The fatty acid synthase of the basidiomycete Omphalotus olearius is a single polypeptide

Fatty acids are essential components of almost all biological membranes. Additionally, they are important in energy storage, as second messengers during signal transduction, and in post-translational protein modification. De novo synthesis of fatty acids is essential for almost all organisms, and entails the iterative elongation of the growing fatty acid chain through a set of reactions conserved in all kingdoms. During our work on the biosynthesis of secondary metabolites, a 450-kDa protein was detected by SDS-PAGE of enriched fractions from mycelial lysates from the basidiomycete Omphalotus olearius. Protein sequencing of this protein band revealed the presence of peptides with homology to both alpha and beta subunits of the ascomycete fatty acid synthase (FAS) family. The FAS encoding gene of O. olearius was sequenced. The positions of its predicted 21 introns were verified. The gene encodes a 3931 amino acids single protein, with an equivalent of the ascomycetous beta subunit at the N-terminus and the a subunit at the C-terminus. This is the first report on an FAS protein from a homobasidiomycete and also the first fungal FAS which is comprised of a single polypeptide.

Effects of the anthelmintic drug PF1022A on mammalian tissue and cells

Nematode infections cause human morbidity and enormous economic loss in livestock. Since resistance against currently available anthelmintics is a worldwide problem, there is a continuous need for new compounds. The cyclooctadepsipeptide PF1022A is a novel anthelmintic that binds to the latrophilin-like transmembrane receptor important for pharyngeal pumping in nematodes. Furthermore, PF1022A binds to GABA receptors, which might contribute to the anthelmintic effect. Like other cyclodepsipeptides, PF1022A acts as an ionophore. However, no correlation between ionophoric activity and anthelmintic properties was found. This is the first study describing the effect of PF1022A on mammalian cells and tissues. While channel-forming activity was observed already at very low concentrations, changes in intracellular ion concentrations and reduction of contractility in isolated guinea pig ileum occurred at multiples of anthelmintically active concentrations. PF1022A did not induce necrotic cell death indicated by complete lack of cellular lactate dehydrogenase release. In contrast, apoptosis induction via the mitochondrial pathway was suggested for long-term drug treatment at high concentrations due to numerous apoptotic morphological changes as well as mitochondrial membrane depolarisation. Short time effects were based on cell cycle blockade in G(0)/G(1) phase. Additionally, the cell cycle and apoptosis regulating proteins p53, p21 and bax, but not Bcl-2 were shown to impact on PF1022A-induced cytotoxicity. However, since PF1022A-induced cytotoxicity was found at drug concentrations higher than those used in anthelmintic treatment, it can be suggested that PF1022A intake might not impair human or animal health. Thus, PF1022A seems to be a safe alternative to other anthelmintic drugs.

Functional Characterization of the RecombinantN-Methyltransferase Domain from the Multienzyme Enniatin Synthetase

A 51 kDa fusion protein incorporating the N-methyltransferase domain of the multienzyme enniatin synthetase from Fusarium scirpi was expressed in Saccharomyces cerevisiae. The protein was purified and found to bind S-adenosyl methionine (AdoMet) as demonstrated by cross-linking experiments with (14)C-methyl-AdoMet under UV irradiation. Cofactor binding at equilibrium conditions was followed by saturation transfer difference (STD) NMR spectroscopy, and the native conformation of the methyltransferase was assigned. STD NMR spectroscopy yielded significant signals for H(2) and H(8) of the adenine moiety, H(1') of D-ribose, and S-CH(3) group of AdoMet. Methyl group transfer catalyzed by the enzyme was demonstrated by using aminoacyl-N-acetylcysteamine thioesters (aminoacyl-SNACs) of L-Val, L-Ile, and L-Leu, which mimic the natural substrate amino acids of enniatin synthetase presented by the enzyme bound 4'-phosphopantetheine arm. In these experiments the enzyme was incubated in the presence of the corresponding aminoacyl-SNAC and (14)C-methyl-AdoMet for various lengths of time, for up to 30 min. N-[(14)C-Methyl]-aminoacyl-SNAC products were extracted with EtOAc and separated by TLC. Acid hydrolysis of the isolated labeled compounds yielded the corresponding N-[(14)C-methyl] amino acids. Further proof for the formation of N-(14)C-methyl-aminoacyl-SNACs came from MALDI-TOF mass spectrometry which yielded 23 212 Da for N-methyl-valyl-SNAC, accompanied by the expected postsource decay (PSD) pattern. Interestingly, L-Phe, which is not a substrate amino acid of enniatin synthetase, also proved to be a methyl group acceptor. D-Val was not accepted as a substrate; this indicates selectivity for the L isomer.

