Evidence for positive selection acting on microcystin synthetase adenylation domains in three cyanobacterial genera

Background  

Cyanobacteria produce a wealth of secondary metabolites, including the group of small cyclic heptapeptide hepatotoxins that constitutes the microcystin family. The enzyme complex that directs the biosynthesis of microcystin is encoded in a single large gene cluster (mcy). mcy genes have a widespread distribution among cyanobacteria and are likely to have an ancient origin. The notable diversity within some of the Mcy modules is generated through various recombination events including horizontal gene transfer.     

Variability of the microcystin synthetase gene cluster in the genus Planktothrix (Oscillatoriales, Cyanobacteria)

In populations of Planktothrix, microcystin-producers and non-producers, which are morphologically identical, coexist. In order to develop a basis for the reliable detection of microcystin producers in field samples with polymerase chain reaction (PCR) based methods, we studied the presence and variability of eight regions of the mcy gene cluster in 46 Planktothrix strains, including both microcystin-producing and non-producing ones. PCR-amplification products for two mcy gene regions were also found in non-microcystin-producing strains, indicating the existence of natural mutants. PCR-products of the other regions studied were only detected in microcystin-producing strains. Two of these mcy-amplicons were variable in sequence and length. Four gene regions remained that were conserved and specific for microcystin-producing Planktothrix strains, and thus qualified to detect the respective chemotypes in environmental samples.     

Selectivity of the yersiniabactin synthetase adenylation domain in the two-step process of amino acid activation and transfer to a holo-carrier protein domain

The adenylation (A) domain of the Yersinia pestis nonribosomal peptide synthetase that biosynthesizes the siderophore yersiniabactin (Ybt) activates three molecules of L-cysteine and covalently aminoacylates the phosphopantetheinyl (P-pant) thiols on three peptidyl carrier protein (PCP) domains embedded in the two synthetase subunits, two in cis (PCP1, PCP2) in subunit HMWP2 and one in trans (PCP3) in subunit HMWP1. This two-step process of activation and loading by the A domain is analogous to the operation of the aminoacyl-tRNA synthetases in ribosomal peptide synthesis. Adenylation domain specificity for the first step of reversible aminoacyl adenylate formation was assessed with the amino acid-dependent [(32)P]-PP(i)-ATP exchange assay to show that S-2-aminobutyrate and beta-chloro-L-alanine were alternate substrates. The second step of A domain catalysis, capture of the bound aminoacyl adenylate by the P-pant-SH of the PCP domains, was assayed both by catalytic release of PP(i) and by covalent aminoacylation of radiolabeled substrates on either the PCP1 fragment of HMWP2 or the PCP3-thioesterase double domain fragment of HMWP1. There was little selectivity for capture of each of the three adenylates by PCP3 in the second step, arguing against any hydrolytic proofreading of incorrect substrates by the A domain. The holo-PCP3 domain accelerated PP(i) release and catalytic turnover by 100-200-fold over the leak rate (<1 min(-1)) of aminoacyl adenylates into solution while PCP1 in trans had only about a 5-fold effect. Free pantetheine could capture cysteinyl adenylate with a 25-50-fold increase in k(cat) while CoA was 10-fold less effective. The K(m) of free pantetheine (30-50 mM) was 3 orders of magnitude larger than that of PCP3-TE (10-25 microM), indicating a net 10(4) greater catalytic efficiency for transfer to the P-pant arm of PCP3 by the Ybt synthetase A domain, relative to P-pant alone.     

Site-directed modification of the adenylation domain of the fusaricidin nonribosomal peptide synthetase for enhanced production of fusaricidin analogs

Fusaricidins produced by Paenibacillus polymyxa DBB1709 are lipopeptide antibiotics active against fungi and Gram-positive bacteria. The cyclic hexapeptide structures of fusaricidins are synthesized by fusaricidin synthetase, a non-ribosomal peptide synthetase. The adenylation domain of the third module (FusA-A3) can recruit L: -Tyr, L: -Val, L: -Ile, L: -allo-Ile, or L: -Phe, which diversifies the fusaricidin structures. Since the L: -Phe-incorporated fusaricidin analog (LI-F07) exhibits more potent antimicrobial activity than other analogs, we modified a specificity-conferring sequence in the substrate binding pocket of FusA-A3 to direct the enhanced production of LI-F07. Base on comparison to the adenylation domain of gramicidin S synthetase 1 and tyrocidine synthetase 1, both of which mainly activate L: -Phe, six mutant strains with altered FusA-A3 were generated using site-directed mutagenesis. M3 (I239W, I299V), M5 (I299V, G322A, V330I), and M6 (S239W, I299V, G322A, V330I) mutants produced significantly more LI-F07 than the wild-type strain.     

