植物类型Ⅲ聚酮合酶超家族基因结构、功能及代谢产物

植物聚酮类化合物主要包括酚类、芪类及类黄酮化合物等,在植物花色、防止紫外线伤害、预防病原菌、昆虫危害以及作为植物与环境互作信号分子方面行使着重要的生物学功能。该类化合物具有显著多样的生物学活性,对人体保健及疾病治疗有显著意义。植物类型Ⅲ聚酮化合物合酶(PKS)在该类化合物生物合成起始反应中行使着关键作用,决定该类化合物基本分子骨架建成和代谢途径碳硫走向,为合成途径关键酶和限速酶。以查尔酮合酶为原型酶的植物类型Ⅲ PKS超家族是研究系统进化和蛋白结构与功能关系的模式分子家族,目前已经分离得到14种植物类型Ⅲ PKS基因,这些同祖同源基因及其表达产物既有共性,也表现出许多独特个性,这些个性赋予此类次生代谢产物结构上的多样性。以下综述了植物类型Ⅲ PKS超家族基因结构、功能及代谢产物研究进展。     

植物类型III聚酮合酶超家族晶体结构与功能

植物类型Ⅲ聚酮化合物合酶(PKS)催化合成多种植物次生代谢产物的基本分子骨架,参与植物体许多重要生物学功能的行使,一直是研究蛋白结构与功能关系、基于结构进行分子改造的重要模式分子家族。目前在蛋白质数据库(PDB)中有超过80个不同种属来源的类型Ⅲ PKS的三维结构被报道,其中包括了研究最为透彻的查尔酮合酶在内的7种酶的晶体结构,这些结构的发表对于阐明该类酶复杂多变的底物专一性、链延伸和不同的环化反应机制奠定了结构基础。三维空间结构解析以及基于定点突变的结构功能分析是进行酶工程、基因工程的基础。以下系统综述了植物类型Ⅲ PKS超家族晶体结构和功能的研究进展。     

植物Ⅲ型聚酮合酶的分子机制与应用前景

植物III型聚酮合酶能催化生成一系列结构各异、具有不同生理活性、包含查耳酮合酶基本骨架的植物次生代谢产物,这类次生代谢产物不仅使植物体本身的抗逆性提高,并且对人类健康医疗有很好的应用前景。以下综述了近年来从植物中克隆、鉴定III型聚酮合酶的研究进展,着重论述了其分子结构、催化反应的类型和机制、表达调控及其在转基因工程方面的研究和应用前景。这些研究将为有效地对其进行基因改造,合成一些难以化学合成的新型天然化合物奠定基础,并且为将来进一步开展III型聚酮合酶的转基因工程提供了参考。     

虎杖苯亚甲基丙酮合酶PcPKS2的表达纯化和晶体生长

植物类型Ⅲ聚酮合酶超家族(PKSs),又称查尔酮合酶(Chalcone synthase,CHS)超家族,催化合成多种植物次生代谢产物的分子骨架。苯亚甲基丙酮合酶(Benzalacetone synthase,BAS)催化4-香豆酰辅酶A与丙二酰辅酶A通过一步脱羧缩合反应生成苯亚甲基丙酮,是一系列具有重要生物学活性苯丁烷类化合物及其衍生物的前体化合物。前期工作从虎杖中分离出苯亚甲基丙酮合酶BAS(PcPKS2)和1个具有CHS和BAS活性的双功能酶(PcPKS1)。两者与超家族其他成员序列经比较,在包括门卫氨基酸Phe215和Phe265在内的重要氨基酸序列存在一定差异。已有蛋白晶体学研究结果表明,PKSs家族不同成员的功能多样性来自于酶催化位点的非常微小的构象变化。为了能够从结构上比较PcPKS2和Pc PKS1双功能酶活性差异可能产生的机制,以确定其高效BAS活性的分子机理,研究利用了大肠杆菌原核表达系统过量表达了C-端融合有His6标签的重组蛋白,经纯化得到了高纯度蛋白。经过对其晶体生长条件进行摸索和优化,得到了能用于X-射线衍射的单晶,为其结构解析、催化机理研究、了解虎杖聚酮类化合物生物合成机制和该类酶在基因工程中的应用提供了基础。     