Bew Beauveriolides Produced by Amino Acid-supplemented Fermentation of Beauveria sp. FO-6979

Five new beauveriolides were isolated from the acetone extracts of Beauveria sp. FO-6979 mycelia fermented in amino acid-supplemented media. The structures were elucidated by spectroscopic studies including NMR experiments and chemical degradation. All the beauveriolides are cyclodepsipeptides consisting of one 3-hydroxy-4-methyl fatty acid, two L-amino acids and one D-amino acid in common. Beauveriolide VII with the structure of cyclo-[3-hydroxy-4-methyloctanoyl-L-phenylalanyl-L-alanyl-D-valyl] inhibited lipid droplet formation and cholesteryl ester synthesis in macrophages, but the other beauveriolides showed only slight or almost no effect on lipid droplet formation.

Antimycobacterial activity of lipodepsipeptides produced by Pseudomonas syringae pv syringae B359

Some lipodepsipeptides produced by Pseudomonas syringae pv. syringae showed strong antimycobacterial activity towards Mycobacterium smegmatis. MIC values found were between 1.5-3.2 microg/ml, which is comparable to some primary drugs for tuberculosis. Among the lipodepsipeptides, Syringomycin E (SRE) appears to be the most potent antimycobacterial agent.

Enniatin synthetase is a monomer with extended structure: evidence for an intramolecular reaction mechanism

Enniatin synthetase (Esyn), a 347-kDa multienzyme consisting of two substrate activation modules, is responsible for the nonribosomal formation of the cyclohexadepsipeptide enniatin. The synthesis follows the so-called thiol template mechanism. While this process is basically well established, no substantial insight into the 3-dimensional arrangement of these enzymes and possible interactions between them exists to date. To find out whether enniatin synthesis is an intramolecular process or the result of three interacting Esyn molecules (intermolecular), analytical ultracentrifugation equilibration studies were carried out. The molecular mass of Esyn was determined by ultracentrifugation and is in good agreement with that calculated from the ORF of the encoding gene, indicating that Esyn exists in solution as a monomer. This strongly suggests that synthesis of the cyclohexadepsipeptide enniatin follows an intramolecular reaction mechanism in which all three reaction cycles are catalyzed by a single Esyn molecule. This finding was supported by in vitro complementation studies in which [(14)C]-methylvalyl Esyn, upon incubation with the second substrate D-2-hydroxyisovaleric acid (D-Hiv) and ATP, did not yield radioactive enniatin. This confirms our previous assumption of an iterative reaction mechanism similar to that for fatty acid synthase. Furthermore, the sedimentation rate constant evaluated from analytical ultracentrifugation was lower (S(20,w)=14.1S) than expected (S(20,w)=16.9S) for a globular protein, indicating that Esyn has an extended structure.

Directed biosynthesis of new enniatins

New cyclohexadepsipeptides of the enniatin type with potential anthelmintic properties were produced by two different strategies: 1. In vitro synthesis by use of the multienzyme enniatin synthetase, and 2. in vivo precursor feeding of enniatin producing strains Fusarium scirpi and Fusarium sambucinum. The compounds were analyzed by HPLC, various NMR measurements and mass spectrometry. The three N-methyl L-amino acid positions in the enniatin B molecule could be gradually replaced by other (N-methyl) L-amino acids, e.g. alanine, cysteine, threonine and serine. The latter two amino acids yield new enniatins with functional groups in the hydrophobic side chains. Similarly the three D-2-hydroxyisovalerate residues, present in all naturally occuring enniatins, could be substituted by D-2-hydroxybutyric acid and D-lactic acid. Despite its lower yield the in vitro synthesis has the advantage of a broader variety of products formed.

Mutational analysis of the N-methyltransferase domain of the multifunctional enzyme enniatin synthetase

N-Methylcyclopeptides like cyclosporins and enniatins are synthesized by multifunctional enzymes representing hybrid systems of peptide synthetases and S-adenosyl-l-methionine (AdoMet)-dependent N-methyltransferases. The latter constitute a new family of N-methyltransferases sharing high homology within procaryotes and eucaryotes. Here we describe the mutational analysis of the N-methyltransferase domain of enniatin synthetase from Fusarium scirpi to gain insight into the assembly of the AdoMet-binding site. The role of four conserved motifs (I, (2085)VLEIGTGSGMIL; II/Y, (2105)SYVGLDPS; IV, (2152)DLVVFNSVVQYFTPPEYL; and V, (2194)ATNGHFLAARA) in cofactor binding as measured by photolabeling was studied. Deletion of the first 21 N-terminal amino acid residues of the N-methyltransferase domain did not affect AdoMet binding. Further shortening close to motif I resulted in loss of binding activity. Truncation of 38 amino acids from the C terminus and also internal deletions containing motif V led to complete loss of AdoMet-binding activity. Point mutations converting the conserved Tyr(223) (corresponding to position 2106 in enniatin synthetase) in motif II/Y (close to motif I) into Val, Ala, and Ser, respectively, strongly diminished AdoMet binding, whereas conversion of this residue to Phe restored AdoMet-binding activity to approximately 70%, indicating that Tyr(223) is important for AdoMet binding and that the aromatic Tyr(223) may be crucial for AdoMet binding in N-methylpeptide synthetases.

