EP1309694A2 - Method for improved production of cyanophycin and the secondary products thereof - Google Patents

Abstract

The invention relates to a thermostable cyanophycin synthetase from synechococcus elongatus, and a method for the improved production of cyanophycin and/or the secondary products thereof.

Description

Process for the improved production of cyanophycin and its derivatives

The present invention relates to a thermostable cyanophycin synthase, transformed organisms containing such an enzyme, and a method for the improved production of cyanophycin and / or its secondary products, for example polyaspartic acid or arginine.

Multi-L-Arginyl-Poly-L-aspartate (cyanophycin) is a branched polypeptide that contains aspartic acid and arginine in a ratio of 1: 1. The chemical

Structure corresponds to a poly-α-aspartate backbone with arginine side residues, which are linked to almost all β-carboxyl groups of the backbone via peptide bonds.

DE-A 198 25 509 describes the identification, cloning and heterologous expression of the gene for the cyanophycin synthetase from Synechocystis PCC 6803. The enzyme activity is determined here by means of a radioactive test in which L- [U- ¹⁴ C] -Argimn is incorporated in cyanophycin from Aphanocapsa PCC 6308 presented as a "primer" (precursor). The enzyme reaction itself takes place here at 28 ° C.

DE-A 197 09 024 discloses the extraction and purification of cyanophycin from Aphanocapsa PCC 6308, the synthesis being carried out at 20 ° C.

DE-A 198 13 692 only discloses the isolation of the cyanophycin synthetase gene from Synechocystis PCC 6803 or Anabaena variabilis ATCC 29 413. However, process engineering features for the production of cyanophycm are not described here.

FEMS Microbiology Letters 181 (1999) 229-236 describes the production of cyanophycin from Synechococcus sp. MA 19 known. A disadvantage of the large-scale production of cyanophycin according to the known processes is that a relatively narrow temperature range, generally below 35 ° C., must not be exceeded for optimum product yield.

This represents a considerable restriction of the degrees of freedom for large-scale industrial production within the process control for the production of cyanophycin, since higher temperatures prevent contamination from foreign cultures from the outset.

It is therefore desirable to produce cyanophycin even at much higher temperatures than previously described, combined with greater flexibility in process control and considerably improved product yields, in order to isolate secondary products such as polyaspartic acid or arginine on an industrial scale.

This object is achieved by the present invention.

The present invention relates to a cyanophycin synthetase which is characterized in that it codes a temperature optimum in the range of> 35 ° C. and an amino acid sequence according to SEQUENCE PROTOCOL 1 by an isolated nucleotide sequence according to SEQUENCE PROTOCOL 2, an allele, homologue or derivative of this nucleotide sequence or with this has a hybridizing nucleotide sequence.

In a preferred variant of the present invention, the cyanophycin synthetase according to the invention has an optimum temperature in the range from 35 ° C. to 55 ° C., preferably in the range from 35 to 50 ° C.

Furthermore, the cyanophycin synthetase according to the invention is distinguished by the fact that it originates from Synechococcus elongatus. The cyanophycin syn- thetase is a thermostable enzyme.

The present invention also relates to isoenzymes of the cyanophycin synthetase according to the invention. This includes enzymes with the same or comparable substrate and activity specificity, but which have a different primary structure. In addition, the present invention also includes modified forms of cyanophycin synthetase. According to the invention, this includes enzymes in which there are changes in the sequence, for example at the N- and / or C-terminus of the polypeptide or in the region of conserved amino acids, but without impairing the function of the enzyme. These changes can be made by exchanging one or more amino acids according to known methods.

A special embodiment variant of the present invention comprises variants of the cyanophycin synthetase according to the invention, the substrate specificity of which has been changed, for example, by amino acid exchange compared with the respective starting protein, for example with regard to the production of polyaspartic acid. The same applies to the stability of the enzymes according to the invention in the cells, which are, for example, more or less susceptible to degradation by proteases.

