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.     

Structure-based mutational analysis of the 4'-phosphopantetheinyl transferases Sfp from Bacillus subtilis: carrier protein recognition and reaction mechanism

The activation of apo-peptidyl carrier proteins (PCPs) of nonribosomal peptide synthetases (NRPSs), apo-acyl carrier proteins (ACPs) of polyketide synthases (PKSs), and fatty acid synthases (FASs) to their active holo form is accomplished with dedicated 4'-phosphopantetheinyl transferases (PPTases). They catalyze the transfer of the essential prosthetic group 4'-phosphopantetheine (4'-Ppant) from coenzyme A (CoA) to a highly conserved serine residue in all PCPs and ACPs. PPTases, based on sequence and substrate specifity, have been classified into three types: bacterial holo-acyl carrier protein synthase (AcpS), fatty acid synthase of eukaryotes (FAS2) and Sfp, a PPTase of secondary metabolism. The recently solved crystal structures of AcpS and Sfp-type PPTases with CoA revealed a common alpha + beta-fold with a beta(1)alpha(3)beta(2) motif and similarities in CoA binding and polymerization mode. However, it was not possible to discern neither the PCP binding region of Sfp nor the priming reaction mechanism from the Sfp-CoA cocrystal. In this work, we provide a model for the reaction mechanism based on mutational analysis of Sfp that suggests a reaction mechanism in which the highly conserved E151 deprotonates the hydroxyl group of the invariant serine of PCP. That, in turn, acts as a nucleophile to attack the beta-phosphate of CoA. The Sfp mutants K112, E117, and K120 further revealed that the loop region between beta4 and alpha5 (residues T111-S124) in Sfp is the PCP binding region. Also, residues T44, K75, S89, H90, D107, E109, E151, and K155 that have been shown in the Sfp-CoA cocrystal structure to coordinate CoA are now all confirmed by mutational and biochemical analysis.     

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.     

海绵共生萎缩芽孢杆菌C89 PPTase bap基因的异源表达

【背景】磷酸泛酰巯基乙胺基转移酶(PPTase)催化非核糖体肽合成酶(NRPS)中肽酰载体蛋白(PCP)从无活性的脱辅基形态转化为有活性的全辅基形态,从而启动非核糖体肽类化合物的生物合成。【目的】鉴定贪婪倔海绵共生萎缩芽孢杆菌C89中Sfp型PPTase Bap,验证Bap激活NRPS中PCP的能力。【方法】通过BLAST和氨基酸多序列比对鉴定萎缩芽孢杆菌C89中Sfp型PPTase Bap。将bap基因在sfp基因突变株枯草芽孢杆菌168中异源表达,通过重组菌枯草芽孢杆菌168-bap的代谢物检测非核糖体肽类化合物Surfactin。【结果】Bap为Sfp型PPTase,检测到重组菌枯草芽孢杆菌168-bap中Surfactin的产生。【结论】本研究为海洋萎缩芽孢杆菌中NRPS基因簇的异源表达奠定了基础。     

Functional characterization of 4'-phosphopantetheinyl transferase genes of bacterial and fungal origin by complementation of Saccharomyces cerevisiae lys5

Lysine biosynthesis in yeast requires the posttranslational conversion of the alpha-aminoadipate semialdehyde reductase Lys2 by the 4'-phosphopantetheinyl transferase (PPTase) Lys5 from the inactive apo-form into the catalytically active holo-form. In this reaction, the peptidyl carrier domain of Lys2 is modified at a conserved serine residue side chain with the 4'-phosphopantetheine moiety derived from coenzyme A. We have deleted the lys5 gene in Saccharomyces cerevisiae to investigate the substrate specificity of various heterologous PPTase genes of bacterial and fungal origin by testing their ability to complement lys5 in trans. Genes encoding PPTases Sfp and Gsp from Bacillus spp., which are involved in non-ribosomal peptide antibiotic synthesis, complemented the lys5 deletion, whereas ydcB of Bacillus subtilis, which encodes the acyl carrier protein synthase involved in fatty acid synthesis, could not. Two yet uncharacterized fungal genes, q10474 of Schizosaccharomyces pombe, meanwhile annotated as the putative lys7 gene, and npgA of Aspergillus nidulans, also complemented the lys5 deletion and have thus been functionally characterized as PPTases. The complementation system described also provides the basis for a simple method of functional characterization of PPTase candidate genes and their cloning from chromosomal DNA or cDNA libraries of diverse origin.     