草菇聚酮合酶编码基因vv-alb的克隆及其表达的初步分析

聚酮化合物（polyketides）是一类庞大的次级代谢家族,聚酮合酶（polyketide synthase,PKS）是介导聚酮化合物生物合成的关键酶。通过巢氏简并PCR与染色体步行的方法,获得了草菇中的编码PKS的基因vv-alb的全长序列,并通过荧光实时定量RT-PCR方法对vv-alb基因在草菇不同生长阶段与不同部位的表达情况进行了初步分析,为进一步研究PKS在草菇和其他食用真菌生物代谢过程中的作用奠定了一定的基础。     

聚酮类化合物生物合成基因簇与药物筛选

由微生物和植物产生的聚酮类化合物的数量极其庞大,是一大类结构多样化和生物活性多样性的天然产物,已经成为新药的重要来源.介绍了3种类型聚酮类化合物生物合成基因簇的特点,即以模块形式存在的I型聚酮合酶,包含一套可重复使用结构域的Ⅱ型聚酮合酶以及不需要ACP参与,以植物中的查耳酮合酶为代表的Ⅲ型聚酮合酶.同时,还介绍了基于3种类型聚酮类化合物生物合成基因的特点,利用分子生物学方法构建筛选探针,进行当前药物基因筛选的进展.     

真菌聚酮合酶基因分离方法的研究进展

真菌聚酮合酶在代谢中可催化合成多种具有重要生物学活性的次级代谢物,所以真菌聚酮合酶正逐渐成为药学、食品科学和农学等领域的研究热点。本文综述了近五年来建立的几种分离真菌聚酮合酶基因的方法。这些方法解决了真菌中聚酮合酶基因簇难以分离的问题,为改造和利用真菌聚酮合酶以及发掘真菌聚酮化合物资源提供了强有力的手段。     

海洋链霉菌酮合成酶结构域基因的克隆及分析

海洋链霉菌通过聚酮合酶(PKS)合成许多结构和功能多样且具有药用价值的聚酮化合物(PKs),酮合成酶结构域(KS)作为PKS的核心结构域,可催化底物与伸长的聚酮之间的脱羧缩合,在聚酮化合物生物合成中起着重要作用。本文通过对从海洋链霉菌Streptomyces sp. X66基因组DNA克隆获得的ks基因的生物信息学分析表明,该ks基因序列长945 bp, BLAST序列比对显示其具有典型的酮合酶结构域的功能区域。理化分析显示其拟编码309个氨基酸,理论等电点为6.60,原子组成为C₁₄₀₁H₂₂₃₉N₄₂₅O₄₁₉S₈,不稳定指数为42.11,平均亲水系数为0.112,编码产物为酸性疏水不稳定蛋白,且不含信号肽和跨膜结构,二级结构以无规则卷曲和α-螺旋为主,SDS-PAGE显示其分子量约为55 kDa。通过对ks基因的研究,为进一步解析聚酮化合物合成代谢中的调控机制及组合生物学和体外酶系合成聚酮化合物提供参考。     

多不饱和脂肪酸合成途径研究进展

多不饱和脂肪酸在大多数生物体膜生物学和信号传递过程中起着至关重要的作用。最近研究发现,一些深海生物合成多不饱和脂肪酸并非由饱和脂肪酸的延长及脱饱和反应,而是由聚酮合酶途径(polyketide synthase,PKS)直接合成。介绍多不饱和脂肪酸的生物合成并总结近年来聚酮合酶这一新途径及其分子机制的研究进展。     

