4 resultados para CCOAOMT
Resumo:
木质素是植物体中具重要生物功能的次生代谢产物。然而纸浆生产主要是将原料中的木质素与用于造纸的纤维素分离,该工艺过程产生了造纸工业的主要污染废液,并且增加造纸成本。本研究目的在于利用反义RNA技术,在分子水平调节木质素的生物合成,降低中国特有造纸树种毛白杨的木质素含量,培育更适于我国造纸工业的原料树种。以下为本研究已取得的相关研究进展: 1.通过RT-PCR技术,从毛白杨中克隆了木质素生物合成的三个相关酶的cDNAs,它们分别为咖啡酸甲基转移酶(caffeic acid O-methyltransferase,COMT)、咖啡酰CoA甲基转移酶(caffeoyl Co-enzyme A O-methyltransferase,CCoAOMT)及香豆酸:辅酶A连接酶(4-coumarate: CoA ligase,4CL)。序列分析显示了毛白杨这三个基因与杨属中其它种的相应基因cDNA核苷酸序列高度同源。Northern点杂交分析表明,COMT、CCoAOMT及4CL基因在毛白杨正在生长的次生木质部中高水平表达,其表达高峰与树木的木质化进程同步;而在叶与叶柄中,这三个基因均不表达。COMT、CCoAOMT及4CL是木质素生物合成的相关酶,该表达特征与其基因功能相一致。本研究克隆的COMT、CCoAOMT及4CL基因的cDNAs已在GenBank注册登记,接受号分别为AF237777、AF240466、AF314180 (publish on Jan l,2002)。 2.通过一系列的DNA重组,构建了携带反义COMT、CCoAOMT或4CLcDNA的反义表达载体以及同时整合反义COMT与CCoAOMT cDNA的双价反义表达载体,PCR扩增与酶切检测确证构建无误。 3.以田间取材的速生三倍体毛白杨B19、B331及B304的茎尖、叶片与嫩茎为外殖体,首次获得了三倍体毛白杨的组培再生试管苗,并建立了速生三倍体毛白杨的组培再生系统,为通过基因工程改良其造纸性能奠定了基础。 4.农杆菌介导转化烟草,PCR与PCR-Southern检测表明我们获得了整合反义COMT、CCoAOMT cDNA及反义COMT及CCoAOMT cDNA共整合的转基因烟草。以Digoxigenin标记的对应于反义链的单链RNA为探针与转基因烟草的总RNA进行NoIthern点杂交,结果表明整合到其中的反义cDNA均已表达。转基因烟草的木质素分析将有助于对COMT及CCoAOMT两个甲基化酶功能的认识。 5.通过农杆菌介导,将反义CCoAOMT cDNA转入欧洲山杨与银白杨的杂交杨(P tremulaXP.alba)。经PCR,PCR-Southern及Southern检测,确认获得了转基因植株。以Digoxigenin标记的对应于CCoAOMT cDNA反义链的单链RNA为探针与转基因杂交杨总RNA进行Northern点杂交,结果表明整合到其中的反义cDNA已在转录水平表达。测定生长5-6个月的转基因杨树下部茎杆的Klason木质素含量,结果显示其中一个株系的Klason木质素含量比野生型对照下降17.9%,表明抑制杨树内源CCoAOMT基因表达可有效降低转基因植株的木质素含量。
Resumo:
木质素是一类酚类次生代谢产物,在植物体内行使重要的生理功能,但它却是形成造纸污染的主要来源。利用基因工程手段,在分子水平调节木质素的生物合成,降低木质素的含量或改变组分以培育适合造纸的植物原料树种具有较大的应用价值和环保效益。本研究利用反义RNA技术,主要围绕木质素合成三种相关酶咖啡酸-O-甲基转移酶(COMT)、咖啡酰辅酶A-O-甲基转移酶(CCoAOMT)、4-香豆酸:辅酶A连接酶(4CL)的基因对植物木质素生物合成途径调节的研究,取得如下进展: 1.农杆菌介导法将COMT和CCoAOMT基因的单价和双价的反义表达载体导入烟草,比较了两个甲基化酶的功能。PCR-Southern和Northern点杂交结果表明反义基因已整合到烟草基因组DNA上,并在转录水平表达。两种反义基因对木质素生物合成调节的效果显示,CCoAOMT能更有效地调节木质素生物总量的合成,COMT仅特异调节S木质素的合成。表达反义CCoAOMT基因的转基因毛白杨,内源CCoAOMT基因的表达在转录和蛋白水平均受到抑制,最终引起转基因植株木质素含量普遍降低,最多降低达26.20%,筛选出木质素含量下降10%以上的转基因毛白杨株系8个,为源头治理造纸废水污染奠定了基础。 2. 对克隆的4CL基因进行了表达特性分析, RT-PCR分析表明,分离的毛白杨4CL基因主要在木质部丰富表达,叶中表达量较少,树皮中不表达。在毛白杨的一个生长季,该基因表达显示明显的双锋特征,该表达模式与木材早材和晚材的发育时期相吻合,表明分离的毛白杨4CL基因与木质素的生物合成密切相关。农杆菌介导法将反义4CL基因导入烟草和毛白杨,利用分子生物学检测手段对转化植株进行筛选,获得批量转基因植株。Klason木质素含量测定分析表明,抑制内源4CL基因表达,能有效降低转基因植物中的木质素含量,且不影响植株正常生长和发育以及碳水化合物的合成。转基因毛白杨的茎杆上一些区域呈红棕色,颜色的深度与转基因毛白杨木质素含量的下降幅度呈一定的正相关性,颜色变化可作为转基因植株筛选的一个辅助指标。现已获得木质素含量下降10%以上的转基因株系3个,最多下降达41.73%,可供中试与制浆实验,为培育低木质素环保型毛白杨提供理论与实践依据。 3.为了优化现有的表达框架,使目的基因更有效地调节木质素的生物合成,应用PCR技术从毛白杨基因组中分离得到C4H(肉桂酸4—羟基化酶)基因启动子片段(GenBank注册号:AY351673)。GUS荧光活性分析和组织化学染色显示,该启动子在一些木质化的组织和器官中特异表达,随着组织成熟度和木质化程度的增加,表达活性逐渐增强,并且该启动子受伤诱导。反义CCoAOMT基因在C4H启动子的调控下,会引起转基因烟草木质素均有不同程度的减少,但不影响碳向碳水化合物的转换合成,对植物的生长发育也无明显负效应。这些结果证明了从毛白杨中分离的C4H 启动子可以应用于造纸原料树种材性改良的遗传工程操作。 4.首次从水稻中华10号(Oryza sativa L. ssp. japonica)分离了CCoAOMT基因家族的三个成员,对其基因结构及表达特性的分析表明,该基因家族的三个成员与水稻的木质化进程关系密切,研究结果有助于了解单子叶植物中的甲基化途径发生机制,为高产水稻抗倒伏和茎杆饲料作物的遗传改良奠定了基础。
Resumo:
