Utility of epimerization domains for the redesign of nonribosomal peptide synthetases

Many pharmacologically important agents are assembled on multimodular nonribosomal peptide synthetases (NRPSs) whose modules comprise a set of core domains with all essential catalytic functions necessary for the incorporation and modification of one building block. Very often, d-amino acids are found in such products which, with few exceptions, are generated by the action of NRPS integrated epimerization (E) domains that alter the stereochemistry of the corresponding peptidyl carrier protein (PCP) bound l-intermediate. In this study we present a quantitative investigation of substrate specificity of four different E domains (two 'peptidyl-' and two 'aminoacyl-'E domains) derived from different NRPSs towards PCP bound peptides. The respective PCP-E bidomain apo-proteins (TycB(3)-, FenD(2)-, TycA- and GrsA-PCP-E) were primed with various peptidyl-CoA precursors by utilizing the promiscuous phosphopantetheinyl transferase Sfp. PCP bound peptidyl-S-Ppant epimerization products were chemically cleaved and analyzed for their l/d-ratios by LCMS. We were able to show that all four E domains tolerate a broad variety of peptidyl-S-Ppant-substrates as evaluated by k(obs) values and final l/d-product equilibria determined for each reaction. The two C-terminal amino acids of the substrate seem to be recognized by 'peptidyl-'E domains. Interestingly, the 'aminoacyl-'E domains GrsA- and TycA-E were also able to convert the elongated intermediates. All four E domains accepted an N-methylated precursor as well and epimerized this substrate with high efficiency. Finally, we could demonstrate that the condensation (C) domain of TycB(1) is also able to process peptidyl substrates transferred by TycA. In conclusion, these findings are of great impact on future engineering attempts.     

Control of directionality in nonribosomal peptide synthesis: role of the condensation domain in preventing misinitiation and timing of epimerization

Product assembly by nonribosomal peptide synthetases (NRPS) is initiated by starter modules that comprise an adenylation (A) and a peptidyl carrier protein (PCP) domain. Elongation modules of NRPS have in addition a condensation (C) domain that is located upstream of the A domain. They cannot initiate peptide bond formation. To understand the role of domain arrangements and the influence of the domains present upstream of the A domains of the elongation modules of TycB on the initiation and epimerization activities, we constructed a set of proteins derived from the tyrocidine synthetases of Bacillus brevis, which represent several N-terminal truncations of TycB and the first module of TycC. The latter was fused with the thioesterase domain (Te) to give TycC(1)-CAT-Te and to ensure product turnover. TycB(2)(-)(3)-AT.CATE and TycB(3)-ATE, lacking an N-terminal C domain, were capable of initiating peptide synthesis and epimerizing. In contrast, the corresponding constructs with a cognate N-terminal C domain, TycB(2)(-)(3)-T.CATE and TycB(3)-CATE, were strongly reduced in initiation and epimerization. Evidence is also provided that this reduction is due to substrate binding in an enantioselective binding pocket at the acceptor position of the C domains. By using TycB(2)(-)(3)-AT.CATE and TycB(3)-ATE, we were able to turn an elongation module into an initiation module, and to establish an in-trans system for the formation of new di- and tripeptides with recombinant NRPS modules. We also show that epimerization domains of elongation modules can in principle epimerize both aminoacyl-S-Ppant (TycB(3)-ATE) and peptidyl-S-Ppant (TycB(2)(-)(3)-AT.CATE) substrates, although the efficiency for epimerizing the noncognate aminoacyl-S-Ppant substrates appears to be lowered.     

Thioesterase portability and peptidyl carrier protein swapping in yersiniabactin synthetase from Yersinia pestis