Biosynthesis of PF1022A and related cyclooctadepsipeptides

PF1022A belongs to a recently identified class of N-methylated cyclooctadepsipeptides (CODPs) with strong anthelmintic properties. Described here is the cell-free synthesis of this CODP and related structures, as well as the purification and enzymatic characterization of the responsible synthetase. For PF1022A synthesis extracts of Mycelia sterilia were incubated with the precursors L-leucine, D-lactate, D-phenyllactate, and S-adenosyl-L-methionine in the presence of ATP and MgCl(2). A 350-kDa depsipeptide synthetase, PFSYN, responsible for PF1022A synthesis was purified to electrophoretic homogeneity. Like other peptide synthetases, PFSYN follows a thiotemplate mechanism in which the substrates are activated as thioesters via adenylation. N-Methylation of the substrate L-leucine takes place after covalent binding prior to peptide bond formation. The enzyme is capable of synthesizing all known natural cyclooctadepsipeptides of the PF1022 type (A, B, C, and D) differing in the content of D-lactate and D-phenyllactate. In addition to PF1022 types A, B, C, and D, the in vitro incubations produced PF1022F (a CODP consisting of D-lactate and N-methyl-L-leucine), as well as di-, tetra-, and hexa-PF1022 homologs. PFSYN strongly resembles the well documented enniatin synthetase in size and mechanism. Our results suggest that PFSYN, like enniatin synthetase, is an enzyme with two peptide synthetase domains and forms CODP by repeated condensation of dipeptidol building blocks. Due to the low specificity of the d-hydroxy acid binding site, D-lactate or D-phenyllactate can be incorporated into the dipeptidols depending on the concentration of these substrates in the reaction mixture.

Capsid protein-encoding genes of hamster polyomavirus and properties of the viral capsid

On the basis of its genome organization the hamster polyomavirus (HaPV) is closely related to the murine polyomavirus Py. But HaPV infection, in contrast to Py infection, gives rise to two different tumor types; depending on the hamster strain used for infection, HaPV induces either epitheliomas or lymphomas. Although the HaPV virions were shown to be similar to those of Py and SV40, more precise information about the structure and protein composition of the HaPV capsid was still missing. Here we describe the primary structure of the capsid protein-encoding HaPV genes and the structure and protein composition of the HaPV capsid. Virions isolated from epitheliomas in HaPV-infected hamsters were shown by electron microscopy to be spherical particles with the typical icosahedral structure of polyomaviruses. However, in contrast to the capsids of SV40 and Py, a T = 7 laevo symmetry of HaPV capsids was observed. Separation of HaPV virions in SDS polyacrylamide gels and Western blotting with VP1-specific antisera identified VP1 as the major capsid protein species corresponding in its molecular weight to the predicted value of 41.8 kDa. Because of the presence of two potential translational initiation sites in the VP1 gene, the N-terminal amino acid sequence of virion VP1 was determined and found to start at the second initiation site. The amino acid homologies of HaPV capsid proteins shared with Py varied between 65.5% (VP1), 45.4% (VP3) and 44.6% (VP2), whereas the homologies to the relevant proteins of other polyomaviruses were found to range between 49.6-57.9% for VP1 and 28.9-41% for VP2/VP3.

Biosynthesis of taxol: enzymatic acetylation of 10-deacetylbaccatin-III to baccatin-III in crude extracts from roots of Taxus baccata

The biosynthesis of taxol is a multistep process. One intermediate reaction is the acetylation of 10-deacetylbaccatin-III (10-DAB) to baccatin-III, an assumed precursor of taxol. Here we describe the cell free acetylation of 10-DAB in crude extracts from roots of Taxus baccata saplings using 14C-or 3H-labeled acetyl-coenzyme A as the acetyl donor. The reaction is strictly dependent on the addition of 10-DAB and is specific for the 10-hydroxyl group of the taxane ring. Formation of radiolabeled baccatin-III was confirmed by co-chromatography of the labeled product with authentic baccatin-III in different TLC-systems and HPLC. Furthermore, the acetylation product showed an identical UV spectrum as authentic baccatin-III. Crude extracts from cambium of stems yielded three- to fivefold lower activity. This is in agreement with our finding that the taxol titer in roots was considerably higher than that in cambium.

Effect of disruption of the enniatin synthetase gene on the virulence of Fusarium avenaceum

Production of the phytotoxic compound enniatin has been proposed to play a role during the infection process of plants by enniatin-synthesizing Fusarium species. Enniatins are cyclohexadepsipeptides synthesized by the multifunctional enzyme enniatin synthetase. To test the hypothesis that enniatin contributes to pathogenicity, enniatin-nonproducing mutants were constructed by gene disruption of the enniatin synthetase gene of a virulent Fusarium avenaceum strain. Four independent enniatin nonproducing mutants were characterized that did not express enniatin synthetase, as proved by RNA and protein blot analysis. The virulence on potato tuber tissue of the enniatin-nonproducing strains was significantly reduced compared with the virulence of the parent strain and three enniatin-producing transformants. Therefore, we conclude that enniatin production contributes to the virulence of Fusarium avenaceum.

