Targeted gene replacements in a Streptomyces polyketide synthase gene cluster: role for the acyl carrier protein

A methodology was developed to construct any desired chromosomal mutation in the gene cluster that encodes the actinorhodin polyketide synthase (PKS) of Streptomyces coelicolor A3(2). A positive selection marker (resistance gene) is first introduced by double crossing-over into the chromosomal site of interest by use of an unstable delivery plasmid. This marker is subsequently replaced by the desired mutant allele via a second high-frequency double recombination event. The technology has been used to: (i) explore the significance of translational coupling between two adjacent PKS genes; (ii) prove that the acyl carrier protein (ACP) encoded by a gene in the cluster is necessary for the function of the actinorhodin PKS; (iii) provide genetic evidence supporting the hypothesis that serine 42 is the site of phosphopantetheinylation in the ACP of the actinorhodin PKS; and (iv) demonstrate that this ACP can be replaced by a Saccharopolyspora fatty acid synthase ACP to generate an active hybrid PKS.     

Solution structures of the acyl carrier protein domain from the highly reducing type I iterative polyketide synthase CalE8

Biosynthesis of the enediyne natural product calicheamicins γ(1) (I) in Micromonospora echinospora ssp. calichensis is initiated by the iterative polyketide synthase (PKS) CalE8. Recent studies showed that CalE8 produces highly conjugated polyenes as potential biosynthetic intermediates and thus belongs to a family of highly-reducing (HR) type I iterative PKSs. We have determined the NMR structure of the ACP domain (meACP) of CalE8, which represents the first structure of a HR type I iterative PKS ACP domain. Featured by a distinct hydrophobic patch and a glutamate-residue rich acidic patch, meACP adopts a twisted three-helix bundle structure rather than the canonical four-helix bundle structure. The so-called 'recognition helix' (α2) of meACP is less negatively charged than the typical type II ACPs. Although loop-2 exhibits greater conformational mobility than other regions of the protein with a missing short helix that can be observed in most ACPs, two bulky non-polar residues (Met(992), Phe(996)) from loop-2 packed against the hydrophobic protein core seem to restrict large movement of the loop and impede the opening of the hydrophobic pocket for sequestering the acyl chains. NMR studies of the hydroxybutyryl- and octanoyl-meACP confirm that meACP is unable to sequester the hydrophobic chains in a well-defined central cavity. Instead, meACP seems to interact with the octanoyl tail through a distinct hydrophobic patch without involving large conformational change of loop-2. NMR titration study of the interaction between meACP and the cognate thioesterase partner CalE7 further suggests that their interaction is likely through the binding of CalE7 to the meACP-tethered polyene moiety rather than direct specific protein-protein interaction.     

Solution structure and dynamics of oxytetracycline polyketide synthase acyl carrier protein from Streptomyces rimosus

Type II polyketide synthases (PKSs) utilize a dedicated and essential acyl carrier protein (ACP) in the biosynthesis of a specific polyketide product. As part of our ongoing studies into the mechanisms and control of polyketide biosynthesis, we report the second structure of a polyketide synthase ACP. In this work, multidimensional, heteronuclear NMR was employed to investigate the structure and dynamics of the ACP involved in the biosynthesis of the commonly prescribed polyketide antibiotic, oxytetracycline (otc). An ensemble of 28 structures of the 95 amino acid otc ACP (9916Da) was computed by simulated annealing with the inclusion of 1132 experimental restraints. Atomic RMSDs about the mean structure for all 28 models is 0.66 A for backbone atoms, 1.15 A for all heavy atoms (both values calculated for the folded part of the protein (residues 3-80)), and 0.41 A for backbone atoms within secondary structure. Otc ACP adopts the typical right-handed, four-helix fold of currently known ACPs but with the addition of a 13-residue flexible C-terminus. A comparison of the global folds of all structurally characterized ACPs is described, illustrating that PKS ACPs show clear differences as well as similarities to FAS ACPs. (15)N relaxation experiments for the protein backbone also reveal that the long loop between helices I and II is flexible and helix II, a proposed site of protein-protein interactions, shows conformational exchange. The helices of the ACP form a rigid scaffold for the protein, but these are interspersed with an unusual proportion of flexible linker regions.     