Multimodular enzymes, including polyketide synthases (PKSs), nonribosomal peptide synthetases (NRPSs), and mixed PKS/NRPS systems, contain functional domains with similar functions. Domain swapping and module fusion are potential powerful strategies for creating hybrid enzymes to synthesize modified natural products. To explore these strategies, yersiniabactin (Ybt) synthetase containing two subunits, HMWP2 [two NRPS modules (N-terminus-ArCP-Cy1-A-PCP1 and Cy2-PCP2-C-terminus)] and HMWP1 [one PKS (N-terminus-KS-AT-MT1-KR-ACP) one NRPS module (Cy3-MT2-PCP3-TE-C-terminus)], was used as a model system to study peptidyl carrier protein (PCP) domain swapping, thioesterase (TE) portability, and module-module fusion. The PCP1 domain of the N-terminal NRPS module of HMWP2 was swapped with either PCP2 or PCP3. The fusion proteins were 3-8-fold less active than the wild-type protein. The swapping of PCP2 of HMWP2 abolished the heterocyclization activity of the Cy2 domain while retaining its condensation function. When the two PCPs of HMWP2 were swapped by PCP3TE, it created two active fusion proteins: one or two NRPS modules fused to the TE domain. The internal TE domain of the two fusion proteins catalyzed the hydrolysis of enzyme-bound intermediates HPT-S-PCP3 to form HPT-COOH and HPTT-S-PCP3 to form HPTT-COOH. The TE activity was eliminated by the S2980A point mutation at its active site. Therefore, the three PCPs of the Ybt synthetase were swappable, and its lone TE domain was portable. The reasons for the observed low activities of the fusion proteins and lessons for protein engineering in generating novel modular enzymes were discussed.     

肽基载体蛋白结构功能的研究进展

肽基载体蛋白(peptidyl carrier protein,PCP)是非核糖体肽合成酶(non-ribosomal peptide synthetase,NRPS)的核心结构域。根据NRPS的装配机制,每个模块都至少包含一个PCP,PCP对于非核糖体肽合成中氨基酸残基及多肽在不同催化结构域中的传递起着重要作用,并为氨基酸残基和多肽向模块内其他修饰酶的转移提供一个平台。本文主要对PCP的结构功能、与其他催化结构域的相互作用及重组模块活性降低的问题等方面进行了综述,期望为重组NRPS模块的构建提供理论依据。     

Chain initiation in the leinamycin-producing hybrid nonribosomal peptide/polyketide synthetase from Streptomyces atroolivaceus S-140. Discrete, monofunctional adenylation enzyme and peptidyl carrier protein that directly load D-alanine

Nonribosomal peptide natural products are biosynthesized from amino acid precursors by nonribosomal peptide synthetases (NRPSs), which are organized into modules. For a typical NRPS initiation module, an adenylation (A) domain activates an amino acid and installs it onto a peptidyl carrier protein (PCP) domain as a thioester; an elongation module, which has a condensation (C) domain located between every consecutive pair of A and PCP domains, catalyzes the formation of the peptide bond between the upstream aminoacyl/peptidyl-S-PCP and the free amino group of the downstream aminoacyl-S-PCP. D-amino acid constituents in peptide natural products usually arise from the L-enantiomers through the action of integral epimerization (E) domains of an NRPS. The biosynthetic gene cluster for leinamycin, a hybrid nonribosomal peptide/polyketide containing a D-alanine moiety, does not encode a typical NRPS initiation module with the expected A-PCP-E domains; instead, it has only an A protein (LnmQ) and a PCP (LnmP), both of which are encoded by separate genes. Here we show the results of biochemical experiments as follows: (i) we demonstrate that LnmQ directly activates D-alanine as D-alaninyl-AMP and installs it onto LnmP to generate a D-alaninyl-S-PCP intermediate; (ii) we confirm that aminoacylation of LnmP by LnmQ in trans is the result of specific communication between the separate A and PCP proteins; and (iii) we reveal that leinamycin production can be improved by supplementation of exogenous D-alanine in the fermentation broth of Streptomyces atroolivaceous S-140. These findings unveil an unprecedented NRPS initiation module structure that is characterized by a discrete D-alanine-specific A protein and a PCP.     