Characterization of a new type of phosphopantetheinyl transferase for fatty acid and siderophore synthesis in Pseudomonas aeruginosa

Phosphopantetheinyl-dependent carrier proteins are part of fatty-acid synthases (primary metabolism), polyketide synthases, and non-ribosomal peptide synthetases (secondary metabolism). For these proteins to become functionally active, they need to be primed with the 4'-phosphopantetheine moiety of coenzyme A by a dedicated phosphopantetheine transferase (PPTase). Most organisms that employ more than one phosphopantetheinyl-dependent pathway also have more than one PPTase. Typically, one of these PPTases is optimized for the modification of carrier proteins of primary metabolism and rejects those of secondary metabolism (AcpS-type PPTases), whereas the other, Sfp-type PPTase, efficiently modifies carrier proteins involved in secondary metabolism. We present here a new type of PPTase, the carrier protein synthase of Pseudomonas aeruginosa, an organism that harbors merely one PPTase, namely PcpS. Gene deletion experiments clearly show that PcpS is essential for growth of P. aeruginosa, and biochemical data indicate its association with both fatty acid synthesis and siderophore metabolism. At first sight, PcpS is a PPTase of the monomeric Sfp-type and was consequently expected to have catalytic properties typical for this type of enzyme. However, in vitro characterization of PcpS with natural protein partners and non-cognate substrates revealed that its catalytic properties differ significantly from those of Sfp. Thus, the situation in P. aeruginosa is not simply the result of the loss of an AcpS-type PPTase. PcpS exhibits high catalytic efficiency with the carrier protein of fatty acid synthesis and shows a reduced although significant conversion rate of the carrier proteins of non-ribosomal peptide synthetases from their apo to holo form. This association with enzymes of primary and secondary metabolism indicates that PcpS belongs to a new sub-class of PPTases.     

Characterization of a nonspecific phosphopantetheinyl transferase from Pseudomonas syringae pv. syringae FF5

The 4'-phosphopantetheinyl transferases (PPTases) catalyze the transfer of a 4'-phosphopantetheine moiety from coenzyme A to phosphopantetheine-dependent carrier proteins. The carrier proteins (CPs) are required for the biosynthesis of peptides synthesized by nonribosomal peptide synthases and the biosynthesis of fatty acids and polyketides. A single PPTase (PcpS) is present in the pathogenic bacterium Pseudomonas aeruginosa. Several pathovars of Pseudomonas syringae produce the chlorosis-inducing phytotoxin coronatine. Structural genes for coronatine biosynthesis include two ACPs, two ACP domains, and one peptidyl carrier protein (PCP) domain. To gain insight into factors affecting coronatine biosynthesis, the PPTase of P. syringae pv. syringae FF5 has been investigated. A single PPTase gene (pspT) was amplified from this organism by PCR. The translation product PspT exhibited 62% identity to PcpS as well as higher levels of identity to other, uncharacterized Pseudomonad PPTases. PspT was overproduced in soluble form in Escherichia coli and its enzymatic properties were compared with those of PcpS. PspT exhibited broad substrate specificity, and it displayed the highest activity with a PCP domain. In contrast, the most efficient substrates for PcpS are CPs from primary metabolism. These results indicate phosphopantetheinyl transferases from different Pseudomonas sp. may vary significantly in their enzymatic properties.     

