Purification, crystallization and preliminary X-ray analysis of Mycobacterium tuberculosisfolylpolyglutamate synthase (MtbFPGS)

The gene encoding Mycobacterium tuberculosis FPGS (MtbFPGS; Rv2447c) has been cloned and the protein (51 kDa) expressed in Escherichia coli. The purified protein was crystallized either by the batch method in the presence of adenosine diphosphate (ADP) and CoCl2 or by vapour diffusion in the presence of ADP, dihydrofolate and CaCl2. X-ray diffraction data to approximately 2.0 and 2.6 A resolution were collected at the Stanford Synchrotron Radiation Laboratory (SSRL) for crystals grown under the respective conditions. Both crystals belong to the cubic space group P2(1)3, with a unit-cell parameter of 112.6 and 111.8 A, respectively. Structure determination is proceeding.

Formylation Domain: An Essential Modifying Enzyme for the Nonribosomal Biosynthesis of Linear Gramicidin

Formylation is an important part of ribosomal peptide synthesis of prokaryotes. In nonribosomal peptide synthesis, however, N-formylation is rather unusual and therefore so far unexplored. In this work, the first module of the linear gramicidin nonribosomal peptide synthetase, LgrA1, consisting of a hypothetical formylation domain, an adenylation, and a peptidyl carrier protein domain was tested for formyltransferase activity in vitro. We demonstrate here that the putative formylation domain does indeed transfer the formyl group of formyltetrahydrofolate (fH4F) onto the first amino acid valine using both cofactors N10- and N5-fH4F, respectively. Most important, the necessity of the formylated starter unit formyl-valine for the initiation of the gramicidin biosynthesis was tested by elongation assays with the bimodular system from LgrA. By omitting the formyl group donor, no condensation product of valine with the subsequent building block glycine was detected, whereas the dipeptide formyl-valyl-glycine was found when assayed in the presence of either formyl donor. The proven formylation activity of the first domain of LgrA represents a novel tailoring enzyme in nonribosomal peptide synthesis.

Nucleotide complexes of Escherichia coli phosphoribosylaminoimidazole succinocarboxamide synthetase

Phosphoribosylaminoimidazole-succinocarboxamide synthetase (SAICAR synthetase) converts 4-carboxy-5-aminoimidazole ribonucleotide (CAIR) to 4-(N-succinylcarboxamide)-5-aminoimidazole ribonucleotide (SAICAR). The enzyme is a target of natural products that impair cell growth. Reported here are the crystal structures of the ADP and the ADP.CAIR complexes of SAICAR synthetase from Escherichia coli, the latter being the first instance of a CAIR-ligated SAICAR synthetase. ADP and CAIR bind to the active site in association with three Mg(2+), two of which coordinate the same oxygen atom of the 4-carboxyl group of CAIR; whereas, the third coordinates the alpha- and beta-phosphoryl groups of ADP. The ADP.CAIR complex is the basis for a transition state model of a phosphoryl transfer reaction involving CAIR and ATP, but also supports an alternative chemical pathway in which the nucleophilic attack of l-aspartate precedes the phosphoryl transfer reaction. The polypeptide fold for residues 204-221 of the E. coli structure differs significantly from those of the ligand-free SAICAR synthetase from Thermatoga maritima and the adenine nucleotide complexes of the synthetase from Saccharomyces cerevisiae. Conformational differences between the E. coli, T. maritima, and yeast synthetases suggest the possibility of selective inhibition of de novo purine nucleotide biosynthesis in microbial organisms.

Crystal structure of the pantothenate synthetase from Mycobacterium tuberculosis, snapshots of the enzyme in action

Pantothenate synthetase (PS) from Mycobacterium tuberculosis represents a potential target for antituberculosis drugs. PS catalyzes the ATP-dependent condensation of pantoate and beta-alanine to form pantothenate. Previously, we determined the crystal structure of PS from M. tuberculosis and its complexes with AMPCPP, pantoate, and pantoyl adenylate. Here, we describe the crystal structure of this enzyme complexed with AMP and its last substrate, beta-alanine, and show that the phosphate group of AMP serves as an anchor for the binding of beta-alanine. This structure confirms that binding of beta-alanine in the active site cavity can occur only after formation of the pantoyl adenylate intermediate. A new crystal form was also obtained; it displays the flexible wall of the active site cavity in a conformation incapable of binding pantoate. Soaking of this crystal form with ATP and pantoate gives a fully occupied complex of PS with ATP. Crystal structures of these complexes with substrates, the reaction intermediate, and the reaction product AMP provide a step-by-step view of the PS-catalyzed reaction. A detailed reaction mechanism and its implications for inhibitor design are discussed.

