CsFAD7基因转化烟草的研究

以"革新一号"烟草种子为试材,采用根癌农杆菌介导的烟草叶盘转化法将来源于黄瓜的脂肪酸去饱和酶基因(FAD7)转入烟草,并在附加300mg/L氨苄青霉素(Amp)的MS+0.1mg/L NAA+1.0mg/L 6-BA的培养基上诱导植株分化,再生芽在附加300mg/L Amp和100mg/L卡那霉素(Kan)的MS培养基上生根,获得再生植株。结果表明:Kan阳性植株经PCR检测筛选,得到转基因阳性植株,证明异源FAD基因已转入烟草基因组中。T1代经PCR-South-ern检测证明转化基因可以遗传;转基因烟草在低温胁迫下生长较好,叶绿素荧光参数F0值下降不大,Fv/Fm值保持较高,表现了对低温的耐受能力,脂肪酸分析表明,该基因可以使烟草叶片的亚麻酸含量比例升高。

野生蕉(Musa spp.,AB group)抗寒基因FAD7的分子克隆与功能分析

以福州旗山国家森林公园野生蕉(Musa spp.,AB group)和福建地方著名栽培品种天宝蕉(Musa acuminata,AAA group)叶片为材料,克隆获得ω-3脂肪酸去饱和酶基因FAD7,并对其cDNA序列进行生物信息学分析;同时,进行了低温胁迫下FAD7转录水平变化的研究。结果表明,旗山野生蕉FAD7(命名为MuFAD7-1,GenBank登录号为JX911314)和天宝蕉FAD7(命名为Ma-FAD7-1,GenBank登录号为KF011506)ORF均为1 371 bp,编码456个氨基酸,两者共有22个差异碱基和10个差异氨基酸残基;生物信息学预测显示,香蕉FAD7编码蛋白为亲水性,不含信号肽,定位于叶绿体;在不同低温胁迫下,天宝蕉Ma-FAD7-1转录水平变化小,而旗山野生蕉Mu-FAD7-1在普通香蕉停止的生长临界温度13℃时表达量显著升高,并达到峰值,降至4℃时仍然维持较高水平,进一步验证了野生蕉FAD7可能具有抗寒基因的功能。

菊花脂肪酸脱饱和酶基因CmFAD7的克隆与表达分析

以秋菊(Chrysanthemum morifolium Ramat.)抗寒品种‘星光灿烂’为材料,利用RT-PCR和RACE方法从叶片中克隆了ω-3脂肪酸去饱和酶基因,命名为Cm FAD7,Gen Bank登录号为KC567246。该基因c DNA全长1 284 bp,编码428个氨基酸,相对分子量为48.98 k D,等电点为9.07,编码的氨基酸序列与高山还阳参同源性最高(84%)。该蛋白含有?12-FADs保守结构域和3个跨膜螺旋,N端含有一段叶绿体转运肽,属于膜脂肪酸去饱和酶超级家族。采用实时荧光定量PCR和气相色谱法研究低温胁迫下叶片和根系中Cm FAD7的表达量及脂肪酸含量变化,Cm FAD7在根系和叶片中均有表达,叶片中的表达量高于根系。根系中5℃时表达量最高,叶片中–4℃时最高,在–8℃时叶片和根系表达量均较低;随着处理温度的降低,叶片中C18:3含量呈逐渐上升趋势,根系中变化不明显。结果表明,菊花Cm FAD7与抗寒性有关,低温条件下不同器官的表达量有较大差异。

麻风树脂肪酸去饱和酶7基因的克隆及生物信息学分析

质体型ω-3(Δ15)脂肪酸去饱和酶(FAD7)是多不饱和脂肪酸合成途径中催化亚油酸(Δ9,12-C18∶2)形成α-亚麻酸(Δ9,12,15-C18∶3,ALA)的关键酶。基于麻风树低温锻炼转录组数据,通过逆转录PCR(RT-PCR)技术克隆到麻风树FAD7基因的全长cDNA,命名为JcFAD7。结果表明,该cDNA序列全长1 796 bp,完整开放阅读框1 341 bp,编码446个氨基酸,理论分子量为51.1 ku,等电点为8.92。序列分析表明,JcFAD7编码蛋白包含膜结合FAD蛋白的4个跨膜区、2个膜嵌合区、1个亚铁血红素结合基序及3个组氨酸簇等特征区域。构建系统进化树显示,麻风树JcFAD7蛋白与芍药(Paeonia lactiflora)的亲缘关系最近。

Non-redundant Contribution of the Plastidial FAD8 ω-3 Desatumse to Glycerolipid Unsatumtion at Different Temperatures in Arabidopsis

Plastidial ω-3 desaturase FAD7 is a major contributor to trienoic fatty acid biosynthesis in the leaves of Arabidopsis plants. However, the precise contribution of the other plastidial ω-3 desaturase, FAD8, is poorly understood. Fatty acid and lipid analysis of several ω-3 desaturase mutants, including two insertion lines of AtFAD7 and AtFAD8, showed that FAD8 partially compensated the disruption of the AtFAD7 gene at 22℃, indicating that FAD8 was active at this growth temperature, contrasting to previous observations that circumscribed the FAD8 activity at low temperatures. Our data revealed that FAD8 had a higher selectivity for 18：2 acyl-lipid substrates and a higher preference for lipids other than galactolipids, particularly phosphatidylglycerol, at any of the temperatures studied. Differences in the mechanism controlling AtFAD7 and AtFAD8 gene expression at different temperatures were also detected. Confocal microscopy and biochemical analysis of FAD8-YFP over-expressing lines confirmed the chloroplast envelope localization of FAD8. Co-localization experiments suggested that FAD8 and FAD7 might be located in close vicinity in the envelope membrane. FAD8-YFP over-expressing lines showed a specific increase in 18：3 fatty acids at 22℃. Together, these results indicate that the function of both plastidial ω-3 desaturases is coordinated in a non-redundant manner.