinogenesis 17:2085-2088, 1996); Sledziewska-Gojska, E., et al. (Mutat. Res. 383:31-37, 1997); and Janion, C. et al. (Mutat. Res. 210:15-22, 1989)]. In addition to the chemicals listed above, other types of DNA mutagens include ionizing radiation and UV-irradiation, which is known to cause DNA mutagenesis in yeast, can also be used to potentially enhance this process (Lee C C, Lin H K, Lin J K, 1994. A reverse mutagenicity assay for alkylating agents based on a point mutation in the beta-lactamase gene at the active site serine codon. Mutagenesis 9:401-405; Vidal A, Abril N, Pueyo C. 1995. DNA repair by Ogt alkyltransferase influences EMS mutational specificity. Carcinogenesis 16:817-821). These agents, which are extremely toxic to host cells and therefore result in a decrease in the actual pool size of altered yeast cells are more tolerated in MMR defective hosts and in turn permit an enriched spectrum and degree of genomic mutagenesis.
The above disclosure generally describes the present invention. A more complete understanding can be obtained by reference to the following specific examples that will be provided herein for purposes of illustration only, and are not intended to limit the scope of the invention.