Solution structure of PCP, a prototype for the peptidyl carrier domains of modular peptide synthetases

BACKGROUND: Nonribosomal peptide synthetases (NRPSs) are large modular enzymes responsible for the synthesis of a variety of microbial bioactive peptides. They consist of modules that each recognise and incorporate one specific amino acid into the peptide product. A module comprises several domains, which carry out the individual reaction steps. After activation by the adenylation domain, the amino acid substrate is covalently tethered to a 4'-phosphopantetheinyl cofactor of a peptidyl carrier domain (PCP) that passes the substrate to the reaction centres of the consecutive domains. RESULTS: The solution structure of PCP, a distinct peptidyl carrier protein derived from the equivalent domain of an NRPS, was solved using NMR techniques. PCP is a distorted four-helix bundle with an extended loop between the first two helices. Its overall fold resembles the topology of acyl carrier proteins (ACPs) from Escherichia coli fatty acid synthase and actinorhodin polyketide synthase from Streptomyces coelicolor; however, the surface polarity and the length and relative alignment of the helices are different. The conserved serine, which is the cofactor-binding site, has the same location as in the ACPs and is situated within a stretch of seven flexible residues. CONCLUSIONS: The structure of PCP reflects its character as a protein domain. The fold is well defined between residues 8 and 82 and the structural core of the PCP domain can now be defined as a region spanning 37 amino acids in both directions from the conserved serine. The flexibility of the post-translationally modified site might have implications for interactions with the cooperating proteins or NRPS domains.     

Recognition of hybrid peptidyl carrier proteins/acyl carrier proteins in nonribosomal peptide synthetase modules by the 4'-phosphopantetheinyl transferases AcpS and Sfp

The acyl carrier proteins (ACPs) of fatty acid synthase and polyketide synthase as well as peptidyl carrier proteins (PCPs) of nonribosomal peptide synthetases are modified by 4'-phosphopantetheinyl transferases from inactive apo-enzymes to their active holo forms by transferring the 4'-phosphopantetheinyl moiety of coenzyme A to a conserved serine residue of the carrier protein. 4'-Phosphopantetheinyl transferases have been classified into two types; the AcpS type accepts ACPs of fatty acid synthase and some ACPs of type II polyketide synthase as substrates, whereas the Sfp type exhibits an extraordinarily broad substrate specificity. Based on the previously published co-crystal structure of Bacillus subtilis AcpS and ACP that provided detailed information about the interacting residues of the two proteins, we designed a novel hybrid PCP by replacing the Bacillus brevis TycC3-PCP helix 2 with the corresponding helix of B. subtilis ACP that contains the interacting residues. This was performed for the PCP domain as a single protein as well as for the TycA-PCP domain within the nonribosomal peptide synthetase module TycA from B. brevis. Both resulting proteins, designated hybrid PCP (hPCP) and hybrid TycA (hTycA), were modified in vivo during heterologous expression in Escherichia coli (hPCP, 51%; hTycA, 75%) and in vitro with AcpS as well as Sfp to 100%. The designated hTycA module contains two other domains: an adenylation domain (activating phenylalanine to Phe-AMP and afterward transferring the Phe to the PCP domain) and an epimerization domain (converting the PCP-bound l-Phe to d-Phe). We show here that the modified PCP domain of hTycA communicates with the adenylation domain and that the co-factor of holo-hPCP is loaded with Phe. However, communication between the hybrid PCP and the epimerization domain seems to be disabled. Nevertheless, hTycA is recognized by the next proline-activating elongation module TycB1 in vitro, and the dipeptide is formed and released as diketopiperazine.     

Cu-free cycloaddition for identifying catalytic active adenylation domains of nonribosomal peptide synthetases by phage display

To engineer the substrate specificities of nonribosomal peptide synthetases (NRPS), we developed a method to display NRPS modules on M13 phages and select catalytically active adenylation (A) domains that would load azide functionalized substrate analogs to the neighboring peptidyl carrier protein (PCP) domains. Biotin conjugated difluorinated cyclooctyne was used for copper free cycloaddition with an azide substituted substrate attached to PCP. Biotin-labeled phages were selected by binding to streptavidin.     

Timing of epimerization and condensation reactions in nonribosomal peptide assembly lines: kinetic analysis of phenylalanine activating elongation modules of tyrocidine synthetase B