Activity screening of carrier domains within nonribosomal peptide synthetases using complex substrate mixtures and large molecule mass spectrometry

For screening a pool of potential substrates that load carrier domains found in nonribosomal peptide synthetases, large molecule mass spectrometry is shown to be a new, unbiased assay. Combining the high resolving power of Fourier transform mass spectrometry with the ability of adenylation domains to select their own substrates, the mass change that takes place upon formation of a covalent intermediate thus identifies the substrate. This assay has an advantage over traditional radiochemical assays in that many substrates, the substrate pool, can be screened simultaneously. Using proteins on the nikkomycin, clorobiocin, coumermycin A1, yersiniabactin, pyochelin, and enterobactin biosynthetic pathways as proof of principle, preferred substrates are readily identified from substrate pools. Furthermore, this assay can be used to provide insight into the timing of tailoring events of biosynthetic pathways as demonstrated using the bromination reaction found on the jamaicamide biosynthetic pathway. Finally, this assay can provide insight into the role and function of orphan gene clusters for which the encoded natural product is unknown. This is demonstrated by identifying the substrates for two NRPS modules from the pksN and pksJ genes that are found on an orphan NRPS/PKS hybrid cluster from Bacillus subtilis. This new assay format is especially timely for activity screening in an era when new types of thiotemplate assembly lines that defy classification are being discovered at an accelerating rate.

Mutation of Gly51 to serine in the P-loop ofLactobacillus caseifolylpolyglutamate synthetase abolishes activity by altering the conformation of two adjacent loops

Based upon the three-dimensional structure of Lactobacillus casei folylpolyglutamate synthetase (FPGS), site-directed mutagenesis studies were performed on three residues associated with the ATPase site: Gly51, Ser52 and Ser73. Gly51 and Ser52 are at the end of the P-loop, which is involved in triphosphate binding. A G51S mutant enzyme and a G51S/S52T double-mutant enzyme were made in order to alter the FPGS P-loop to more closely resemble the sequences found in other ATPase and GTPase enzymes. Ser73 is on a neighboring loop (the Omega-loop) and precedes a proline residue found to be in a cis conformation. The carbonyl O atom of Ser73 is one of the protein ligands for the essential Mg(2+) ion involved in ATP binding and hydrolysis and the Omega-loop is involved in binding the folate substrate 5,10-methylenetetrahydrofolate. The serine residue was mutated to alanine and this is the only one of the three mutants which retains some FPGS activity. The structures of the G51S, G51S/S52T and S73A mutant proteins have been solved to high resolution, along with the structure of the apo wild-type FPGS. The P-loop in both the G51S and G51S/S52T mutant proteins remains unaltered, yet both structures show a large conformational rearrangement of the Omega-loop in which a cis-Pro residue has switched conformation to a trans-peptide. The structure of the Omega-loop is severely disrupted and as a consequence structural rearrangements are observed in the peptide linker joining the two domains of the enzyme. Magnesium binding in the active site is also disrupted by the presence of the serine side chain at position 51 and by the repositioning of the carbonyl O atom of Ser73 and a water molecule is bound in place of the Mg(2+) ion. The S73A mutant protein retains the cis-Pro configuration in the Omega-loop and the Mg(2+) site remains intact. The cis-Pro is also observed in the structure of the substrate-free form of FPGS (apoFPGS), maintained in the absence of Mg(2+) by a hydrogen-bonding network involving water molecules in the active site. It is only in the complete absence of water or Mg(2+) in the binding site that the cis-Pro switches to the trans conformation.

