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。     

两种不同植物来源白藜芦醇生物合成关键酶——芪合酶催化效率比较

白藜芦醇是一种天然植保素,且具有特殊的药理和保健功能,芪合酶(Stilbene synthase,STS)是该化合物生物合成的关键酶和限速酶。白藜芦醇存在于有限几种植物且含量差异很大,虎杖中白藜芦醇含量比葡萄、花生高1 000倍以上,推测不同STS的催化能力有可能是白藜芦醇含量差异的原因之一。为验证上述推测,文中通过overlap PCR技术从葡萄叶片基因组DNA中克隆得到葡萄STS基因,连同前期工作中获得的虎杖STS基因(PcPKS5),进行了原核表达分析。诱导表达产物经过Ni2+亲和柱纯化和PD-10柱脱盐后,均得到分子量约43 kDa的可溶性纯化蛋白。酶促产物分析结果表明,两种酶催化产物均为白藜芦醇。酶动力学分析表明,虎杖STS催化效率(Kcat/Km)是葡萄STS的2.4倍。文中从植物类型Ⅲ聚酮化合物合酶(Polyketide synthase,PKS)超家族催化活性位点和保守位点角度分析了造成上述两种酶活性产生差异可能存在的原因。     

查尔酮合酶基因对转基因植物花色和育性的影响

查尔酮合酶 ( chalcone synthase,CHS)是花色素合成途径中的一个关键酶 ,它在植物中表达量的改变可能影响花的颜色。从矮牵牛 ( Petunia hybrida)特定发育阶段的花瓣的 c DNA中 ,克隆到查尔酮合酶基因 ,并正向插入到原核表达载体和含有花椰菜花叶病毒 Ca MV 35 S启动子的真核表达载体中 ,在原核中得到高效表达 ,并通过土壤农杆菌介导的方法转化矮牵牛。转基因植物的花色不但发生了明显的变异 ,其育性也受到了影响 ,不能产生正常花粉粒 ,成为雄性不育植株。 Northern杂交表明 ,转基因植物花瓣中 ,内源及外源查尔酮合酶基因转录均受到抑制     

非洲菊查尔酮合酶基因的克隆、序列分析及在大肠杆菌中的表达

利用RT-PCR方法,从非洲菊(Gerbera hybrida)花瓣的CDNA中克隆到了查尔酮合酶(Chalcone Synthase,CHS)基因CHS,进行了序列分析。结果表明,克隆到的CHS基因全长为1197bps,编码一个由398个氨基酸残基组成的多肽,与Helariutta等发表的非洲菊查尔酮合酶CHSI基因的CDNA序列的CHS基因同源性高达99％。进一步将该基因克隆到表达载体pET32a上,经IPTG诱导表达,得到高效表达的融合蛋白。     

中国水仙查尔酮合酶cDNA的克隆及序列分析(简报)

中国水仙系石蒜科水仙属多年生草本植物。其花枝多,花香浓郁,素有“凌波仙子”的美称。但水仙花色单一,影响其观赏价值。花色形成与植物体内的一类次级代谢产物类黄酮有关。查尔酮合酶(Chalcone synthase,CHS)是类黄酮合成途径中的一个关键酶,在植物体内它催化丙二酰基辅酶A的三个乙酸基和对羟苯丙烯酰辅酶A的一个乙酸基的缩合,产生柚配基查尔酮(naringenin)。此中心中     

葡萄CHS和STS基因家族生物信息学鉴定和表达分析

查尔酮合成酶(CHS,chalcone synthase)是植物体类黄酮类化合物合成的第1个关键酶和限速酶,它能够催化丙二酰-Co A和对香豆酸-Co A合成柚皮素查尔酮。二苯乙烯合成酶(STS,stilbene synthase)是芪类化合物合成路径的关键酶,与查尔酮合成酶有共同的作用底物,二者具有很高的相似度。为更好地了解葡萄中CHS和STS基因的种类和数量,本研究采用生物信息学方法检索获得葡萄(Vitis vinifera L.)基因组数据库中的CHS和STS基因,通过分析其染色体定位、系统进化和保守基序,发现葡萄基因组可能含有33个STS基因,9个CHS基因,这些基因集中分布在6条葡萄染色体上,部分家族基因在染色体上形成基因簇。葡萄CHS和STS基因家族蛋白长度、基因结构和蛋白基序非常保守,具有很近的进化关系。葡萄芯片数据结果表明,葡萄CHS和STS基因在葡萄果实不同发育时期的果皮和果肉中均有表达,尤其葡萄CHS GroupsⅢ亚家族基因在葡萄果皮中大量表达。葡萄STS基因家族在果实中的表达量较低,部分探针在葡萄果实成熟期的果皮中表达量急剧增加。本研究结果可为葡萄CHS和STS基因在果实发育过程中的功能研究提供参考。     

