Patent Publication Number: US-10767142-B2

Title: Proteases with improved enzyme stability in detergents

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application is a U.S. National-Stage entry under 35 U.S.C. § 371 based on International Application No PCT/EP2017/055277, filed Mar. 7, 2017 which was published under PCT Article 21(2) and which claims priority to German Application No. 10 2016 204 815.5, filed Mar. 23, 2016, which are all hereby incorporated in their entirety by reference. 
     TECHNICAL FIELD 
     The present disclosure lies in the field of enzyme technology. The present disclosure relates to proteases from  Bacillus pumilus  of which the amino-acid sequence has been altered, in particular with respect to use in washing and cleaning agents, in order to impart improved storage stability thereto, to the nucleic acids which code for said proteases, and to the preparation of said proteases. The present disclosure further relates to uses of said proteases, to methods in which said proteases are used, and to agents, in particular washing and cleaning agents, which contain said proteases. 
     BACKGROUND 
     Proteases are among the industrially most significant enzymes of all. In the context of washing and cleaning agents, proteases are the longest established enzymes that are contained in virtually all modern, high-performance washing and cleaning agents. They cause the breakdown of protein-containing stains on the item to be cleaned. Of these proteases, subtilisin-type proteases (subtilases, subtilopeptidases, EC 3.4.21.62) are particularly significant, which proteases are serine proteases owing to the catalytically active amino acids. Said proteases act as non-specific endopeptidases and hydrolyze any acid amide bonds that are within peptides or proteins. Their pH optimum is usually in the highly alkaline range. An overview of this family is found, for example, in the article “Subtilases: Subtilisin-like Proteases” by R. Siezen, pages 75-95 in “Subtilisin enzymes”, published by R. Bott and C. Betzel, New York, 1996. Subtilases are formed naturally by microorganisms. Of these, subtilisins that are formed by and secreted from  Bacillus  species should be mentioned in particular as the most significant group within the subtilases. 
     Examples of the subtilisin-type proteases that are preferably used in washing and cleaning agents are the subtilisins BPN′ and Carlsberg, protease PB92, subtilisins 147 and 309, protease from  Bacillus lentus , in particular from  Bacillus lentus  DSM 5483, subtilisin DY, the enzymes thermitase, proteinase K and proteases TW3 and TW7, which belong to the subtilases but no longer to the subtilisins in the narrower sense, and variants of the mentioned proteases which have an altered amino-acid sequence by comparison with the starting protease. Proteases are altered, selectively or randomly, by methods known from the prior art, and are thereby optimized for use in washing and cleaning agents, for example. These methods include point, deletion or insertion mutagenesis, or fusion with other proteins or protein parts. Therefore, variants that are appropriately optimized are known for most of the proteases known from the prior art. 
     The European patent application EP 2 016 175 A1 discloses a protease from  Bacillus pumilus  provided for washing and cleaning agents, for example. In general, only selected proteases are at all suitable for use in liquid surfactant-containing preparations. In preparations of this kind, many proteases do not demonstrate sufficient catalytic performance or stability. In particular when used in washing agents which are usually purchased by the consumer in such an amount that several weeks or months may pass until the washing agent is finally consumed (i.e. the washing agents need to be stored by the consumer for weeks or months), many proteases demonstrate instability, which in turn leads to insufficient catalytic activity during the washing process. In phosphonate-containing liquid surfactant preparations, this problem is even more serious, for example due to the complex-forming properties of the phosphonates or due to disadvantageous interactions between the phosphonate and the protease. 
     As a result, protease- and surfactant-containing liquid formulations from the prior art have the disadvantage that, after storing, said formulations often do not have satisfactory proteolytic activity and therefore do not demonstrate optimal cleaning performance on protease-sensitive stains. 
     BRIEF SUMMARY 
     A protease is provided herein. The protease has an amino-acid sequence which has an at least about 70% sequence identity to the amino acid sequence set forth in SEQ ID NO:2 over the entire length thereof. The protease has an amino acid substitution at one or more of the positions P9, Q62, D101, N130, G166, N187, 5216, N238 and Q271, based on the numbering according to SEQ ID NO:2. 
     A method for preparing a protease is also provided herein. The method includes substituting the amino acids at the positions which correspond to positions 9, 62, 101, 130, 166, 187, 216, 238 and 271 in SEQ ID NO:2 in a starting protease of which the sequence is at least about 70% identical to the amino acid sequence set forth in SEQ ID NO:2 over the entire length thereof. 
    