The cyclic decapeptide antibiotic tyrocidine has D-Phe residues at positions 1 and 4, produced during peptide chain growth from L-Phe residues by 50 kDa epimerase (E) domains embedded, respectively, in the initiation module (TycA) and the TycB3 module of the three-subunit (TycABC), 10-module nonribosomal peptide synthetase. While the initiation module clearly epimerizes the aminoacyl thioester Phe1-S-TycA intermediate, the timing of epimerization versus peptide bond condensation at internal E domains has been less well characterized in nonribosomal peptide synthetases. In this study, we use rapid quench techniques to evaluate a three-domain (ATE) and a four-domain version (CATE) of the TycB3 module and a six-domain fragment (ATCATE) of the TycB2(-3) bimodule to measure the ability of the E domain in the TycB3 module to epimerize the aminoacyl thioester Phe-S-TycB3 and the dipeptidyl-S-enzyme (L-Phe-L-Phe-S-TycB3 if L-Phe-D-Phe-S-TycB3). The chiralities of the Phe-S-enzyme and Phe-Phe-S-enzyme species over time were determined by hydrolysis and chiral TLC separations, allowing for the clear conclusion that epimerization in the internal TycB3 module occurs preferentially on the peptidyl-S-enzyme rather than the aminoacyl-S-enzyme, by a factor of about 3000/1. In turn, this imposes constraints on the chiral selectivity of the condensation (C) domains immediately upstream and downstream of E domains. The stereoselectivity of the upstream C domain was shown to be L-selective at both donor and acceptor sites ((L)C(L)) by site-directed mutagenesis studies of an E domain active site residue and using the small-molecule surrogate D-Phe-Pro-L-Phe-N-acetylcysteamine thioester (D-Phe-Pro-L-Phe-SNAC) and D-Phe-Pro-D-Phe-SNAC as donor probes.     

The structure of VibH represents nonribosomal peptide synthetase condensation,cyclization and epimerization domains

Nonribosomal peptide synthetases (NRPSs) are large, multidomain enzymes that biosynthesize medically important natural products. We report the crystal structure of the free-standing NRPS condensation (C) domain VibH, which catalyzes amide bond formation in the synthesis of vibriobactin, a Vibrio cholerae siderophore. Despite low sequence identity, NRPS condensation enzymes are structurally related to chloramphenicol acetyltransferase (CAT) and dihydrolipoamide acyltransferases. However, although the latter enzymes are homotrimers, VibH is a monomeric pseudodimer. The VibH structure is representative of both NRPS condensation and epimerization domains, as well as the condensation-variant cyclization domains, which are all expected to be monomers. Surprisingly, despite favorable positioning in the active site, a universally conserved histidine important in CAT and in other C domains is not critical for general base catalysis in VibH.     

Analysis of the linker region joining the adenylation and carrier protein domains of the modular nonribosomal peptide synthetases

Nonribosomal peptide synthetases (NRPSs) are multimodular proteins capable of producing important peptide natural products. Using an assembly line process, the amino acid substrate and peptide intermediates are passed between the active sites of different catalytic domains of the NRPS while bound covalently to a peptidyl carrier protein (PCP) domain. Examination of the linker sequences that join the NRPS adenylation and PCP domains identified several conserved proline residues that are not found in standalone adenylation domains. We examined the roles of these proline residues and neighboring conserved sequences through mutagenesis and biochemical analysis of the reaction catalyzed by the adenylation domain and the fully reconstituted NRPS pathway. In particular, we identified a conserved LPxP motif at the start of the adenylation‐PCP linker. The LPxP motif interacts with a region on the adenylation domain to stabilize a critical catalytic lysine residue belonging to the A10 motif that immediately precedes the linker. Further, this interaction with the C‐terminal subdomain of the adenylation domain may coordinate movement of the PCP with the conformational change of the adenylation domain. Through this work, we extend the conserved A10 motif of the adenylation domain and identify residues that enable proper adenylation domain function. Proteins 2014; 82:2691–2702. © 2014 Wiley Periodicals, Inc.     

Mutational analysis of the epimerization domain in the initiation module PheATE of gramicidin S synthetase