白色念珠菌中几丁质合酶CHS3对菌丝生长及致病性的影响

CHS3是催化白色念珠菌(Candida albicans)几丁质合成的关键酶，构建白色念珠菌几丁质合酶CHS3基因缺失菌株，确定CHS3的功能及对致病性的影响。以野生型白色念珠菌SC5314为母本菌株，通过SAT1-flipper技术构建chs3Δ/Δ突变体，对该突变体在小鼠系统性感染模型中的毒力进行检测，并对该突变体的毒力相关表型进行分析。结果表明，chs3Δ/Δ突变体的细胞壁几丁质含量下降、菌丝生长缺陷以及在小鼠系统性感染模型中的毒力减弱。CHS3可能通过调控白色念珠菌的菌丝生长，从而影响白色念珠菌的致病性。     

水母雪莲查尔酮合酶基因的克隆、表达及酶活分析

从水母雪莲Saussurea medusa Maxim. cDNA文库中得到一段查尔酮合酶基因 (SmCHS) 片段,然后通过RT-PCR得到完整的查尔酮合酶基因cDNA。序列分析表明SmCHS全长1 313 bp,其开放阅读框为1 170 bp,编码389个氨基酸,预测表达蛋白的分子量为43 kDa。构建原核表达质粒pET28a(+)-SmCHS,重组质粒转化大肠杆菌BL21(DE3),获得表达菌株。经IPTG诱导表达后,对表达产物进行SDS-PAGE分析,结果显示,表达的融合蛋白以部分可溶的形式存在。用Ni-NTA预装柱对融合蛋白进行亲和纯化,对纯化蛋白进行酶活检测,结果表明融合蛋白具有查尔酮合酶活性,可催化底物4-香豆酰辅酶A和丙二酰辅酶A缩合生成产物柚皮素查尔酮。     

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。     

大豆异黄酮生物合成关键酶及其代谢工程研究进展

异黄酮是一类具有C-6/C-3/C-6骨架的二次代谢产物,具有抗氧化和抗肿瘤活性。异黄酮与黄酮类物质具有相似的苯丙烷生物合成途径。天然的绝大部分异黄酮分布在豆科植物中,目前在大豆中已经发现了超过12个异黄酮(苷)。大豆异黄酮的生物合成主要涉及三个关键的酶查尔酮合酶(CHS)、查尔酮异构酶(CHI)和异黄酮合酶(IFS)。总结了大豆异黄酮的提取分离方法和生物合成途径,着重综述了CHI、CHS、IFS生物学特征和功能及异黄酮的代谢工程研究。     

Two type III polyketide synthases from Polygonum cuspidatum: gene structure, evolutionary route and metabolites

In our recent work (Ma et al., in Planta 229(3):457–469, 2009a and 229(4):1077–1086, 2009b), two three-intron type III PKS genes, PcPKS1 and PcPKS2, were isolated from Polygonum cuspidatum Sieb. et Zucc. Phylogenetic and functional analyses revealed PcPKS1 is a three-intron chalcone synthase (CHS) gene, and PcPKS2 is found to be a three-intron benzalacetone synthase (BAS) gene. The regular CHS encoded by a single intron gene have not been isolated and characterized from P. cuspidatum. In this work a further CHS with one intron (PcPKS3) and a stilbene synthase (STS) gene with three-intron (PcPKS5) were isolated and characterized by functional and phylogenetic analyses. In comparison with PcPKS1, a bifunctional enzyme with both CHS and BAS activity, the enzymatic product of recombinant PcPKS3 was naringenin, bis-noryangonin (BNY) and 4-coumaroyltriacetic acid lactone (CTAL) occurred as side products. The PcPKS5 synthesized resveratrol and a trace amount of naringenin from p-coumaroyl-CoA. To our knowledge, PcPKS5 is the first reported three-intron STS gene in flowering plants. In this work, we speculated that this involved a possible evolutionary route of plant-specific type III PKS superfamily in P. cuspidatum.     