    
     DETAILED DESCRIPTION 
     The following detailed description is merely exemplary in nature and is not intended to limit the disclosure or the application and uses of the subject matter as described herein. Furthermore, there is no intention to be bound by any theory presented in the preceding background or the following detailed description. 
     It has surprisingly now been found that a subtilisin-type protease from  Bacillus pumilus  or a reasonably similar protease (in terms of sequence identity) which has an amino-acid substitution at least one of the positions P9, Q62, D101, N130, G166, N187, 5216, N238 or Q271, in each case based on the numbering according to SEQ ID NO:2, is improved with regard to (storage) stability with respect to the wild type form, and is therefore particularly suitable for use in washing or cleaning agents. 
     In a first aspect, the present disclosure therefore relates to a protease having an amino-acid sequence which is at least about 70% identical to the amino-acid sequence shown in SEQ ID NO:2 over the entire length thereof and has an amino-acid substitution at least one of the positions P9, Q62, D101, N130, G166, N187, 5216, N238 or Q271, based in each case on the numbering according to SEQ ID NO:2. 
     The present disclosure also relates to a method for preparing a protease, comprising substituting an amino acid at least one position which corresponds to the position 9, 62, 101, 130, 166, 187, 216, 238 or 271 in SEQ ID NO:2 in a starting protease of which the sequence is at least about 70% identical to the amino-acid sequence shown in SEQ ID NO:2 over the entire length thereof, such that the protease has at least one of the amino-acid substitutions P9T/S/H, Q62E, D101E, N130D, G166S, N187H, S216C, N238K or Q271E. 
     A “protease” within the meaning of the present patent application therefore covers both the protease as such and a protease prepared using a method as contemplated herein. All comments made with regard to the protease therefore relate to both the protease as such and proteases prepared using corresponding methods. 
     Other aspects of the present disclosure relate to the nucleic acids which code for these proteases, to non-human host cells which contain proteases or nucleic acids as contemplated herein, to agents, in particular washing and cleaning agents, which comprise proteases as contemplated herein, to washing and cleaning methods, and to uses of the proteases as contemplated herein in washing or cleaning agents for removing fat-containing stains. 
     “At least one”, as used herein, means one or more, i.e. one, two, three, four, five, six, seven, eight, nine, ten, eleven, twelve, thirteen, fourteen, or more. 
     The present disclosure is based on the surprising finding of the inventor that an amino-acid substitution at least one of the positions 9, 62, 101, 130, 166, 187, 216, 238 or 271 of the protease from  Bacillus pumilus  according to SEQ ID NO:2 in a protease which has an amino-acid sequence that is at least about 70% identical to the amino-acid sequence shown in SEQ ID NO:2 such that the amino acids 9T/S/H, 62E, 101E, 130D, 166S, 187H, 216C, 238K or 271E are present at the corresponding positions brings about improved (storage) stability of this altered protease in washing and cleaning agents. This is particularly surprising since none of the above-mentioned amino-acid substitutions have previously been associated with increased stability of the protease. 
     The proteases as contemplated herein have increased stability in washing or cleaning agents, in particular when stored for about 3 or more days, about 4 or more days, about 7 or more days, about 10 or more days, about 12 or more days or about 14 or more days. Proteases of this kind that are improved in terms of performance provide for improved washing results on proteolytically sensitive stains in a wide temperature range. 
     Proteases as contemplated herein have enzymatic activity, i.e. they are capable of hydrolyzing peptides and proteins, in particular in a washing or cleaning agent. A protease as contemplated herein is therefore an enzyme which catalyzes the hydrolysis of amide/peptide bonds in protein/peptide substrates and is therefore capable of cleaving peptides or proteins. Furthermore, a protease as contemplated herein is preferably a mature protease, i.e. the catalytically active molecule without signal peptide(s) and/or propeptide(s). Unless indicated otherwise, the specified sequences also each relate to mature (processed) enzymes. 
     In various embodiments, the protease as contemplated herein contains at least one amino-acid substitution which is selected from the group including of P9T/S/H, Q62E, D101E, N130D, G166S, N187H, S216C, N238K and Q271E, based in each case on the numbering according to SEQ ID NO:2. In more preferred embodiments, the protease as contemplated herein contains one of the following amino-acid substitution variants: (i) P9T; (ii) Q271E; (iii) P9S and N238K; (iv) P9H; (v) N187H; (vi) S216C; (vii) Q62E and N130D; (viii) Q62E, D101E, N130D, G166S and Q271E; or (ix) P9T, N187H, S216C and Q271E, the numbering being based in each case on the numbering according to SEQ ID NO:2. 
     In a further embodiment of the present disclosure, the protease has an amino-acid sequence that is at least about 70%, about 71%, about 72%, about 73%, about 74%, about 75%, about 76%, about 77%, about 78%, about 79%, about 80%, about 81%, about 82%, about 83%, about 84%, about 85%, about 86%, about 87%, about 88%, about 89%, about 90%, about 90.5%, about 91%, about 91.5%, about 92%, about 92.5%, about 93%, about 93.5%, about 94%, about 94.5%, about 95%, about 95.5%, about 96%, about 96.5%, about 97%, about 97.5%, about 98%, about 98.5% and about 98.8% identical to the amino-acid sequence shown in SEQ ID NO:2 over the entire length thereof, and has one or more of the amino acid substitutions 9T/S/H, 62E, 101E, 130D, 166S, 187H, 216C, 238K or 271E at least one of the positions 9, 62, 101, 130, 166, 187, 216, 238 or 271 in the numbering according to SEQ ID NO:2. In the context of the present disclosure, the feature whereby a protease has the stated substitutions means that it contains at least one of the corresponding amino acids at the corresponding positions, i.e. not all of the nine positions are otherwise mutated or deleted, for example by fragmentation of the protease. The amino-acid sequences of proteases of this kind that are preferred as contemplated herein are shown in SEQ ID NOs 3-11. 
     The identity of nucleic-acid or amino-acid sequences is determined by a sequence comparison. This sequence comparison is based on the BLAST algorithm (cf. for example Altschul, S. F., Gish, W., Miller, W., Myers, E. W. &amp; Lipman, D. J. (1990) “Basic local alignment search tool.” J. Mol. Biol. 215:403-410 and Altschul, Stephan F., Thomas L. Madden, Alejandro A. Schaffer, Jinghui Zhang, Hheng Zhang, Webb Miller, and David J. Lipman (1997): “Gapped BLAST and PSI-BLAST: a new generation of protein database search programs”; Nucleic Acids Res., 25, pages 3389-3402) which is established and commonly used in the prior art and is carried out, in principle, by similar series of nucleotides or amino acids in the nucleic-acid or amino-acid sequences being assigned to one another. The assignment of the relevant positions shown in a table is referred to as an “alignment”. Another algorithm available from the prior art is the FASTA algorithm. Sequence comparisons (alignments), in particular multiple sequence comparisons, are generated using computer programs. For example, the Clustal series (cf. for example Chenna et al. (2003): Multiple sequence alignment with the Clustal series of programs. Nucleic Acid Research 31, 3497-3500), T-Coffee (cf. for example Notredame et al. (2000): T-Coffee: A novel method for multiple sequence alignments. J. Mol. Biol. 302, 205-217) or programs based on these programs or algorithms are often used. Also possible are sequence comparisons (alignments) using the computer program Vector NTI® Suite 10.3 (Invitrogen Corporation, 1600 Faraday Avenue, Carlsbad, Calif., USA) with the specified standard parameters, the AlignX-Modul of which program for the sequence comparisons is based on ClustalW. Unless indicated otherwise, the sequence identity specified herein is determined using the BLAST algorithm. 
     A comparison of this kind makes it possible to specify the similarity between the compared sequences. This similarity is usually expressed in percent identity, i.e. the percentage of identical nucleotides or amino-acid residues at the same positions or at positions that correspond to one another in an alignment. In amino-acid sequences, the broader concept of “homology” factors in conserved amino-acid exchanges, i.e. amino acids having similar chemical activity, since these usually have similar chemical activities within the protein. Therefore, the similarity between the compared sequences can also be expressed in percent homology or percent similarity. Information relating to identity and/or homology may apply to the entirety of the polypeptides or genes or only to individual segments. Homologous or identical segments of different nucleic-acid or amino-acid sequences are therefore defined by matches in the sequences. Segments of this kind often have identical functions. Said segments may be small and only comprise a few nucleotides or amino acids. Segments that are this small often perform functions that are essential to the overall activity of the protein. Therefore, it may be expedient for sequence matches to only relate to individual, optionally small, segments. However, unless indicated otherwise, information relating to identity or homology in the present application relates to the entire length of the nucleic-acid or amino-acid sequence specified in each case. 
     In the context of the present disclosure, if it is stated that an amino-acid position corresponds to a numerically identified position in SEQ ID NO:2, this means that the corresponding position is assigned to the numerically identified position in SEQ ID NO:2 in an alignment as defined above. 
     In a further embodiment of the present disclosure, the protease cleaning performance is not significantly reduced by comparison with a protease which has an amino-acid sequence that corresponds to the amino-acid sequence shown in SEQ ID NO:2, i.e. said protease has at least about 80%, preferably at least about 100%, more preferably at least about 110%, of the reference washing performance. The cleaning performance can be determined in a washing system which contains a washing agent in a dosage of between from about 4.5 and about 7.0 grams per liter of washing liquor, and the protease, the proteases to be compared being used in the same concentration (based on the active protein) and the cleaning performance with respect to a stain on cotton is determined by measuring the extent to which the washed textiles have been cleaned. For example, the washing process can be carried out for about 70 minutes at a temperature of about 40° C., and the water can have a water hardness of between from about 15.5 and about 16.5° (German degree of hardness). The concentration of the protease in the washing agent intended for this washing system is from about 0.001 to about 0.1 wt. %, preferably from about 0.01 to about 0.06 wt. %, based on the purified active protein. 
     A liquid reference washing agent for a washing system of this kind can be composed as follows (all amounts are given in percent by weight): 4.4% of alkyl benzene sulfonic acid, about 5.6% of further anionic surfactants, about 2.4% of C12-C18 Na salts of fatty acids (soaps), about 4.4% of non-ionic surfactants, about 0.2% of phosphonates, about 1.4% of citric acid, about 0.95% of NaOH, about 0.01% of defoamers, about 2% of glycerol, about 0.08% of preservatives, about 1% of ethanol, and the remaining percentage of demineralized water. The dosage of the liquid washing agent is preferably between from about 4.5 and about 6.0 grams per liter of washing liquor, for example about 4.7, about 4.9 or about 5.9 grams per liter of washing liquor. Washing is preferably carried out within a pH range of between from about pH 8 and about pH 10.5, preferably between from about pH 8 and about pH 9. 
     Within the scope of the present disclosure, the cleaning performance is determined, for example, at about 40° C. using a liquid washing agent as specified above, the washing process preferably being carried out for about 60 minutes at about 600 rpm. 
