Formation of D-Phe-Pro-Val-cyclo-Orn by gramicidin S synthetase in the absence of L-leucine

An Amidinohydrolase Provides the Missing Link in the Biosynthesis of Amino Marginolactone Antibiotics

Desertomycin A is an aminopolyol polyketide containing a macrolactone ring. We have proposed that desertomycin A and similar compounds (marginolactones) are formed by polyketide synthases primed not with γ-aminobutanoyl-CoA but with 4-guanidinylbutanoyl-CoA, to avoid facile cyclization of the starter unit. This hypothesis requires that there be a final-stage de-amidination of the corresponding guanidino-substituted natural product, but no enzyme for such a process has been described. We have now identified candidate amidinohydrolase genes within the desertomycin and primycin clusters. Deletion of the putative desertomycin amidinohydrolase gene dstH in Streptomyces macronensis led to the accumulation of desertomycin B, the guanidino form of the antibiotic. Also, purified DstH efficiently catalyzed the in vitro conversion of desertomycin B into the A form. Hence this amidinohydrolase furnishes the missing link in this proposed naturally evolved example of protective-group chemistry.

Parallel interrogation of covalent intermediates in the biosynthesis of gramicidin S using high-resolution mass spectrometry

For determination of multiple covalent intermediates bound to the ultra-large enzymes responsible for biosynthesis via nonribosomal peptide synthesis, mass spectrometry (MS) is a promising method to provide new mechanistic insight. Application of a quadrupole-Fourier-transform instrument (Q-FTMS) for direct analysis of aminoacyl intermediates is demonstrated for the first two modules (127 and 120 kDa) involved in the nonribosomal synthesis of gramicidin S. Cyanogen bromide digestions of recombinant proteins afforded detection of two active site peptides (both ~13 kDa) that provided direct evidence for modules copurifying with their preferred amino acid substrates. Given the ability to detect multiple covalent intermediates in tandem, a competition experiment among several nonnatural substrates in parallel was performed using the first module. This defined mixture of acyl-enzyme intermediates was used to probe the selectivity of the condensation step producing a diversity of noncognate dipeptides on the second module.

Substrate recognition and selection by the initiation module PheATE of gramicidin S synthetase

The initiation module of non-ribosomal peptide synthetases (NRPS) selects and activates the first amino acid and serves as the aminoacyl donor in the first peptide bond-forming step of the NRPS assembly line. The gramicidin S synthetase initiation module (PheATE) is a three-domain subunit, recognizing L-phenylalanine (L-Phe) and activating it (by adenylation domain) as tightly bound L-phenylalanyl-adenosine-5'-monophosphate diester (L-Phe-AMP), transferring it to the HS-phosphopantetheine arm of the holo-thiolation (holo-T) domain, and then epimerizing it (by epimerization domain) to the D-Phe-S-4'-Ppant-acyl enzyme. In this study, we have assayed the selectivity of the PheATE adenylation domain with a number of proteinogenic amino acids and observed that three additional amino acids, L-Tyr, L-Trp, and L-Leu, were activated to the aminoacyl-AMPs and transferred to the HS-phosphopantetheine arm of the holo-T domain. Hydrolytic editing of noncognate aminoacyl-AMPs and/or aminoacyl-S-4'-Ppant-acyl enzymes by the enzyme was not observed by three different assays for adenylation domain function. The microscopic reaction rates and thermodynamic equilibrium constants obtained from single-turnover studies of reactions of L-Phe, L-Trp, L-Tyr, and L-Leu with holoPheATE allowed us to construct free energy profiles for the reactions, revealing the kinetic and thermodynamic basis for substrate recognition and selection. In particular, the rates of epimerization of the L-aminoacyl-S-enzyme to the D-aminoacyl-S-enzyme intermediate showed reductions of 245-, 300-, and 540-fold for L-Trp, L-Tyr, and L-Leu respectively, suggesting that the epimerization domain is an important gatekeeper for generation of the D-Phe-S-enzyme that starts gramicidin S chain growth.