Rapid and flexible biochemical assays for evaluating 4'-phosphopantetheinyl transferase activity

PPTases (phosphopantetheinyl transferases) are of great interest owing to their essential roles in activating fatty acid, polyketide and non-ribosomal peptide synthetase enzymes for both primary and secondary metabolism, as well as an increasing number of biotechnological applications. However, existing techniques for PPTase characterization and development are cumbersome and technically challenging. To address this, we have developed the indigoidine-synthesizing non-ribosomal peptide synthetase BpsA as a reporter for PPTase activity. Simple co-transformation allows rapid assessment of the ability of a PPTase candidate to activate BpsA in vivo. Kinetic parameters with respect to either CoA or BpsA as variable substrate can then be derived in vitro by continuously measuring the rate of indigoidine synthesis as the PPTase progressively converts BpsA from its apo into holo form. Subsequently, a competition assay, in which BpsA and purified carrier proteins compete for a limited pool of CoA, enables elucidation of kinetic parameters for a PPTase with those carrier proteins. We used this system to conduct a rapid characterization of three different PPTase enzymes: Sfp of Bacillus subtilis A.T.C.C.6633, PcpS of Pseudomonas aeruginosa PAO1, and the putative PPTase PP1183 of Ps. putida KT2440. We also demonstrate the utility of this system for discovery and characterization of PPTase inhibitors.     

Phosphopantetheinylation in the green microalgae <Emphasis Type="Italic">Chlamydomonas reinhardtii</Emphasis>

Microalgal biofuel is a promising solution to the decline of fossil fuels. However, algal fatty acid metabolism, the machinery producing the raw material for biofuels, remains poorly understood. The central unit of the fatty acid synthase (FAS) is the acyl carrier protein (ACP), which is responsible for holding the product. Fatty acid biosynthesis is initiated through posttranslational modification of the ACP by the phosphopantetheinyl transferase (PPTase). We identified two PPTases, PptC1 and PptC2, in the model alga Chlamydomonas reinhardtii by genome analysis and phylogenetic and structural comparison. Both PPTases are of Sfp-type, the archetypical PPTase type for non-ribosomal peptide and polyketide biosynthetic pathways in bacteria and cyanobacteria. In vitro analysis revealed that PptC2 has a broader substrate range than PptC1. Both PPTases were able to activate the cognate ACP of the type II FAS, while PptC2 also recognized ACP of Escherichia coli type II FAS and actinorhodin type II polyketide synthase. Besides FAS as PPTase target, the C. reinhardtii genome encodes a single type I PKS, and we hypothesize that PptC2 is responsible for its activation. Screening of the currently available microalgal genome data revealed that most green microalgae appear to carry two PPTases forming clusters with each C. reinhardtii PPTase, while microalgae of other divisions carry one or two PPTases and do not cluster in the pattern of the green algal data. This new understanding on the PPTases in microalgae shows that microalgae are already primed for biotechnological applications in contrast to other organisms. Thus, microalgae have great potential for metabolic engineering efforts in the realm of biofuel and high-value products including direct engineering of the fatty acid or secondary metabolism using the natural genomic reservoir and as biotechnological platform for heterologous expression.     

The phosphopantetheinyl transferase KirP activates the ACP and PCP domains of the kirromycin NRPS/PKS of Streptomyces collinus Tü 365

The main steps in the biosynthesis of complex secondary metabolites such as the antibiotic kirromycin are catalyzed by modular polyketide synthases (PKS) and/or nonribosomal peptide synthetases (NRPS). During antibiotic assembly, the biosynthetic intermediates are attached to carrier protein domains of these megaenzymes via a phosphopantetheinyl arm. This functional group of the carrier proteins is attached post-translationally by a phosphopantetheinyl transferase (PPTase). No experimental evidence exists about how such an activation of the carrier proteins of the kirromycin PKS/NRPS is accomplished. Here we report on the characterization of the PPTase KirP, which is encoded by a gene located in the kirromycin biosynthetic gene cluster. An inactivation of the kirP gene resulted in a 90% decrease in kirromycin production, indicating a substantial role for KirP in the biosynthesis of the antibiotic. In enzymatic assays, KirP was able to activate both acyl carrier protein and petidyl carrier domains of the kirromycin PKS/NRPS. In addition to coenzyme A (CoA), which is the natural substrate of KirP, the enzyme was able to transfer acyl-phosphopantetheinyl groups to the apo forms of the carrier proteins. Thus, KirP is very flexible in terms of both CoA substrate and carrier protein specificity. Our results indicate that KirP is the main PPTases that activates the carrier proteins in kirromycin biosynthesis.     