     The degree of whiteness, i.e. the lightening of the stains, is determined using optical measurement methods, preferably photometrically, as a measure of cleaning performance. A device suitable for this purpose is the spectrometer Minolta CM508d, for example. The devices used for the measurement are usually calibrated, in advance, against a white standard, preferably a white standard that is supplied therewith. 
     Each protease being applied in an identical manner in terms of activity ensures that the relevant enzymatic properties, i.e. for example cleaning performance on particular stains, are compared even if there is some kind of divergence in the ratio of active substance to overall protein (the values for specific activity). In general, low specific activity can be compensated for by adding a larger amount of protein. 
     Otherwise, a person skilled in the art of enzyme technology is familiar with methods for determining protease activity, and he uses said methods as a matter of routine. For example, methods of this kind are disclosed in Tenside, Band 7 (1970), pages 125-132. Alternatively, protease activity can be determined by releasing the chromophore para-nitroaniline (pNA) from the substrate suc-L-Ala-L-Ala-L-Pro-L-Phe-p-nitroanilide (AAPF). The protease cleaves the substrate and releases pNA. The release of pNA causes an increase in the extinction at about 410 nm, the temporal progression of which is a measure of enzymatic activity (cf. Del Mar et al., 1979). The measurement is taken at a temperature of about 25° C., a pH of about 8.6, and a wavelength of about 410 nm. The measurement time is 5 min and the measurement interval is from about 20 s to about 60 s. Protease activity is usually expressed in protease units (PU). Suitable protease activities are, for example, about 2.25, about 5 or about 10 PU per ml of washing liquor. However, the protease activity is not zero. 
     An alternative test for establishing the proteolytic activity of the proteases as contemplated herein is an optical measurement method, preferably a photometric method. The test suitable for this purpose comprises the protease-dependent cleavage of the substrate protein casein. Said protein is cleaved by the protease into a plurality of smaller subproducts. All of these subproducts have an increased absorption at about 290 nm by comparison with uncleaved casein, this increased absorption being determined using a photometer, and it thus being possible to draw a conclusion on the enzymatic activity of the protease. 
     The protein concentration can be determined using known methods, for example the BCA method (bicinchoninic acid; 2,2′-biquinolyl-4,4′-dicarboxylic acid) or the Biuret method (A. G. Gornall, C. S. Bardawill and M. M. David, J. Biol. Chem., 177 (1948), pages 751-766). The active protein concentration can be determined, in this respect, by titrating the active centers using a suitable irreversible inhibitor and determining the residual activity (cf. M. Bender et al., J. Am. Chem. Soc. 88, 24 (1966), pages 5890-5913). 
     In addition to the aforementioned amino-acid alterations, proteases as contemplated herein can have further amino-acid alterations, in particular amino-acid substitutions, insertions or deletions. Proteases of this kind are developed, for example, by targeted genetic alteration, i.e. by mutagenesis methods, and optimized for particular uses or in respect of specific properties (for example in respect of their catalytic activity, stability, etc.). Furthermore, nucleic acids as contemplated herein can be incorporated in recombination approaches and are thus used to produce completely new types of proteases or other polypeptides. 
     The aim is to introduce targeted mutations, such as substitutions, insertions or deletions, into known molecules, in order to improve the cleaning performance of enzymes as contemplated herein, for example. For this purpose, in particular the surface charges and/or isoelectric point of the molecules, and thus their interactions with the substrate, can be altered. For example, the net charge of the enzymes can be changed in order to thereby influence the substrate binding, in particular for use in washing and cleaning agents. Alternatively, or in addition, the stability of the protease can be increased further still, and thus the cleaning performance thereof can be improved, by one or more appropriate mutations. Advantageous properties of individual mutations, e.g. individual substitutions, may complement one another. A protease that has already been optimized in terms of particular properties, for example in terms of the stability thereof during storage, can therefore also be developed within the scope of the present disclosure. 
     In order to describe substitutions that affect exactly one amino-acid position (amino-acid exchanges), the following convention is used herein: the internationally conventional single-letter code of the naturally present amino acid is given first, and then the associated sequence position, and finally the amino acid that has been added. If a position can be replaced by a number of alternative amino acids, the alternatives are separated from one another by slashes. For example, P9T/S/H means that proline can be replaced at position 9 by threonine, serine or histidine. For insertions, additional amino acids are indicated after the sequence position. For deletions, the amino acid that has been removed is replaced with a symbol, for example a star or a dash, or a Δ is put before the corresponding position. For example, P9T describes the substitution of proline at position 9 by threonine, P9KT describes the insertion of threonine after the amino acid lysine at position 9 and P9* or ΔP9 describes the deletion of proline at position 9. This nomenclature is known to a person skilled in the art of enzyme technology. 
     Therefore, the present disclosure further relates to a protease which can be obtained from a protease as described above acting as a starting molecule by employing one or more conservative amino-acid substitutions, the protease still having in the numbering according to SEQ ID NO:2 at least one of the amino-acid substitutions as contemplated herein at the positions which correspond to positions 9, 62, 101, 130, 166, 187, 216, 238 and 271 in SEQ ID NO:2, as described above. The term “conservative amino-acid substitutions” means the exchange (substitution) of an amino-acid residue with another amino-acid residue, this exchange not resulting in a change in the polarity or charge at the position of the exchanged amino acid, e.g. the exchange of a nonpolar amino-acid residue with another nonpolar amino-acid residue. Within the scope of the present disclosure, conservative amino-acid substitutions include for example: G=A=S, I=V=L=M, D=E, N=Q, K=R, Y=F, S=T, G=A=l=V=L=M=Y=F=W=P=S=T. 
     Alternatively or in addition, the protease can be obtained from a protease as contemplated herein acting as a starting molecule by employing fragmentation, deletion, insertion or substitution mutagenesis and has an amino-acid sequence which matches that of the starting molecule over a length of at least about 50, about 60, about 70, about 80, about 90, about 100, about 110, about 120, about 130, about 140, about 150, about 160, about 170, about 180, about 190, about 200, about 210, about 220, about 230, about 240, about 250, about 260, about 265, about 270, about 271, about 272, about 273 or about 274 interconnected amino acids, the amino-acid substitutions contained in the starting molecule still being present at one or more of the positions which correspond to positions 9, 62, 101, 130, 166, 187, 216, 238 and 271 in SEQ ID NO:2. 
     It is thus possible, for example, for individual amino acids to be deleted from the enzyme termini or loops, without this resulting in the proteolytic activity being lost or reduced. Furthermore, by employing fragmentation, deletion, insertion or substitution mutagenesis of this kind, the allergenicity of relevant enzymes, for example, can also be reduced and thus the usability thereof can be improved overall. The enzymes advantageously still have their proteolytic activity even after the mutagenesis, i.e. the proteolytic activity thereof corresponds at least to that of the starting enzyme, i.e. in a preferred embodiment, the proteolytic activity is at least about 80%, preferably at least about 90%, of the activity of the starting enzyme. Other substitutions can also have advantageous effects. It is possible to exchange a single amino acid or several interconnected amino acids with other amino acids. 
     Alternatively or additionally, said protease can be obtained as a starting molecule from a protease as contemplated herein by employing one or more conservative amino-acid substitutions, the protease having at least one of the amino-acid substitutions P9T/S/H, Q62E, D101E, N130D, G166S, N187H, S216C, N238K or Q271E at the positions which correspond to the positions 9, 62, 101, 130, 166, 187, 216, 238 and 271 according to SEQ ID NO:2. 
     In other embodiments, said protease can be obtained as a starting molecule from a protease as contemplated herein by employing fragmentation, deletion, insertion or substitution mutagenesis, and has an amino-acid sequence which matches that of the starting molecule over a length of at least about 50, about 60, about 70, about 80, about 90, about 100, about 110, about 120, about 130, about 140, about 150, about 160, about 170, about 180, about 190, about 200, about 210, about 220, about 230, about 240, about 250, about 260, about 265, about 270, about 271, about 272, about 273 or about 274 interconnected amino acids, the protease having at least one of the amino-acid substitutions P9T/S/H, Q62E, D101E, N130D, G166S, N187H, S216C, N238K or Q271E at the positions which correspond to positions 9, 62, 101, 130, 166, 187, 216, 238 and 271 according to SEQ ID NO:2. 
     In this case, the other amino-acid positions are defined by an alignment of the amino-acid sequence of a protease as contemplated herein with the amino-acid sequence of the protease from  Bacillus pumilus , as shown in SEQ ID NO:2. Furthermore, the assignment of the positions is determined by the mature protein. In particular, this assignment is also used if the amino-acid sequence of a protease as contemplated herein has a higher number of amino-acid residues than the protease from  Bacillus pumilus  according to SEQ ID NO:2. Proceeding from the mentioned positions in the amino-acid sequence of the protease from  Bacillus pumilus , the alteration positions in a protease as contemplated herein are those which are precisely assigned to these positions in an alignment. 
     Advantageous positions for sequence alterations, in particular substitutions, of the protease from  Bacillus pumilus  which when transferred to homologous positions of the proteases as contemplated herein are preferably of significance and impart advantageous functional properties to the protease are therefore the positions which correspond to positions 9, 62, 101, 130, 166, 187, 216, 238 and 271 in SEQ ID NO:2, i.e. in the numbering according to SEQ ID NO:2, in an alignment. At the stated positions, the following amino-acid residues are present in the wild-type molecule of the protease from  Bacillus pumilus : P9, Q62, D101, N130, G166, N187, 5216, N238 and Q271. 
     Further confirmation of the correct assignment of the amino acids to be altered, i.e. in particular of the functional correspondence thereof, can be provided by comparison tests during which the two positions assigned to one another on the basis of an alignment are altered in the same way in the two proteases being compared with one another and it is observed whether the enzymatic activity is altered in the same way in the two proteases. If, for example, an amino-acid exchange at a particular position of the protease from  Bacillus pumilus  according to SEQ ID NO:2 is associated with a change in an enzymatic parameter, for example with the increase in the K M  value, and if a corresponding change in the enzymatic parameter, thus for example also an increase in the K M  value, is observed in a protease variant as contemplated herein of which the amino-acid exchange was achieved by the same added amino acid, this is considered to be confirmation of the correct assignment. 
     All elements specified can also be applied to the methods as contemplated herein for preparing a protease. A method as contemplated herein therefore further comprises one or more of the following method steps: 
     a) introducing one or more conservative amino-acid substitutions, the protease having at least one of the amino-acid substitutions P9T/S/H, Q62E, D101E, N130D, G166S, N187H, S216C, N238K or Q271E at the positions which correspond to positions 9, 62, 101, 130, 166, 187, 216, 238 and 271 according to SEQ ID NO:2;
 