The present invention furthermore relates to polypeptides with the function of a cyanophycin synthetase, the amino acid sequence of which is changed in such a way that they are desensitive to regulatory compounds, for example the end products of metabolism regulating their activity (feedback-desensitive).

According to the invention, an isolated nucleotide sequence or an isolated nucleic acid fragment is to be understood as a polymer made from RNA or DNA, which can be single or double-stranded and optionally contain natural, chemically synthesized, modified or artificial nucleotides. The term DNA polymer also includes genomic DNA, cDNA or mixtures thereof. According to the invention, alleles are to be understood as functionally equivalent, ie essentially equivalent nucleotide sequences. Functionally equivalent sequences are those sequences which, despite a different nucleotide sequence, for example due to the degeneracy of the genetic code, still have the desired functions. Functional equivalents thus include naturally occurring variants of the sequences described here as well as artificial nucleotide sequences, for example those obtained by chemical synthesis and possibly adapted to the codon use of the host organism. In addition, functionally equivalent sequences include those which have an altered nucleotide sequence which corresponds to the

Enzyme, for example, gives a desensitivity or resistance to inhibitors.

A functional equivalent is also understood to mean, in particular, natural or artificial mutations in an originally isolated sequence which continues to show the desired function. Mutations include substitutions, additions,

Deletions, exchanges or insertions of one or more nucleotide residues. Also included here are so-called sense mutations, which can lead to the exchange of conserved amino acids at the protein level, but which do not lead to a fundamental change in the activity of the protein and are therefore function-neutral. This also includes changes in the nucleotide sequence that affect the N- or C-terminus of a protein at the protein level, but without significantly impairing the function of the protein. These changes can even have a stabilizing influence on the protein structure.

Furthermore, the present invention also encompasses, for example, those nucleotide sequences which are obtained by modifying the nucleotide sequence, resulting in corresponding derivatives. The aim of such a modification can, for example, be to further narrow down the coding sequence contained therein or, for example, also to insert further recognition sites for restriction enzymes. Functional equivalents are also those variants whose function is weakened or enhanced compared to the original gene or gene fragment. In addition, artificial DNA sequences are the subject of the present invention as long as they impart the desired properties as described above and can be incorporated or appended into the gene of the cyanophycin synthetase according to the invention. Such artificial DNA sequences can be determined, for example, by back-translating proteins created using computer-aided programs (molecular modeling) or by in-vitro selection. Coding DNA sequences which are obtained by back-translating a polypeptide sequence according to the codon usage specific for the host organism are particularly suitable. The specific codon usage can easily be determined by a person familiar with molecular genetic methods by computer evaluations of other, already known genes of the organism to be transformed.

According to the invention, homologous sequences are to be understood as those which are complementary to and / or hybridize with the nucleotide sequences according to the invention. According to the invention, the term hybridizing sequences includes substantially similar nucleotide sequences from the group of DNA or RNA which, under known stringent conditions, enter into a specific interaction (binding) with the aforementioned nucleotide sequences. This also includes short nucleotide sequences with a length of, for example, 10 to 30, preferably

12 to 15 nucleotides. According to the invention, this includes also so-called nucleotide primers or probes.

According to the invention, the preceding (5'- or upstream) and / or subsequent (3'- or downstream) coding regions (structural genes) are also

Sequence areas included. In particular, this includes sequence areas with a regulatory function. You can influence the transcription, the RNA stability or the RNA processing as well as the translation. Examples of regulatory sequences include promoters, enhancers, operators, terminators or translation enhancers. An operative link is understood to mean the sequential arrangement of, for example, the promoter, coding sequence, terminator and, if appropriate, further regulatory elements in such a way that each of the regulatory elements can fulfill its function as intended when expressing the coding sequence. These regulatory nucleotide sequences can be of natural origin or can be obtained by chemical synthesis. In principle, any promoter which can control gene expression in the corresponding host organism is suitable as the promoter. According to the invention, this can also be a chemically inducible promoter by means of which the expression of the genes underlying it in the host cell can be controlled at a specific point in time. A promoter that can be induced by IPTG (isopropyl-β-thiogalactoside) is mentioned here as an example.