Conformational switches modulate protein interactions in peptide antibiotic synthetases

Protein dynamics plays an important role in protein function. Many functionally important motions occur on the microsecond and low millisecond time scale and can be characterized by nuclear magnetic resonance relaxation experiments. We describe the different states of a peptidyl carrier protein (PCP) that play a crucial role in its function as a peptide shuttle in the nonribosomal peptide synthetases of the tyrocidine A system. Both apo-PCP (without the bound 4'-phosphopantetheine cofactor) and holo-PCP exist in two different stable conformations. We show that one of the apo conformations and one of the holo conformations are identical, whereas the two remaining conformations are only detectable by nuclear magnetic resonance spectroscopy in either the apo or holo form. We further demonstrate that this conformational diversity is an essential prerequisite for the directed movement of the 4'-PP cofactor and its interaction with externally acting proteins such as thioesterases and 4'-PP transferase.

Solution structure of Asl1650, an acyl carrier protein from Anabaena sp. PCC 7120 with a variant phosphopantetheinylation-site sequence

Cyanobacteria, such as Anabaena, produce a variety of bioactive natural products via polyketide synthases (PKS), nonribosomal peptide synthetases (NRPS), and hybrid peptide/polyketide pathways. The protein Asl1650, which is a member of the acyl carrier protein family from the cyanobacterium Anabaena sp. PCC 7120, is encoded in a region of the Anabaena genome that is rich in PKS and NRPS genes. To gain new insight into the physiological role of acyl carriers in Anabaena, the solution structure of Asl1650 has been solved by NMR spectroscopy. The protein adopts a twisted antiparallel four-helix bundle fold, with a variant phosphopantetheine-attachment motif positioned at the start of the second helix. Structure comparisons with proteins from other organisms suggest a likely physiological function as a discrete peptidyl carrier protein.

Priming type II polyketide synthases via a type II nonribosomal peptide synthetase mechanism

Benzoic acid priming of the enterocin and actinorhodin type II polyketide synthase complexes was accomplished in vitro via an unprecedented type II nonribosomal peptide synthetase-like mechanism involving the benzoate:acyl carrier protein (ACP) ligase EncN and the ACP EncC. The transfer of the aryl acid to the ACP is ATP-dependent, yet coenzyme A-independent, as characterized with radiolabeled substrates and protein mass spectrometry. Subsequent transport of the ACP-bound aryl group to the native enterocin and the aberrant actinorhodin ketosynthase chain length factor heterodimers was further demonstrated, thereby demonstrating the potential of this biocatalyst for engineering diverse aryl-primed aromatic polyketide agents.

Structure of SAICAR synthase from Thermotoga maritima at 2.2 angstroms reveals an unusual covalent dimer

The crystal structure of phophoribosylaminoimidazole-succinocarboxamide or SAICAR synthase from T. maritima at 2.2 Å revealed an unusual covalent dimer.

As a part of a structural genomics program, the 2.2 Å resolution crystal structure of the PurC gene product from Thermotoga maritima has been solved. This 26.2 kDa protein belongs to the phophoribosylaminoimidazole-succinocarboxamide or SAICAR synthase family of enzymes, the members of which are involved in de novo purine biosynthesis. SAICAR synthase can be divided into three subdomains: two α+β regions exhibiting structural homology with ATP-binding proteins and a carboxy-terminal subdomain of two α-helices. The asymmetric unit contains two copies of the protein which are covalently linked by a disulfide bond between Cys126(A) and Cys126(B). This 230-amino-acid protein exhibits high structural homology with SAICAR synthase from baker’s yeast. The protein structure is described and compared with that of the ATP–SAICAR synthase complex from yeast.

