Chitose Maruyama

ε-Poly- L -lysine dispersity is controlled by a highly unusual nonribosomal peptide synthetase

Epsilon-Poly-L-lysine (epsilon-PL) consists of 25-35 L-lysine residues in isopeptide linkages and is one of only two amino acid homopolymers known in nature. Elucidating the biosynthetic mechanism of epsilon-PL should open new avenues for creating novel classes of biopolymers. Here we report the purification of an epsilon-PL synthetase (Pls; 130 kDa) and the cloning of its gene from an epsilon-PL-producing strain of Streptomyces albulus. Pls was found to be a membrane protein with adenylation and thiolation domains characteristic of the nonribosomal peptide synthetases (NRPSs). It had no traditional condensation or thioesterase domain; instead, it had six transmembrane domains surrounding three tandem soluble domains. These tandem domains iteratively catalyzed L-lysine polymerization using free L-lysine polymer (or monomer in the initial reaction) as acceptor and Pls-bound L-lysine as donor, directly yielding chains of diverse length. Thus, Pls is a new single-module NRPS having an amino acid ligase-like catalytic activity for peptide bond formation.

Mechanism of ε-Poly-l-Lysine Production and Accumulation Revealed by Identification and Analysis of an ε-Poly-l-Lysine-Degrading Enzyme

ABSTRACT ε-Poly-l-lysine (ε-PL) is produced by Streptomyces albulus NBRC14147 as a secondary metabolite and can be detected only when the fermentation broth has an acidic pH during the stationary growth phase. Since strain NBRC14147 produces ε-PL-degrading enzymes, the original chain length of the ε-PL polymer product synthesized by ε-PL synthetase (Pls) is unclear. Here, we report on the identification of the gene encoding the ε-PL-degrading enzyme (PldII), which plays a central role in ε-PL degradation in this strain. A knockout mutant of the pldII gene was found to produce an ε-PL of unchanged polymer chain length, demonstrating that the length is not determined by ε-PL-degrading enzymes but rather by Pls itself and that the 25 to 35 l-lysine residues of ε-PL represent the original chain length of the polymer product synthesized by Pls in vivo. Transcriptional analysis of pls and a kinetic study of Pls further suggested that the Pls catalytic function is regulated by intracellular ATP, high levels of which are required for full enzymatic activity. Furthermore, it was found that acidic pH conditions during ε-PL fermentation, rather than the inhibition of the ε-PL-degrading enzyme, are necessary for the accumulation of intracellular ATP.

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.

A peptide ligase and the ribosome cooperate to synthesize the peptide pheganomycin

Peptide antibiotics are typically biosynthesized by one of two distinct machineries in a ribosome-dependent or ribosome-independent manner. Pheganomycin (PGM (1)) and related analogs consist of the nonproteinogenic amino acid (S)-2-(3,5-dihydroxy-4-hydroxymethyl)phenyl-2-guanidinoacetic acid (2) and a proteinogenic core peptide, making their origin uncertain. We report the identification of the biosynthetic gene cluster from Streptomyces cirratus responsible for PGM production. Unexpectedly, the cluster contains a gene encoding multiple precursor peptides along with several genes plausibly encoding enzymes for the synthesis of amino acid 2. We identified PGM1, which has an ATP-grasp domain, as potentially capable of linking the precursor peptides with 2, and validate this hypothesis using deletion mutants and in vitro reconstitution. We document PGM1s substrate permissivity, which could be rationalized by a large binding pocket as confirmed via structural and mutagenesis experiments. This is to our knowledge the first example of cooperative peptide synthesis achieved by ribosomes and peptide ligases using a peptide nucleophile.

Development of a recombinant ε-poly-L-lysine synthetase expression system to perform mutational analysis

ε-Poly-L-lysine (ε-PL) synthetase (Pls), which is a membrane protein with adenylation and thiolation domains characteristic of the nonribosomal peptide synthetases, catalyzes polymerization of L-lysine molecules (25-mer to 35-mer). Here, we report on the development of a recombinant Pls expression system that allowed us to perform a site-directed mutational analysis.