The epimerase (E) domain of the three-domain (ATE) initiation module of Bacillus brevis gramicidin S synthetase equilibrates the Calpha configuration of the phenylalanyl moiety presented as Phe-S-4'-phosphopantetheine-modified (Ppant) acyl enzyme. Mutants at 22 residues of this E domain that are conserved across the approximately 450 residue E domains of nonribosomal peptide synthetases were constructed, and the PheATE derivatives expressed in Escherichia coli as C-terminal His tag fusions and then purified and assayed for three activities: (1) the L-Phe Calpha-[(3)H] exchange to solvent, (2) the rate of approach to D-Phe/L-Phe-S-Ppant acyl enzyme equilibrium from either L- or D-Phe, and (3) the rate of Phe-Pro dipeptidyl-S-Ppant enzyme formation with the downstream ProCAT module. We found that for wild-type PheATE epimerization is much faster than subsequent condensation, leading to a 1.9:1 ratio of D-Phe-S-Ppant/L-Phe-S-Ppant acyl enzyme. Only D-Phe is then transferred to yield D-Phe-L-Pro-S-Ppant ProCAT acyl enzyme. Among the mutants generated, three PheATE constructs, H753A, D757S, and Y976A, showed no detectable Calpha-(3)H washout, while E892A and R896A were among a larger set partially impaired. All these mutants were dramatically impaired in approach to D-Phe/L-Phe-S-Ppant equilibrium from either D- or L-Phe, while another construct, D767S, was asymmetrically impaired only for D-to-L-Phe direction. In the D-Phe-L-Pro dipeptidyl-S-Ppant condensation assay, the H753A and E892A forms of PheATE were only slightly active from L-Phe but unimpaired from D-Phe; N975A epimerizes faster than Y976A from L-Phe. When the chirality of the Phe-Pro-diketopiperazine released product was analyzed the D,L/L,L ratio from wild-type PheATE and ProCAT was 98:2. From E892A and N975A it was comparably 95:5 and 92:8, but H753A and Y976A yielded 56% of the L,L-product, reflecting a gain of function to transfer L-Phe. The 98:2 preference of wild-type PheATE for D-Phe transfer reflects the kinetically controlled stereopreference of the condensation (C) domain of ProCAT for the D-Phe-S-Ppant donor substrate. It may be that other NRPS C domains immediately downstream of E domains will likewise be D-selective.     

A beta-lysine adenylating enzyme and a beta-lysine binding protein involved in poly beta-lysine chain assembly in nourseothricin synthesis in Streptomyces noursei.

Nourseothricins (syn. Streptothricins), a group of nucleoside peptides produced by several streptomycete strains, contain a poly beta-lysine chain of variable length attached in amide linkage to the amino sugar moiety gulosamine of the nucleoside portion. We show that the nourseothricin-producing Streptomyces noursei contains an enzyme (NpsA) of an apparent M(r) 56,000 that specifically activates beta-lysine by adenylation but does not bind to it as a thioester. Cloning and sequencing of npsA from S. noursei including its flanking DNA regions revealed that it is closely linked to the nourseothricin resistance gene nat1 and some other genes on the chromosome possibly involved in nourseothricin biosynthesis. The deduced amino-acid sequence revealed that NpsA is a stand-alone adenylation domain with similarity to the adenylation domains of nonribosomal peptide synthetases (NRPS). Further analysis revealed that S. noursei contains a beta-lysine binding enzyme (NpsB) of about M(r) 64,100 which can be loaded by NpsA with beta-lysine as a thioester. Analysis of the deduced amino-acid sequence from the gene (npsB) of NpsB showed that it consists of two domains. The N-terminal domain of approximately 100 amino-acid residues has high similarity to PCP domains of NRPSs whereas the 450-amino-acid C-terminal domain has a high similarity to epimerization (E)-domains of NRPSs. Remarkably, in this E-domain the conserved H-H-motif is changed to H-Q, which suggests that either the domain is nonfunctional or has a specialized function. The presence of one single adenylating beta-lysine activating enzyme in nourseothricin-producing streptomycete and a separate binding protein suggests an iteratively operating NRPS-module catalyses synthesis of the poly beta-lysine chain.     

Structure of PA1221, a nonribosomal peptide synthetase containing adenylation and peptidyl carrier protein domains