Structural characterization of in vitro and in vivo intermediates on the loading module of microcystin synthetase

The microcystin family of toxins is the most common cause of hepatotoxicity associated with water blooms of cyanobacterial genera. The biosynthetic assembly line producing the toxic cyclic peptide, microcystin, contains an adenylation-peptidyl carrier protein didomain (A-PCP) at the N-terminus of the initiator module McyG (295 kDa) that has been postulated to activate and load the starter unit phenylacetate for formation of the unusual aromatic beta-amino acid residue, Adda, before subsequent extension. Characterization of the McyG A-PCP didomain (78 kDa) using ATP-PP i exchange assays and mass spectrometry revealed that assorted phenylpropanoids are preferentially activated and loaded onto the PCP carrier domain rather than phenylacetate itself. For the first time, thioesters formed in vivo were detected directly using large molecule mass spectrometry. Additionally substrates were cleaved using a type II thioesterase for structural elucidation by small molecule mass spectrometry. Unprecedented features of the McyG A-PCP didomain include the in vivo acylation of the holo PCP with exogenous and endogenous substrates, along with the ability of the apo protein to retain the acyl-AMP intermediate during affinity purification. These results imply that phenylpropanoids are preferentially loaded onto the McyG PCP; however one carbon must be excised following extension of the starter unit with malonyl-CoA in order to generate the expected polyketide chain which leads us to ponder the novel biochemistry by which this occurs.

Chemoenzymatic and template-directed synthesis of bioactive macrocyclic peptides

Non-ribosomally synthesized peptides have compelling biological activities ranging from antimicrobial to immunosuppressive and from cytostatic to antitumor. The broad spectrum of applications in modern medicine is reflected in the great structural diversity of these natural products. They contain unique building blocks, such as d-amino acids, fatty acids, sugar moieties, and heterocyclic elements, as well as halogenated, methylated, and formylated residues. In the past decades, significant progress has been made toward the understanding of the biosynthesis of these secondary metabolites by nonribosomal peptide synthetases (NRPSs) and their associated tailoring enzymes. Guided by this knowledge, researchers genetically redesigned the NRPS template to synthesize new peptide products. Moreover, chemoenzymatic strategies were developed to rationally engineer nonribosomal peptides products in order to increase or alter their bioactivities. Specifically, chemical synthesis combined with peptide cyclization mediated by nonribosomal thioesterase domains enabled the synthesis of glycosylated cyclopeptides, inhibitors of integrin receptors, peptide/polyketide hybrids, lipopeptide antibiotics, and streptogramin B antibiotics. In addition to the synthetic potential of these cyclization catalysts, which is the main focus of this review, different enzymes for tailoring of peptide scaffolds as well as the manipulation of carrier proteins with reporter-labeled coenzyme A analogs are discussed.

Genetic Engineering in Streptomyces roseosporus to Produce Hybrid Lipopeptide Antibiotics

Daptomycin is a lipopeptide antibiotic produced by a nonribosomal peptide synthetase (NRPS) in Streptomyces roseosporus. The holoenzyme is composed of three subunits, encoded by the dptA, dptBC, and dptD genes, each responsible for incorporating particular amino acids into the peptide. We introduced expression plasmids carrying dptD or NRPS genes encoding subunits from two related lipopeptide biosynthetic pathways into a daptomycin nonproducing strain of S. roseosporus harboring a deletion of dptD. All constructs successfully complemented the deletion in trans, generating three peptide cores related to daptomycin. When these were coupled with incomplete methylation of 1 amino acid and natural variation in the lipid side chain, 18 lipopeptides were generated. Substantial amounts of nine of these compounds were readily obtained by fermentation, and all displayed antibacterial activity against gram-positive pathogens.

Nonribosomal Peptide Synthesis in Schizosaccharomyces pombe and the Architectures of Ferrichrome-Type Siderophore Synthetases in Fungi

A nonribosomal peptide synthetase (NRPS) in Schizosaccharomyces pombe, which possesses an unusual structure incorporating three adenylation domains, six thiolation domains and six condensation domains, has been shown to produce the cyclohexapeptide siderophore ferrichrome. One of the adenylation domains is truncated and contains a distorted key motif. Substrate-binding specificities of the remaining two domains were assigned by molecular modelling to glycine and to N-acetyl-N-hydroxy-L-ornithine. Hexapeptide siderophore synthetase genes of Magnaporthe grisea and Fusarium graminearum were both identified and analyzed with respect to substrate-binding sites, and the predicted product ferricrocin was identified in each. A comparative analysis of these synthetase systems, including those of the basidiomycete Ustilago maydis, the homobasidiomycete Omphalotus olearius and the ascomycetes Aspergillus nidulans, Aspergillus fumigatus, Fusarium graminearum, Cochliobolus heterostrophus, Neurospora crassa and Aureobasidium pullulans, revealed divergent domain compositions with respect to their number and positioning, although all produce similar products by iterative processes. A phylogenetic analysis of both NRPSs and associated L-N5-ornithine monooxygenases revealed that ferrichrome-type siderophore biosynthesis has coevolved in fungi with varying in trans interactions of NRPS domains.