Enniatin production by fusarium strains and its effect on potato tuber tissue

Several Fusarium strains produce the cyclohexadepsipeptide enniatin, a host-nonspecific phytotoxin. Enniatins are synthesized by the 347-kDa multifunctional enzyme enniatin synthetase. In the present study, 36 Fusarium strains derived from a wide range of host plants were characterized with respect to enniatin production in different media. Thirteen of these strains produced enniatins on one or more of these media. To determine whether enniatin production affected virulence, an assay on potato tuber tissue was performed. Seven enniatin-producing and 16 nonproducing strains induced necrosis of potato tuber tissue, so that enniatin synthesis is not essential for the infection of potato tuber tissue. The application of a mixture of enniatins to slices of potato tuber, however, caused necrosis of the tissue. Therefore, enniatin production by the enniatin-synthesizing strains may affect their pathogenicity. The enniatin synthetase gene (esyn1) of Fusarium scirpi ETH 1536 was used as a probe to determine if similar sequences were present in the strains examined. In Southern blot analyses, DNA sequences hybridizing with the esyn1 probe were present in all but two of the strains examined. In some cases, enniatin-nonproducing strains had the same hybridization pattern as enniatin producers.

Highly conserved N-methyltransferases as an integral part of peptide synthetases

The methyltransferase portion of the N-methyl-peptide-synthetase gene, synthesizing enniatin from Fusarium sambucinum, was amplified with the polymerase chain reaction (PCR) using primers derived from the highly conserved sequences of the flanking peptide synthetase domain. The deduced amino acid sequence of the product shares high similarity to the 430 amino acid methyltransferase portion of enniatin synthetase of Fusarium scirpi and the corresponding portions of another fungal peptide synthetase catalyzing the biosynthesis of the N-methylated cyclopeptide cyclosporin. As the methyltransferase portions show only local similarity to motifs apparently conserved within methyltransferases, the segments of peptide synthetases involved in the biosynthesis of bioactive peptides represent a new class of S-adenosyl-L-methionine dependent methyltransferases.

Arrangement of catalytic sites in the multifunctional enzyme enniatin synthetase

Enniatin synthetase is an N-methyl peptide synthetase comprising 3131 amino acids. Catalytic sites of the 347-kDa multifunctional enzyme were mapped by N-terminal sequencing of substrate affinity-labelled enzyme fragments formed by proteolysis, and functional studies of purified enniatin synthetase fragments. An N-terminal 200-kDa fragment containing the cofactor 4'-phosphopantetheine was able to activate D-hydroxyisovaleric acid (D-HOiVl) as a thioester. The N-termini of two [14C]HOiVl-labelled enzyme fragments could be assigned to amino acid position 429 within the N-terminal conserved enniatin synthetase portion named EA. This portion of about 600 amino acids shares high similarity to microbial peptide synthetase regions. A 68-kDa L-[14C]Val-labelled enniatin synthetase fragment was localized at amino acid position 2294 within the second C-terminal conserved protein portion EB. Additionally enniatin synthetase was labelled with isovaleryl-L-[14C]Val, an analogue of the D-hydroxyisovaleryl-L-Val intermediate in enniatin biosynthesis. The N-terminus of a 30-kDa isovaleryl-L-[14C]Val-labelled enniatin synthetase fragment was mapped in a C-terminal segment of the protein portion EA. The same N-terminal sequence was obtained from a 60-kDa enniatin synthetase fragment modified with [3H]beta Ala, a constituent of the cofactor 4'-phosphopantetheine. This indicates the presence of the cofactor in this protein fragment. Localization of the methyltransferase function of enniatin synthetase in an amino acid portion integrated into region EB was achieved by N-terminal sequencing of a photolabelled S-[methyl-14C]adenosyl methionine 45-kDa fragment and the identification of a photolabelled peptide Asn-Leu-Asn-Pro-Gly-Leu-Asn-Ser-Tyr.

Cloning and sequencing of a cyclophilin gene from the cyclosporin producer Tolypocladium niveum

The gene of a 19 kDa cyclophilin of Tolypocladium niveum was isolated and sequenced. The open reading frame of 956 bp is interrupted by four introns of 76, 221, 58, and 61 bp size. 101 nucleotides upstream of the start codon ATG we found a putative promoter region containing a TATA and a CAAT box. The predicted amino acid sequence shows high identity to other cyclophilins, especially to the cyclophilin A family members of eucaryotic and procaryotic origin. Similar to the case of N. crassa we found a segment of 13 additional amino acid residues near the N-terminus which is not present in the other cyclophilins.