Many bacteria use large modular enzymes for the synthesis of polyketide and peptide natural products. These multidomain enzymes contain integrated carrier domains that deliver bound substrates to multiple catalytic domains, requiring coordination of these chemical steps. Nonribosomal peptide synthetases (NRPSs) load amino acids onto carrier domains through the activity of an upstream adenylation domain. Our lab recently determined the structure of an engineered two-domain NRPS containing fused adenylation and carrier domains. This structure adopted a domain-swapped dimer that illustrated the interface between these two domains. To continue our investigation, we now examine PA1221, a natural two-domain protein from Pseudomonas aeruginosa. We have determined the amino acid specificity of this new enzyme and used domain specific mutations to demonstrate that loading the downstream carrier domain within a single protein molecule occurs more quickly than loading of a nonfused carrier domain intermolecularly. Finally, we have determined crystal structures of both apo- and holo-PA1221 proteins, the latter using a valine-adenosine vinylsulfonamide inhibitor that traps the adenylation domain-carrier domain interaction. The protein adopts an interface similar to that seen with the prior adenylation domain-carrier protein construct. A comparison of these structures with previous structures of multidomain NRPSs suggests that a large conformational change within the NRPS adenylation domains guides the carrier domain into the active site for thioester formation.     

The crystal structure of BlmI as a model for nonribosomal peptide synthetase peptidyl carrier proteins

Carrier proteins (CPs) play a critical role in the biosynthesis of various natural products, especially in nonribosomal peptide synthetase (NRPS) and polyketide synthase (PKS) enzymology, where the CPs are referred to as peptidyl‐carrier proteins (PCPs) or acyl‐carrier proteins (ACPs), respectively. CPs can either be a domain in large multifunctional polypeptides or standalone proteins, termed Type I and Type II, respectively. There have been many biochemical studies of the Type I PKS and NRPS CPs, and of Type II ACPs. However, recently a number of Type II PCPs have been found and biochemically characterized. In order to understand the possible interaction surfaces for combinatorial biosynthetic efforts we crystallized the first characterized and representative Type II PCP member, BlmI, from the bleomycin biosynthetic pathway from Streptomyces verticillus ATCC 15003. The structure is similar to CPs in general but most closely resembles PCPs. Comparisons with previously determined PCP structures in complex with catalytic domains reveals a common interaction surface. This surface is highly variable in charge and shape, which likely confers specificity for interactions. Previous nuclear magnetic resonance (NMR) analysis of a prototypical Type I PCP excised from the multimodular context revealed three conformational states. Comparison of the states with the structure of BlmI and other PCPs reveals that only one of the NMR states is found in other studies, suggesting the other two states may not be relevant. The state represented by the BlmI crystal structure can therefore serve as a model for both Type I and Type II PCPs. Proteins 2014; 82:1210–1218. © 2013 Wiley Periodicals, Inc.     

Mutational analysis of peptidyl carrier protein and acyl carrier protein synthase unveils residues involved in protein-protein recognition

4'-Phosphopantetheinyl transferases (PPTases) are essential for the production of fatty acids by fatty acid synthases (primary metabolism) and natural products by nonribosomal peptide synthetases and polyketide synthases (secondary metabolism). These systems contain carrier proteins (CPs) for the covalent binding of reaction intermediates during synthesis. PPTases transfer the 4'-phosphopantetheine moiety from coenzyme A (CoA) onto conserved serine residues of the apo-CPs to convert them to their functionally active holo form. In bacteria, two types of PPTases exist that are evolutionary related but differ in their substrate spectrum. Acyl carrier protein synthases (AcpSs) recognize CPs from primary metabolism, whereas Sfp- (surfactin production-) type PPTases have a preference for CPs of secondary metabolism. Previous investigations showed that a peptidyl carrier protein (PCP) of secondary metabolism can be altered to serve as substrate for AcpS. We demonstrate here that a single mutation in PCP suffices for the modification of this CP by AcpS, and we have identified by mutational analysis several other PCP residues and two AcpS residues involved in substrate discrimination by this PPTase. These altered PCPs were still capable of serving their designated function in NRPS modules, and selective use of AcpS or Sfp leads to production of two different products by a trimodular NRPS.     

Carrier protein recognition in siderophore-producing nonribosomal peptide synthetases