A gene structure is produced by fusing a suitable promoter with the nucleotide sequence according to the invention using common recombination and cloning techniques as are known from the literature. For connecting the

DNA fragments with one another can be attached to the fragments adapters or linkers.

In addition, the present invention relates to a vector comprising at least one nucleotide sequence of the type described above coding for a cyanophycin synthetase specific for the production of cyanophycin, to regulative nucleotide sequences operatively linked thereto and to additional nucleotide sequences for selecting transformed host cells, for replication within the host cell or for Integration into the corresponding host cell genome. Furthermore, the vector according to the invention can contain a gene structure of the aforementioned type.

Suitable vectors are those which are replicated in microorganisms, such as bacteria, fungi and / or plants. Known vectors are, for example, pBluescript (Stratagene, 11099 North Torney Pines Rd., La Jolla, CA 92 037, USA) or pET (Novagen, 601 Science Drive, Madison, WJ 53 711, USA). However, this list is not limiting for the present invention. Using the nucleic acid sequences according to the invention, corresponding probes or nucleotide primers can be synthesized and used to amplify and isolate analog genes from other single or multicellular organisms, preferably bacteria, fungi, algae or plants, for example with the aid of PCR technology.

The present invention thus also relates to a probe for identifying and / or isolating genes coding for proteins involved in the biosynthesis of cyanophycin, preferably further thermostable cyanophycin synthetases, this probe being produced on the basis of the nucleic acid sequences of the type described above and one for detection contains suitable marking. The probe can be a partial section of the sequence according to the invention, for example from a conserved area, which e.g. has a length of 10 to 30 or preferably 12 to 15 nucleotides and can hybridize specifically with homologous nucleotide sequences under stringent conditions. Suitable markings are well known from the literature.

The present invention further relates to the transfer of the nucleic acid sequence according to the invention or a part thereof coding for a cyanophycin synthetase, an allele, homolog or derivative thereof or a nucleotide sequence hybridizing with these sequences into a heterologous host system. This also includes the transfer of a gene construct or vector according to the invention into a heterologous host system.

According to the invention, a heterologous host system is understood to mean a single-cell or multi-cell organism. Examples of these are microorganisms, fungi, lower or higher plants, tissues or cells thereof. Bacteria are preferred according to the invention, particularly preferred the genus of enterobacteria and in particular the type Escherichia coli. Furthermore, useful plants, such as potatoes or

Tobacco particularly preferred. The nucleotide sequence coding for a thermostable cyanophycin synthetase according to the invention is transferred into one of the host systems mentioned above by known methods. Examples of methods for DNA transfer into suitable host systems are transformation, electroporation, conjugation and agrobacterium-mediated DNA transfer or “particle bombardment”. These lists are only used to explain the present invention and are not limiting.

A transformed single or multicellular organism resulting from a successfully carried out nuclear acid transfer thus differs from the correspondingly not transformed organism in that it contains additional nucleic acids of the type according to the invention and can accordingly express them.

The present invention thus also relates to a transformed single or multicellular organism containing a cyanophycin synthetase according to the invention and / or a vector containing a cyanophycin synthetase of the type described above.

Furthermore, the present invention relates to a method for providing a cyanophycin synthetase according to the invention of the type described above, wherein the nucleotide sequence coding for the enzyme is isolated from a thermophilic single or multicellular organism, if necessary operatively linked to regulatory structures and / or into one suitable for heterologous expression Vector is cloned, optionally transferred to a heterologous host system, expressed there and then isolated from this host system and optionally purified and / or enriched.