Bacterial expression of catalytically active fragments of the multifunctional enzyme enniatin synthetase

Enniatin synthetase catalyzes the biosynthesis of N-methylated cyclohexadepsipeptides. The 347 kDa enzyme is encoded by the esyn1 gene of Fusarium scirpi and contains two domains (EA and EB) homologous to each other and to regions of other microbial peptide synthetases. Parts of the esyn1 gene were subcloned in frame to a small lacZ gene portion of Escherichia coli expression vectors. Overproduced recombinant proteins showed a high tendency towards inclusion body formation and could be only partially dissolved in 8 M urea or 6 M guanidine hydrochloride. After renaturation, a 121 kDa recombinant protein representing the N-terminal conserved domain EA of enniatin synthetase was shown to activate D-hydroxyisolvaleric acid via adenylation. Similarly, a 158 kDa recombinant protein comprising the C-terminal conserved domain EB catalyzed the activation of the substrate amino acid (e.g. L-valine). Moreover, this protein could be photolabeled with S-[methyl-14C]adenosyl-L-methionine, (AdoMet) indicating the presence of the methyltransferase. Both functions, L-valine activation and AdoMet binding, could be assigned to a 108 kDa recombinant protein encompassing the A and the M segment of domain EB. The fact that a 65 kDa recombinant protein representing the M portion could be photolabeled, indicated the localization of the methyltransferase in this region. Three deletion mutants of the 65 kDa protein were shown to be inactive with respect to UV-induced AdoMet labeling.

Purification and characterization of eucaryotic alanine racemase acting as key enzyme in cyclosporin biosynthesis

A specific alanine racemase, which is a key enzyme in the biosynthesis of the undecapeptide cyclosporin A, was purified to electrophoretic homogeneity from the fungus Tolypocladium niveum. This is the first enzyme of this kind isolated from a eucaryotic organism. The enzyme catalyzes the reversible racemization of alanine and requires pyridoxal phosphate as the exclusive cofactor. Km values for L- and D-alanine were found to be 38 and 2 mM, respectively. Maximal reaction velocity was observed at 42 degrees C and pH 8.8 for the L to D direction. Molecular mass determinations of the denatured enzyme by SDS-polyacrylamide gel electrophoresis gave a value of 37 kDa, whereas gel filtration calibration studies yielded a value between 120 and 150 kDa, indicating an oligomeric native structure.

Molecular characterization of the enniatin synthetase gene encoding a multifunctional enzyme catalysing N-methyldepsipeptide formation in Fusarium scirpi

The gene encoding the multifunctional enzyme enniatin synthetase from Fusarium scirpi (esyn1) was isolated and characterized by transcriptional mapping and expression studies in Escherichia coli. This is the first example of a gene encoding an N-methyl peptide synthetase. The nucleotide sequence revealed an open reading frame of 9393 bp encoding a protein of 3131 amino acids (M(r) 346,900). Two domains designated EA and EB within the protein were identified which share similarity to each other and to microbial peptide synthetase domains. In contrast to the N-terminal domain EA, the carboxyl terminal domain EB is interrupted by a 434-amino-acid portion which shows local similarity to a motif apparently conserved within adenine and cytosine RNA and DNA methyltransferases and therefore seems to harbour the N-methyl-transferase function of the multienzyme.

Two new cyclophilins from Fusarium sambucinum and Aspergillus niger: resistance of cyclophilin/cyclosporin A complexes against proteolysis

Two new peptidyl-prolyl-cis/trans-isomerases were purified to homogeneity from Fusarium sambucinum and Aspergillus niger. They belong to the class of cyclosporin A binding proteins (cyclophilins) and have molecular masses of about 18 kDa. As has been shown for other cyclophilins, the isomerase activity of the enzymes is inhibited by cyclosporin A in the nanomolar range. Furthermore binding of cyclosporin A prevents proteolytic digestion of the cyclophilin/cyclosporin complexes by the endoproteases GluC, LysC and alpha-chymotrypsin, in contrast to the free cyclophilins, which are readily cleaved by these proteases. We could also observe this protection for cyclophilins from sheep thymus and from the cyclosporin producing fungus Tolypocladium inflatum.

Enniatin synthetases from different fusaria exhibiting distinct amino acid specificities

Enniatin synthetases from the cyclodepsipeptide producers Fusarium lateritium and Fusarium sambucinum were purified to homogeneity and characterized. Like the previously described enniatin synthetase from Fusarium scirpi both enzymes consist of a single polypeptide chain and are very similar concerning their Mr (250 kdaltons) and reaction mechanism. Limited proteolytic digests show only slight differences in their patterns in SDS-gels. Interestingly the synthetases differ in their amino acids specificities. The enzyme from the enniatin A producer F. sambucinum exhibits a high affinity to the substrate amino acids L-Leu and L-Ile. In contrast the synthetase from the enniatin B producer F. lateritium preferably accepts L-Val, the constituent amino acid of enniatin B.