b) altering the amino-acid sequence by employing fragmentation, deletion, insertion or substitution mutagenesis such that the protease has an amino-acid sequence which matches that of the starting molecule over a length of at least about 50, about 60, about 70, about 80, about 90, about 100, about 110, about 120, about 130, about 140, about 150, about 160, about 170, about 180, about 190, about 200, about 210, about 220, about 230, about 240, about 250, about 260, about 265, about 270, about 271, about 272, about 273 or about 274 interconnected amino acids, the protease having at least one of the amino-acid substitutions P9T/S/H, Q62E, D101E, N130D, G166S, N187H, S216C, N238K or Q271E at the positions which correspond to positions 9, 62, 101, 130, 166, 187, 216, 238 and 271 according to SEQ ID NO:2.
 
     All comments made also apply to the methods as contemplated herein. 
     In further embodiments of the present disclosure, the protease or the protease prepared using a method as contemplated herein is still at least about 70%, about 71%, about 72%, about 73%, about 74%, about 75%, about 76%, about 77%, about 78%, about 79%, about 80%, about 81%, about 82%, about 83%, about 84%, about 85%, about 86%, about 87%, about 88%, about 89%, about 90%, about 90.5%, about 91%, about 91.5%, about 92%, about 92.5%, about 93%, about 93.5%, about 94%, about 94.5%, about 95%, about 95.5%, about 96%, about 96.5%, about 97%, about 97.5%, about 98%, about 98.5% and about 98.8% identical to the amino-acid sequence shown in SEQ ID NO:2 over the entire length thereof. Alternatively, the protease or the protease prepared using a method as contemplated herein is still at least about 70%, about 71%, about 72%, about 73%, about 74%, about 75%, about 76%, about 77%, about 78%, about 79%, about 80%, about 81%, about 82%, about 83%, about 84%, about 85%, about 86%, about 87%, about 88%, about 89%, about 90%, about 90.5%, about 91%, about 91.5%, about 92%, about 92.5%, about 93%, about 93.5%, about 94%, about 94.5%, about 95%, about 95.5%, about 96%, about 96.5%, about 97%, about 97.5%, or about 98% identical to one of the amino-acid sequences shown in SEQ ID NOs:3-11 over the entire length thereof. The protease or the protease prepared using a method as contemplated herein has an amino-acid substitution at least one of the positions P9, Q62, D101, N130, G166, N187, 5216, N238 and Q271, based in each case on the numbering according to SEQ ID NO:2. In more preferred embodiments, the amino-acid substitution is at least one selected from the group including of P9T/S/H, Q62E, D101E, N130D, G1665, N187H, S216C, N238K and Q271E, based in each case on the numbering according to SEQ ID NO:2. In more preferred embodiments, the protease has one of the following amino-acid substitution variants: (i) P9T; (ii) Q271E; (iii) P9S and N238K; (iv) P9H; (v) N187H; (vi) S216C; (vii) Q62E and N130D; (viii) Q62E, D101E, N130D, G166S and Q271E; or (ix) P9T, N187H, S216C and Q271E. 
     The present disclosure also relates to a protease as described above which is additionally stabilized, in particular by employing one or more mutations, for example substitutions, or by being coupled to a polymer. Increasing stability during storage and/or during use, for example during the washing process, leads to the enzymatic activity being maintained for longer and thus to the cleaning performance being improved. In principle, all stabilizing possibilities that are expedient and/or described in the prior art can be considered for this. Stabilizations which are achieved by employing mutations of the enzyme itself are preferred, since stabilizations of this kind do not require any further working steps after the enzyme has been obtained. Examples of sequence alterations suitable for this purpose have been mentioned above. Further suitable sequence alterations are known from the prior art. 
     Further possibilities for stabilization include for example:
         altering the binding of metal ions, in particular the calcium binding sites, for example by exchanging one or more of the amino acid(s) that are involved in the calcium binding with one or more negatively charged amino acids and/or by introducing sequence alterations in at least one of the sequences of the two amino acids arginine and glycine;   protecting against the influence of denaturing agents, such as surfactants, by employing mutations which cause the amino-acid sequence to be altered on or at the surface of the protein;   exchanging amino acids which are close to the N-terminus with amino acids which are assumed to come into contact with the rest of the molecule by employing non-covalent interactions, and thus contribute to maintaining the globular structure.       