It is also conceivable to directly isolate an amount of cyanophycin synthetase sufficient for the synthesis of cyanophycm from a thermophilic organism. mus, without the previous enrichment in a heterologous system. Furthermore, the enzyme cyanophycin synthetase according to the invention can then be used, for example, in an in vitro system for the synthesis of cyanophycin and / or its secondary products.

The present invention also relates to a process for the preparation of cyanophycin and / or its secondary products, a cyanophycin synthetase and / or a vector and / or a transformed single or multicellular organism of the type described above being used. However, the present invention comprises not only the production of cyanophycin and / or its secondary products in a living host system, but also the in vitro synthesis of cyanophycin with the aid of an isolated cyanophycin synthetase of the type described above.

The process according to the invention for the production of cyanophycin is characterized in that the enzyme-catalyzed synthesis takes place in a temperature range from 35 ° C. to 55 ° C., preferably in a range from 35 ° C. to 50 ° C.

The process according to the invention is advantageously characterized in that the process is less susceptible to faults due to the wide temperature range, in particular above 28 ° C., allows greater variability in the process control and thus delivers an improved product yield. The production of cyanophycin and / or its secondary products according to the invention is thus substantially more reproducible and more economical than the previously known processes.

At the molecular level, the cyanophycin synthetase according to the invention catalyzes an ATP-dependent chain extension reaction (elongation). Surprisingly, the enzyme has two active (catalytic) centers. The cyanophycin synthetase according to the invention gradually and alternately (sequentially) incorporates a molecule of aspartic acid and then a molecule of arginine into a cyanophyne precursor (peptide primer). Without a primer, the enzyme-catalyzed

Chain extension cannot be started. Investigations on this are shown in FIG. posed. The chemical structure of various primers used for the synthesis of cyanophycin is shown in FIG. 1. Here it becomes clear that the installation takes place exclusively at the C-terminal end of the precursor and only if both amino acids, i.e. aspartic acid and arginine or another basic amino acid, are present together. A summary of these investigations is shown in Fig. 3 and Table 1.

Table 1

No. primer substrate (s) product

C-terminal blocked primer:

(1) (ß-Asp-Arg) ₃ -ε-Ahx ₂ Asp + Arg none

(2) (ß-Asp-Arg) ₃ -ε-Ahx ₂ Asp or Arg none

N-terminal blocked primer:

(3) ε-Ahx ₂ - (ß-Asp-Arg) ₃ Asp + Arg cyanophycin

(4) ε-Ahx ₂ - (ß-Asp-Arg) ₃ Asp ε-Ahx ₂ - (ß-Asp-Arg) ₃ -Asp

(5) ε-Ahx ₂ - (ß-Asp-Arg) ₃ Arg none

Unblocked primers:

(6) (β-Asp-Arg) ₃ Asp + Arg cyanophycin

(7) (ß-Asp-Arg) ₃ Asp (ß-Asp-Arg) ₃ -Asp ^a)

(8) (ß-Asp-Arg) ₃ Arg none

(9) (ß-Asp-Arg) ₃ ß-Asp-Arg none

(10) (β-Asp-Arg) ₃ -Asp Asp + Arg cyanophycin

(11) (ß-Asp-Arg) ₃ -Asp Asp none

(12) (ß-Asp-Arg) ₃ -Asp Arg (ß-Asp-Arg) ₄ ^{a) In} principle, the reaction product could also be Asp- (ß-Asp-Arg) ₃ . This

However, possibility is excluded due to the results with the N-terminal or C-terminal blocked primers (reactions 2 and 4 of this table).

