植物乙酰辅酶A羧化酶的分子生物学与基因工程

植物中的乙酰辅酶A羧化酶(acetylCoAcarboxylase,ACCase)分两种类型:原核类型的ACCase位于质体中,是脂肪酸合成途径中的关键酶;真核类型的ACCase位于胞质溶胶中,催化形成的产物主要用于长链脂肪酸的合成以及类黄酮等次生代谢产物的合成。但禾本科植物的质体和胞质溶胶中的ACCase都属于真核类型,其中质体中的是环己烯酮类和芳氧苯氧丙酸类等除草剂作用的靶蛋白。文中主要综述了植物中ACCase的生理功能、分子生物学特征及其对两类除草剂的敏感性,并对其基因工程作了展望。     

乙酰辅酶A羧化酶在治疗肥胖中的潜在作用

肥胖作为一种疾病引起了世界各国越来越多的重视。目前,对乙酰辅酶A羧化酶的研究表明,该酶和肥胖的发生有着重大关系．脂肪的代谢异常是导致肥胖的重要原因之一。乙酰辅酶A羧化酶是脂肪代谢过程中的一种重要的调节酶．它的产物丙二酰辅酶A的含量在一定程度上控制着脂肪酸的代谢。因此对乙酰辅酶A羧化酶的深入研究很可能为肥胖的治疗提供新的医疗手段。该文介绍乙酰辅酶A羧化酶在脂肪代谢中的作用、分类与调控．以及当前国际上对其研究的最新进展。     

甘薯质体中的乙酰辅酶A羧化酶亚基基因accD的克隆与序列分析

依据烟草质体全基因组序列设计引物,以甘薯质体基因组DNA为模板,PCR扩增包含质体accD基因完整编码区在内的一段序列（GenBank登录号为GQ395771）。序列分析表明：该片段全长为2209bp,包括1548bp的nccD基因编码序列,推测编码515个氨基酸的蛋白质,该蛋白序列具有异质型β-CT中保守的锌指结构和C末端5个基元。同时绘制了该DNA片段的限制性酶切图谱。相似性比较显示,甘薯accD基因与大豆、马铃薯、拟南芥、人参、莴苣、葡萄、海岛棉、甘蓝、辣椒、菠菜、番茄和烟草的accD基因核苷酸相似性为72％-87％,氨基酸相似性为58％-83％。     

油菜叶绿体乙酰辅酶A羧化酶单交换表达载体的构建

根据已知序列设计引物,通过PCR扩增获得质体定位的乙酰辅酶A羧化酶的4个亚基的基因序列。先将该酶4个亚基的基因进行拼接,然后将这4个拼接好的片段,克隆到pMD18-T载体上,得到质粒pH BM714。再以质粒pHBM714 DNA为模板,用分别带有CpoI和Asc I酶切位点的引物进行PCR扩增,PCR产物在dTTP的保护下经T4 DNA聚合酶处理,与将质粒pHBM720DNA纯化后经CpoI和AscI双酶切后得到的大片段连接,连接产物转化大肠杆菌Xl_(10)-gold,得到正确的重组子命名为pHBM726。此质粒pH BM726,即为带有壮观霉素抗性基因(aadA)筛选标记的质体定位的乙酰辅酶A羧化酶基因油菜叶绿体单交换表达载体;在此载体中壮观霉素抗性基因(aadA)、乙酰辅酶A羧化酶的4个亚基的基因(ACC)和绿色荧光蛋白基因(gfp)共6个基因串联在一起,共用一个启动子序列,一起来进行表达;通过酶切检测、PCR验证和测序验证,均表明该表达载体构建成功。最后此载体在大肠杆菌中表达时,发现重组菌能够在含壮观霉素的培养基上生长,且在可见光下,能看到绿色荧光,表明壮观霉素抗性基因和绿色荧光蛋白基因均在大肠杆菌中成功表达;表达产物通过Western印迹验证表明组成乙酰辅酶A羧化酶的4个亚基的基因在大肠杆菌中成功表达。以上结果表明,该表达载体中串联排列的这6个基因均在大肠杆菌中成功表达。该研究结果可为质体定位的乙酰辅酶A羧化酶转叶绿体的研究奠定基础,为油菜油脂代谢研究提供参考。     

谷子叶绿体乙酰辅酶A羧化酶cDNA的克隆和禾本科除草剂靶位点的序列分析

乙酰辅酶A羧化酶是一个生物素羧化酶,它所催化的反应是脂肪酸生物合成中的第一个植物叶绿体中的乙酰辅酶A羧化酶是两类禾本科除草剂的靶蛋白.从抗除草剂拿捕净和感拿捕净的谷子(SetariaitalicaBeauv.)中克隆了两个乙酰辅酶A羧化酶的全长cDNA,分别命名为foxACC-R和foxACC-S,它们推导的蛋白质均编码2 321个氨基酸,然而在第1 780个氨基酸处,foxACC-R编码亮氨酸,而foxACC-S编码异亮氨酸.采用生物信息学方法,我们推断这个cDNA编码的是叶绿体中的乙酰辅酶A羧化酶,并预测了它的功能域和保守区.通过这两个cDNA编码的氨基酸序列与其他乙酰辅酶A羧化酶的序列比较得出结论,亮氨酸/异亮氨酸位点可能是APPs和CHDs两类除草剂作用的关键位点.Southern杂交分析的结果显示,该基因在谷子基因组中只有一个拷贝.     