     Preferred embodiments are those in which the enzyme is stabilized in several different ways, since several stabilizing mutations have a cumulative or synergistic effect. 
     The present disclosure also relates to a protease as described above which has at least one chemical modification. A protease that is altered in this way is referred to as a “derivative”, i.e. the protease is derivatized. 
     Within the meaning of the present application, “derivatives” are therefore understood to mean proteins of which the pure amino-acid chain has been modified chemically. Derivatizations of this kind can be carried out in vivo, for example, by the host cell which expresses the protein. In this respect, couplings to low-molecular-weight compounds, such as lipids or oligosaccharides, are of particular importance. However, derivatizations may also be carried out in vitro, for example by the chemical conversion of a side chain of an amino acid or by covalent bonding of another compound to the protein. For example, it is possible to couple amines to carboxyl groups of an enzyme in order to change the isoelectric point. This other compound may also be another protein which is bound to a protein as contemplated herein via bifunctional chemical compounds, for example. Derivatization is also understood to mean covalent bonding to a macromolecular carrier, or non-covalent inclusion in suitable macromolecular cage structures. Derivatizations can, for example, influence the substrate specificity or the bond strength to the substrate or cause temporary inhibition of enzymatic activity, if the coupled substance is an inhibitor. This can be expedient in terms of the period of storage, for example. Modifications of this kind can also influence stability or enzymatic activity. They can also be used to reduce the allergenicity and/or immunogenicity of the protein and to thus increase the skin compatibility thereof, for example. For example, couplings to macromolecular compounds, for example polyethylene glycol, can improve the protein in terms of stability and/or skin compatibility. 
     In the broadest sense, derivatives of a protein as contemplated herein can be understood to also include preparations of these proteins. Depending on how a protein is obtained, recovered or prepared, said protein can be combined with a wide range of other substances, for example from the culture of the microorganisms that produce it. A protein may also have been deliberately mixed with other substances in order to increase its storage stability, for example. Therefore, the present disclosure also covers all preparations of a protein as contemplated herein. This is still true irrespective of whether or not this enzymatic activity actually develops in a particular preparation. This is because it may be desirable for the protein to not have any activity or to only have low activity when being stored, and for the enzymatic function to only develop once the protein is in use. This can be controlled, for example, by appropriate accompanying substances. In particular, in this respect, it is possible to jointly prepare proteases and specific inhibitors. 
     Among all above-described proteases or protease variants and/or derivatives, particularly preferred within the scope of the present disclosure are proteases, protease variants and/or derivatives of which the stability and/or activity corresponds to at least one of those of the proteases according to SEQ ID NOs: 3-11, and/or of which the cleaning performance corresponds to at least one of those of the proteases according to SEQ ID NOs: 3-11, the cleaning performance being determined in a washing system, as described above. 
     The present disclosure also relates to a nucleic acid which codes for a protease as contemplated herein, and to a vector containing a nucleic acid of this kind, in particular a cloning vector or an expression vector. A nucleic acid of this kind can have the nucleotide sequence shown in SEQ ID NO:1 as the coding sequence, which nucleotide sequence is mutated at the corresponding positions in order to give the desired amino-acid substitution. 
     These may be DNA or RNA molecules. They may be present as a single strand, as a single strand that is complementary to the first single strand, or as a double strand. In the case of DNA molecules, in particular, the sequences of the two complementary strands should be considered in all three possible reading frames. It should also be noted that different codons, i.e. base triplets, can code for the same amino acids, such that a particular amino-acid sequence can be coded for by several different nucleic acids. Owing to this degeneracy of the genetic code, all nucleic-acid sequences which can code for one of the above-described proteases are included in this subject of the present disclosure. A person skilled in the art can identify these nucleic-acid sequences with absolute certainty since, despite the degeneracy of the genetic code, defined amino acids can be assigned to individual codons. Therefore, proceeding from an amino-acid sequence, a person skilled in the art can easily identify nucleic acids which code for said amino-acid sequence. Furthermore, in nucleic acids as contemplated herein, one or more codons can be replaced by synonymous codons. This aspect relates in particular to the heterologous expression of the enzymes as contemplated herein. Therefore, each organism, for example a host cell of a production strain, has a particular codon usage. “Codon usage” is understood to mean the translation of the genetic code into amino acids by employing the relevant organism. Bottlenecks can occur in protein biosynthesis if the codons on the nucleic acid are accompanied by a comparatively low number of charged tRNA molecules in the organism. Although coding for the same amino acid, this leads to a codon being translated less efficiently in the organism than a synonymous codon which codes for the same amino acid. Owing to the presence of a higher number of tRNA molecules for the synonymous codon, said codon can be translated more efficiently in the organism. 
     Using methods which are currently generally known, such as chemical synthesis or the polymerase chain reaction (PCR), in conjunction with molecular biological and/or protein chemical standard methods, it is possible for a person skilled in the art, on the basis of known DNA and/or amino acid sequences, to produce the corresponding nucleic acids and even complete genes. Methods of this kind are known from, for example, Sambrook, J., Fritsch, E. F. and Maniatis, T. 2001. Molecular cloning: a laboratory manual, 3rd Edition Cold Spring Laboratory Press. 
     Within the meaning of the present disclosure, vectors are understood to mean elements which consist of nucleic acids and which contain a nucleic acid as contemplated herein as a characterizing nucleic-acid range. Vectors allow establishment of this nucleic acid in a species or a cell line over multiple generations or cell divisions as a stable genetic element. Vectors are specific plasmids, i.e. circular genetic elements, in particular for use in bacteria. Within the scope of the present disclosure, a nucleic acid as contemplated herein is cloned in a vector. These may include vectors, for example, which originate from bacterial plasmids, from viruses, or from bacteriophages, or predominantly synthetic vectors or plasmids having elements of various origins. Using the further genetic elements which are present in each case, vectors are able to become established as stable units in the host cells in question over several generations. They may be present as separate units outside of a chromosome or be integrated in a chromosome or chromosomal DNA. 
     Expression vectors have nucleic-acid sequences which enable them to replicate in the host cells, preferably microorganisms, particularly preferably bacteria, which contain them and to express therein a contained nucleic acid. The expression is influenced, in particular, by promoter(s) which regulate the transcription. In principle, the expression can be carried out by the natural promoter which is originally located in front of the nucleic acid to be expressed, by a promoter of the host cell provided on the expression vector, or by a modified or completely different promoter of another organism or another host cell. In the present case, at least one promoter is provided for the expression of a nucleic acid as contemplated herein and is used for the expression thereof. Expression vectors can also be regulated, for example by changing the culturing conditions, by reaching a particular cell density in the host cells containing said vectors, or by adding particular substances, in particular activators for gene expression. An example of a substance of this kind is the galactose derivative isopropyl-β-D-thiogalactopyranoside (IPTG) which is used as an activator for the bacterial lactose operon (lac operon). Unlike in expression vectors, the contained nucleic acid in cloning vectors is not expressed. 
     The present disclosure also relates to a non-human host cell containing a nucleic acid as contemplated herein or a vector as contemplated herein, or containing a protease as contemplated herein, in particular a non-human host cell which secretes the protease into the medium surrounding the host cell. A nucleic acid as contemplated herein or a vector as contemplated herein is preferably transformed into a microorganism which then constitutes a host cell as contemplated herein. Alternatively, individual components, i.e. nucleic-acid parts or fragments of a nucleic acid as contemplated herein, can be introduced into a host cell such that the resulting host cell contains a nucleic acid as contemplated herein or a vector as contemplated herein. This procedure is particularly suitable if the host cell already contains one or more components of a nucleic acid as contemplated herein or of a vector as contemplated herein, and the additional components are then added accordingly. Methods for transforming cells are established in the prior art and are sufficiently known to a person skilled in the art. In principle, all cells, i.e. prokaryotic or eukaryotic cells, are suitable as host cells. Preferred host cells are those which may be advantageously managed genetically, which involves, for example, transformation using the nucleic acid or the vector and stable establishment thereof, for example unicellular fungi or bacteria. In addition, preferred host cells are distinguished by good microbiological and biotechnological manageability. This relates, for example, to ease of culturing, high growth rates, low demands on fermentation media, and good production and secretion rates for foreign proteins. Preferred host cells as contemplated herein secrete the (transgenically) expressed protein into the medium surrounding the host cells. Furthermore, the proteases can be modified, following preparation, by the cells that produced them, for example by the attachment of sugar molecules, by formylations, by aminations, etc. Post-translational modifications of this kind can influence the protease in terms of its function. 