A highly specific D-hydroxyisovalerate dehydrogenase from the enniatin producer Fusarium sambucinum

A highly specific D-hydroxyisovalerate (D-HIV) dehydrogenase, which is a key enzyme in depsipeptide synthesis, was purified to near homogeneity from the enniatin-producing fungus Fusarium sambucinum. The enzyme catalyzes the reversible reaction of 2-ketoisovalerate (2-KIV) to D-HIV. It is strictly dependent on NADPH and exhibits a high substrate specificity with respect to 2-KIV. NADH was not accepted by the enzyme. Km values for 2-KIV and NADPH were found to be 200 and 333 microM, respectively. D-HIV dehydrogenase consists of a single polypeptide chain with a molecular mass of about 53 kDa. Optimum temperature for the reduction of 2-KIV was 35 degrees C and for the oxidation reaction was 45 degrees C. The optimum pH was found to be 7 for the reduction and 8-9 for the oxidation reaction.

A seventeen kilodaltons peptidyl-prolyl cis-trans isomerase of the cyclosporin-producer Tolypocladium inflatum is sensitive to cyclosporin A

A peptidyl-prolyl cis-trans isomerase (PPIase) was purified to homogeneity about 24-fold from the cyclosporin-producing fungus Tolypocladium inflatum. The molecular mass of the enzyme was in the range of 17 kdaltons. Remarkably, the enzyme could be inhibited by cyclosporin A in the nanomolar range as has been shown for numerous other cyclophilins from eukaryotic organisms. This indicates, that Tolypocladium inflatum must possess a self protection system in order to survive in the presence of cyclosporin.

FK-506 binding protein from tolypocladium inflatum: Resistance of FKBPFK-506 complex against proteolysis

A 12-kDa peptidyl-prolyl-cis/trans-isomerase was purified 225-fold to homogeneity from the cyclosporin producing fungus Tolypocladium inflatum. The enzyme is highly sensitive to the immunosuppressant FK-506 but not to cyclosporin and thus belongs to the class of FK-506 binding proteins (FKBP). Interestingly the FKBP/FK-506 complex is resistant against proteolytic digestion by the endoproteases GluC and LysC, in contrast to the free FKBP, which is readily cleaved by these proteases. This protection may play a role in the effects of FK-506 in the living cell.

Isolation and partial characterization of cyclosporin synthetase from a cyclosporin non-producing mutant of Beauveria nivea

Cyclosporin synthetase was isolated from a cyclosporin non-producing mutant of Beauveria nivea, strain YP 582. The enzyme has a molecular mass in the range of active cyclosporin synthetase and also contains 4'-phosphopantetheine as a prosthetic group. It is able to activate all constituent amino acids of cyclosporin A as thioesters and to carry out specific N-methylation reactions. Overall synthesis of the undecapeptide cyclosporin A in the presence of all necessary substrates was not observed, but the formation of the diketopiperazine cyclo-(D-alanyl-N-methyl-leucyl). This diketopiperazine represents a partial sequence of the cyclosporin molecule. It could be detected in the mycelium of the non-producing strain, whereas mycelium of the producing strain 7939/45 did not contain this compound. The results suggest that the inability of this mutant to produce cyclosporin A is caused by a mutation of the polypeptide chain of cyclosporin synthetase.

Cyclosporin synthetase. The most complex peptide synthesizing multienzyme polypeptide so far described

Cyclosporin A and its homologues are synthesized by a single multifunctional enzyme from their precursor amino acids. Cyclosporin synthetase is a polypeptide chain with a molecular mass of approximately 800 kDa. In 3% polyacrylamide-sodium dodecyl sulfate gels it shows a single band of approximately 650 kDa, which appears to not be glycosylated. The enzyme could be purified to near-homogeneity in five steps. A 72-fold purification was obtained. All constitutive amino acids of cyclosporins are activated as thioesters via aminoadenylation by the same enzyme. Then N-methylation of the thioester-bound amino acids which are present in methylated form in the cyclosporin molecule takes place, whereby S-adenosyl-L-methionine serves as the methyl group donor. Methyltransferase activity is an integral entity of the enzyme; this could be shown by a photoaffinity labeling method. 4'-Phosphopantetheine is a prosthetic group of cyclosporin synthetase similar to other peptide and depsipeptide synthetases. Cyclosporin synthetase shows cross-reactions with monoclonal antibodies directed against enniatin synthetase.