Rapid decline in cell-wall digestibility hinders efficient use of warm-season grasses. The objective of this study was to identify genes whose expressions are related to the slope of decline in cell-wall digestibility. Eleven guineagrass genotypes were harvested at three ages and classified according to fibre digestibility. Extreme genotypes were separated into groups with either FAST or SLOW decline in fibre digestibility. Expression of transcripts from six genes from the lignin synthesis pathway was quantified by real-time PCR. Fast decline in fibre digestibility was associated with higher DM yield after 90 d of regrowth. Apart from lower fibre digestibility and higher lignin content for the FAST group, there were no other differences between the two groups for the chemical composition of stems and leaves. Maturity affected differently the expression of two of the six genes, cinnamate 4-hydroxylase and caffeoyl-CoA O-methyltransferase (C4H and CCoAOMT). Genotypes with fast decline in fibre digestibility had greater increase in the expression of C4H and CCoAOMT from 30 to 60 d of regrowth, than genotypes with slower decline. Expression of C4H and CCoAOMT appears to be related to the decline in cell-wall digestibility with advance in maturity of guineagrass.
Resumo:
S-adenosyl-l-methionine (SAM)-dependent O-methyltransferases (OMTs) catalyze the methylation of hydroxycinnamic acid derivatives for the synthesis of methylated plant polyphenolics, including lignin. The distinction in the extent of methylation of lignins in angiosperms and gymnosperms, mediated by substrate-specific OMTs, represents one of the fundamental differences in lignin biosynthesis between these two classes of plants. In angiosperms, two types of structurally and functionally distinct lignin pathway OMTs, caffeic acid 3-O-methyltransferases (CAOMTs) and caffeoyl CoA 3-O-methyltransferases (CCoAOMTs), have been reported and extensively studied. However, little is known about lignin pathway OMTs in gymnosperms. We report here the first cloning of a loblolly pine (Pinus taeda) xylem cDNA encoding a multifunctional enzyme, SAM:hydroxycinnamic Acids/hydroxycinnamoyl CoA Esters OMT (AEOMT). The deduced protein sequence of AEOMT is partially similar to, but clearly distinguishable from, that of CAOMTs and does not exhibit any significant similarity with CCoAOMT protein sequences. However, functionally, yeast-expressed AEOMT enzyme catalyzed the methylation of CAOMT substrates, caffeic and 5-hydroxyferulic acids, as well as CCoAOMT substrates, caffeoyl CoA and 5-hydroxyferuloyl CoA esters, with similar specific activities and was completely inactive with substrates associated with flavonoid synthesis. The lignin-related substrates were also efficiently methylated in crude extracts of loblolly pine secondary xylem. Our results support the notion that, in the context of amino acid sequence and biochemical function, AEOMT represents a novel SAM-dependent OMT, with both CAOMT and CCoAOMT activities and thus the potential to mediate a dual methylation pathway in lignin biosynthesis in loblolly pine xylem.