Relationship between activating and editing functions of the adenylation domain of apo-tyrocidin synthetase 1 (apo-TY1)

Tyrocidine synthetase 1 (TY1), the initial monomodular constituent of the tyrocidine biosynthetic system, exhibits relaxed substrate specificity, however an efficient editing of the mis-activated amino acid provides for fidelity of product formation. We chose to analyse the consequence of single amino acid substitutions, in the amino acid activation site of apo-TY1, on the editing functions of the enzyme. Discrimination between L-Phe and D-Phe by apo-TY1 depends primarily on the editing reaction. Distraction of unnatural amino acid substrates, such as L-PheSer, implies that editing is not designated to select a specific mis-activated amino acid, but instead to discriminate all mis-activated amino acid analogues. It was shown that active site residues which interact with the adenylate are essential for both activation and editing. Substitution of Lys186 with arginine substantially reduces the editing capacity of the protein. Loss of amino acid discrimination ability by the apo-K186T and apo-R416T mutant proteins suggests a role of active site residues in maintaining the structural determinants for substrate selection. Inadequate conformational changes, induced by non-cognate amino acid substrates, promote ATP breakdown yielding P(i) and ADP. Replacement of residue Lys186 or Arg416 enhances ATP hydrolysis implying a role in binding or adjusting of the triphosphate chain for adenylate formation and pyrophosphate cleavage.     

Natural variation in the microcystin synthetase operon mcyABC and impact on microcystin production in Microcystis strains

Toxic Microcystis strains often produce several isoforms of the cyclic hepatotoxin microcystin, and more than 65 isoforms are known. This has been attributed to relaxed substrate specificity of the adenylation domain. Our results show that in addition to this, variability is also caused by genetic variation in the microcystin synthetase genes. Genetic characterization of a region of the adenylation domain in module mcyB1 resulted in identification of two groups of genetic variants in closely related Microcystis strains. Sequence analyses suggested that the genetic variation is due to recombination events between mcyB1 and the corresponding domains in mcyC. Each variant could be correlated to a particular microcystin isoform profile, as identified by matrix-assisted laser desorption ionization-time of flight mass spectrometry. Among the Microcystis species studied, we found 11 strains containing different variants of the mcyABC gene cluster and 7 strains lacking the genes. Furthermore, there is no concordance between the phylogenies generated with mcyB1, 16S ribosomal DNA, and DNA fingerprinting. Collectively, these results suggest that recombination between imperfect repeats, gene loss, and horizontal gene transfer can explain the distribution and variation within the mcyABC operon.     

Fur from Microcystis aeruginosa binds in vitro promoter regions of the microcystin biosynthesis gene cluster

Promoter regions of the mcy operon from Microcystis aeruginosa PCC7806, which is responsible for microcystin synthesis in this organism, exhibit sequences that are similar to the sequences recognized by Fur (ferric uptake regulator). This DNA-binding protein is a sensor of iron availability and oxidative stress. In the presence of Fe(2+), a dimer of Fur binds the iron-boxes in their target genes, repressing their expression. When iron is absent the expression of those gene products is allowed. Here, we show that Fur from M. aeruginosa binds in vitro promoter regions of several mcy genes, which suggests that Fur might regulate, among other factors, microcystin synthesis. The binding affinity is increased by the presence of metal and DTT, suggesting a response to iron availability and redox status of the cell.     

Diversity of and selection acting on cylindrospermopsin cyrB gene adenylation domain sequences in Florida

Aphanizomenon ovalisporum is the only confirmed cylindrospermopsin producer identified in the United States to date. On the other hand, Cylindrospermopsis raciborskii is a prominent feature of many lakes in Florida and other regions of the United States. To see the variation in cylindrospermopsin cyrB gene adenylation domain sequences and possibly discover new cylindrospermopsin producers, we collected water samples for a 3-year period from 17 different systems in Florida. Positive amplicons were cloned and sequenced, revealing that approximately 92% of sequences were A. ovalisporum-like (>99% identity). Interestingly, 6% of sequences were very similar (>99% identity) to cyrB sequences of C. raciborskii from Australia and of Aphanizomenon sp. from Germany. Neutrality tests suggest that A. ovalisporum-like cyrB adenylation domain sequences are under purifying selection, with abundant low-frequency polymorphisms within the population. On the other hand, when compared between species by codon-based methods, amino acids of CyrB also seem to be under purifying selection, in accordance with the one proposed amino acid thought to be activated by the CyrB adenylation domain.     