Self-malonylation is an intrinsic property of a chemically synthesized type II polyketide synthase acyl carrier protein

During polyketide biosynthesis, malonyl groups are transferred to the acyl carrier protein (ACP) component of the polyketide synthase (PKS), and it has been shown that a number of type II polyketide ACPs undergo rapid self-acylation from malonyl-CoA in the absence of a malonyl-CoA:holo-acyl carrier protein transacylase (MCAT). More recently, however, the observation of self-malonylation has been ascribed to contamination with Escherichia coli MCAT (FabD) rather than an intrinsic property of the ACP. The wild-type apo-ACP from the actinorhodin (act) PKS of Streptomyces coelicolor (synthetic apo-ACP) has therefore been synthesized using solid-state peptide methods and refolded using the GroEL/ES chaperone system from E. coli. Correct folding of the act ACP has been confirmed by circular dichroism (CD) and 1H NMR. Synthetic apo-ACP was phosphopantetheinylated to 100% by S. coelicolor holo-acyl carrier protein synthase (ACPS), and the resultant holo-ACP underwent self-malonylation in the presence of malonyl-CoA. No malonylation of negative controls was observed, confirming that the use of ACPS and GroEL/ES did not introduce contamination with E. coli MCAT. This result proves unequivocally that self-malonylation is an inherent activity of this PKS ACP in vitro.     

Purification and characterization of the acyl carrier protein of the Streptomyces glaucescens tetracenomycin C polyketide synthase.

The acyl carrier protein (ACP) of the tetracenomycin C polyketide synthase, encoded by the tcmM gene, has been expressed in both Streptomyces glaucescens and Escherichia coli and purified to homogeneity. Expression of the tcmM gene in E. coli results mainly in the TcmM apo-ACP, whereas expression in S. glaucescens yields solely the holo-ACP. The purified holo-TcmM is active in a malonyl coenzyme A:ACP transacylase assay and is labeled by radioactive beta-alanine, confirming that it carries a 4'-phosphopantetheine prosthetic group.     

Functional characterization of the acyl-[acyl carrier protein] ligase in the Cryptosporidium parvum giant polyketide synthase

The apicomplexan Cryptosporidium parvum possesses a unique 1500-kDa polyketide synthase (CpPKS1) comprised of 29 enzymes for synthesising a yet undetermined polyketide. This study focuses on the biochemical characterization of the 845-amino acid loading unit containing acyl-[ACP] ligase (AL) and acyl carrier protein (ACP). The CpPKS1-AL domain has a substrate preference for long chain fatty acids, particularly for the C20:0 arachidic acid. When using [3H]palmitic acid and CoA as co-substrates, the AL domain displayed allosteric kinetics towards palmitic acid (Hill coefficient, h=1.46, K50=0.751 microM, Vmax=2.236 micromol mg(-1) min(-1)) and CoA (h=0.704, K50=5.627 microM, Vmax=0.557 micromol mg(-1) min(-1)), and biphasic kinetics towards adenosine 5'-triphosphate (Km1=3.149 microM, Vmax1=373.3 nmol mg(-1) min(-1), Km2=121.0 microM, and Vmax2=563.7 nmol mg(-1) min(-1)). The AL domain is Mg2+-dependent and its activity could be inhibited by triacsin C (IC50=6.64 microM). Furthermore, the ACP domain within the loading unit could be activated by the C. parvum surfactin production element-type phosphopantetheinyl transferase. After attachment of the fatty acid substrate to the AL domain for conversion into the fatty-acyl intermediate, the AL domain is able to transfer palmitic acid to the activated holo-ACP in vitro. These observations ultimately validate the function of the CpPKS1-AL-ACP unit, and make it possible to further dissect the function of this megasynthase using recombinant proteins in a stepwise procedure.     

Biochemical analysis of the substrate specificity of the beta-ketoacyl-acyl carrier protein synthase domain of module 2 of the erythromycin polyketide synthase