     Those host cells of which the activity can be regulated due to genetic regulation elements which are provided on the vector, for example, but which may also be present in these cells from the outset, represent other preferred embodiments. These host cells may be induced to express, for example by the controlled addition of chemical compounds which are used as activators, by changing the culturing conditions, or upon reaching a certain cell density. This provides for cost-effective production of the proteins as contemplated herein. An example of a compound of this kind is IPTG, as described above. 
     Prokaryotic or bacterial cells are preferred host cells. Bacteria are distinguished by short generation times and low demands on the culturing conditions. Cost-effective culturing methods or preparation methods can thereby be established. Furthermore, a person skilled in the art has a vast pool of experience with regard to bacteria in fermentation technology. Gram-negative or gram-positive bacteria may be suitable for specific production for a wide variety of reasons, which should be determined by experiment in any given case, for example nutrient sources, product formation rate, time constraints, etc. 
     In the case of gram-negative bacteria, such as  Escherichia coli , numerous proteins are secreted into the periplasmatic space, i.e. the compartment between the two membranes which enclose the cells. This may be advantageous for particular applications. Furthermore, gram-negative bacteria may also be formed such that they secrete the expressed proteins not only into the periplasmatic space, but also into the medium surrounding the bacterium. By contrast, gram-positive bacteria, for example Bacilli or actinomycetes or other representatives of the actinomycetales, have no outer membrane, and therefore secreted proteins are released directly into the medium surrounding the bacteria, generally the nutrient medium, from which the expressed proteins may be purified. They may be isolated directly from the medium or processed further. Moreover, gram-positive bacteria are related to or identical to most origin organisms for industrially significant enzymes and they themselves usually form comparable enzymes, such that they have a similar codon usage and the protein synthesis apparatus thereof is naturally aligned accordingly. 
     Host cells as contemplated herein may be altered in terms of their requirements for culture conditions, may have different or additional selection markers, or may express different or additional proteins. These host cells may be in particular host cells that express a plurality of proteins or enzymes transgenically. 
     The present disclosure can be used, in principle, for all microorganisms, in particular for all fermentable microorganisms, particularly preferably for those from the  Bacillus  genus, and leads to it being possible to prepare proteins as contemplated herein by using microorganisms of this kind. Microorganisms of this kind then constitute host cells within the meaning of the present disclosure. 
     In a further embodiment of the present disclosure, the host cell is a bacterium, preferably a bacterium selected from the group of the genera of  Escherichia, Klebsiella, Bacillus, Staphylococcus, Corynebacterium, Arthrobacter, Streptomyces, Stenotrophomonas  and  Pseudomonas , more preferably a bacterium selected from the group of  Escherichia coli, Klebsiella planticola, Bacillus licheniformis, Bacillus lentus, Bacillus amyloliquefaciens, Bacillus subtilis, Bacillus alcalophilus, Bacillus globigii, Bacillus gibsonii, Bacillus clausii, Bacillus halodurans, Bacillus pumilus, Staphylococcus carnosus, Corynebacterium glutamicum, Arthrobacter oxidans, Streptomyces lividans, Streptomyces coelicolor  and  Stenotrophomonas maltophilia.    
     However, the host cell may also be a eukaryotic cell which has a nucleus. Therefore, the present disclosure further relates to a host cell which has a nucleus. Unlike prokaryotic cells, eukaryotic cells are able to modify the formed protein post-translationally. Examples thereof are fungi such as actinomycetes or yeasts such as  Saccharomyces  or  Kluyveromyces . This may be particularly advantageous, for example, if, in the context of their synthesis, the proteins are intended to undergo specific modifications which systems of this kind allow. The modifications which are carried out by eukaryotic systems, particularly in the context of protein synthesis, include, for example, the binding of low-molecular-weight compounds such as membrane anchors or oligosaccharides. Oligosaccharide modifications of this kind may be desirable, for example, as a means to reduce the allergenicity of an expressed protein. A co-expression with the enzymes formed naturally by cells of this kind, such as cellulases, can also be advantageous. Furthermore, thermophilic fungal expression systems, for example, may be particularly suitable for expressing temperature-resistant proteins or variants. 
     The host cells as contemplated herein are cultured and fermented in a conventional manner, for example in batch or continuous systems. In the first case, a suitable nutrient medium is inoculated with the host cells, and the product is harvested from the medium after a period of time that can be determined by experiment. Continuous fermentation is distinguished by the achievement of a steady state in which, over a comparatively long period of time, some cells die, but also regenerate, and at the same time, the formed protein can be removed from the medium. 
     Host cells as contemplated herein are preferably used in order to prepare proteases as contemplated herein. Therefore, the present disclosure also relates to a method for preparing a protease, comprising: 
     a) culturing a host cell as contemplated herein, and 
     b) isolating the protease from the culture medium or from the host cell. 
     This subject of the present disclosure preferably includes fermentation methods. Fermentation methods are known per se from the prior art, and constitute the actual large-scale production step, generally followed by a suitable method for purifying the prepared product, for example the proteases as contemplated herein. All fermentation methods which are based on a corresponding method for preparing a protease as contemplated herein constitute embodiments of this subject of the present disclosure. 
     Fermentation methods which the fermentation is carried out via an inflow strategy are in particular considered. Here, the media components that are consumed by the continuous culturing are fed in. Significant increases both in the cell density and in the cell mass or dry mass, and/or in particular in the activity of the protease of interest, can be achieved in this way. Furthermore, the fermentation may also be designed in such a way that undesirable metabolic products are filtered out or neutralized by adding a buffer or appropriate counterions. 
     The prepared protease can be harvested from the fermentation medium. A fermentation method of this kind is preferred over isolation of the protease from the host cell, i.e. product recovery from the cell mass (dry mass); however, said method requires that suitable host cells or one or more suitable secretion markers or mechanisms and/or transport systems be provided, so that the host cells secrete the protease into the fermentation medium. Alternatively, without secretion, the protease can be isolated from the host cell, i.e. separated from the cell mass, for example by precipitation with ammonium sulfate or ethanol, or by chromatographic purification. 
     All aforementioned elements can be combined to form methods for preparing proteases as contemplated herein. 
     The present disclosure also relates to an agent which contains a protease as contemplated herein, as described above. The agent is preferably a washing or cleaning agent. 
     This covers all conceivable types of washing or cleaning agents, including both concentrates and agents to be used in undiluted form, for use on a commercial scale in washing machines or for washing or cleaning by hand. These agents include, for example, washing agents for textiles, carpets or natural fibers for which the term “washing agent” is used. These also include, for example, dishwashing detergents for dishwashers or manual dishwashing detergents or cleaners for hard surfaces, such as metal, glass, porcelain, ceramics, tiles, stone, coated surfaces, plastics materials, wood or leather for which the term “cleaning agent” is used, i.e. in addition to manual and automatic dishwashing detergents, also abrasive cleaners, glass cleaners, WC rim blocks, etc. Within the scope of the present disclosure, the washing and cleaning agents also include auxiliary washing agents, which are added to the actual washing agent when washing textiles manually or using a machine in order to achieve an additional effect. Furthermore, within the scope of the present disclosure, washing and cleaning agents also include textile pre-treatment and post-treatment agents, i.e. agents with which the piece of laundry comes into contact before it is actually washed, for example in order to loosen stubborn dirt, and also agents which impart other desirable properties to the laundry, for example softness to touch, crease resistance or low static charge, in a step that comes after the actual textile washing process. The agents mentioned last include, inter alia, softeners. 