Cell-free biosynthesis of new cyclosporins

An enzyme preparation, isolated from extracts of the fungus Beauveria nivea (previously designated Tolypocladium inflatum), is able to synthesize cyclosporins (Cy's) in vitro. At suboptimal temperature it was possible to yield about 50 micrograms of CyA per ml. The enzyme also produces several of the naturally occurring congeners of CyA, such as the Cy's B, C, D, G, M, O, Q, U and V and some of the analogues known to be produced by the fungus via precursor directed biosynthesis, like dihydro-CyA, [N-methyl-L-beta-cyclohexylalanine]CyA, [L-allylglycine]CyA and [D-serine]CyA. Furthermore, Cy's not obtainable by the fungus could be prepared by the enzyme system in the presence of the appropriate precursor amino acids; the synthesis of [N-methyl-(+)-2-amino-3-hydroxy-4,4-dimethyloctanoic acid]CyA, [L-norvaline, N-methyl-L-norvaline]CyA, [L-norvaline, N-methyl-L-norvaline]CyA, [L-allo-isoleucine, N-methyl-L-allo-isoleucine]CyA, [L-allo-isoleucine]CyA, [D-2-aminobutyric acid]CyA and [beta-chloro-D-alanine]CyA could be established. The immunosuppressive effects of the new derivatives are discussed.

Destruction of ethidium bromide in solution by ozonolysis

Ethidium bromide can be rapidly destroyed in aqueous solutions or in isoamyl alcohol by ozonolysis in the presence of H2O2 to give a mixture of organic acids. In a variety of buffers commonly used in recombinant DNA technology destruction of ethidium bromide was more than 99.9%. The yellow reaction mixture after ozonolysis was shown to be nonmutagenic. This method may be used in laboratories for the disposal of ethidium bromide wastes.

Constitutive Expression of Enniatin Synthetase during Fermentative Growth of Fusarium scirpi

The production of enniatins by Fusarium scirpi during fermentative growth in submerged cultures was measured. The fungus produced the antibiotic during mycelial growth, but not during the stationary phase of cultivation. By contrast, enniatin synthetase, the enzyme responsible for enniatin synthesis, was present during growth, during the stationary phase, and even in spores. Similarly, the enniatin synthetase mRNA was present at every stage of the cultivation of the fungus. Therefore, this multifunctional peptide synthetase is a constitutive enzyme, the expression of which is not regulated by any specific mechanism. The findings stand in contrast to the common assumption that production of secondary metabolites underlies regulatory control, leading to separation of the trophophase and the idiophase.

Synthesis of beauvericin by a multifunctional enzyme

Beauvericin synthetase, a multifunctional enzyme catalyzing depsipeptide formation in Beauveria bassiana was purified to near homogeneity. The enzyme consists of a single polypeptide chain with a molecular mass of about 250 kdaltons. The mechanism of beauvericin formation is very similar to that of the cyclohexadepsipeptide enniatin. The constituents of the beauvericin molecule, L-phenylalanine and D-alpha-hydroxyisovaleric acid are activated as thioesters via the corresponding adenylates. N-Methylation takes place at the thioester bound stage of the phenylalanine residues. Omission of the methyl donor S-adenosyl-L-methionine results in the formation of demethylbeauvericin. Studies on substrate specificity revealed that phenylalanine could be replaced by a number of other aromatic or aliphatic amino acids like beta-phenylserine, ortho-, meta-, para-fluorophenylalanine, isoleucine, norleucine and leucine. Valine, the constituent amino acid of enniatin B was not accepted by the enzyme.

Enzymatic synthesis of cyclosporin A

An enzyme fraction, isolated from crude extracts of the fungus Tolypocladium inflatum, strain 7939/F, is able to synthesize the undecapeptide cyclosporin A. The formation of cyclosporin A was monitored by incorporation of the radiolabeled constituent amino acids of cyclosporin A or by using S-adenosyl-L-[14C-methyl] methionine. The structure of cyclosporin A, synthesized enzymatically in vitro, was confirmed by chromatographic comparison with the authentic compound and by amino acid analyses. Replacement of L-2-aminobutyric acid in the reaction mixture by L-alanine, L-threonine, L-valine, or L-norvaline yields the naturally occurring cyclosporins B, C, D, and G. Also, D-alanine could be replaced by D-serine to yield [D-Ser8]cyclosporin A.

Monoclonal antibodies to the multienzyme enniatin synthetase. Production and use in structural studies

Monoclonal antibodies have been prepared against the multifunctional enzyme enniatin synthetase, which catalyses the biosynthesis of the cyclodepsipeptide antibiotic enniatin. Five different antibodies (designated 1.56, 21.1, 25.91, 28.7 and 28.34) were characterized. 1.56, 21.1 and 25.91 were of IgG1 and 28.7 and 28.34 of IgM subclass. Binding studies showed that 21.1 and 25.91 are obviously directed against determinants based on the primary structure of the enzyme, whereas 28.7, 28.34 and 1.56 bind to the native enzyme. All antibodies inhibited enniatin formation. Based on their ability to inhibit different partial reactions of the multienzyme the antibodies could be divided into three groups: 21.1 and 25.91 inhibit valyl thioester formation, 1.56 additionally inhibits D-2-hydroxyisovaleric acid thioesterification, and 28.7 and 28.34 block both thioester sites as well as the N-methylation step. None of the antibodies affected the formation of L-valyl or D-hydroxyisovaleryl adenylate by the enzyme. The results indicate that there must be distinct thioester activation sites for valine and D-hydroxyisovalerate close to each other and in the neighbourhood of the methyltransferase site. The adenylation sites for D-hydroxy-isovalerate and L-valine are obviously located at some distance.

