我国文昌鱼研究50年

文昌鱼是研究脊椎动物起源与进化十分珍贵的模式动物。近50年来,我国在文昌鱼生物学研究方面取得很大进展。本文系统介绍了我国学者在文昌鱼发育、免疫和进化方面所取得的研究成果。     

文昌鱼抗金葡菌感染差减文库的构建及免疫相关基因分析

适应性免疫的起源一直是免疫学研究的关键问题.文昌鱼被认为是最接近于脊椎动物的祖先 自从被发现以来一直是研究脊椎动物起源与进化机制的经典模式动物.为了在文昌鱼中寻找适应性免疫系统的分子证据,采用金黄色葡萄球菌感染文昌鱼以调查免疫的起源.应用抑制性差减杂交(SSH)技术,通过对差减文库克隆序列的测定,共获得588个表达序列标签(EST).对这些EST进行生物信息学分析和进一步功能分类,发现了一些免疫上调基因,如免疫调控基因、凋亡相关基因、细胞黏附相关基因、转录相关基因、信号传导相关基因等,以及一些非免疫相关基因;这些基因在文昌鱼中绝大多数为首次报道.金黄色葡萄球菌差减文库的成功构建,为调查文昌鱼抗细菌感染的分子事件提供了重要线索,对于这些新发现基因的进一步研究将有助于深入了解免疫系统起源与进化的机制.     

文昌鱼分类学研究及展望

文昌鱼是最接近脊椎动物直接祖先的现生动物,在脊椎动物起源与演化研究中占有极其重要的位置。近年来,对文昌鱼的研究已引起越来越多的科学家的兴趣,然而作为生命科学研究的重要基础,这类动物的分类学研究相对滞后。依据已有的中国文昌鱼资源调查资料,中国沿海文昌鱼的分布应当十分广泛,即只要有适合文昌鱼栖息的沙滩,均有文昌鱼分布的可能。根据目前的分类学研究成果和动物命名法中的优先权原则,建议将产于青岛等地的文昌鱼种名Brnachiostoma belcheri tsingtauense订正为B.japonicus,南方的文昌鱼保留其原种名B.belcheri。由此,目前分布在中国沿海的鳃口文昌鱼属(Branchiostoma)至少有2种,侧殖文昌鱼属(Epigonichthys)有1～3种,漂浮文昌鱼(Amphioxides pelagicus)1种。DNA分子标记技术在文昌鱼分类学研究中将会发挥更大的作用。     

白氏文昌鱼单个体基因组BAC文库的构建

隶属于头索动物亚门的文昌鱼是现存生物中最近似于脊椎动物亚门直接祖先的一个类群, 具有重要的进化地位, 是研究脊椎动物原始祖先的重要材料和模式动物。随着文昌鱼实验室连续繁殖的成功, 全基因组测序成为中国文昌鱼模式化急需完成的工作之一。文章从单条雄性白氏文昌鱼精巢组织中提取高质量的基因组DNA, 经EcoRⅠ限制性内切酶和EcoRⅠ甲基化酶酶切, 脉冲场电泳选择合适酶切DNA片段, 连接线性磷酸化的载体pCC1BAC, 转化大肠杆菌EPI300 E. coli, 构建了含有44 706个克隆的全基因组BAC( Bacterial artificial chromosome)文库, 该文库平均插入片段80 kb,具有9倍的基因组覆盖率, 基本能够满足功能基因等研究需要, 为中国文昌鱼全基因组测序打下基础。     

厦门两种文昌鱼染色体的制备与观察(英文）

文昌鱼的进化地位十分重要,对其染色体的研究在进化和比较基因组学方面有重要意义。然而文昌鱼的染色体制备困难,使研究受到了限制。本文介绍了一种改良的文昌鱼胚胎细胞染色体标本制备方法,以及用文昌鱼成体再生细胞制备染色体,首次获得了文昌鱼体细胞中期染色体标本,并观察了厦门2种文昌鱼的染色体,其中白氏文昌鱼（Branchiostoma belcheri）二倍体2n=40,日本文昌鱼（B. japonicum）二倍体2n=36。再次从细胞分类学角度证实白氏文昌鱼和日本文昌鱼作为两个独立物种的分类地位。     