Construction of hybrid peptide synthetases by module and domain fusions

Nonribosomal peptide synthetases are modular enzymes that assemble peptides of diverse structures and important biological activities. Their modular organization provides a great potential for the rational design of novel compounds by recombination of the biosynthetic genes. Here we describe the extension of a dimodular system to trimodular ones based on whole-module fusion. The recombinant hybrid enzymes were purified to monitor product assembly in vitro. We started from the first two modules of tyrocidine synthetase, which catalyze the formation of the dipeptide dPhe-Pro, to construct such hybrid systems. Fusion of the second, proline-specific module with the ninth and tenth modules of the tyrocidine synthetases, specific for ornithine and leucine, respectively, resulted in dimodular hybrid enzymes exhibiting the combined substrate specificities. The thioesterase domain was fused to the terminal module. Upon incubation of these dimodular enzymes with the first tyrocidine module, TycA, incorporating dPhe, the predicted tripeptides dPhe-Pro-Orn and dPhe-Pro-Leu were obtained at rates of 0.15 min(-1) and 2.1 min(-1). The internal thioesterase domain was necessary and sufficient to release the products from the hybrid enzymes and thereby facilitate a catalytic turnover. Our approach of whole-module fusion is based on an improved definition of the fusion sites and overcomes the recently discovered editing function of the intrinsic condensation domains. The stepwise construction of hybrid peptide synthetases from catalytic subunits reinforces the inherent potential for the synthesis of novel, designed peptides.

Characterization of the binding site of the tripeptide intermediate D-Phenylalanyl L-prolyl-L-valine in gramicidin S biosynthesis

The tripeptide intermediate D-Phe-Pro-Val in the biosynthesis of gramicidin S was labeled by incorporation of either L-[14C]phenylalanine or L-[14C]valine in an in vitro biosynthetic assay. The gramicidin S synthetase 2-tripeptide complex was first digested with CNBr and subsequently by Staphylococcus aureus V8 protease. The active site peptide carrying the radioactively labeled tripeptide was isolated in pure form by reversed phase high performance liquid chromatography technology and analyzed by liquid phase sequencing, mass spectrometry, and amino acid analysis. It was demonstrated that D-Phe-Pro-Val is attached to the 4'-phosphopantetheine cofactor at the thiolation center for valine of gramicidin S synthetase 2. In this way the attachment site of a peptide intermediate in nonribosomal peptide biosynthesis was identified for the first time. Our results are in full agreement with the multiple carrier model of nonribosomal peptide biosynthesis (Stein, T., Vater, J., Kruft, V., Otto, A., Wittmann-Liebold, B., Franke, P., Panico, M., McDowell, R., and Morris, H. R. (1996) J. Biol. Chem. 271, 15426-15435), which predicts that the growing peptide chain in the elongation process should always be bound to the thiotemplate site specific for its C-terminal amino acid component.

The modular organization of multifunctional peptide synthetases

Gramicidin S synthetase 2 from B. brevis was affinity labeled at its valine thiolation center with the thiol reagent N-[3H]ethylmaleimide. From a tryptic digest of the enzyme-inhibitor complex a radioactive fragment was isolated in pure form by two reversed-phase HPLC steps. It was identified by liquid-phase N-terminal sequencing in combination with electrospray mass spectrometry (ESI-MS) as a hexadecapeptide containing the thiolation motif LGG(H/D)S(L/I). By ESI-MS it was demonstrated that a 4'-phosphopantetheine cofactor was attached to this fragment at its reactive serine. These results are consistent with the "Multiple Carrier Model" of nonribosomal peptide biosynthesis. Site-specific mutagenesis has been performed in thiolation, elongation, and epimerization motifs of some of the modules of surfactin synthetase from B. subtilis to clarify the function of prominent conserved amino acid residues in the intermediate steps of peptide biosynthesis. The modular structure of multifunctional peptide synthetases is discussed.

The multiple carrier model of nonribosomal peptide biosynthesis at modular multienzymatic templates

Gramicidin S synthetase 1 and 2 were affinity-labeled at their thiolation centers either by thioesterification with the amino acid substrate or by specific alkylation with the thiol reagent N-ethylmaleimide in combination with a substrate protection technique. The labeled proteins were digested either chemically by cyanogen bromide or by proteases. An efficient multistep high pressure liquid chromatography methodology was developed and used to isolate the active site peptide fragments of all five thiolation centers of gramicidin S synthetase in pure form. The structures of these fragments are investigated by N-terminal sequencing, mass spectrometry, and amino acid analysis. Each of the active site peptide fragments contains the consensus motif LGG(H/D)S(L/I), which is specific for thioester formation in nonribosomal peptide biosynthesis. It was demonstrated that a 4'-phosphopantetheine cofactor is attached to the central serine of the thiolation motif in each amino acid-activating module of the gramicidin S synthetase multienzyme system forming the thioester binding sites for the amino acid substrates and catalyzing the elongation process. Our data are strong support for a "multiple carrier model" of nonribosomal peptide biosynthesis at multifunctional templates, which is discussed in detail.