Gene cloning,expression and functional characterization of a phosphopantetheinyl transferase from <Emphasis Type="Italic">Vibrio anguillarum</Emphasis> serotype O1

Phosphopantetheinyl transferases (PPTases) catalyze the essential post-translational activation of carrier proteins from fatty acid synthetases (FASs) in primary metabolism and polyketide synthetases (PKSs) and non-ribosomal polypeptide synthetases (NRPSs) in secondary metabolism. Bacteria typically harbor one PPTase specific for carrier proteins of primary metabolism (ACPS-type PPTases) and at least one capable of modifying carrier proteins involved in secondary metabolism (Sfp-type PPTases). Anguibactin, an important virulent factor in Vibrio anguillarum serotype O1, has been reported to be synthesized by a nonribosomal peptide synthetases (NRPS) system encoded on a 65-kb virulent plasmid pJM1 from strain 775 of V. anguillarum serotype O1, and the PPTase, necessary for the activation of the anguibactin-NRPS, is therefore expected to lie on the pJM1 plasmid. In this work, a putative PPTase gene, angD, was first identified on pEIB1 plasmid (a pJM1-like plasmid) from a virulent strain MVM425 of V. anguillarum serotype O1. A recombinant clone carrying complete angD was able to complement an Escherichia coli entD mutant deficient in Sfp-type PPTase. angD was overexpressed in E. coli and the resultant protein, AngD, was purified. Simultaneously, two carrier proteins involved in anguibactin-NRPS, ArCP and PCP, were overproduced in E. coli and purified. The purified AngD, PCP and ArCP were used to establish an in vitro enzyme reaction, and the PPTase activity of AngD was proved through HPLC analysis to detect the conversion of inactive carrier proteins to active carrier proteins in the reaction mixture. Co-expression of AngD with PCP or ArCP showed that AngD functioned well as a PPTase in vivo in E. coli, modifying PCP and ArCP completely.     

Acyl carrier protein: structure-function relationships in a conserved multifunctional protein family.

Acyl carrier protein (ACP) is a universal and highly conserved carrier of acyl intermediates during fatty acid synthesis. In yeast and mammals, ACP exists as a separate domain within a large multifunctional fatty acid synthase polyprotein (type I FAS), whereas it is a small monomeric protein in bacteria and plastids (type II FAS). Bacterial ACPs are also acyl donors for synthesis of a variety of products, including endotoxin and acylated homoserine lactones involved in quorum sensing; the distinct and essential nature of these processes in growth and pathogenesis make ACP-dependent enzymes attractive antimicrobial drug targets. Additionally, ACP homologues are key components in the production of secondary metabolites such as polyketides and nonribosomal peptides. Many ACPs exhibit characteristic structural features of natively unfolded proteins in vitro, with a dynamic and flexible conformation dominated by 3 parallel alpha helices that enclose the thioester-linked acyl group attached to a phosphopantetheine prosthetic group. ACP conformation may also be influenced by divalent cations and interaction with partner enzymes through its "recognition" helix II, properties that are key to its ability to alternately sequester acyl groups and deliver them to the active sites of ACP-dependent enzymes. This review highlights recent progress in defining how the structural features of ACP are related to its multiple carrier roles in fatty acid metabolism.     