The beta-ketoacyl-acyl carrier protein synthase (KS) domain of the modular 6-deoxyerythronolide B synthase (DEBS) catalyzes the fundamental chain building reaction of polyketide biosynthesis. The KS-catalyzed reaction involves two discrete steps consisting of formation of an acyl-enzyme intermediate generated from the incoming acylthioester substrate and an active site cysteine residue, and the conversion of this intermediate to the beta-ketoacyl-acyl carrier protein product by a decarboxylative condensation with a paired methylmalonyl-SACP. We have determined the rate constants for the individual biochemical steps by a combination of protein acylation and transthioesterification experiments. The first-order rate constant (k(2)) for formation of the acyl-enzyme intermediate from [1-(14)C]-(2S,3R)-2-methyl-3-hydroxypentanoyl-SNAC (2) and recombinant DEBS module 2 is 5.8 +/- 2.6 min(-)(1), with a dissociation constant (K(S)) of 3.5 +/- 2.8 mM. The acyl-enzyme adduct was formed at a near-stoichiometric ratio of approximately 0.8:1. Transthioesterification between unlabeled diketide-SNAC 2 and N-[1-(14)C-acetyl]cysteamine gave a k(exch) of 0.15 +/- 0.06 min(-)(1), with a K(m) for HSNAC of 5.7 +/- 4.9 mM and a K(m) for 2 of 5.3 +/- 0.9 mM. Under the conditions that were used, k(exch) was equal to k(-)(2), the first-order rate constant for reversal of the acyl-enzyme-forming reaction. Since the rate of the decarboxylative condensation is much greater that the rate of reversion to the starting material (k(3) > k(-)(2)), formation of the acyl-enzyme adduct is effectively irreversible, thereby establishing that the observed value of the specificity constant (k(cat)/K(m)) is solely a reflection of the intrinsic substrate specificity of the KS-catalyzed acyl-enzyme-forming reaction. These findings were also extended to a panel of diketide- and triketide-SNAC analogues, revealing that some substrate analogues that are not converted to product by DEBS module 2 form dead-end acyl-enzyme intermediates.     

Solution structure and proposed domain domain recognition interface of an acyl carrier protein domain from a modular polyketide synthase

Polyketides are a medicinally important class of natural products. The architecture of modular polyketide synthases (PKSs), composed of multiple covalently linked domains grouped into modules, provides an attractive framework for engineering novel polyketide-producing assemblies. However, impaired domain-domain interactions can compromise the efficiency of engineered polyketide biosynthesis. To facilitate the study of these domain-domain interactions, we have used nuclear magnetic resonance (NMR) spectroscopy to determine the first solution structure of an acyl carrier protein (ACP) domain from a modular PKS, 6-deoxyerythronolide B synthase (DEBS). The tertiary fold of this 10-kD domain is a three-helical bundle; an additional short helix in the second loop also contributes to the core helical packing. Superposition of residues 14-94 of the ensemble on the mean structure yields an average atomic RMSD of 0.64 +/- 0.09 Angstrom for the backbone atoms (1.21 +/- 0.13 Angstrom for all non-hydrogen atoms). The three major helices superimpose with a backbone RMSD of 0.48 +/- 0.10 Angstrom (0.99 +/- 0.11 Angstrom for non-hydrogen atoms). Based on this solution structure, homology models were constructed for five other DEBS ACP domains. Comparison of their steric and electrostatic surfaces at the putative interaction interface (centered on helix II) suggests a model for protein-protein recognition of ACP domains, consistent with the previously observed specificity. Site-directed mutagenesis experiments indicate that two of the identified residues influence the specificity of ACP recognition.     

Functional analysis of putative beta-ketoacyl:acyl carrier protein synthase and acyltransferase active site motifs in a type II polyketide synthase of Streptomyces glaucescens.

The significance of potential active site motifs for acyltransferase and beta-ketoacyl:acyl carrier protein synthase regions within the TcmK protein was investigated by determining the effects of mutations in the proposed active sites on the production of tetracenomycins F2 and C. In a Streptomyces glaucescens tcmGHI JKLMNO null mutant, plasmids carrying the S351A mutation produced high amounts of tetracenomycin F2 but plasmids carrying the C173A or C173S mutation or the H350L-S351A double mutation produced no detectable amount of any known intermediate. In a tcmK mutant, plasmids with the S351A mutation restored high production of tetracenomycin C and plasmids carrying the other mutations were able to complement the chromosomal defect to some extent. None of the mutations affected the amount of TcmK produced.     

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.     