Structure of MurF from Streptococcus pneumoniae co-crystallized with a small molecule inhibitor exhibits interdomain closure

In a broad genomics analysis to find novel protein targets for antibiotic discovery, MurF was identified as an essential gene product for Streptococcus pneumonia that catalyzes a critical reaction in the biosynthesis of the peptidoglycan in the formation of the cell wall. Lacking close relatives in mammalian biology, MurF presents attractive characteristics as a potential drug target. Initial screening of the Abbott small-molecule compound collection identified several compounds for further validation as pharmaceutical leads. Here we report the integrated efforts of NMR and X-ray crystallography, which reveal the multidomain structure of a MurF-inhibitor complex in a compact conformation that differs dramatically from related structures. The lead molecule is bound in the substrate-binding region and induces domain closure, suggestive of the domain arrangement for the as yet unobserved transition state conformation for MurF enzymes. The results form a basis for directed optimization of the compound lead by structure-based design to explore the suitability of MurF as a pharmaceutical target.

Chemoenzymatic approaches for streamlined detection of active site modifications on thiotemplate assembly lines using mass spectrometry

For the direct interrogation of peptides harboring covalently modified serines in nonribosomal peptide synthetases, streamlined methodologies described here employ proteolysis and reporter-coenzyme A analogues of four types. The chromophoric and fluorescent coenzyme A analogues pyrene-maleimidyl-S-CoA and BODIPY-FL-N-(2-aminoethyl)maleimidyl-S-CoA were enzymatically loaded onto the active site serines harbored in the ArCP, PCP1, and PCP2 thiolation domains of PchE and PchF, the nonribosomal peptide synthetases responsible for the biosynthesis of the siderophore pyochelin. During the chromatographic separation of cyanogen bromide digests, observation of the absorbance (at 338 and 504 nm) or fluorescence (after irradiation at 365 nm) enabled the selective detection of peptides containing each active site serine. This resulted in quick detection of each active site peptide by Fourier transform mass spectrometry in the fully reconstituted pyochelin system. The loading of short acyl chain reporters in equimolar quantities permitted further insights into digestion heterogeneity and side reactions by virtue of a mass shift signature on each active site peptide. The chromatographic shift of the reporter-loaded peptides relative to peptides carrying on pathway intermediates was 2 min at 7 kDa, providing a general strategy for efficient localization of "carrier" peptides in complex digests of thiotemplate enzymes. Also, the use of the affinity reporter, biotin-maleimidyl-S-coenzyme A, permitted the isolation of intact synthetases at high purity via removal of contaminating Escherichia coli proteins.

Fluorescence resonance energy transfer as a probe of peptide cyclization catalyzed by nonribosomal thioesterase domains

Macrocyclization of synthetic peptides by thioesterase (TE) domains excised from nonribosomal peptide synthetases (NRPS) has been limited to peptides that contain TE-specific recognition elements. To alter substrate specificity of these enzymes by evolution efforts, macrocyclization has to be detected under high-throughput conditions. Here we describe a method to selectively detect cyclic peptides by fluorescence resonance energy transfer (FRET). Using this method, picomolar detection limits were easily realized, providing novel entry for kinetic studies of catalyzed macrocyclization. Application of this method also provides an ideal tool to track TE-mediated peptide cyclization in real time. The general utility of FRET-assisted detection of cyclopeptides was demonstrated for two cyclases, namely tyrocidine (Tyc) TE and calcium-dependent antibiotic (CDA) TE. For the latter cyclase, this approach was combined with site-directed affinity labeling, opening the possibility for high-throughput enzymatic screening.