Polyketide synthase gene coupled to the peptide synthetase module involved in the biosynthesis of the cyclic heptapeptide microcystin

The peptide synthetase gene operon, which consists of mcyA, mcyB, and mcyC, for the activation and incorporation of the five amino acid constituents of microcystin has been identified [T. Nishizawa et al. (1999) J. Biochem. 126, 520-529]. By sequencing an additional 34 kb of DNA from microcystin-producing Microcystis aeruginosa K-139, we identified the residual microcystin synthetase gene operon, which consists of mcyD, mcyE, mcyF, and mcyG, in the opposite orientation to the mcyABC operon. McyD consisted of two polyketide synthase modules, and McyE contained a polyketide synthase module at the N-terminus and a peptide synthetase module at the C-terminus. McyF was found to exhibit similarity to amino acid racemase. McyG consisted of a peptide synthetase module at the N-terminus and a polyketide synthase at the C-terminus. The microcystin synthetase gene cluster was conserved in another microcystin-producing strain, Microcystis sp. S-70, which produces Microcystin-LR, -RR, and -YR. Insertional mutagenesis of mcyA, mcyD, or mcyE in Microcystis sp. S-70 abolished microcystin production. In conclusion, the mcyDEFG operon is presumed to be responsible for 3-amino-9-methoxy-2,6, 8-trimethyl-10-phenyldeca-4,6-dienoic acid (Adda) biosynthesis, and the incorporation of Adda and glutamic acid into the microcystin molecule.     

Active site of lysyl-tRNA synthetase: structural studies of the adenylation reaction

Aminoacyl-tRNA synthetases play a key role in protein biosynthesis by catalyzing the specific aminoacylation of tRNA. The energy required for the formation of the ester bond between the amino acid carboxylate group and the tRNA acceptor stem is supplied by coupling the reaction to the hydrolysis of ATP. Lysyl-tRNA synthetase from Escherichia coli belongs to the family of class II synthetases and carries out a two-step reaction, in which lysine is activated by being attached to the alpha-phosphate of AMP before being transferred to the cognate tRNA. Crystals of the thermo-inducible E. coli lysyl-tRNA synthetase LysU which diffract to 2.1 A resolution have been used to determine crystal structures of the enzyme in the presence of lysine, the lysyl-adenylate intermediate, and the nonhydrolyzable ATP analogue AMP-PCP. Additional data have been obtained from crystals soaked in a solution containing ATP and Mn(2+). The refined crystal structures give "snapshots" of the active site corresponding to key steps in the aminoacylation reaction and provide the structural framework for understanding the mechanism of lysine activation. The active site of LysU is shaped to position the substrates for the nucleophilic attack of the lysine carboxylate on the ATP alpha-phosphate. No residues are directly involved in catalysis, but a number of highly conserved amino acids and three metal ions coordinate the substrates and stabilize the pentavalent transition state. A loop close to the catalytic pocket, disordered in the lysine-bound structure, becomes ordered upon adenine binding.     

A stand-alone adenylation domain forms amide bonds in streptothricin biosynthesis

The streptothricin (ST) antibiotics, produced by Streptomyces bacteria, contain L-β-lysine ((3S)-3,6-diaminohexanoic acid) oligopeptides as pendant chains. Here we describe three unusual nonribosomal peptide synthetases (NRPSs) involved in ST biosynthesis: ORF 5 (a stand-alone adenylation (A) domain), ORF 18 (containing thiolation (T) and condensation (C) domains) and ORF 19 (a stand-alone A domain). We demonstrate that ST biosynthesis begins with adenylation of L-β-lysine by ORF 5, followed by transfer to the T domain of ORF 18. In contrast, L-β-lysine molecules adenylated by ORF 19 are used to elongate an L-β-lysine peptide chain on ORF 18, a reaction unexpectedly catalyzed by ORF 19 itself. Finally, the C domain of ORF 18 catalyzes the condensation of L-β-lysine oligopeptides covalently bound to ORF 18 with a freely diffusible intermediate to release the ST products. These results highlight an unusual activity for an A domain and unique mechanisms of crosstalk within NRPS machinery.     

