ycaCR基因在文昌鱼早期胚胎表达研究

文昌鱼作为现存的与脊椎动物最接近的无脊椎动物,一直被作为研究生物进化和胚胎发育的典型材料.利用整体原位杂交方法对从文昌鱼肠cDNA文库克隆到的ycaCR基因进行基因的胚胎表达模式研究,结果显示该基因在早期胚胎发育阶段没有表达,在2天幼虫的原始消化道表达,暗示ycaCR基因可能在原始消化道内发挥生物学作用.     

Drosophila cathepsin B-like proteinase: a suggested role in yolk degradation

A cysteine, cathepsin B-like proteinase activity has been found in Drosophila embryos. It appears associated with yolk granules and its activity during embryogenesis correlates well with the degradation of these organelles. In mature oocytes, the enzyme is found in an inactive form which may be activated by limited proteolysis by a serine proteinase also present in oocytes. In early embryos, when solubilized in vitro, the cathepsin B-like proteinase is found in a form of high molecular mass (approx 1000 kDa). This decreases with development down to about 39 kDa, likely the mass of the free proteinase. The heavy form apparently results from the tight association with a yolk protein complex. The proteinase has been found in vitro to degrade readily the yolk polypeptides. The proteinase activity increases during early embryogenesis in parallel with the decrease in molecular weight of the heavy form, and decreases to low values in late embryos. We have also found that ammonium chloride can inhibit in vivo the degradation of yolk and, in parallel, the developmental inactivation of the proteinase. The results altogether suggest that the cathepsin B-like proteinase is implicated in yolk degradation in Drosophila.     

Identification and expression of amphioxus beta-microseminoprotein (MSP)-like gene encoding an ancient and rapidly evolving protein in chordates

The cDNA encoding beta-microseminoprotein-like (beta-MSPL) was identified from the gut cDNA library of amphioxus. It contains a 336 bp open reading frame corresponding to a deduced protein of 111 amino acids and has eight cysteines conserved and located at the same positions as those in the vertebrate beta-MSPs. At amino acid level, it shares 12-20% similarity to the vertebrate beta-MSPs, and seems lacking the signal peptide at the N-terminus. This not only confirms that beta-MSP is a rapidly evolving protein during phylogeny, but also provides further data on the degree of diversity between species of this protein. RT-PCR and Northern blotting show that amphioxus beta-MSPL is expressed in all tissues examined, suggesting that beta-MSPL plays a fundamental role. However, in situ hybridization reveals that positive hybridization signals were present in all blastomeres of the embryos from 4-cell to gastrula stages, while its expression is restricted exclusively to notochord, somites and primitive gut in neurulae and larvae, and disappears in the ectoderm including the neural tube differentiated from the ectoderm. This suggests that beta-MSPL is possibly involved in the differentiation of ectoderm during embryonic development of cephalochordate amphioxus though it is ubiquitously expressed in embryos prior to gastrula stage and in the adult animal.     

Characterization and expression of p23 gene in the amphioxus Branchiostoma belcheri

The cDNA AmphiP23, encoding an amphioxus p23, was identified from the gut cDNA library of amphioxus Branchiostoma belcheri. It contains a 513 bp open reading frame corresponding to a deduced protein of 170 amino acids. Phylogenetic analysis shows that vertebrate and invertebrate p23/p23-like proteins are each grouped together, with AmphiP23 falling at the base of vertebrate p23/p23-like clade, suggesting that the divergence of vertebrate and invertebrate p23 genes probably occurs prior to the split of invertebrate/vertebrate from a common ancestor around 550 million years ago. Northern blotting reveals a ubiquitous expression pattern of AmphiP23 in all adult tissues examined, while whole mount in situ hybridization demonstrates a tissue- and stage-specific expression pattern of AmphiP23 in developing embryos and larvae. Presumably, the ubiquitous expression pattern of AmphiP23 in adult amphioxus represents the ancestral type of p23 gene prior to its split to human paralogs p23 and tsp23, while the tissue- and stage-specific expression pattern during early embryonic development implicates a role of AmphiP23 in anterior/posterior patterning.