Phosphinothricin tripeptide synthetases in Streptomyces viridochromogenes Tü494

The tripeptide backbone of phosphinothricin (PT) tripeptide (PTT), a compound with herbicidal activity from Streptomyces viridochromogenes, is assembled by three stand-alone peptide synthetase modules. The enzyme PhsA (66 kDa) recruits the PT-precursor N-acetyl-demethylphosphinothricin (N-Ac-DMPT), whereas the two alanine residues of PTT are assembled by the enzymes PhsB and PhsC (129 and 119 kDa, respectively). During or after assembly, the N-Ac-DMPT residue in the peptide is converted to PT by methylation and deacetylation. Both phsB and phsC appear to be cotranscribed together with two other genes from a single promoter and they are located at a distance of 20 kb from the gene phsA, encoding PhsA, in the PTT biosynthesis gene cluster of S. viridochromogenes. PhsB and PhsC represent single nonribosomal peptide synthetase elongation modules lacking a thioesterase domain. Gene inactivations, genetic complementations, determinations of substrate specificity of the heterologously produced proteins, and comparison of PhsC sequence with the amino terminus of the alanine-activating nonribosomal peptide synthetase PTTSII from S. viridochromogenes confirmed the role of the two genes in the bialanylation of Ac-DMPT. The lack of an integral thioesterase domain in the PTT assembly system points to product release possibly involving two type II thioesterase genes (the1 and the2) located in the PTT gene cluster alone or in conjunction with an as yet unknown mechanism of product release.

Excision of the epothilone synthetase B cyclization domain and demonstration of in trans condensation/cyclodehydration activity

The epothilones are potent anticancer natural products produced by a polyketide synthase (PKS)-nonribosomal peptide synthetase (NRPS) hybrid involving proteins EpoA-F. The single NRPS module of the epothilone assembly line, EpoB, is a distinct subunit of approximately 160 kDa and consists of four successive domains: cyclization, adenylation, oxidation, and peptidyl carrier protein (Cy-A-Ox-PCP). The cyclization domain is responsible for introduction of the thiazoline heterocycle into the growing polyketide/nonribosomal peptide chain from the precursors malonyl-CoA and cysteine through the multiple steps of condensation, cyclization, and dehydration. This enzyme-bound thiazoline intermediate is subsequently oxidized to a thiazole by the EpoB Ox domain. The EpoB module was dissected to provide 57 kDa EpoB(Cy) and 102 kDa EpoB(A-Ox-PCP) as subunit fragments to evaluate Cy as a free-standing domain. EpoB was reconstituted by these fragments in trans to generate the methylthiazole product. Using this system, apparent kinetic constants for the upstream acyl donor EpoA(ACP) and EpoB(Cy) were determined, providing a measure of affinity for the naturally occurring interface of the amino terminus of EpoB and the EpoA carboxy terminus. Site-directed mutants in excised EpoB(Cy) were prepared and used to examine residues involved in condensation and heterocycle formation. This work demonstrates the ability to define a functional Cy domain by excision from its native NRPS module, and examine both its protein-protein interactions and mechanism of activity.

Harnessing the potential of communication-mediating domains for the biocombinatorial synthesis of nonribosomal peptides

The interaction between enzymes of a nonribosomal peptide synthetase (NRPS) complex relies on the interplay of compatible sets of donor and acceptor communication-mediating (COM) domains. Hence, these domains are essential for the formation of a defined biosynthetic template, thereby directing the synthesis of a specific peptide product. Without the selectivity provided by different sets of COM domains, NRPSs should form random biosynthetic templates, which would ultimately lead to combinatorial peptide synthesis. This study aimed to exploit this inherent combinatorial potential of COM domains. Based on sequence alignments between COM domains, the crosstalk between different biosynthetic systems was predicted and experimentally proven. Furthermore, key residues important for maintaining (or preventing) NRPS interaction were identified. Point mutation of one of these key residues within the acceptor COM domain of TycC1 was sufficient to shift its selectivity from the cognate donor COM of TycB3 toward the noncognate donor COM domain of TycB1. Finally, an artificial NRPS complex was constructed, constituted of enzymes derived from three different biosynthetic systems. By virtue of domain fusions, the interactions between all enzymes were established by the same set of COM domains. Because of the abrogated selectivity, this universal communication system was able to simultaneously form two biosynthetic complexes that catalyzed the combinatorial synthesis of different peptide products.