The phosphopantetheinyl transferase superfamily: phylogenetic analysis and functional implications in cyanobacteria

Phosphopantetheinyl transferases (PPTs) are a superfamily of essential enzymes required for the synthesis of a wide range of compounds including fatty acid, polyketide, and nonribosomal peptide metabolites. These enzymes activate carrier proteins in specific biosynthetic pathways by the transfer of a phosphopantetheinyl moiety to an invariant serine residue. PPTs display low levels of sequence similarity but can be classified into two major families based on several short motifs. The prototype of the first family is the broad-substrate-range PPT Sfp, which is required for biosynthesis of surfactin in Bacillus subtilis. The second family is typified by the Escherichia coli acyl carrier protein synthase (AcpS). Facilitated by the growing number of genome sequences available for analyses, large-scale phylogenetic studies were utilized in this research to reveal novel subfamily groupings, including two subfamilies within the Sfp-like family. In the present study degenerate oligonucleotide primers were designed for amplification of cyanobacterial PPT gene fragments. Subsequent phylogenetic analyses suggested a unique, function-based PPT type, defined by the PPTs involved in heterocyst differentiation. Evidence supporting this hypothesis was obtained by sequencing the region surrounding the partial Nodularia spumigena PPT gene. The ability to genetically classify PPT function is critical for the engineering of novel compounds utilizing combinatorial biosynthesis techniques. Information regarding cyanobacterial PPTs has important ramifications for the ex situ production of cyanobacterial natural products.     

A genome rearrangement has orphaned the Escherichia coli K-12 AcpT phosphopantetheinyl transferase from its cognate Escherichia coli O157:H7 substrates

Phosphopantetheinyl transferases (PPTases) are enzymes that catalyse the transfer of a 4'-phosphopantetheine moiety from CoA to a conserved serine residue of a carrier protein. These carrier proteins use the 4'-phosphopantetheine thiol to shuttle intermediates between the active sites of biosynthetic enzymes involved in fatty acid, non-ribosomal peptide and polyketide synthesis. Three PPTases have been previously been identified in Escherichia coli K-12 and other E. coli strains by homology searches and are encoded by the genes acpS, entD and acpT. Both AcpS and EntD have been well studied whereas the function of AcpT has been an enigma because no carrier protein substrate could be found. We report genetic and biochemical evidence that AcpT modifies two carrier proteins encoded in O-island 138, a cluster of fatty acid biosynthesis-like genes located adjacent to acpT in the genome of the pathogenic E. coli strain O157:H7 (E. coli K-12 and several other sequenced E. coli and Shigella strains lack O-island 138). The two carrier proteins of O-island 138 of strain O157:H7 are not modified (or only very poorly modified) by AcpS, the PPTase responsible for 4'-phosphopantetheine attachment to the acyl carrier protein (AcpP) of fatty acid synthesis. We demonstrate that AcpT cannot functionally replace AcpS in E. coli K-12 either in its native chromosomal location or upon insertion of acpT into the acpS chromosomal location. However, in the absence of AcpS activity AcpT does allow very slow growth thus providing a rationale for its retention in the absence of its cognate substrates. These results together with phylogenetic analyses and comparisons of the E. coli and Shigella strains of known genome sequence strongly argue that AcpT has been orphaned from its cognate substrates by a deletion event that occurred in a common ancestor of these organisms. This seems one of the few cases where a chromosomal rearrangement has been functionally demonstrated to be a deletion event rather than an insertion event in the reference organism. We also show that the previously reported suppression of an acpS mutation by the deletion of Lon protease is an artifact of the increased capsular polysaccharide production of lon strains.     

Structure-Function Analysis of the Acyl Carrier Protein Synthase (AcpS) from Mycobacterium tuberculosis