谷子叶绿体乙酰辅酶A羧化酶cDNA的克隆和禾本科除草剂靶位点的序列分析

乙酰辅酶A羧化酶是一个生物素羧化酶,它所催化的反应是脂肪酸生物合成中的第一个关键步骤。禾本科植物叶绿体中的乙酰辅酶A羧化酶是两类禾本科除草剂的靶蛋白。从抗除草剂拿捕净和感拿捕净的谷子(Setaria italicaBeauv.)中克隆了两个乙酰辅酶A羧化酶的全长cDNA,分别命名为foxACC-R和foxACC-S,它们推导的蛋白质均编码2 321个氨基酸,然而在第1 780个氨基酸处,foxACC-R编码亮氨酸,而foxACC-S编码异亮氨酸。采用生物信息学方法,我们推断这个cDNA编码的是叶绿体中的乙酰辅酶A羧化酶,并预测了它的功能域和保守区。通过这两个cDNA编码的氨基酸序列与其他乙酰辅酶A羧化酶的序列比较得出结论,亮氨酸/异亮氨酸位点可能是APPs和CHDs两类除草剂作用的关键位点。Southern 杂交分析的结果显示,该基因在谷子基因组中只有一个拷贝。     

乙酰辅酶A合成代谢对酿酒酵母生理功能的影响

【目的】研究酿酒酵母(Saccharomycesc erevisiae)中乙酰辅酶A合成酶基因ACS1和ACS2的生理作用。【方法】将来源于S.cerevisiae的ACS1和ACS2分别进行过量表达,研究过量表达ACS1和ACS2后S.cerevisiae胞内乙酰辅酶A含量、ATP水平、甲羟戊酸途径转录和乙醇耐受性等生理学特性变化。【结果】与出发菌株相比,过量表达ACS1和ACS2使得:(1)胞内乙酰辅酶A含量提高了2.19倍(ACS1)和5.02倍(ACS2);(2)胞内ATP含量提高了3.93倍(ACS1)和2.05倍(ACS2);(3)甲羟戊酸途径8个关键基因表达量显著上调;(4)S.cerevisiae对乙醇胁迫抵御能力显著增强。过量表达ACS1对乙醇胁迫的耐受能力强于过量表达ACS2。【结论】增加胞内乙酰辅酶A的含量可以显著增加甲羟戊酸途径碳代谢流量,并增强S.cerevisiae对发酵过程主要副产物乙醇的耐受能力。     

富硒灵芝调控大鼠乙酰辅酶A羧化酶α表达治疗非酒精性脂肪肝病的研究

60只SD大鼠随机分为正常对照组、模型对照组、富硒灵芝治疗组。非酒精性脂肪肝病(Non-Alcoholic Fatty Liver Disease,NAFLD)模型建立成功后富硒灵芝治疗组给予富硒灵芝水灌胃治疗,模型对照组给予生理盐水灌胃辅助对比,空白对照组不加以任何干涉,分别于6周和12周处死大鼠各半。大鼠肝脏HE染色显示,治疗6周后富硒灵芝组脂肪变性程度及细胞肿胀相较于模型组明显减轻,炎性细胞浸润及坏死灶较模型对照组明显减少,富硒灵芝12周组大鼠比富硒灵芝6周组肝脏改善效果更佳;治疗6周后,富硒灵芝治疗组与模型对照组相比,血清中乳酸脱氢酶(LDH)、天门冬氨酸氨基转移酶(AST)、丙氨酸氨基转移酶(ALT)、谷胱甘肽(GSH)、丙二醛(MDA),肝脏组织中超氧化物歧化酶(SOD)、MDA和GSH,差异显著(P0.05);SERBF-1mRNA和蛋白表达:富硒灵芝6周组与模型对照6周组相比,只有微小差异(P0.05),12周富硒灵芝组与模型对照组相比,差距则具有统计学意义(P0.05);ACCαmRNA和蛋白表达:富硒灵芝6周组与模型对照6周组相比,差别具有统计学意义(P0.05);12周时差异更加显著;胰岛素抵抗指数6周时没有改善,12周时呈现出统计学意义(P0.05)。因而推测,富硒灵芝可通过调控大鼠ACCα的表达、以提高抗氧化能力及改善肝功能来治疗NAFLD,但药效疗程较长,可能需长期服用。     