Detection of 4'-phosphopantetheine at the thioester binding site for L-valine of gramicidinS synthetase 2

Biosynthesis of gramicidinS in Bacillus brevis is catalysed by a multienzyme system consisting of two multifunctional proteins, gramicidinS synthetase 1 and 2 codified by the grsA and grsB genes, respectively. GramicidinS synthetase 2 shows a modular architecture of four amino acid-activating domains each containing a thioester binding motif LGG H/D S L/I highly conserved in its C-terminal region, as demonstrated by sequence analysis of the grsB gene [W. Schlumbohm et al. (1991) J. Biol. Chem. 266, 23135-23141]. This multienzyme was specifically labeled at the thioester binding site of L-valine with [3H]N-ethylmaleimide using a substrate protection technique. After enzymatic digestion a labeled active site peptide was isolated in pure form by multistep methodology. This fragment was identified by gas-phase sequencing as the active site peptide of the thiotemplate site for L-Val by comparison with the grsB gene sequence. By mass spectrometry in combination with amino acid analysis it was demonstrated that a 4'-phosphopantetheine carrier was attached to the active serine in this motif. Our results give evidence that multiple peripheral 4'-phosphopantetheine carriers are involved in the formation of gramicidinS in contrast to a central carrier arm as assumed in the original version of the thiotemplate mechanism. A 'Multiple Carrier Model' of nonribosomal peptide biosynthesis is proposed.

Characterization of the pyoverdines of Azotobacter vinelandii ATCC 12837 with regard to heterogeneity

Azotobacter vinelandii strain ATCC 12837 produces peptide siderophores of the general class known as pyoverdines. In the past, it was assumed that a single well-defined pyoverdine was produced by each parent microorganism. However, there are a number of reports of incompletely characterized pyoverdines that demonstrate heterogeneity in pyoverdine preparations obtained from a single organism, but the nature of this phenomena has not been explained. This study shows that A. vinelandii does indeed produce more than one pyoverdine and that these compounds differ in their peptide components. The metabolism of these siderophores suggests that only one of them is a true siderophore while the others are metabolic byproducts. It was demonstrated that this phenomenon is likely due to intrinsic limitations of the synthetase complex involved in the biosynthesis of these compounds. Characterization of two of the major pyoverdines produced demonstrated that they are novel compounds, although they belonged to the Azotobacter-type family of pyoverdines.

Nonribosomal biosynthesis of peptide antibiotics

Peptide antibiotics are known to contain non-protein amino acids, D-amino acids, hydroxy acids, and other unusual constituents. In addition they may be modified by N-methylation and cyclization reactions. Their biosynthetic origin has been connected in many cases to an enzymatic system referred to as the 'thiotemplate multienzymic mechanism'. This mechanism includes the activation of the constituent residues as adenylates on the enzymic template, the acylation of specific template thiol groups, epimerization or N-methylation at this thioester stage, and polymerization in the sequence directed by the multienzymic structure with the aid of 4'-phosphopantetheine as a cofactor, including possible cyclization or terminal modification reactions. The reaction sequences leading to gramicidin S, tyrocidine, cyclosporine, bacitracin, polymyxin, actinomycin, enniatin, beauvericin, delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine and linear gramicidin are discussed. The structures of the multienzymes, their genetic organization, the biological functions of these peptides and results on related systems are discussed.

Peptide antibiotics, beta-lactams, and related compounds

In the field of natural peptides, beta-lactams, and related compounds, recent exciting developments are discussed. The increasing interest in this class of bioactive amino-acid derived structures has been attributed to the use of new directed screens (enzyme inhibition assays, beta-lactam detection, immunomodulator studies), new and improved applications (antibiotic, transplantation, and cancer chemotherapy), and advances in functional studies (DNA binding peptides, nucleotide complexones, cell wall and protein processing inhibitors). Peptides offer unique access to modifications and analog production by in vivo (directed biosynthesis) and in vitro procedures (enzymatic synthesis) due to their general linear precursors permitting point replacements. Of special interest are recent developments in the genetics of these compounds (cyclic peptides and beta-lactams), which will find applications in production methods in the near future.