Ogasawara Yasushi, Dairi Tohru
Graduate School of Engineering, Hokkaido University, Sapporo, Japan.
Front Microbiol. 2018 Feb 6;9:156. doi: 10.3389/fmicb.2018.00156. eCollection 2018.
D-Amino acid residues have been identified in peptides from a variety of eukaryotes and prokaryotes. In microorganisms, UDP--acetylmuramic acid pentapeptide (UDP-MurNAc-L-Ala-D-Glu-meso-diaminopimelate-D-Ala-D-Ala), a unit of peptidoglycan, is a representative. During its biosynthesis, D-Ala and D-Glu are generally supplied by racemases from the corresponding isomers. However, we recently identified a unique unidirectional L-Glu epimerase catalyzing the epimerization of the terminal L-Glu of UDP-MurNAc-L-Ala-L-Glu. Several such enzymes, introducing D-amino acid resides into peptides via epimerization, have been reported to date. This includes a L-Ala-D/L-Glu epimerase, which is possibly used during peptidoglycan degradation. In bacterial primary metabolisms, to the best of our knowledge, these two machineries are the only examples of peptide epimerization. However, a variety of peptides containing D-amino acid residues have been isolated from microorganisms as secondary metabolites. Their biosynthetic mechanisms have been studied and three different peptide epimerization machineries have been reported. The first is non-ribosomal peptide synthetase (NRPS). Excellent studies with dissected modules of gramicidin synthetase and tyrocidine synthetase revealed the reactions of the epimerization domains embedded in the enzymes. The obtained information is still utilized to predict epimerization domains in uncharacterized NRPSs. The second includes the biosynthetic enzymes of lantibiotics, which are ribosome-dependently supplied peptide antibiotics containing polycyclic thioether amino acids (lanthionines). A mechanism for the formation of the D-Ala moiety in lanthionine by two enzymes, dehydratases catalyzing the conversion of L-Ser into dehydroalanine and enzymes catalyzing nucleophilic attack of the thiol of cysteine into dehydroalanine, was clarified. Similarly, the formation of a D-Ala residue by reduction of the dehydroalanine residue was also reported. The last type of machinery includes radical--adenosylmethionine (rSAM)-dependent enzymes, which catalyze a variety of radical-mediated chemical transformations. In the biosynthesis of polytheonamide, a marine sponge-derived and ribosome-dependently supplied peptide composed of 48 amino acids, a rSAM enzyme (PoyD) is responsible for unidirectional epimerizations of multiple different amino acids in the precursor peptide. In this review, we briefly summarize the discovery and current mechanistic understanding of these peptide epimerization enzymes.
在来自各种真核生物和原核生物的肽中已鉴定出D-氨基酸残基。在微生物中,肽聚糖的一个单元——UDP-N-乙酰胞壁酸五肽(UDP-MurNAc-L-Ala-D-Glu-内消旋二氨基庚二酸-D-Ala-D-Ala)就是一个代表。在其生物合成过程中,D-Ala和D-Glu通常由消旋酶从相应的异构体提供。然而,我们最近鉴定出一种独特的单向L-Glu差向异构酶,它催化UDP-MurNAc-L-Ala-L-Glu末端L-Glu的差向异构化。迄今为止,已经报道了几种通过差向异构化将D-氨基酸残基引入肽中的此类酶。这包括一种L-Ala-D/L-Glu差向异构酶,它可能在肽聚糖降解过程中发挥作用。据我们所知,在细菌的初级代谢中,这两种机制是肽差向异构化的唯一例子。然而,已经从微生物中分离出多种含有D-氨基酸残基的肽作为次级代谢产物。它们的生物合成机制已经得到研究,并且已经报道了三种不同的肽差向异构化机制。第一种是非核糖体肽合成酶(NRPS)。对短杆菌肽合成酶和短杆菌酪肽合成酶的剖析模块进行的出色研究揭示了嵌入酶中的差向异构化结构域的反应。所获得的信息仍被用于预测未表征的NRPS中的差向异构化结构域。第二种包括羊毛硫抗生素的生物合成酶,羊毛硫抗生素是一类依赖核糖体供应的肽抗生素,含有多环硫醚氨基酸(羊毛硫氨酸)。已经阐明了两种酶形成羊毛硫氨酸中D-Ala部分的机制,即脱水酶催化L-Ser转化为脱氢丙氨酸,以及酶催化半胱氨酸的硫醇对脱氢丙氨酸进行亲核攻击。同样,也报道了通过还原脱氢丙氨酸残基形成D-Ala残基的过程。最后一种机制包括依赖自由基-腺苷甲硫氨酸(rSAM)的酶,它们催化各种自由基介导的化学转化。在多西环肽的生物合成中,多西环肽是一种源自海洋海绵且依赖核糖体供应的由48个氨基酸组成的肽,一种rSAM酶(PoyD)负责前体肽中多种不同氨基酸的单向差向异构化。在这篇综述中,我们简要总结了这些肽差向异构化酶的发现以及当前对其机制的理解。