A conformational switch from a closed apo- to an open holo-form equips the acyl carrier protein for acyl chain accommodation

Acyl carrier proteins (ACPs) play crucial roles in the biosynthesis of fatty acids, non-ribosomal polypeptides and polyketides. The three-dimensional NMR structure of Leishmania major holo-LmACP, belonging to the type II pathway, has been reported previously, but the structure of its apo-form and its conformational differences with the holo-form remain to be explored. Here we report the crystal structures of apo-LmACP (wild-type and S37A mutant) at 2.0 Å resolution and compare their key features with the structures of holo-LmACP (wild-type) and other type II ACPs from Escherichia coli and Plasmodium falciparum. The crystal structure of apo-LmACP, which is homologous to other type II ACPs, displays some key structural rearrangements as compared to its holo-structure. Contrary to holo-form, which exists predominantly as a monomer, the apo-form exists as a mixture of monomeric and dimeric population in solution. In contrast to the closed structure of apo-LmACP, holo-LmACP structure was observed in an open conformation as a result of reorganization of specific helices and loops. We propose that the structural changes exhibited by LmACP occur due to the attachment of the phosphopantetheine arm and may be a prerequisite for the initiation of fatty acid synthesis. The movement of helix 3 may also play a role in the dissociation of holo-LmACP from its cognate enzymes of the FAS II pathway.     

Ketosynthases in the initiation and elongation modules of aromatic polyketide synthases have orthogonal acyl carrier protein specificity

Many bacterial aromatic polyketides are synthesized by type II polyketide synthases (PKSs) which minimally consist of a ketosynthase-chain length factor (KS-CLF) heterodimer, an acyl carrier protein (ACP), and a malonyl-CoA:ACP transacylase (MAT). This minimal PKS initiates polyketide biosynthesis by decarboxylation of malonyl-ACP, which is catalyzed by the KS-CLF complex and leads to incorporation of an acetate starter unit. In non-acetate-primed PKSs, such as the frenolicin (fren) PKS and the R1128 PKS, decarboxylative priming is suppressed in favor of chain initiation with alternative acyl groups. Elucidation of these unusual priming pathways could lead to the engineered biosynthesis of polyketides containing novel starter units. Unique to some non-acetate-primed PKSs is a second catalytic module comprised of a dedicated homodimeric KS, an additional ACP, and a MAT. This initiation module is responsible for starter-unit selection and catalysis of the first chain elongation step. To elucidate the protein-protein recognition features of this dissociated multimodular PKS system, we expressed and purified two priming and two elongation KSs, a set of six ACPs from diverse sources, and a MAT. In the presence of the MAT, each ACP was labeled with malonyl-CoA rapidly. In the presence of a KS-CLF and MAT, all ACPs from minimal PKSs supported polyketide synthesis at comparable rates (k(cat) between 0.17 and 0.37 min(-1)), whereas PKS activity was attenuated by at least 50-fold in the presence of an ACP from an initiation module. In contrast, the opposite specificity pattern was observed with priming KSs: while ACPs from initiation modules were good substrates, ACPs from minimal PKSs were significantly poorer substrates. Our results show that KS-CLF and KSIII recognize orthogonal sets of ACPs, and the additional ACP is indispensable for the incorporation of non-acetate primer units. Sequence alignments of the two classes of ACPs identified a tyrosine residue that is unique to priming ACPs. Site-directed mutagenesis of this amino acid in the initiation and elongation module ACPs of the R1128 PKS confirmed the importance of this residue in modulating interactions between KSs and ACPs. Our study provides new biochemical insights into unusual chain initiation mechanisms of bacterial aromatic PKSs.     

The multifunctional polypeptide chain of rabbit mammary fatty acid synthase contains a domain homologous with the acyl carrier protein of Escherichia coli

The phosphopantetheine thiol of rabbit mammary fatty acid synthase was specifically alkylated using chloro[14C]acetyl-CoA and a radioactive fragment generated by limited elastase digestion of the modified protein was purified by gel filtration. We have previously mapped this fragment to an internal location in the 250 000-Mr polypeptide adjacent to the thioesterase domain [Eur. J. Biochem. 130, 185-193 (1983)]. The purified fragment had apparent molecular weights of 23 000 by gel filtration and 10 000 by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate, while amino acid analysis indicated a minimal molecular weight of 10 400. We have determined the amino acid sequence of the first 64 residues of the fragment. The phosphopantetheine moiety is esterified to a serine at residue 38 in the sequence. When the sequences of the rabbit acyl carrier fragment and the 8847-Mr acyl carrier protein of Escherichia coli are aligned, 17 out of 64 residues are identical. These results suggest that the limited proteolysis delineates an internal acyl carrier domain within the rabbit protein and provide the first clear evidence that multifunctional fatty acid synthases have arisen by fusion of ancestral monofunctional proteins.     