We have solved the crystal structure of the acyl carrier protein synthase (AcpS) from Mycobacterium tuberculosis (Mtb) at 1.95 Å resolution. AcpS, a 4-phosphopantetheinyl transferase, activates two distinct acyl carrier proteins (ACPs) that are present in fatty acid synthase (FAS) systems FAS-I and FAS-II, the ACP-I domain and the mycobacterial ACP-II protein (ACPM), respectively. Mtb, the causal agent of tuberculosis (TB), and all other members of the Corynebacterineae family are unique in possessing both FAS systems to produce and to elongate fatty acids to mycolic acids, the hallmark of mycobacterial cell wall. Various steps in this process are prime targets for first-line anti-TB agents. A comparison of the Mtb AcpS structure determined here with those of other AcpS proteins revealed unique structural features in Mtb AcpS, namely, the presence of an elongated helix followed by a flexible loop and a moderately electronegative surface unlike the positive surface common to other AcpSs. A structure-based sequence comparison between AcpS and its ACP substrates from various species demonstrated that the proteins of the Corynebacterineae family display high sequence conservation, forming a segregated subgroup of AcpS and ACPs. Analysis of the putative interactions between AcpS and ACPM from Mtb, based on a comparison with the complex structure from Bacillus subtilis, showed that the Mtb AcpS and ACPM lack the electrostatic complementarity observed in B. subtilis. Taken together, the common characteristic of the Corynebacterineae family is likely reflected in the participation of different residues and interactions used for binding the Mtb AcpS to ACP-I and ACPM. The distinct features and essentiality of AcpS, as well as the mode of interaction with ACPM and ACP-I in Mtb, could be exploited for the design of AcpS inhibitors, which, similarly to other inhibitors of fatty acid synthesis, are expected to be effective anti-TB-specific drugs.     

Analysis of Streptomyces coelicolor phosphopantetheinyl transferase, AcpS, reveals the basis for relaxed substrate specificity

The transfer of the phosphopantetheine chain from coenzyme A (CoA) to the acyl carrier protein (ACP), a key protein in both fatty acid and polyketide synthesis, is catalyzed by ACP synthase (AcpS). Streptomyces coelicolor AcpS is a doubly promiscuous enzyme capable of activation of ACPs from both fatty acid and polyketide synthesis and catalyzes the transfer of modified CoA substrates. Five crystal structures have been determined, including those of ligand-free AcpS, complexes with CoA and acetyl-CoA, and two of the active site mutants, His110Ala and Asp111Ala. All five structures are trimeric and provide further insight into the mechanism of catalysis, revealing the first detailed structure of a group I active site with the essential magnesium in place. Modeling of ACP binding supported by mutational analysis suggests an explanation for the promiscuity in terms of both ACP partner and modified CoA substrates.     

Characterization of PPTNs, a cyanobacterial phosphopantetheinyl transferase from Nodularia spumigena NSOR10

The phosphopantetheinyl transferases (PPTs) are a superfamily of essential enzymes required for the synthesis of a wide range of compounds, including fatty acids, polyketides, and nonribosomal peptide metabolites. These enzymes activate carrier proteins in specific biosynthetic pathways by transfer of a phosphopantetheinyl moiety. The diverse PPT superfamily can be divided into two families based on specificity and conserved sequence motifs. The first family is typified by the Escherichia coli acyl carrier protein synthase (AcpS), which is involved in fatty acid synthesis. The prototype of the second family is the broad-substrate-range PPT Sfp, which is required for surfactin biosynthesis in Bacillus subtilis. Most cyanobacteria do not encode an AcpS-like PPT, and furthermore, some of their Sfp-like PPTs belong to a unique phylogenetic subgroup defined by the PPTs involved in heterocyst differentiation. Here, we describe the first functional characterization of a cyanobacterial PPT based on a structural analysis and subsequent functional analysis of the Nodularia spumigena NSOR10 PPT. Southern hybridizations suggested that this enzyme may be the only PPT encoded in the N. spumigena NSOR10 genome. Expression and enzyme characterization showed that this PPT was capable of modifying carrier proteins resulting from both heterocyst glycoplipid synthesis and nodularin toxin synthesis. Cyanobacteria are a unique and vast source of bioactive metabolites; therefore, an understanding of cyanobacterial PPTs is important in order to harness the biotechnological potential of cyanobacterial natural products.     

