Nagasawa Tatsuki, Kawaguchi Mari, Sano Kaori, Yasumasu Shigeki
Department of Materials and Life Sciences, Faculty of Science and Technology, Sophia University, 7-1 Kioi-cho, Chiyoda-ku, Tokyo, Japan.
Department of Chemistry, Faculty of Science, Josai University, 1-1 Keyakidai, Sakado, Saitama, Japan.
J Exp Zool B Mol Dev Evol. 2015 Dec;324(8):720-32. doi: 10.1002/jez.b.22660. Epub 2015 Oct 30.
We investigated the evolution of the hatching enzyme gene using bester sturgeon (hybrid of Acipencer ruthenus and Huso huso), a basal member of ray-finned fishes. We purified the bester hatching enzyme from hatching liquid, yielding a single band on SDS-PAGE, then isolated its cDNA from embryos by PCR. The sturgeon hatching enzyme consists of an astacin family protease domain and a CUB domain. The CUB domains are present in frog and bird hatching enzymes, but not in teleostei, suggesting that the domain structure of sturgeon hatching enzyme is the tetrapod type. The purified hatching enzyme swelled the egg envelope, and selectively cleaved one of five egg envelope proteins, ZPAX. Xenopus hatching enzyme preferentially digests ZPAX, thus, the egg envelope digestion process is conserved between amphibians and basal ray-finned fish. Teleostei hatching enzymes cleave the repeat sequences at the N-terminal region of ZPB and ZPC, suggesting that the targets of the teleostei hatching enzymes differ from those of amphibians and sturgeons. Such repeat sequences were not found in the N-terminal region of ZPB and ZPC of amphibians and sturgeons. Our results suggest that the change in substrates of the hatching enzymes was accompanied by the mutation of the amino acid sequence of N-terminal regions of ZPB and ZPC. We conclude that the changes in the mechanism of egg envelope digestion, including the change in the domain structure of the hatching enzymes and the switch in substrate, occurred during the evolution of teleostei, likely triggered by the teleost-specific third whole genome duplication. J. Exp. Zool. (Mol. Dev. Evol.) 324B: 720-732, 2015. © 2015 Wiley Periodicals, Inc.
我们利用贝斯特鲟鱼(俄罗斯鲟和欧洲鳇的杂交种)这一硬骨鱼的基部成员,研究了孵化酶基因的进化。我们从孵化液中纯化出贝斯特鲟鱼的孵化酶,其在SDS - PAGE上呈现单一条带,然后通过PCR从胚胎中分离出其cDNA。鲟鱼孵化酶由一个阿斯他汀家族蛋白酶结构域和一个CUB结构域组成。CUB结构域存在于青蛙和鸟类的孵化酶中,但在硬骨鱼中不存在,这表明鲟鱼孵化酶的结构域结构是四足动物类型。纯化后的孵化酶使卵膜膨胀,并选择性地切割五种卵膜蛋白之一的ZPAX。非洲爪蟾孵化酶优先消化ZPAX,因此,卵膜消化过程在两栖动物和基部硬骨鱼之间是保守的。硬骨鱼的孵化酶切割ZPB和ZPC N端区域的重复序列,这表明硬骨鱼孵化酶的作用靶点与两栖动物和鲟鱼不同。在两栖动物和鲟鱼的ZPB和ZPC的N端区域未发现此类重复序列。我们的结果表明,孵化酶底物的变化伴随着ZPB和ZPC N端区域氨基酸序列的突变。我们得出结论,卵膜消化机制的变化,包括孵化酶结构域结构的变化和底物的转换,发生在硬骨鱼的进化过程中,可能是由硬骨鱼特有的第三次全基因组复制引发的。《实验动物学杂志(分子与发育进化)》324B:720 - 732,2015年。© 2015威利期刊公司