文昌鱼肝盲囊与脊椎动物肝脏起源

早期形态和胚胎学研究结果表明, 文昌鱼哈氏窝、内柱和肝盲囊分别是脊椎动物脑垂体、甲状腺和肝脏的同源器官。文章总结了近年来有关文昌鱼肝盲囊与脊椎动物肝脏之间关系的研究成果, 揭示文昌鱼肝盲囊和脊椎动物肝脏具有同源性, 并证明文昌鱼中存在类似脊椎动物的GH/IGF (Growth hormone/insulin-like growth factor)和TH/THR (Thyroid hormone/thyroid hormone receptor)信号通路, 为脊椎动物肝脏起源于文昌鱼肝盲囊样结构提供了分子水平证据。     

文昌鱼左右体轴建立机制的研究进展

两侧对称动物左右体轴建立机制研究是发育生物学领域重要的基础科学问题之一。文昌鱼(amphioxus)由于其特殊的进化地位以及与脊椎动物相似的胚胎发育模式和身体构筑方式,是研究动物左右体轴建立机制的理想模式物种。近年来随着文昌鱼室内全人工繁育技术、高效显微注射技术和基因敲除技术的建立,国内外学者在左右体轴建立机制研究上取得了丰硕的成果。本文从文昌鱼胚胎左右不对称发育特点出发,总结了近期文昌鱼左右体轴建立方面取得的研究进展,并提出了文昌鱼左右体轴调控网络图:纤毛运动导致Hh蛋白在文昌鱼中不对称分布(L相似文献   

文昌鱼的实验室繁育及子二代获得

文昌鱼特殊的进化地位、简单的器官系统和终生透明的躯体等特征，使其很有希望成为一个新型实验室模式动物。要实现文昌鱼的模式动物化，实验室内全人工条件下繁殖是关键的第一步。为此，我们于2003年9月和2004年4月两次采集产于厦门海域的2种文昌鱼，开展实验室内养殖研究。经过3年多的持续实验室养殖，继2005年夏季于实验室内繁殖出子一代文昌鱼后，又在2006年夏季成功获得了这两种文昌鱼的子二代，初步实现文昌鱼在实验室内的全人工养殖。对子代文昌鱼养殖的初步观察发现，不同水温对生长发育速度有一定影响，提示有可能通过水温控制实现文昌鱼一年多次产卵的目的。目前这两种文昌鱼子二代幼体已完成变态，进入亚成体生长发育阶段，其体长分别已达14.6 mm(日本文昌鱼Branchiostoma japonicum)和6.5 mm(白氏文昌鱼B. belcheri)。     

文昌鱼的实验室繁育及子二代获得

文昌鱼特殊的进化地位、简单的器官系统和终生透明的躯体等特征,使其很有希望成为一个新型实验室模式动物。要实现文昌鱼的模式动物化,实验室内全人工条件下繁殖是关键的第一步。为此,我们于2003年9月和2004年4月两次采集产于厦门海域的2种文昌鱼,开展实验室内养殖研究。经过3年多的持续实验室养殖,继2005年夏季于实验室内繁殖出子一代文昌鱼后,又在2006年夏季成功获得了这两种文昌鱼的子二代,初步实现文昌鱼在实验室内的全人工养殖。对子代文昌鱼养殖的初步观察发现,不同水温对生长发育速度有一定影响,提示有可能通过水温控制实现文昌鱼一年多次产卵的目的。目前这两种文昌鱼子二代幼体已完成变态,进入亚成体生长发育阶段,其体长分别已达14.6mm(日本文昌鱼Branchiostomajaponicum)和6.5mm(白氏文昌鱼B.belcheri)。     

