Schmitt D, Pakusch A E, Matern U
Institut für Biologie II, Universität Freiburg, Federal Republic of Germany.
J Biol Chem. 1991 Sep 15;266(26):17416-23.
Trans-Caffeoyl-CoA 3-O-methyltransferase is involved in the reinforcement of the plant cell wall under conditions that trigger the disease resistance response (Pakusch, A.-E., Kneusel, R.E., and Matern, U. (1989) Arch. Biochem. Biophys. 271, 488-494). Partial amino acid sequences of the enzyme from cultured parsley cells that had been treated with a crude elicitor were identified (Pakusch, A.-E., Matern, U., and Schiltz, E. (1991) Plant Physiol. 95, 137-143), and corresponding degenerated oligonucleotides of 29- and 30-nucleotide length were synthesized. Northern hybridizations with these probes revealed one specific RNA band, and the amount of this RNA appeared to be transiently induced upon elicitation of the cells. De novo enzyme synthesis was confirmed by Western blotting experiments using a specific antiserum. The time course of induction closely followed the pattern observed for phenylalanine ammonia-lyase and suggested the operational coordination of the methyltransferase with the general phenylpropanoid pathway in vivo. Full size cDNA of 1.258 kilobases was isolated in lambda gt11, sequenced and found to contain a remarkably long 5'-untranslated leader sequence followed by an open reading frame that codes for a 241-residue polypeptide representing the 27-kDa subunit of the native, dimeric parsley enzyme. Almost no homology was found to protein sequences filed in data banks. Southern hybridization with genomic DNA suggested that only one or two copies of the respective gene(s) are present in the parsley genome. Caffeoyl-CoA-specific methyltransferase activity was demonstrated in taxonomically widely diverse plants such as Dianthus caryophyllus (Caryophyllaceae), Carthamus tinctorius (Asteraceae) or Daucus carota, and Ammi majus (Apiaceae) where it is commonly induced by elicitor treatment. In Northern blots with RNA from Ammi or Daucus, parsley cDNA hybridized specifically to one band comparable in size to the parsley RNA, whereas Dianthus and Carthamus appear to code for slightly larger RNAs (roughly 1.45 and 1.3 kilobases, respectively). Slot-blot hybridizations revealed in all instances the rapid and transient increase of mRNA levels in response to elicitation. This emphasizes the integral role of the enzyme in disease resistance expression in plants far beyond parsley and also illustrates a new physiological context for the induction of 4-coumarate:CoA ligase.
反式咖啡酰辅酶A 3 - O -甲基转移酶在触发抗病反应的条件下参与植物细胞壁的强化(帕库施,A.-E.,克内泽尔,R.E.,和马特恩,U.(1989年)《生物化学与生物物理学报》271,488 - 494)。已鉴定了用粗激发子处理过的培养欧芹细胞中该酶的部分氨基酸序列(帕库施,A.-E.,马特恩,U.,和席尔茨,E.(1991年)《植物生理学》95,137 - 143),并合成了长度为29和30个核苷酸的相应简并寡核苷酸。用这些探针进行的Northern杂交显示出一条特异性RNA条带,并且该RNA的量在细胞受到激发时似乎会被短暂诱导。使用特异性抗血清的Western印迹实验证实了从头合成酶。诱导的时间进程与观察到的苯丙氨酸解氨酶的模式密切相关,并表明甲基转移酶与体内一般苯丙烷类途径的协同作用。在λgt11中分离出了1.258千碱基的全长cDNA,进行了测序,发现其含有一个非常长的5' - 非翻译前导序列,随后是一个开放阅读框,该阅读框编码一个241个残基的多肽,代表天然二聚体欧芹酶的27 - kDa亚基。几乎未发现与数据库中存档的蛋白质序列有同源性。用基因组DNA进行的Southern杂交表明,欧芹基因组中仅存在该相应基因的一两个拷贝。在分类学上广泛不同的植物如香石竹(石竹科)、红花(菊科)、胡萝卜和大阿米芹(伞形科)中都证明了咖啡酰辅酶A特异性甲基转移酶活性,在这些植物中,它通常由激发子处理诱导。在用来自大阿米芹或胡萝卜的RNA进行的Northern印迹中,欧芹cDNA特异性地与一条大小与欧芹RNA相当的条带杂交,而香石竹和红花似乎编码稍大一些的RNA(分别约为1.45和1.3千碱基)。狭缝印迹杂交在所有情况下都显示出mRNA水平响应激发而迅速且短暂地增加。这强调了该酶在植物抗病性表达中的不可或缺的作用,远远超出了欧芹的范围,也说明了诱导4 - 香豆酸:辅酶A连接酶的新的生理背景。