Assay of enzymes forming AMP + PPi by the pyrophosphate determination based on the formation of 18-molybdopyrophosphate

The formation of 18-molybdopyrophosphate anion has been studied to develop a simple and rapid assay of the enzymatic reaction involving ATP→AMP+PPi(P(2)O(7)(4-)). By the addition of P(2)O(7)(4-) anion to an acidic acetonitrile-water solution containing MoO(4)(2-) anion, the colorless Mo(VI) solution immediately became yellow due to the formation of 18-molybdopyrophosphate anion. The absorbance of the P(2)O(7)(4-)-Mo(VI) mixture at, for example, 450nm was proportional to the analytical concentration of P(2)O(7)(4-) anion. Although the test Mo(VI) solution remained colorless by the addition of AMP, it gradually turned to yellow by ATP. The undesired color development is attributed to the formation of a yellow molybdophosphate species accompanied by the dissociation of PO(4)(3-) from the unstable ATP molecule. However, the color development became much slower when ethylenediaminetetraacetic acid was added into an assay mixture, where ATP may form a kinetically stable species. Thus, P(2)O(7)(4-) anion can be determined spectrophotometrically in the enzymatic reaction mixture containing ATP. By the addition of ascorbic acid, the yellow P(2)O(7)(4-)-Mo(VI) mixture turned to blue due to the reduction of the molybdopyrophosphate anion. Thus, P(2)O(7)(4-) anion can be detected colorimetrically by the blueness. The spectrophotometric and colorimetric methods could be applied advantageously to the assay of acetyl-CoA synthetase.

ε-Poly-l-Lysine Peptide Chain Length Regulated by the Linkers Connecting the Transmembrane Domains of ε-Poly-l-Lysine Synthetase

ABSTRACT ε-Poly-l-lysine (ε-PL), consisting of 25 to 35 l-lysine residues with linkages between the α-carboxyl groups and ε-amino groups, is produced by Streptomyces albulus NBRC14147. ε-PL synthetase (Pls) is a membrane protein with six transmembrane domains (TM1 to TM6) as well as both an adenylation domain and a thiolation domain, characteristic of the nonribosomal peptide synthetases. Pls directly generates ε-PL chain length diversity (25- to 35-mer), but the processes that control the chain length of ε-PL during the polymerization reaction are still not fully understood. Here, we report on the identification of Pls amino acid residues involved in the regulation of the ε-PL chain length. From approximately 12,000 variants generated by random mutagenesis, we found 8 Pls variants that produced shorter chains of ε-PL. These variants have one or more mutations in two linker regions connecting the TM1 and TM2 domains and the TM3 and TM4 domains. In the Pls catalytic mechanism, the growing chain of ε-PL is not tethered to the enzyme, implying that the enzyme must hold the growing chain until the polymerization reaction is complete. Our findings reveal that the linker regions are important contributors to grasp the growing chain of ε-PL.

Mutational analysis of the three tandem domains of ε-poly-l-lysine synthetase catalyzing the l-lysine polymerization reaction

ε-Poly-l-lysine (ε-PL) synthetase (Pls) is a nonribosomal peptide synthetase (NRPS)-like enzyme with three tandem domains to catalyze the l-lysine polymerization reaction. Mutational analysis of the three tandem domains demonstrated that the interconnected action of all three domains is essential for the enzyme activity.

Detection of Biopolymer ϵ-poly-L-lysine with Molybdosilicate Anion for Screening of Synthetic Enzymes

ϵ-Poly-L-lysine (ϵ-PL) exists as a cationic polymer in acidic solution. Yellow tetravalent 12-molybdosilicate ([SiMo12O40]4−) anion is formed in acidic solution containing and anions. By mixing the test ϵ-PL solution with the acidic − solution, the [SiMo12O40]4− anion associates with the cationic ϵ-PL to form yellow precipitate. The yellowness of the supernatant decreased with the initial concentration of ϵ-PL in the test solution due to the residual [SiMo12O40]4− anion. By addition of ascorbic acid to the supernatant, the residual [SiMo12O40]4− anion was reduced to blue molybdosilicate species. Thus the concentration of ϵ-PL in sample media can also be estimated by the blueness of the reaction mixture. The present method can be applied successfully to the screening of ϵ-PL-synthetase in culture media.

The biological function of the bacterial isochorismatase-like hydrolase SttH.

The streptothricin hydrolase (SttH), which is a member of the isochorismatase-like hydrolase (ILH) super-family, catalyzes the hydrolysis of the streptolidine lactam group in streptothricin (ST) antibiotics, thereby inactivating them. In this study we identified a novel homologous gene (sttH-sn) and sequenced the flanking regions of the sttH and sttH-sn genes. The organization of genes around the sttH, sttH-sn, and ILH genes revealed that a number of the genes were clustered with genes encoding oxidoreductases with molybdopterin binding subunits, suggesting that the true role of these gene products (SttHs and a number of ILHs) might have to do with the chemical modification of molybdopterin, rather than ST-resistance. In addition, mutant enzymes were constructed in which Ser was substituted for highly conserved Cys-176 and Cys-158 of SttH and SttH-sn respectively, and no enzyme activities were detected. Thus, biochemically, these ILHs were found to be “cysteine hydrolases.”