长松萝中一个聚酮合酶基因簇的克隆和鉴定

【目的】探索药用地衣长松萝(Usnea longissima Ach)聚酮化合物的生物合成基因簇,克隆聚酮合酶(PKS)基因并分析其功能。【方法】以长松萝地衣型真菌为材料,通过巢氏PCR获得聚酮合酶基因片段和原位杂交筛选基因组文库获得聚酮合酶基因及相邻基因簇。并对获得聚酮合酶进行分子系统进化分析和基因表达分析。【结果】获得药用地衣长松萝中的编码聚酮合酶基因UlPKS5的全长序列以及相邻修饰基因β-内酰胺酶和脱水酶。聚酮合酶UlPKS5含有酮体合成酶(KS),酰基转移酶(AT),产物模板(PT)以及酰基载体蛋白(ACP)结构域。分子系统进化分析显示UlPKS5属于非还原型聚酮合酶中第五组,与蒽醌类化合物生物合成相关。通过半定量RT-PCR分析表明山梨醇(10%)和蔗糖(2%和10%)能够强烈诱导UlPKS5基因表达。【结论】聚酮合酶(UlPKS5)及相邻修饰基因β-内酰胺酶和脱水酶与长松萝中蒽醌类化合物生物合成相关。     

Enzymatic formation of an aromatic dodecaketide by engineered plant polyketide synthase

Octaketide synthase (OKS) from Aloe arborescens is a plant-specific type III polyketide synthase (PKS) that catalyzes iterative condensations of eight molecules of malonyl-CoA to produce the C₁₆ aromatic octaketides SEK4 and SEK4b. On the basis of the crystal structures of OKS, the F66L/N222G double mutant was constructed and shown to produce an unnatural dodecaketide TW95a by sequential condensations of 12 molecules of malonyl-CoA. The C₂₄ naphthophenone TW95a is a product of the minimal type II PKS (whiE from Streptomyces coelicolor), and is structurally related to the C₂₀ decaketide benzophenone SEK15, the product of the OKS N222G point mutant. The C₂₄ dodecaketide naphthophenone TW95a is the first and the longest polyketide scaffold generated by a structurally simple type III PKS. A homology model predicted that the active-site cavity volume of the F66L/N222G mutant is increased to 748 Å³, from 652 Å³ of the wild-type OKS. The structure-based engineering thus greatly expanded the catalytic repertoire of the simple type III PKS to further produce larger and more complex polyketide molecules.     

Structural insights into biosynthesis of resorcinolic lipids by a type III polyketide synthase in Neurospora crassa

Microbial type III polyketide synthases (PKSs) have revealed remarkable mechanistic as well as functional versatility. Recently, a type III PKS homolog from Azotobacter has been implicated in the biosynthesis of resorcinolic lipids, thus adding a new functional significance to this class of proteins. Here, we report the structural and mutational investigations of a novel type III PKS protein from Neurospora crassa involved in the biosynthesis of resorcinolic metabolites by utilizing long chain fatty acyl-CoAs. The structure revealed a long hydrophobic tunnel responsible for its fatty acyl chain length specificity resembling that of PKS18, a mycobacterial type III PKS. Structure-based mutational studies to block the tunnel not only altered the fatty acyl chain specificity but also resulted in change of cyclization pattern affecting the product profile. This first structural characterization of a resorcinolic lipid synthase provides insights into the coordinated functioning of cyclization and a substrate-binding pocket, which shows mechanistic intricacy underlying type III PKS catalysis.     

Characterization of His-tagged Rat Uroporphyrinogen III Synthase Wild-Type and Variant Enzymes

The structurally related tetrapyrrolic pigments are a group of natural products that participate in many of the fundamental biosynthetic and catabolic processes of living organisms. Urogen III synthase catalyzes a key step in the formation of urogen III, a common intermediate for tetrapyrrolic natural products. In the present study, we cloned, purified, and characterized His-tagged rat urogen III synthase. The mechanism of enzymatic reaction was studied through site-directed mutagenesis of eight highly conserved residues with functional side chains around the active site followed with activity tests. Lys10, Asp17, Glu68, Tyr97, Asn121, Lys147, and His173 have not been studied previously, which were found to be unessential for enzymatic reaction. Tyr168 was identified as an important residue for enzymatic reaction catalyzed by rat urogen III synthase. Molecular modeling suggests the hydroxyl group of Tyr168 side chain is 3.5 A away from the D ring, and is within hydrogen bond distance (1.9 A) with acetate side chain of the D ring.     