     The washing or cleaning agents as contemplated herein, which may be present in the form of powdered solids, compressed particles, homogeneous solutions or suspensions, can contain, in addition to a protease as contemplated herein, all known ingredients that are common in agents of this kind, at least one further ingredient preferably being present in the agent. The agents as contemplated herein may in particular contain surfactants, builders, peroxygen compounds or bleach activators. They may also contain water-miscible organic solvents, further enzymes, sequestering agents, electrolytes, pH regulators and/or further auxiliaries such as optical brighteners, graying inhibitors, foam regulators, and dyes and fragrances, and combinations thereof. 
     In particular, a combination of a protease as contemplated herein with one or more further ingredient(s) of the agent is advantageous, since an agent of this kind has improved cleaning performance in preferred embodiments as contemplated herein on account of synergies obtained thereby. In particular, such synergy can be achieved by the combination of a protease as contemplated herein with a surfactant and/or a builder and/or a peroxygen compound and/or a bleach activator. Since the proteases described herein have high enzyme stability even without an enzyme stabilizer, for example boric acid, the addition of such stabilizers to the enzyme-containing agents can be omitted or the amount of said stabilizers can be reduced in various embodiments. 
     Advantageous ingredients of agents as contemplated herein are disclosed in international patent application WO2009/121725, starting on the penultimate paragraph of page 5 and ending on page 13 after the second paragraph. Reference is made explicitly to this disclosure and the content thereof is incorporated in the present patent application. 
     An agent as contemplated herein preferably contains the protease in an amount of from about 2 μg to about 20 mg, preferably from about 5 μg to about 17.5 mg, particularly preferably from about 20 μg to about 15 mg, and very particularly preferably from about 50 μg to about 10 mg per g of the agent. Furthermore, the protease contained in the agent and/or further ingredients of the agent may be encapsulated in a substance that is impermeable to the enzyme at room temperature or in the absence of water, which substance becomes permeable to the enzyme under use conditions of the agent. Such an embodiment as contemplated herein the protease is encapsulated in a substance that is impermeable to the protease at room temperature or in the absence of water. Furthermore, the washing or cleaning agent itself can also be packaged in a container, preferably an airtight container, from which it is released shortly before use or during the washing process. 
     In other embodiments of the present disclosure, the agent is present in solid form, in particular as a flowable powder having a bulk density of from about 300 g/l to about 1200 g/l, in particular from about 500 g/l to about 900 g/l, or 
     is present in paste or liquid form, and/or 
     is present in gel or pouch form, and/or 
     is present as a single-component system, or 
     is divided into a plurality of components. 
     These embodiments of the present disclosure cover all solid, powder, liquid, gel or paste dosage forms of agents as contemplated herein that may optionally also consist of a plurality of phases and may be present in compressed or uncompressed form. The agent may be present in the form of a flowable powder, in particular having a bulk density of from about 300 g/l to about 1200 g/l, more particularly from about 500 g/l to about 900 g/l or from about 600 g/l to about 850 g/l. The solid dosage forms of the agent also include extrudates, granules, tablets or pouches. Alternatively, the agent may also be a liquid, gel or paste, for example in the form of a non-aqueous liquid washing agent or a non-aqueous paste or in the form of an aqueous liquid washing agent or water-containing paste. Furthermore, the agent may be present as a single-component system. Agents of this kind consist of one phase. Alternatively, an agent can also consist of a plurality of phases. An agent of this kind is therefore divided into a plurality of components. 
     Washing or cleaning agents as contemplated herein may only contain a protease. Alternatively, they may also contain further hydrolytic enzymes or other enzymes in a concentration that is expedient in terms of the effectiveness of the agent. Another embodiment of the present disclosure thus relates to agents which also comprise one or more further enzymes. All enzymes which can develop catalytic activity in the agent as contemplated herein, in particular a lipase, amylase, cellulase, hemicellulase, mannanase, tannase, xylanase, xanthanase, xyloglucanase, β-glucosidase, pectinase, carrageenase, perhydrolase, oxidase, oxidoreductase or other proteases which are different from the protease as contemplated herein, and mixtures thereof, can preferably be used as further enzymes. Further enzymes are contained in the agent advantageously in an amount of from about 1×10 −8  to about 5 wt. % in each case, based on the active protein. Each further enzyme is contained in agents as contemplated herein in an amount of, in order of increasing preference, from about 1×10 −7  to about 3 wt. %, from about 0.00001 to about 1 wt. %, from about 0.00005 to about 0.5 wt. %, from about 0.0001 to about 0.1 wt. %, and most particularly preferably from about 0.0001 to about 0.05 wt. %, based on the active protein. The enzymes particularly preferably have synergistic cleaning performances with respect to particular stains or marks, i.e. the enzymes contained in the agent composition assist one another in terms of the cleaning performance thereof. Very particularly preferably, such synergy exists between the protease contained as contemplated herein and a further enzyme of an agent as contemplated herein, in particular between the stated protease and an amylase and/or a lipase and/or a mannanase and/or a cellulase and/or a pectinase. Synergistic effects can occur not only between different enzymes, but also between one or more enzymes and other ingredients of the agent as contemplated herein. 
     The present disclosure further relates to a method for cleaning textiles or hard surfaces, exemplified in that an agent as contemplated herein is used in at least one method step, or in that a protease as contemplated herein becomes catalytically active in at least one method step, in particular such that the protease is used in an amount of from about 40 μg to about 4 g, preferably from about 50 μg to about 3 g, particularly preferably from about 100 μg to about 2 g, and very particularly preferably from about 200 μg to about 1 g. 
     In various embodiments, the above-described method is distinguished in that the protease is used at a temperature of from about 0 to about 100° C., preferably from about 0 to about 60° C., more preferably from about 20 to about 40° C., and most preferably at a temperature of approximately 35° C. 
     These embodiments include both manual and automatic methods, automatic methods being preferred. Methods for cleaning textiles are generally distinguished in that various substances that have a cleaning effect are applied to the item to be cleaned in a plurality of method steps and washed off after the contact time, or in that the item to be cleaned is treated with a washing agent or a solution or dilution of this agent in some other way. The same applies to methods for cleaning all materials other than textiles, in particular hard surfaces. All conceivable washing or cleaning methods can be enhanced in at least one of the method steps using a washing or cleaning agent as contemplated herein or a protease as contemplated herein, and then constitute embodiments of the present disclosure. All elements, subjects and embodiments that are described for protease as contemplated herein and agents that contain them can also be applied to this subject of the present disclosure. Therefore, at this juncture, reference is explicitly made to the disclosure at the corresponding point when it was indicated that this disclosure also applies to the above methods as contemplated herein. 
     Since proteases as contemplated herein naturally already have hydrolytic activity and these also develop in media that otherwise have no cleaning force, such as in simple buffers, an individual and/or the only step of a method of this kind can consist in bringing a protease as contemplated herein into contact with the stain as the only component that has a cleaning effect, preferably in a buffer solution or in water. This constitutes a further embodiment of this subject of the present disclosure. 
     Methods for treating textile raw materials or for textile care in which a protease as contemplated herein becomes active in at least one method step also constitute alternative embodiments of this subject of the present disclosure. Of such methods, methods for textile raw materials, fibers or textiles having natural components are preferred, and very particularly for those containing wool or silk. 
     Finally, the present disclosure further relates to the use of the proteases described herein in washing or cleaning agents, for example as described above, for (improved) removal of fat-containing stains, for example from textiles or hard surfaces. 
     All elements, subjects and embodiments that are described for protease as contemplated herein and agents that contain them can also be applied to this subject of the present disclosure. Therefore, at this juncture, reference is explicitly made to the disclosure at the corresponding point when it was indicated that this disclosure also applies to the above use as contemplated herein. 
     EXAMPLES 
     All working steps involving molecular biology followed standard methods, as specified, for example, in the manual by Fritsch, Sambrook and Maniatis “Molecular cloning: a laboratory manual”, Cold Spring Harbour Laboratory Press, New York, 1989, or comparable relevant pieces of work. Enzymes and kits were used according to the manufacturer&#39;s instructions in each case. 
     Overview of the Mutations 
     