Engineered biosynthesis of a novel amidated polyketide, using the malonamyl-specific initiation module from the oxytetracycline polyketide synthase

Tetracyclines are aromatic polyketides biosynthesized by bacterial type II polyketide synthases (PKSs). Understanding the biochemistry of tetracycline PKSs is an important step toward the rational and combinatorial manipulation of tetracycline biosynthesis. To this end, we have sequenced the gene cluster of oxytetracycline (oxy and otc genes) PKS genes from Streptomyces rimosus. Sequence analysis revealed a total of 21 genes between the otrA and otrB resistance genes. We hypothesized that an amidotransferase, OxyD, synthesizes the malonamate starter unit that is a universal building block for tetracycline compounds. In vivo reconstitution using strain CH999 revealed that the minimal PKS and OxyD are necessary and sufficient for the biosynthesis of amidated polyketides. A novel alkaloid (WJ35, or compound 2) was synthesized as the major product when the oxy-encoded minimal PKS, the C-9 ketoreductase (OxyJ), and OxyD were coexpressed in CH999. WJ35 is an isoquinolone compound derived from an amidated decaketide backbone and cyclized with novel regioselectivity. The expression of OxyD with a heterologous minimal PKS did not afford similarly amidated polyketides, suggesting that the oxy-encoded minimal PKS possesses novel starter unit specificity.     

Structure of the mitochondrial beta-ketoacyl-[acyl carrier protein] synthase from Arabidopsis and its role in fatty acid synthesis

Mitochondrial fatty acid synthesis is catalyzed by a dissociated fatty acid synthase similar to those of plant plastids and bacteria. The crystal structure of a mitochondrial beta-ketoacyl-[acyl carrier protein] synthase (mtKAS), namely that from Arabidopsis thaliana, has been determined for the first time. This enzyme accomplishes the vital condensation steps in constructing fatty acid carbon skeletons. The product profile of mtKAS is unusual in that C8 and C(14-16) fatty acyl chains predominate. An enzyme architecture that likely is the basis for the observed bimodal profile of mtKAS products can be derived from the shape of the acyl binding pocket.     

An approach to the semisynthesis of acyl carrier protein

A scheme has been devised for the preparation of semisynthetic derivatives of acyl carrier protein (ACP). Acetylated synthetic ACP_1–6 is coupled via its activated pentachlorophenol ester to native ACP (7–77), which had previously been acetylated and converted to the S-5′-dithiobis(2-nitrobenzoate)(DTNB) derivative. Removal of the DTNB moiety after the coupling yielded active ACP in good yield.     

Holo-(acyl carrier protein) synthase and phosphopantetheinyl transfer in Escherichia coli

Holo-(acyl carrier protein) synthase (AcpS) post-translationally modifies apoacyl carrier protein (apoACP) via transfer of 4'-phosphopantetheine from coenzyme A (CoA) to the conserved serine 36 gamma-OH of apoACP. The resulting holo-acyl carrier protein (holo-ACP) is then active as the central coenzyme of fatty acid biosynthesis. The acpS gene has previously been identified and shown to be essential for Escherichia coli growth. Earlier mutagenic studies isolated the E. coli MP4 strain, whose elevated growth requirement for CoA was ascribed to a deficiency in holoACP synthesis. Sequencing of the acpS gene from the E. coli MP4 strain (denoted acpS1) showed that the AcpS1 protein contains a G4D mutation. AcpS1 exhibited a approximately 5-fold reduction in its catalytic efficiency when compared with wild type AcpS, accounting for the E. coli MP4 strain phenotype. It is shown that a conditional acpS mutant accumulates apoACP in vivo under nonpermissive conditions in a manner similar to the E. coli MP4 strain. In addition, it is demonstrated that the gene product, YhhU, of a previously identified E. coli open reading frame can completely suppress the acpS conditional, lethal phenotype upon overexpression of the protein, suggesting that YhhU may be involved in an alternative pathway for phosphopantetheinyl transfer and holoACP synthesis in E. coli.     

Structure elucidation of Sch 538415, a novel acyl carrier protein synthase inhibitor from a microorganism

A novel acyl carrier protein synthase inhibitor, Sch 538415 (1), was isolated from an unidentified bacterial microbe. Structure elucidation of 1 was accomplished based on analysis of spectroscopic data including UV, MS and 2D-NMR spectra. Compound 1 exhibited inhibitory activity in the acyl carrier protein synthase (AcpS) assay with an IC(50) value of 4.19 microM and showed antibacterial activity against Staphylococcus aureus in the agar diffusion assay.