Transformation of acridone synthase to chalcone synthase.

Acridone synthase (ACS) and chalcone synthase (CHS) catalyse the pivotal reactions in the formation of acridone alkaloids or flavonoids. While acridone alkaloids are confined almost exclusively to the Rutaceae, flavonoids occur abundantly in all seed-bearing plants. ACSs and CHSs had been cloned from Ruta graveolens and shown to be closely related polyketide synthases which use N-methylanthraniloyl-CoA and 4-coumaroyl-CoA, respectively, as the starter substrate to produce the acridone or naringenin chalcone. As proposed for the related 2-pyrone synthase from Gerbera, the differential substrate specificities of ACS and CHS might be attributed to the relative volume of the active site cavities. The primary sequences as well as the immunological cross reactivities and molecular modeling studies suggested an almost identical spatial structure for ACS and CHS. Based on the Ruta ACS2 model the residues Ser132, Ala133 and Val265 were assumed to play a critical role in substrate specificity. Exchange of a single amino acid (Val265Phe) reduced the catalytic activity by about 75% but grossly shifted the specificity towards CHS activity, and site-directed mutagenesis replacing all three residues by the corresponding amino acids present in CHS (Ser132Thr, Ala133Ser and Val265Phe) fully transformed the enzyme to a functional CHS with comparatively marginal ACS activity. The results suggested that ACS divergently has evolved from CHS by very few amino acid exchanges, and it remains to be established why this route of functional diversity has developed in the Rutaceae only.     

A bifunctional type III polyketide synthase from raspberry (<Emphasis Type="Italic">Rubus idaeus</Emphasis> L.) with both chalcone synthase and benzalacetone synthase activity

Raspberry ketone accounts for the characteristic aroma of the raspberry fruit. A bifunctional enzyme with both chalcone synthase (CHS) and benzalacetone synthase (BAS) activity is thought to play a crucial role in the synthesis of p-hydroxybenzalacetone, yet the in vitro enzymatic properties and reaction products of the CHS/BAS recombinant enzyme from raspberry have not been characterized. In this work, a type III polyketide synthase (PKS) gene (RinPKS1) and its corresponding cDNA were isolated from raspberry. Sequence and phylogenetic analyses demonstrated that RinPKS1 is a CHS. However, functional and enzymatic analyses showed that recombinant RinPKS1 is a bifunctional enzyme with both CHS and BAS activity. RinPKS1 showed some interesting characteristics: (1) no traces of bis-noryangonin and 4-coumaroyltriacetic acid lactone could be detected in the enzyme reaction mixture at different pH values; and (2) recombinant RinPKS1 overexpressed in Escherichia coli effectively yielded p-hydroxybenzalacetone as a dominant product at high pH; however, it effectively yielded naringenin as a dominant product at low pH. Furthermore, 4-coumaroyl-CoA and feruloyl-CoA were the only cinnamoyl-CoA derivatives accepted as starter substrates. RinPKS1 did not accept isobutyryl-CoA, isovaleryl-CoA or acetyl-CoA as substrates.     

Structure-based engineering of benzalacetone synthase

Benzalacetone synthase (BAS) and chalcone synthase (CHS) are plant-specific type III polyketide synthases (PKSs), sharing 70% amino acid sequence identity and highly homologous overall protein structures. BAS catalyzes the decarboxylative coupling of 4-coumaroyl-CoA with malonyl-CoA to produce the diketide benzalacetone, whereas CHS produces the tetraketide chalcone by iterative condensations with three molecules of malonyl-CoA, and folding the resulting intermediate into a new aromatic ring system. Recent crystallographic analyses of Rheum palmatum BAS revealed that the characteristic substitution of Thr132 (numbering of Medicago sativa CHS2), a conserved CHS residue lining the active-site cavity, with Leu causes steric contraction of the BAS active-site to produce the diketide, instead of the tetraketide. To test this hypothesis, we constructed a set of R. palmatum BAS site-directed mutants (L132G, L132A, L132S, L132C, L132T, L132F, L132Y, L132W and L132P), and investigated the mechanistic consequences of the point mutations. As a result, the single amino acid substitution L132T restored the chalcone-forming activity in BAS, whereas the Ala, Ser, and Cys substitutions expanded the product chain length to produce 4-coumaroyltriacetic acid lactone (CTAL) after three condensations with malonyl-CoA, but without the formation of the aromatic ring system. Homology modeling suggested that this is probably caused by the restoration of the ‘coumaroyl binding pocket’ in the active-site cavity. These findings provide further insights into the structural details of the catalytic mechanism of the type III PKS enzymes.     

