Takei Yoshio, Joss Jean M P, Kloas Werner, Rankin J Cliff
Ocean Research Institute, University of Tokyo, 164-8639, Japan.
Gen Comp Endocrinol. 2004 Feb;135(3):286-92. doi: 10.1016/j.ygcen.2003.10.011.
In order to delineate further the molecular evolution of the renin-angiotensin system in vertebrates, angiotensin I (ANG I) has been isolated after incubation of plasma and kidney extracts of emu (Dromiceus novaehollandiae), axolotl (Ambystoma mexicanum), and sea lamprey (Petromyzon marinus). The identified sequences were [Asp1, Val5, Asn9] ANG I in emu, [Asp1, Val5, His9] ANG I in axolotl, and [Asn1, Val5, Thr9] ANG I in sea lamprey. These results confirmed the previous findings that tetrapods have Asp and fishes including cyclostomes have Asn at the N-terminus, and that the amino acid residue at position 9 of ANG I was highly variable but, those at other positions were well conserved among different species. Since Asp and Asn are convertible during incubation, angiotensinogen sequences were searched in the genome and/or EST database to determine the N-terminal amino acid residue from the gene. The screening detected 12 tetrapod (10 mammalian, one avian, and one amphibian) and seven teleostean angiotensinogen sequences. Among them, all tetrapods have [Asp1] ANG except for Xenopus, and all teleosts have [Asn1] ANG, thereby confirming the above rule. Comparison of the vasopressor activity in the eel revealed that [Asn1] ANG I and II were more potent than [Asp1] peptides, which was opposite to the previous results in mammals and birds, in which [Asp1] ANG I and II were more potent. Collectively, the present results support the general rule that tetrapods have [Asp1] ANG and fishes including cyclostomes have [Asn1] ANG. However, an aquatic anuran (Xenopus) has [Asn1] ANG in its gene despite another aquatic urodele (axolotl) has [Asp1] ANG. From the functional viewpoint, homologous [Asn1] ANG was more potent in fish as is homologous [Asp1] ANG in tetrapods, suggesting that ANG II molecule has undergone co-evolution with its receptor during vertebrate phylogeny.
为了进一步阐明脊椎动物肾素 - 血管紧张素系统的分子进化,在对鸸鹋(Dromiceus novaehollandiae)、蝾螈(Ambystoma mexicanum)和海七鳃鳗(Petromyzon marinus)的血浆和肾脏提取物进行孵育后,分离出了血管紧张素I(ANG I)。鉴定出的序列在鸸鹋中为[天冬氨酸1,缬氨酸5,天冬酰胺9]ANG I,在蝾螈中为[天冬氨酸1,缬氨酸5,组氨酸9]ANG I,在海七鳃鳗中为[天冬酰胺1,缬氨酸5,苏氨酸9]ANG I。这些结果证实了先前的发现,即四足动物在N端有天冬氨酸,包括圆口纲的鱼类在N端有天冬酰胺,并且ANG I第9位的氨基酸残基高度可变,但其他位置的氨基酸残基在不同物种间保守性良好。由于天冬氨酸和天冬酰胺在孵育过程中可相互转换,因此在基因组和/或EST数据库中搜索血管紧张素原序列,以从基因层面确定N端氨基酸残基。筛选检测到12种四足动物(10种哺乳动物、1种鸟类和1种两栖动物)和7种硬骨鱼的血管紧张素原序列。其中,除了非洲爪蟾外,所有四足动物都有[天冬氨酸1]ANG,所有硬骨鱼都有[天冬酰胺1]ANG,从而证实了上述规律。对鳗鱼中血管升压活性的比较表明,[天冬酰胺1]ANG I和II比[天冬氨酸1]肽更有效,这与先前在哺乳动物和鸟类中的结果相反,在哺乳动物和鸟类中[天冬氨酸1]ANG I和II更有效。总体而言,目前的结果支持了一般规律,即四足动物有[天冬氨酸1]ANG,包括圆口纲的鱼类有[天冬酰胺1]ANG。然而,一种水生无尾目动物(非洲爪蟾)在其基因中有[天冬酰胺1]ANG,而另一种水生有尾目动物(蝾螈)有[天冬氨酸1]ANG。从功能角度来看,同源的[天冬酰胺1]ANG在鱼类中更有效,就如同同源的[天冬氨酸1]ANG在四足动物中一样,这表明在脊椎动物系统发育过程中,ANG II分子与其受体共同进化。