A type III polyketide synthase from Wachendorfia thyrsiflora and its role in diarylheptanoid and phenylphenalenone biosynthesis

Chalcone synthase (CHS) related type III plant polyketide synthases (PKSs) are likely to be involved in the biosynthesis of diarylheptanoids (e.g. curcumin and polycyclic phenylphenalenones), but no such activity has been reported. Root cultures from Wachendorfia thyrsiflora (Haemodoraceae) are a suitable source to search for such enzymes because they synthesize large amounts of phenylphenalenones, but no other products that are known to require CHSs or related enzymes (e.g. flavonoids or stilbenes). A homology-based RT-PCR strategy led to the identification of cDNAs for a type III PKS sharing only approximately 60% identity with typical CHSs. It was named WtPKS1 (W. thyrsiflora polyketide synthase 1). The purified recombinant protein accepted a large variety of aromatic and aliphatic starter CoA esters, including phenylpropionyl- and side-chain unsaturated phenylpropanoid-CoAs. The simplest model for the initial reaction in diarylheptanoid biosynthesis predicts a phenylpropanoid-CoA as starter and a single condensation reaction to a diketide. Benzalacetones, the expected release products, were observed only with unsaturated phenylpropanoid-CoAs, and the best results were obtained with 4-coumaroyl-CoA (80% of the products). With all other substrates, WtPKS1 performed two condensation reactions and released pyrones. We propose that WtPKS1 catalyses the first step in diarylheptanoid biosynthesis and that the observed pyrones are derailment products in the absence of downstream processing proteins.     

Type III polyketide synthases in lichen mycobionts

Lichenized and non-lichenized fungi produce a wide range of secondary metabolites. So far, type I polyketide synthases (PKSs) are the suggested catalysts for the biosynthesis of lichen compounds. We were interested whether lichen mycobionts also contain type III PKSs, representing a class that was only recently discovered in fungi. With an alignment of known type III CHS-like genes we applied the CODEHOP strategy to design degenerate PCR primers. We further screened available fungal genomes for type III PKS genes and aligned these sequences for a phylogenetic analysis. Type III-like genes from lichen mycobionts are closely related to those known from non-lichenized fungi, but not to those of bacteria and/or plants. We conclude that type III PKS genes are ubiquitous in fungi. They are present in diverse unrelated lichen mycobionts, but their function in lichens is so far unclear.     

Diversity of type I polyketide synthase genes in the wood-decay fungus Xylaria sp. BCC 1067

Fungal type I polyketide (PK) compounds are highly valuable for medical treatment and extremely diverse in structure, partly because of the enzymatic activities of reducing domains in polyketide synthases (PKSs). We have cloned several PKS genes from the fungus Xylaria sp. BCC 1067, which produces two polyketides: depudecin (reduced PK) and 19,20-epoxycytochalasin Q (PK-nonribosomal peptide (NRP) hybrid). Two new degenerate primer sets, KA-series and XKS, were designed to amplify reducing PKS and PKS-NRP synthetase hybrid genes, respectively. Five putative PKS genes were amplified in Xylaria using KA-series primers and two more with the XKS primers. All seven are predicted to encode proteins homologous to highly reduced (HR)-type PKSs. Previously designed primers in LC-, KS-, and MT-series identified four additional PKS gene fragments. Selected PKS fragments were used as probes to identify PKS genes from the genomic library of this fungus. Full-length sequences for five PKS genes were obtained: pks12, pks3, pksKA1, pksMT, and pksX1. They are structurally diverse with 1-9 putative introns and products ranging from 2162 to 3654 amino acids in length. The finding of 11 distinct PKS genes solely by means of PCR cloning supports that PKS genes are highly diverse in fungi. It also indicates that our KA-series primers can serve as powerful tools to reveal the genetic potential of fungi in production of multiple types of HR PKs, which the conventional compound screening could underestimate.