Determination of all nOes in 1H-13C-Me-ILV-U-2H-15N proteins with two time-shared experiments

We present two time-shared experiments that enable the characterization of all nOes in 1H-13C-ILV methyl-labelled proteins that are otherwise uniformly deuterated and 15N enriched and possibly selectively protonated for distinct residue types. A 3D experiment simultaneously provides the spectra of a 3D NOESY-HN-TROSY and of a 3D NOESY-HC-PEP-HSQC. Thus, nOes from any protons to methyl or amide protons are dispersed with respect to 15N and 13C chemical shifts, respectively. The single 4D experiment presented here yields simultaneously the four 4D experiments HC-HSQC-NOESY-HC-PEP-HSQC, HC-HSQC-NOESY-HN-TROSY, HN-HSQC-NOESY-HN-TROSY and HN-HSQC-NOESY-HC-PEP-HSQC. This allows for the unambiguous determination of all nOes involving amide and methyl protons. The method was applied to a (1H,13C)-ILV-(1H)-FY-(U-2H,15N) sample of a 37 kDa di-domain of the E. coli enterobactin synthetase module EntF.

Flexible Secondary Structure Based Protein Structure Comparison Applied to the Detection of Circular Permutation

We present a novel method for structural comparison of protein structures. The approach consists of two main phases: 1) an initial search phase where, starting from aligned pairs of secondary structure elements, the space of 3D transformations is searched for similarities and 2) a subsequent refinement phase where interim solutions are subjected to parallel, local, iterative dynamic programming in the areas of possible improvement. The proposed method combines dynamic programming for finding alignments but does not restrict solutions to be sequential. In addition, to deal with the problem of nonuniqueness of optimal similarities, we introduce a consensus scoring method in selecting the preferred similarity and provide a list of top-ranked solutions. The method, called FASE (flexible alignment of secondary structure elements), was tested on well-known data and various standard problems from the literature. The results show that FASE is able to find remote and weak similarities consistently using a reasonable run time. The method was tested (using the SCOP database) on its ability to discriminate interfold pairs from intrafold pairs at the level of the best existing methods. The method was then applied to the problem of finding circular permutations in proteins.

4'-phosphopantetheine biosynthesis in Archaea

Coenzyme A as the principal acyl carrier is required for many synthetic and degradative reactions in intermediary metabolism. It is synthesized in five steps from pantothenate, and recently the CoaA biosynthetic genes of eubacteria, plants, and human were all identified and cloned. In most bacteria, the so-called Dfp proteins catalyze the synthesis of the coenzyme A precursor 4'-phosphopantetheine. Dfp proteins are bifunctional enzymes catalyzing the synthesis of 4'-phosphopantothenoylcysteine (CoaB activity) and its decarboxylation to 4'-phosphopantetheine (CoaC activity). Here, we demonstrate the functional characterization of the CoaB and CoaC domains of an archaebacterial Dfp protein. Both domains of the Methanocaldococcus jannaschii Dfp protein were purified as His tag proteins, and their enzymatic activities were then identified and characterized by site-directed mutagenesis. Although the nucleotide binding motif II of the CoaB domain resembles that of eukaryotic enzymes, Methanocaldococcus CoaB is a CTP- and not an ATP-dependent enzyme, as shown by detection of the 4'-phosphopantothenoyl-CMP intermediate. The proposed 4'-phosphopantothenoylcysteine binding clamp of the Methanocaldococcus CoaC activity differs significantly from those of other characterized CoaC proteins. In particular, the active site cysteine residue, which otherwise is involved in the reduction of an aminoenethiol reaction intermediate, is not present. Moreover, the conserved Asn residue of the PXMNXXMW motif, which contacts the carboxyl group of 4'-phosphopantothenoylcysteine, is exchanged for His.