Cross-reaction of chalcone synthase and stilbene synthase overexpressed in Escherichia coli

Chalcone synthase (CHS) and stilbene synthase (STS) are related plant polyketide synthases belonging to the CHS superfamily. CHS and STS catalyze common condensation reactions of p-coumaroyl-CoA and three C₂-units from malonyl-CoA but different cyclization reactions to produce naringenin chalcone and resveratrol, respectively. Using purified Pueraria lobata CHS and Arachis hypogaea STS overexpressed in Escherichia coli, bisnoryangonin (BNY, the derailed lactone after two condensations) and p-coumaroyltriacetic acid lactone (the derailed lactone after three condensations) were detected from the reaction products. More importantly, we found a cross-reaction between CHS and STS, i.e. resveratrol production by CHS (2.7–4.2% of naringenin) and naringenin production by STS (1.4–2.3% of resveratrol), possibly due to the conformational flexibility of their active sites.     

Molecular analysis of chalcone and dihydropinosylvin synthase from Scots pine (Pinus sylvestris), and differential regulation of these and related enzyme activities in stressed plants

Chalcone synthase (CHS) and stilbene synthase (STS) are closely related polyketide synthases which are key enzymes in the biosynthesis of flavonoids and stilbenes. Scots pine (Pinus sylvestris) is an interesting plant for a direct comparison of the enzymes. It not only contains the usual flavonoids, but also an unusual chalcone derivative (pinocembrin), and it synthesizes stilbenes of the pinosylvin type. We analysed a CHS and a STS by molecular cloning and functional expression in Escherichia coli. The CHS was active not only with 4-coumaroyl-CoA (to naringenin chalcone), but also with cinnamoyl-CoA (leading to pinocembrin). The STS was identified as dihydropinosylvin synthase, because it preferred dihydrocinnamoyl-CoA to cinnamoyl-CoA. The protein deviated in 47 positions from the CHS consensus. It had 73.2% identity with the CHS from P. sylvestris and only 65.3% with a STS from peanut (Arachis hypogaea). We also investigated the regulation of both enzyme types in P. sylvestris plantlets exposed to stress. CHS was present in non-stressed plantlets, and induction led to a transient increase with a peak after 16 h. STS¹ type activities were regulated differently and were absent in non-stressed plantlets. Increases were observed after a lag period of at least 6 h, and highest activities were obtained after 30 h. The analysis of the reactions in the plant extracts and the substrate specificity of the cloned STS indicate that the plants contain at least two different types of STS: the cloned dihydropinosylvin synthase and a pinosylvin synthase which preferentially utilizes cinnamoyl-CoA as substrate.     

Chalcone synthase homologues from Humulus lupulus: some enzymatic properties and expression

The enzymatic properties of four chalcone synthase homologues CHS_H1, VPS, CHS 2 and CHS 4 from Humulus lupulus L. were investigated after heterologous expression in Escherichia coli. It was found that both VPS and CHS_H1 can utilize isovaleryl-CoA and isobutyryl-CoA as substrates producing compounds with positions in thin layer chromatography characteristic for phloroisovalerophenone and phloroisobutyrophenone. These reactions are accompanied by the formation of associated byproducts. The formation of naringenin chalcone can be catalyzed primarily by CHS_H1. Comparatively the ability of VPS to perform chalcone synthase reaction is very limited. Since only CHS_H1 has true chalcone synthase activity, this enzyme can be considered a key enzyme in prenylflavonoid biosynthesis. Both CHS 2 and CHS 4 utilize isovaleryl-CoA and isobutyryl-CoA as substrates, but the reactions were prematurely terminated. In comparison with VPS and CHS_H1, the optimum pH of CHS 2 was shifted to lower value. High expression of chalcone synthase-like genes were found in maturating hop cones of cultivars with high bitter acid content (Agnus, Magnum, Target) by Northern and Western blotting using probes specific for vps, chs_H1, chs 4 and polyspecific serum risen against recombinant protein CHS4, respectively. It was also found that these cultivars maintained expression of CHS homologues for a longer period of time during cone development in contrast to time-limited expression of CHS homologues in cultivars with low bitter acids content.