The present invention further relates to the use of a vector containing a cyanophycin synthetase according to the invention of the aforementioned type for position of a transformed single or multicellular organism as described above. The use of such a transformed single or multi-cell organism for the production of a cyanophycin synthetase according to the invention and / or for the production of cyanophycin and / or its secondary products is also included in the present invention. In addition, a cyanophycin synthetase isolated according to the invention can also be used for the in vitro production of cyanophycin and / or its secondary products. In addition, the use of cyanophycin and / or its derivatives for the production of food supplements and / or agents in the field of agriculture and / or crop protection is covered in the present invention. Further

Areas of application of cyanophycin and / or its secondary products can be seen in the paper, textile, pigment, lacquer, ceramic, building material or detergent industries as well as in the areas of water and waste water treatment.

The present invention is characterized in more detail by the following examples, which, however, are not limiting for the invention:

General genetic methods:

DNA isolation, plaque hybridization, polymerase chain reaction (PCR), creation of a genomic DNA library and the procedures for analyzing proteins using SDS-polyacrylamide gel electrophoresis (SDS-PAGE) including protein purification, as well as the cultivation of microorganisms such as: Escherichia coli take place according to standard methods described in Sambrook, J. et al. (1998, Molecular Cloning: A Laboratory Manual, 2 ^nd Edition, Cold Spring Harbor Laboratory Press, NY.) Or according to the manufacturer's instructions. The

Cultivation of blue-green algae, such as B. Synechococcus elongatus was carried out as described in Yamaoka, T., et al. (1978, Plant Cell Physiol., 19: 943-954).

Synthesis of the peptide primers: The branched peptide primers (β-Asp-Arg) ₃ , (β-Asp-Arg) ₃ -Asp, ε-Ahx ₂ - (b-Asp-

Arg) ₃ and (β-Asp-Arg) ₃ -ε-Ahx ₂ (see FIG. 1; Ahx = ε-aminohexanoic acid) were on a solid phase based on Fmoc / tbu chemistry via O- (benzotriazol-l-yl) - N, N, N ', N'-tetramethyluronium tetrafluoroborate activation with the building block Fmoc-Asp- [Arg (Pmc) -OtBu ] -OH synthesized. The building block was produced in solution by the following reaction sequence: (i) Acylation of H-Arg (Pmc) -OtBu (Bachern Biochemicals) with Fmoc-Asp-All (All = Allylester) (ovabiochem) under

Use of dicyclohexylcarbodiimide / N-hydroxybenzotriazole (Novabiochem) as activating agents and then (ii) opening of the allyl ester using N-methylaniline and tetrakis (triphenylphosphine) palladium (0) as a catalyst. The synthesis is started on a resin loaded with Fmoc-Arg (Pmc) -TentaGel-S-PHB (rapp polymers). The peptide primers are linked by the following reaction: (i) coupling of Fmoc-Asp-OtBu and subsequently (ii) twice attaching the building block Fmoc-Asp- [Arg- (Pmc) -OtBu] -OH. Furthermore, the N-terminally blocked peptide primer ε-Ahx ₂ - (b-Asp-Arg) _{3 was produced} by attaching Fmoc-ε-aminohexanoic acid (Novabiochem) twice to the peptide primer bound to the resin described above. The finished peptides were made by

Treatment with 94% trifluoroacetic acid, 1% phenol, 2% water, 3% triisobutylsilane deprotected and cleaved from the resin, the peptides and the N-terminally blocked peptide primers being obtained as free acids. The C-terminally blocked peptide primer (β-Asp-Arg) ₃ -ε-Ahx was produced on a TentaGel-SRAM resin (Rapp polymers) according to the following procedure: (i) two coupling of

Fmoc-ε-aminohexanoic acid and subsequent coupling of the building block Fmoc-L-Asp- [L-Arg (Pmc) -OtBu) three times. The cleavage of the finished primer was carried out as described above and gave the peptide as carboxamide.