提高光滑球拟酵母乙酰辅酶A水平促进a-酮戊二酸合成

【目的】为了了解光滑球拟酵母中乙酰辅酶A含量对其碳代谢及其通量的影响。【方法】将来源于酿酒酵母中编码乙酰辅酶A合成酶ACS2基因过量表达于发酵法生产丙酮酸的生产菌株Torulopsis glabrata中,获得了一株乙酰辅酶A合成酶活性提高9.2倍(1.20 U/mg protein)的重组菌T. glabrata ACS2-1。【结果】与出发菌株WSH-IP303相比,重组菌T. glabrata ACS2-1：(1)能以乙酸为唯一碳源在胞内积累0.94 mmol/(L·g DCW)的乙酰辅酶A;(2)以葡萄糖为唯一碳源时胞内乙酰辅酶A浓度、a-酮戊二酸产量和Ca-KG/Cpyr是出发菌株WSH-IP303 的3.22、2.05和2.52倍;(3)在葡萄糖培养基中添加4 g/L乙酸,使乙酰辅酶A浓度、a-酮戊二酸产量和Ca-KG/Cpyr是出发菌株WSH-IP303的4.55、2.47和3.75倍,a-酮戊二酸浓度达到17.8 g/L。【结论】这一结果表明,改变细胞内关键辅因子的浓度能使碳代谢流的流向与通量发生改变,从积累丙酮酸转向过量积累a-酮戊二酸。     

Regulation of Plant Acetyl-CoA Carboxylase by Adenylate Nucleotides

The assay of acetyl-CoA carboxylase (EC 6.4.1.2) does not follow ideal zero-order kinetics when assayed in a crude extract from wheat (Triticum aestivum L.) germ. Our results show that the lack of ideality is the consequence of contamination by ATPase and adenylate kinase. These enzyme activities generate significant amounts of ADP and AMP in the assay mixture, thus limiting the availability of ATP for the carboxylase reaction. Moreover, ADP and AMP are competitive inhibitors, with respect to ATP, of acetyl-CoA carboxylase. Similar relationships between adenylate nucleotides and acetyl-CoA carboxylase are found in isolated chloroplasts. There is no evidence that acetyl-CoA carboxylase activity in the extracts of the plant systems examined is altered by covalent modification, such as a phosphorylation-dephosphorylation cycle. A scheme is presented that illustrates the dependency of acetyl-CoA carboxylase and fatty acid synthesis on the energy demands of the chloroplasts in vivo.     

Acetyl-CoA Carboxylase in Higher Plants: Most Plants Other Than Gramineae Have Both the Prokaryotic and the Eukaryotic Forms of This Enzyme

The presence and the absence of a prokaryote type and a eukaryotetype of acetyl-CoA carboxylase (EC 6.4.1.2 [EC] ; ACCase) were examinedin members of 28 plant families by two distinct methods: thedetection of biotinylated subunits of ACCase with a streptavidinprobe, and the detection of the accD gene, which encodes a subunitof the prokaryotic ACCase, by Southern hybridization analysis.The protein extracts of all the plants studied contained a biotinylatedpolypeptide of 220 kDa, which was probably the eukaryotic ACCase.All the plants but those belonging to Gramineae also containeda biotinylated polypeptide of ca. 35 kDa, which is a putativesubunit of the prokaryotic ACCase. In all plants but those inGramineae, the ca. 35 kDa polypeptide was found in the proteinextracts of plastids, while the 220 kDa polypeptide was absentfrom these plastid extracts. The plastid extracts of the plantsin Gramineae contained the 220 kDa polypeptide, as did the homogenatesof the leaves. Southern hybridization analysis demonstratedthat all the plants but those in the Gramineae contained theaccD gene. These findings suggest that most higher plants havethe prokaryotic ACCase in the plastids and the eukaryotic ACCasein the cytosol. Only Gramineae plants might contain the eukaryoticACCases both in the plastids and in the cytosol. The originof the plastid-located eukaryotic ACCase in Gramineae is discussedas the first possible example of substitution of a plastid geneby a nuclear gene for a non-ribosomal component. ⁴Present address: Plant-Growth Regulation Laboratory, The Instituteof Physical and Chemical Research (RIKEN), Hirosawa 2-1, Wako,351-01 Japan ⁵Present address: Laboratory of Plant Molecular Biology, Schoolof Agricultural Sciences, Nagoya University, Chikusa-ku, Nagoya,464-01 Japan     

Inhibition of Acetyl-CoA Carboxylase Activity by Haloxyfop and Tralkoxydim

Acetyl-coenzyme A (CoA) carboxylase from maize (Zea mays L.) is inhibited by nanomolar concentrations of both haloxyfop, an aryloxyphenoxypropionate, and tralkoxydim, a cyclohexanedione herbicide. These results suggest that acetyl-CoA carboxylase, which catalyzes the first committed step in fatty acid biosynthesis, may be the target of these herbicides, contrary to an earlier report suggesting that aryloxyphenoxypropionate herbicides do not inhibit acetyl-CoA carboxylase.     