非核糖体肽合成酶缩合结构域基因片段克隆

从大连渤海海域筛选出1株放线菌L1,结合形态观察、生理生化实验和16S rDNA分子鉴定,确定L1属于链霉菌属球孢链霉菌(Streptomyces globisporus)。根据GenBank发布的非核糖体肽合成酶(NRPS)序列设计引物,从放线菌L1的基因组DNA中扩增获得NRPS基因片段。测序结果及比对分析表明该片段属于NRPS缩合结构域部分序列。三维建模显示其结构呈V型,包含缩合结构域核心序列,与数据库已知结构相一致,可以推断该克隆片段为NRPS缩合结构域基因片段,为后续深入研究缩合结构域特异性与相关NRPS功能提供基础。     

全细胞多重PCR检测蓝藻、微囊藻及产毒微囊藻方法初探

选取三对分别针对微囊藻、蓝藻16S rDNA及微囊藻毒素合成酶基因mcyB的保守序列的特异性引物209F/409R、27F1/409R、MTR/MTF,其中409R为一条共用引物。设计并优化了一种可以同时检测蓝藻和微囊藻的两重全细胞PCR方法和一种可以同时检测蓝藻、微囊藻和可产毒微囊藻的三重全细胞PCR方法,并且测试了这两种PCR反应的灵敏度区间,分别为10⁵～10³cell·mL^-1、10⁵～10²cell·mL^-1。对采集水库水样检测结果表明双重全细胞PCR方法可以直接应用于对天然水样的检测,三重全细胞PCR方法可用于实验室培养藻细胞的筛查。全细胞多重PCR方法具有快速、简便、准确等特点,在水体微囊藻毒素检测预警方面具有应用价值。     

Quantification of toxigenic Microcystis spp. in freshwaters by quantitative real-time PCR based on the microcystin synthetase A gene

A method to estimate the abundance of toxigenic Microcystis in environmental samples by using quantitative real-time PCR was developed and optimized. The basis of this method is the amplification of a highly conserved region of the mcyA gene within the microcystin synthetase gene cluster. Using this method, the average copy number of mcyA gene per cell in toxigenic Microcystis strains was estimated. The molecular markers and method developed in this study can be used to monitor toxigenic strains of Microcystis in Korean freshwaters, in which harmful cyanobacterial blooms are routinely found.     

Estimating toxic cyanobacteria in a Brazilian reservoir by quantitative real-time PCR, based on the microcystin synthetase D gene

The production of microcystin toxins by cyanobacteria is an intrapopulation feature and the toxic and nontoxic genotypes can be separated only through molecular analyses targeting the mcy markers. Quantitative real-time PCR (qPCR) is a procedure that has been established, not only to detect but to specifically quantify these genotypes. In the present work, primers were designed for the mcyD region to estimate the number of cyanobacteria that are potential microcystin producers. Laboratory tests to verify the efficiency and the specificity of the primers were performed. The methodology was first established for single strain cultures and thereafter was applied in environmental water samples, from a reservoir located in the Brazilian savannah (“cerrado”). The results were very satisfactory, demonstrating the high efficiency and the specificity of the primers used, and their ability to detect different cyanobacteria genera. Of particular interest were the results showing a high proportion of toxic strains (as high as 100 %) in the environmental samples, as previously reported in another tropical system. Furthermore, the occurrence of a smaller fraction of toxic strains at high cyanobacteria densities, and of more toxic populations when fewer cyanobacteria were present, deserves further investigation. Although records of cyanobacteria blooms are very common in the tropics and suggest an increasing incidence of toxic populations, the present research is one of the few applying qPCR in a tropical environment. The results obtained here, by a technique that allows a more precise quantification and in situ follow-up of changes in toxicity, will make possible new observations of seasonal and spatial dynamics in these environments.     

The pur6 gene of the puromycin biosynthetic gene cluster from Streptomyces alboniger encodes a tyrosinyl-aminonucleoside synthetase

The pur6 gene of the puromycin biosynthetic gene (pur) cluster from Streptomyces alboniger is shown to be essential for puromycin biosynthesis. Cell lysates from this mycelial bacterium were active in linking L-tyrosine to both 3'-amino-3'-deoxyadenosine and N6,N6-dimethyl-3'-amino-3'-deoxyadenosine with a peptide-like bond. Identical reactions were performed by cell lysates from Streptomyces lividans or Escherichia coli transformants that expressed pur6 from a variety of plasmid constructs. Physicochemical and biochemical analyses suggested that their products were tridemethyl puromycin and O-demethylpuromycin, respectively. Therefore, it appears that Pur6 is the tyrosinyl-aminonucleoside synthetase of the puromycin biosynthetic pathway.