Biosynthesis of cyclosporin A: partial purification and properties of a multifunctional enzyme from Tolypocladium inflatum

An enzyme fraction most probably involved in the biosynthesis of cyclosporin A was purified 540-fold from Tolypocladium inflatum. The enzyme was capable of forming covalent enzyme-substrate complexes and catalyzed the ATP-pyrophosphate exchange reactions dependent on the unmethylated constituent amino acids of cyclosporin A. Evidence was obtained that covalent binding of substrate amino acids occurred via thioester linkage. Furthermore, the N-methylation of thio-esterified valine, leucine, and glycine residues with S-adenosyl-L-methionine was demonstrated. De novo synthesis of cyclosporin A was not observed but the formation of the diketopiperazine cyclo-(D-Ala-MeLeu) from D-alanine and L-leucine under the consumption of ATP and S-adenosyl-L-methionine. This cyclodipeptide represents a partial sequence of cyclosporin A. Molecular mass determinations revealed the enzyme activity to be lying in the range of about 700 kDa.

4-Methyl-3-hydroxyanthranilic acid activating enzyme from actinomycin-producing Streptomyces chrysomallus

A 4-methyl-3-hydroxyanthranilic acid (4-MHA) activating enzyme was purified 24-fold from a crude protein extract of Streptomyces chrysomallus . The enzyme catalyzes both 4-MHA-dependent ATP/PPi exchange and the formation of the corresponding adenylate. No AMP was formed during the reaction, indicating that no covalent binding of 4-MHA takes place. Besides 4-MHA, the enzyme also catalyzes the formation of adenylates from 3-hydroxyanthranilic acid (3-HA), anthranilic acid (AA), benzoic acid (BA), 3-hydroxybenzoic acid (3-HB), 4-methyl-3-hydroxybenzoic acid (4-MHB), 4-methyl-3-methoxybenzoic acid (4- MMB ), and 4-aminobenzoic acid (4-AB). No such adenylates were formed from 2-aminophenol (2-AP), 2-hydroxybenzoic acid (2-HB), 3-hydroxykynurenine (3-HK), and tryptophan (Trp). 3-HA, 4-MHB, and 4-AB were among the structural analogues of 4-MHA that were the most effective for adenylate synthesis. In the case of 3-HA, considerable AMP release was observed, most probably due to nonenzymatic hydrolysis of the corresponding adenylate. A molecular weight between 53 000 and 57 000 was estimated. The specific activity of the enzyme was correlated with the titer of antibiotic in the cultures, and feeding experiments with whole mycelium of S. chrysomallus showed that 4-MHB was a strong inhibitor of actinomycin synthesis in vivo. The data strongly suggest that the enzyme is involved in the biosynthesis of actinomycin.

D-lysergic acid-activating enzyme from the ergot fungus Claviceps purpurea

A D-lysergic acid-activating enzyme from the ergot fungus Claviceps purpurea was purified about 145-fold. The enzyme was able to catalyse both the D-lysergic acid-dependent ATP-pyrophosphate exchange and the formation of ATP from D-lysergic acid adenylate and pyrophosphate. Both reactions were also catalysed to a decreased but significant extent with respect to dihydrolysergic acid. The molecular mass of the enzyme was estimated to lie between 135 and 140 kDa. The involvement of the enzyme in the biosynthesis of ergot peptide alkaloids is discussed.

Cell-free synthesis of the depsipeptide beauvericin

The enzymatic formation of the cyclodepsipeptide beauvericin was demonstrated in cell-free extracts from Beauveria bassiana. In analogy to the enniatin synthetase system formation of beauvericin is strictly dependent on the presence of the constituent amino and hydroxy acid, S-adenosylmethionine, and ATP/Mg2+. Synthesizing activity could be enriched about 12-fold by fractional ammonium sulfate precipitation. Besides the enniatin synthetase system this represents another example of the cell-free synthesis of a depsipeptide from eucaryotic origin.

Mechanism of depsipeptide formation catalyzed by enniatin synthetase

Covalently bound intermediates of enniatin B synthesis could be isolated from enniatin synthetase by treatment with performic acid. By comparison with products of mild alkaline cleavage of authentic enniatin B they could be identified as the dipeptide D-2-hydroxyisovaleryl-N-methylvaline and the corresponding tetrapeptide. Synthesis of enniatins apparently proceeds via condensation of dipeptides. This was confirmed by the use of the substrate analogue isovaleric acid, which has shown to be a strong inhibitor for enniatin synthesis by formation of N-isovaleryl-N-methyl valine.