Loss of the Acetyl-CoA Carboxylase (accD) Gene in Poales

The loss of a gene is a rare genome-shaping event and as such, contributes important information to our understanding of phylogenetic relationships between genes and between species. Deletion of a gene can help to define a lineage. Here, we utilize the deletion of the chloroplast gene encoding the acetyl-CoA carboxylase subunit D (accD) to help us define lineages based on its presence or absence in monocot plants specifically in Poales. Southern blots were constructed and probed for the presence of the accD gene. The existence of the portion of the accD gene represented by the probe was also verified by PCR and sequencing. Sequences were utilized for assembly of gene trees to link the absence or partial loss of the gene with a particular lineage. Here, we report new information adding accD gene presence in the Xyridaceae, pseudogene presence in the Flagellariaceae, and the absence of accD in Restionaceae and Joinvilleaceae. Based on our findings and the available data for accD sequences in Poales, we propose a model for accD loss beginning with a single event creating a pseudogene in the common ancestor to the restiid and graminid clades within Poales. This model also suggests that this pseudogene is carried as the ancestral state throughout most of the divergence of the Poales, a condition that would explain the highly varied pattern of accD pseudogene presence or gene absence in members of the restiid and graminid clades.     

Purification and Characterization of Acetyl-CoA Carboxylase from the Diatom Cyclotella cryptica

Acetyl-CoA carboxylase from the diatom Cyclotella cryptica has been purified to near homogeneity by the use of ammonium sulfate fractionation, gel filtration chromatography, and affinity chromatography with monomeric avidin-agarose. The specific activity of the final preparation was as high as 14.6 micromoles malonyl-CoA formed per milligram protein per minute, indicating a 600-fold purification. Native acetyl-CoA carboxylase has a molecular weight of approximately 740 kilodaltons and appears to be composed of four identical biotin-containing subunits. The enzyme has maximal activity at pH 8.2, but enzyme stability is greater at pH 6.5. K_m values for MgATP, acetyl-CoA, and HCO₃- were determined to be 65, 233, and 750 micromolar, respectively. The purified enzyme is strongly inhibited by palmitoyl-CoA, and is inhibited to a lesser extent by malonyl-CoA, ADP, and phosphate. Pyruvate stimulates enzymatic activity to a slight extent. Acetyl-CoA carboxylase from Cyclotella cryptica is not inhibited by cyclohexanedione or aryloxyphenoxypropionic acid herbicides as strongly as monocot acetyl-CoA carboxylases; 50% and 0% inhibition was observed in the presence of 23 micromolar clethodim and 100 micromolar haloxyfop, respectively.     

Acetyl-CoA Carboxylase Inhibitors from Avocado (Persea americana Mill) Fruits

A methanol extract of avocado fruits showed potent inhibitory activity against acetyl-CoA carboxylase, a key enzyme in fatty acid biosynthesis. The active principles were isolated and identified as (5E,12Z,15Z)-2-hydroxy-4-oxoheneicosa-5,12,15-trienyl (1), (2R,12Z,15Z)-2-hydroxy-4-oxoheneicosa-12,15-dienyl (2), (2R^*,4R^*)-2,4-dihydroxyheptadec-16-enyl (3) and (2R^*,4R^*)-2,4-dihydroxyheptadec-16-ynyl (4) acetates by instrumental analyses. The IC₅₀ of the compounds were 4.0×10^-6, 4.9×10^-6, 9.4×10^-6, and 5.1×10^-6M, respectively.     

Cyclohexanedione Herbicides Are Selective and Potent Inhibitors of Acetyl-CoA Carboxylase from Grasses

Biochemical studies of plant species susceptible to the cyclohexanedione herbicides, alloxydim, sethoxydim, and clethodim, have demonstrated that these selective grass herbicides inhibit acetyl-coenzyme A carboxylase, the second enzyme common to both fatty acid and flavonoid biosynthetic pathways. The K_is for the cyclohexanediones tested ranged from 0.02 to 1.95 micromolar, depending on the species. The enzyme isolated from broadleaf plants was much less sensitive to inhibition by these herbicides (K_is from 53 micromolar to 2.2 millimolar). These results may explain the mechanism of action of these herbicides and their selectivity for monocotyledonous species.