       
         
           
               
               
               
               
               
               
               
             
               
                   
               
               
                   
                   
                   
                   
                   
                   
                 SEQ  
               
               
                 Variant 
                 Sequence 
                   
                   
                   
                   
                 ID NO: 
               
               
                   
               
             
            
               
                   
               
            
           
           
               
               
               
               
               
               
               
            
               
                 Variant 1 
                 P9T 
                   
                   
                   
                   
                 3 
               
               
                 Variant 2 
                 Q271E 
                   
                   
                   
                   
                 4 
               
               
                 Variant 3 
                 P9S 
                 N238K 
                   
                   
                   
                 5 
               
               
                 Variant 4 
                 P9H 
                   
                   
                   
                   
                 6 
               
               
                 Variant 5 
                 N187H 
                   
                   
                   
                   
                 7 
               
               
                 Variant 6 
                 S216C 
                   
                   
                   
                   
                 8 
               
               
                 Variant 7 
                 Q62E 
                 N130D 
                   
                   
                   
                 9 
               
               
                 Variant 8 
                 Q62E 
                 D101E 
                 N130D 
                 G166S 
                 Q271E 
                 10 
               
               
                 Variant 9 
                 P9T 
                 N187H 
                 S216C 
                 Q271E 
                   
                 11 
               
               
                   
               
            
           
         
       
     
     Example 1: Storage Stability of the Enzyme in Washing Agent 
     The proteases are stirred in a washing agent matrix at the same activity level and stored at 30° C. Using a standard activity assay for proteases (hydrolysis of suc-AAPF-pNA), the initial activity and the remaining activity of the protease is measured after 42 hours and 9 days of storage at 30° C. 
     In order to generate harsh conditions, the proteases are stored once in the washing agent matrix without a stabilizer (boric acid) and, for comparison, once with boric acid. 
     This is the washing agent matrix that has been used in this case (LSPA+): 
                                         Wt. % active   Wt. % active           substance in the   substance in the       Chemical name   raw material   formulation                                            demineralized water   100   remainder       alkylbenzene sulfonic acid   96   4.4       anionic surfactants   70   5.6       C12-C18 fatty acid Na salt   30   2.4       non-ionic surfactants   100   4.4       phosphonates   40   0.2       citric acid   100   1.4       NaOH   50   0.95       defoamers   t.q.   0.01       glycerol   100   2       preservatives   100   0.08       ethanol   93   1       without optical brighteners,       perfume, dye and enzymes.                    
This matrix is provided for the measurements using stabilizer with 1% boric acid.
 
     Example 2: Enzymes 
     The proteases are present in  Bacillus subtilis  in supernatants generated in shake flasks. Said proteases are diluted to the same activity level. 50% washing agent matrix+/−boric acid are mixed with 50% correspondingly diluted  Bacillus subtilis  protease supernatant and mixed well. The closed glasses are incubated at 30° C. At the time the sample is taken, a certain amount of matrix/protease mixture is removed and dissolved by stirring for 20 minutes at RT in the sample buffer (0.1 M Tris/HCl, pH 8.6). The AAPF assay is then carried out as described below. 
     9 mutants (SEQ ID NOs 3-11) have proven to be advantageous; the activity is shown in % of the initial value. This was measured immediately after intermixing the proteases with the matrix and is set at 100% in each case: 
     
       
         
           
               
               
               
               
               
               
             
               
                   
               
               
                   
                 Initial 
                 4 d − 
                 4 d + 
                 12 d − 
                 12 d + 
               
               
                 Protease 
                 activity 
                 B(OH) 3   
                 B(OH) 3   
                 B(OH) 3   
                 B(OH) 3   
               
               
                   
               
             
            
               
                 SEQ ID NO: 2 
                 100% 
                 78% 
                 106% 
                 38% 
                 88% 
               
               
                 SEQ ID NO: 3 
                 100% 
                 99% 
                 103% 
                 77% 
                 92% 
               
               
                 SEQ ID NO: 4 
                 100% 
                 91% 
                 103% 
                 56% 
                 94% 
               
               
                 SEQ ID NO: 5 
                 100% 
                 98% 
                 105% 
                 83% 
                 90% 
               
               
                 SEQ ID NO: 6 
                 100% 
                 102%  
                 100% 
                 82% 
                 92% 
               
               
                 SEQ ID NO: 7 
                 100% 
                 96% 
                 111% 
                 63% 
                 95% 
               
               
                 SEQ ID NO: 8 
                 100% 
                 99% 
                 106% 
                 73% 
                 97% 
               
               
                   
               
            
           
         
       
     
     The mutants according to SEQ ID NOs 9 to 11 are recombinants which have been measured in another test: 
     
       
         
           
               
               
               
               
               
             
               
                   
                   
               
               
                   
                   
                 Initial 
                 3.5 d − 
                 3.5 d + 
               
               
                   
                 Protease 
                 activity 
                 B(OH) 3   
                 B(OH) 3   
               
               
                   
                   
               
             
            
               
                   
                 SEQ ID NO: 2 
                 100% 
                 76% 
                  98% 
               
               
                   
                 SEQ ID NO: 9 
                 100% 
                 93% 
                 110% 
               
               
                   
                 SEQ ID NO: 10 
                 100% 
                 88% 
                 112% 
               
               
                   
                 SEQ ID NO: 11 
                 100% 
                 93% 
                 101% 
               
               
                   
                   
               
            
           
         
       
     
     All mutants demonstrate a washing performance comparable to that of the wild type, i.e. the washing performance thereof is at most 10% poorer, which is within the limits of measurement variation (results not shown). 
     Example 3: Protease Activity Assays 
     The activity of the proteases is determined by releasing the chromophore para-nitroaniline from the substrate succinyl alanine-alanine-proline-phenylalanine-para-nitroanilide (AAPFpNA; Bachem L-1400). The release of pNA causes an increase in the extinction at 410 nm, the temporal progression of which is a measure of enzymatic activity. 
     The measurement is taken at a temperature of 25° C., a pH of 8.6, and a wavelength of 410 nm. The measurement time was 5 minutes at a measurement interval of 20 to 60 seconds. 
     Measurement Formulation 
     10 μL AAPF solution (70 mg/mL) 
     1000 μL Tris/HCl (0.1 M; pH 8.6 with 0.1% Brij 35) 
     10 μL diluted protease solution 
     Kinetics produced over 5 minutes at 25° C. (410 nm)