The peptide primer (β-Asp-Arg) ₃ -Asp was synthesized on a TentaGel-S-PHB resin (Rapp polymers) loaded with Fmoc-Asp (OtBu) by attaching the corresponding building block three times. The peptide was also cleaved from the resin and deprotected as previously described. Here, the peptide was obtained as a free acid. All peptide primers were purified on a C-18 column (Vydac 201SP54) and analyzed using RP-HPLC and MALDI-MS. The dipeptide β-Asp-Arg was also produced on a TentaGel-S-PHB phase, which had previously been loaded with Fmoc-Arg (Pmc). After the Fmoc protecting group was cleaved with 20% piperidine-DMF solution, the resin was treated with 4 eq (equivalents) of Boc-Asp-OtBu (Bachern Chemicals), 4 eq O- (benzotriazol-l-yl) - N , N, N ', N'-tetramethyluronium tetrafluoroborate and 8 eq diisopropyl-emylamine treated in DMF. The peptide was cleaved from the resin with trifluoroacetic acid containing 1% phenol, 2% water and 3% triisobutylsilane, then precipitated with cold t-butylmethyl and finally purified on a C-18 column (Vydac 201SP54) and with RP-HPLC and MALDI-MS analyzed.

Reaction approaches and product analysis:

The reaction batches for product analysis by mass spectrometry contain the following components in a volume of 125 μl: 100 mM NEUHCO;} (pH 8.0), 4 mM ATP disodium salt, 20 mM MgCl ₂ , 8 mM KC1, 2 mM DTT, 0.2 mM L-aspartic acid, 0.2 mM L-arginine, ≥ 10 μM synthetic primers and 3 μg cyanophycin synthetase.

For product analysis using SDS-PAGE, the reaction mixture of 125 μl contains the following: 50 mM Tris-HCl (pH 8.0), 4 mM ATP disodium salt, 20 mM MgCl ₂ , 20 mM KC1, 1 mM DTT, 0.8 mM L Aspartic acid, 0.4 mM L-arginine,> 10 μM synthetic primer and 3 μg cyanophycin synthetase.

The samples are incubated for 10-14 hours at room temperature and then either mixed with sample buffer (SDS-PAGE) or frozen (mass spectrometry). Product analysis using mass spectrometry (MALDI-

MS) is carried out according to the information in the user manual of the device manufacturer (PerSeptive Biosystems). Legend for the figures, tables and additional pages:

Additional pages 1 to 3

SEQUENCE LIST 1 of the airioic acid sequence of the thermostable cyanophycin synthetase according to the invention derived from the corresponding one

Cyanophycinsynthetase gene.

Additional pages 4 to 7:

SEQUENCE LIST 2 of the nucleotide sequence of the cyanophycin synthetase gene according to the invention coding for the cyanophycin synthetase according to the invention.

1: Chemical structure of the synthetic peptide primers used for the synthesis of a cyanophycin using cyanophycin synthetase.

2: Representation of the results of an SDS-polyacrylamide gel electrophoresis (SDS-PAGE) for the in vitro synthesis of cyanophycin-like material by means of purified cyanophyme synthetase. The reaction mixture contains, inter alia, about 10 μM primer (β-Asp-Arg) ₃ . After an incubation of 24 hours at room temperature, aliquots of the

Reaction approaches analyzed using SDS-PAGE and proteins visualized using standard methods. Lane 1: complete reaction approach; Lane 2: reaction mixture without aspartic acid; Lane 3: reaction mixture without arginine; Lane 4: reaction batch without ATP; Lane 5: reaction mixture without primer (β-Asp-Arg) ₃ ; Lane 6: reaction mixture with heat-inactivated enzyme (5 min,

100 ° C). The protein band above the 97.4 kDa standard represents the cyanophycin synthetease. The diffuse bands below 29 kDa in lanes 1, 2 and 3 represent cyanophycin-like material. 3: Representation of the results of an SDS-PAGE for chain extension of a primer by means of cyanophycin synthetase at the C-terminal end of the peptide primer.