Nonribosomal peptide synthetases (NRPSs) use phosphopantetheine (pPant) bearing carrier proteins to chaperone activated aminoacyl and peptidyl intermediates to the various enzymes that effect peptide synthesis. Using components from siderophore NRPSs that synthesize vibriobactin, enterobactin, yersiniabactin, pyochelin, and anguibactin, we examined the nature of the interaction of such cofactor-carrier proteins with acyl-activating adenylation (A) domains. While VibE, EntE, and PchD were all able to utilize "carrier protein-free" pPant derivatives, the pattern of usage indicated diversity in the binding mechanism, and even the best substrates were down at least 3 log units relative to the native cofactor-carrier protein. When tested with four noncognate carrier proteins, EntE and VibE differed both in the range of substrate utilization efficiency and in the distribution of the efficiencies across this range. Correlating sequence alignments to kinetic efficiency allowed for the construction of eight point mutants of VibE's worst substrate, HMWP2 ArCP, to the corresponding residue in its native VibB. Mutants S49D and H66E combined to increase activity 6.2-fold and had similar enhancing effects on the downstream condensation domain VibH, indicating that the two NRPS enzymes share carrier protein recognition determinants. Similar mutations of HMWP2 ArCP toward EntB had little effect on EntE, suggesting that the position of recognition determinants varies across NRPS systems.     

The tyrocidine biosynthesis operon of Bacillus brevis: complete nucleotide sequence and biochemical characterization of functional internal adenylation domains.

The cyclic decapeptide antibiotic tyrocidine is produced by Bacillus brevis ATCC 8185 on an enzyme complex comprising three peptide synthetases, TycA, TycB, and TycC (tyrocidine synthetases 1, 2, and 3), via the nonribosomal pathway. However, previous molecular characterization of the tyrocidine synthetase-encoding operon was restricted to tycA, the gene that encodes the first one-module-bearing peptide synthetase. Here, we report the cloning and sequencing of the entire tyrocidine biosynthesis operon (39.5 kb) containing the tycA, tycB, and tycC genes. As deduced from the sequence data, TycB (404,562 Da) consists of three modules, including an epimerization domain, whereas TycC (723,577 Da) is composed of six modules and harbors a putative thioesterase domain at its C-terminal end. Each module incorporates one amino acid into the peptide product and can be further subdivided into domains responsible for substrate adenylation, thiolation, condensation, and epimerization (optional). We defined, cloned, and expressed in Escherichia coli five internal adenylation domains of TycB and TycC. Soluble His6-tagged proteins, ranging from 536 to 559 amino acids, were affinity purified and found to be active by amino acid-dependent ATP-PPi exchange assay. The detected amino acid specificities of the investigated domains manifested the colinear arrangement of the peptide product with the respective module in the corresponding peptide synthetases and explain the production of the four known naturally occurring tyrocidine variants. The Km values of the investigated adenylation domains for their amino acid substrates were found to be comparable to those published for undissected wild-type enzymes. These findings strongly support the functional integrities of single domains within multifunctional peptide synthetases. Directly downstream of the 3' end of the tycC gene, and probably transcribed in the tyrocidine operon, two tandem ABC transporters, which may be involved in conferring resistance against tyrocidine, and a putative thioesterase were found.     

The Modular Organization of Domain Structures: Insights into Protein–Protein Binding

Domains are the building blocks of proteins and play a crucial role in protein–protein interactions. Here, we propose a new approach for the analysis and prediction of domain–domain interfaces. Our method, which relies on the representation of domains as residue-interacting networks, finds an optimal decomposition of domain structures into modules. The resulting modules comprise highly cooperative residues, which exhibit few connections with other modules. We found that non-overlapping binding sites in a domain, involved in different domain–domain interactions, are generally contained in different modules. This observation indicates that our modular decomposition is able to separate protein domains into regions with specialized functions. Our results show that modules with high modularity values identify binding site regions, demonstrating the predictive character of modularity. Furthermore, the combination of modularity with other characteristics, such as sequence conservation or surface patches, was found to improve our predictions. In an attempt to give a physical interpretation to the modular architecture of domains, we analyzed in detail six examples of protein domains with available experimental binding data. The modular configuration of the TEM1-β-lactamase binding site illustrates the energetic independence of hotspots located in different modules and the cooperativity of those sited within the same modules. The energetic and structural cooperativity between intramodular residues is also clearly shown in the example of the chymotrypsin inhibitor, where non–binding site residues have a synergistic effect on binding. Interestingly, the binding site of the T cell receptor β chain variable domain 2.1 is contained in one module, which includes structurally distant hot regions displaying positive cooperativity. These findings support the idea that modules possess certain functional and energetic independence. A modular organization of binding sites confers robustness and flexibility to the performance of the functional activity, and facilitates the evolution of protein interactions.