Crystal structures of substrate binding to Bacillus subtilis holo-(acyl carrier protein) synthase reveal a novel trimeric arrangement of molecules resulting in three active sites

BACKGROUND: Holo-(acyl carrier protein) synthase (AcpS), a member of the phosphopantetheinyl transferase superfamily, plays a crucial role in the functional activation of acyl carrier protein (ACP) in the fatty acid biosynthesis pathway. AcpS catalyzes the attachment of the 4'-phosphopantetheinyl moiety of coenzyme A (CoA) to the sidechain of a conserved serine residue on apo-ACP. RESULTS: We describe here the first crystal structure of a type II ACP from Bacillus subtilis in complex with its activator AcpS at 2.3 A. We also have determined the structures of AcpS alone (at 1.8 A) and AcpS in complex with CoA (at 1.5 A). These structures reveal that AcpS exists as a trimer. A catalytic center is located at each of the solvent-exposed interfaces between AcpS molecules. Site-directed mutagenesis studies confirm the importance of trimer formation in AcpS activity. CONCLUSIONS: The active site in AcpS is only formed when two AcpS molecules dimerize. The addition of a third molecule allows for the formation of two additional active sites and also permits a large hydrophobic surface from each molecule of AcpS to be buried in the trimer. The mutations Ile5-->Arg, Gln113-->Glu and Gln113-->Arg show that AcpS is inactive when unable to form a trimer. The co-crystal structures of AcpS-CoA and AcpS-ACP allow us to propose a catalytic mechanism for this class of 4'-phosphopantetheinyl transferases.     

Crystal structure of the surfactin synthetase-activating enzyme sfp: a prototype of the 4'-phosphopantetheinyl transferase superfamily

The Bacillus subtilis Sfp protein activates the peptidyl carrier protein (PCP) domains of surfactin synthetase by transferring the 4'-phosphopantetheinyl moiety of coenzyme A (CoA) to a serine residue conserved in all PCPs. Its wide PCP substrate spectrum renders Sfp a biotechnologically valuable enzyme for use in combinatorial non-ribosomal peptide synthesis. The structure of the Sfp-CoA complex determined at 1.8 A resolution reveals a novel alpha/beta-fold exhibiting an unexpected intramolecular 2-fold pseudosymmetry. This suggests a similar fold and dimerization mode for the homodimeric phosphopantetheinyl transferases such as acyl carrier protein synthase. The active site of Sfp accommodates a magnesium ion, which is complexed by the CoA pyrophosphate, the side chains of three acidic amino acids and one water molecule. CoA is bound in a fashion that differs in many aspects from all known CoA-protein complex structures. The structure reveals regions likely to be involved in the interaction with the PCP substrate.     

Solution structure and backbone dynamics of the holo form of the frenolicin acyl carrier protein

During polyketide biosynthesis, acyl carrier proteins (ACPs) perform the central role of transferring polyketide intermediates between active sites of polyketide synthase. The 4'-phosphopantetheine prosthetic group of a holo-ACP is a long and flexible arm that can reach into different active sites and provide a terminal sulfhydryl group for the attachment of acyl groups through a thioester linkage. We have determined the solution structure and characterized backbone dynamics of the holo form of the frenolicin acyl carrier protein (fren holo-ACP) by nuclear magnetic resonance (NMR). Unambiguous assignments were made for 433 hydrogen atoms, 333 carbon atoms, and 84 nitrogen atoms, representing a total of 94.6% of the assignable atoms in this protein. From 879 meaningful NOEs and 45 angle constraints, a family of 24 structures has been calculated. The solution structure is composed of three major alpha-helices packed in a bundle with three additional short helices in intervening loops; one of the short helices slowly exchanges between two conformations. Superposition of the major helical regions on the mean structure yields average atomic rmsd values of 0.49 +/- 0.09 and 0.91 +/- 0.08 A for backbone and non-hydrogen atoms, respectively. Although the three-helix bundle fold is conserved among acyl carrier proteins involved in fatty acid synthases and polyketide synthases, a detailed comparison revealed that ACPs from polyketide biosynthetic pathways are more related to each other in tertiary fold than to their homologues from fatty acid biosynthetic pathways. Comparison of the free form of ACPs (NMR structures of fren ACP and the Bacillus subtilis ACP) with the substrate-bound form of ACP (crystal structure of butyryl-ACP from Escherichia coli) suggests that conformational exchange plays a role in substrate binding.