Various primers (Fig. 1) are added to the reaction mixture. After incubation of the reaction batches for 24 hours at room temperature

Aliquots of the reaction mixture were analyzed using SDS-PAGE and proteins were visualized using standard methods. Lane 1: approach without primer; Lane 2: approach with approximately 8 μM unprotected primer (β-Asp-Arg) ₃ ; Lane 3: Approach with about 8 μM N-terminally protected primer (ε-Ahx ₂ - (ß-Asp-Arg) ₃ ); Lane 4: Approach with about 8 μM C-terminally protected primer ((β-Asp-Arg) ₃ -ε-

Ahx); Lane 5: like lane 4 but with about 160 μM primer. ^" The diffuse bands below 29 kDa in lanes 1, 2 and 3 represent cyanophycin-like material.

Tab. 1: Cyanophycin synthetase-catalyzed incorporation of L-aspartic acid (Asp) and L-arginine (Arg) into synthetic peptide primers.

Claims

Patentansprflche

1. Cyanophycin synthetase, characterized in that it encodes a temperature optimum in the range from 35 ° C to 55 ° C and an amino acid sequence according to SEQUENCE LIST 1 by a nucleotide sequence according to

SEQUENCE PROTOCOL 2, an allele, homolog or derivative of this nucleotide sequence or a hybridizing with this nucleotide sequence and comes from Synechococcus elongatus.

2. Vector containing at least one nucleotide sequence coding for one

Production of cyanophycin-specific cyanophycin synthetase according to claim 1.

3. Transformed single or multicellular organism containing a cyanophycin synthetase according to claim 1 and / or a vector according

Claim 2.

4. Transformed single or multicellular organism according to claim 3, characterized in that it is a microorganism, a fungus, a lower or higher plant, tissue or a cell thereof.

5. The method for providing a cyanophycin synthetase according to claim 1, characterized in that the nucleotide sequence coding for the enzyme is operatively linked to regulatory structures and / or cloned in a vector suitable for heterologous expression, transferred into a heterologous host system, expressed and from this host system is isolated and purified and / or enriched.

6. A process for the preparation of cyanophycin and the derived products to be produced therefrom, characterized in that a cyanophycin synthetase according to claim 1 and / or a vector according to claim 2 and / or a transformed single or multicellular organism according to one of claims 3 or 4 is used.

7. Use of a vector according to claim 2 for the production of a transformed single or multicellular organism according to one of claims 3 or 4.

8. Use of a transformed single or multi-cell organism according to one of claims 3 or 4 for the production of a cyanophycin synthetase according to claim 1 and / or for the production of cyanophycin.

9. Use of a cyanophycin synthetase according to Claim 1 for the production of cyanophycin.

10. Isoenzymes and modified forms of cyanophycin synthetase, characterized in that they are obtained by modification of the cyanophycin synthetase from Synechococcus elongatus.

11. Isoenzymes and modified forms of cyanophycin synthetase according to Anspmch 10, characterized in that they are obtained by amino acid exchange.

12. Isoenzymes and modified forms of cyanophycin synthetase according to Anspmch 11, characterized in that the amino acid exchange takes place by modifying the nucleotide sequence of the underlying gene.

13. Artificial DNA sequences, characterized in that they are incorporated or appended to the gene of cyanophycin synthetase according to Claim 1.

14. A probe for the identification and / or isolation of genes coding for proteins involved in the biosynthesis of cyanophycin, characterized in that it contains a label suitable for detection of the cyanophycin synthetase and its modification according to claims 1 and 10.

15. Heterologous host systems containing a nucleic acid sequence or a part thereof coding for a cyanophycin synthetase, an isoenzyme or a modified form thereof according to claims 1 and 10.

16. Use of cyanophycin prepared according to Anspmch 9 for the synthesis of

Polyaspartic acid or arginine.

17. Natural or artificial DNA sequences in 5 'or upstream and / or 3' or downstream position of the cyanophycin synthetase according to spoke 1, characterized in that these influence the transcription, the RNA stability or the RNA processing and the translation.