基于COXI基因的太平洋西岸文昌鱼地理种群分析

文昌鱼是进化发育研究的重要模式动物,目前实验材料均采自野外.因此,对其进行正确的物种鉴定和地理种群的遗传分化分析十分必要.该研究扩增并测定了COX 1基因部分序列,结合NCBI数据库中的COX 1序列信息,对太平洋西岸文昌鱼的种类和地理种群分化情况进行了分析.结果表明,马来文昌鱼(Branchiostoma malayanum)、白氏文昌鱼(B.belcheri)和日本文昌鱼(B.japonicum)这3个种之间的遗传差异很大,再次证实3个物种的有效性,同时提出应当审慎对待NCBI数据库中文昌鱼的种名标注;太平洋西岸文昌鱼属Branchiostoma的3种文昌鱼群体遗传多样性均处于较高水平,同一物种的不同地理种群间没有出现明显的遗传分化,反映了海洋动物的基因交流较容易,不同海域隔离较弱.     

厦门两种文昌鱼染色体的制备与观察

文吕鱼的进化地位十分重要,对其染色体的研究在进化和比较基因组学方面有重要意义.然而文昌鱼的染色体制备困难,使研究受到了限制.本文介绍了一种改良的义昌鱼胚胎细胞染色体标本制备方法,以及用文昌鱼成体再生细胞制备染色体,首次获得了文昌鱼体细胞中期染色体标本,并观察了厦门2种文昌鱼的染色体,其中白氏文吕鱼(Branchiostoma belcheri)二倍体2n=40,日本文昌鱼(B.japonicum)二倍体2n=36.再次从细胞分类学角度证实白氏文昌鱼和日本文昌鱼作为两个独立物种的分类地位.     

Characterization of Evolutionarily Conserved MicroRNAs in Amphioxus

Amphioxus is an extant species closest to the ancestry of vertebrates.Observation of microRNA(miRNA)distribution of amphioxus would lend some hints for evolutionary research of vertebrates.In this study,using the publicly available scaffold data of the Florida amphioxus(Branchiostoma floridae)genome,we screened and characterized homologs of miRNAs that had been identified in other species.In total,68 pieces of such homologs were obtained and classified into 33 families.Most of these miRNAs were distributed as clusters in genome.Inter-species comparison showed that many miRNAs,which had been thought as vertebrate-or mammal-specific before,were also present in amphioxus,while some miRNAs that had been considered as protostome-specific before also existed in amphioxus.Compared with ciona,amphioxus had an apparent miRNA gene expansion,but phylogenetic analysis showed that the duplicated miRNAs or clusters of amphioxus had a higher homology level than those duplicated ones in vertebrates.     

Transposon diversity is higher in amphioxus than in vertebrates: functional and evolutionary inferences

Transposable elements (TEs) are main components of eukaryote genomes-up to 50% in some vertebrates-which can replicate and jump to new locations. TEs contribute to shape genome evolution, actively by creating new genes (or exons) or altering gene expression as consequence of transposition, and passively by serving as illegitimate recombinational hotspots. Analysis of amphioxus TEs can help to shed light on the ancestral status of chordate TEs and to understand genome evolution in cephalochordates and early vertebrates. The Branchiostoma floridae genome project has revealed that TE content constitutes ～28% of the amphioxus genome. Amphioxus TEs belong to more than 30 superfamilies, which represent a higher diversity than in vertebrates. Amphioxus TE families are also highly heterogeneous as generally none of their members are drastically more abundant than others, and none of the TEs seems to have suffered any massive expansion. Such diversity and heterogeneity make the amphioxus genome not to be particularly prone to major evolutionary changes mediated by TEs, and therefore favoring genomic evolutionary stasis. Comparison of TE diversity and content between amphioxus and vertebrates allows us to discuss whether or not a burst of TEs happened after the two rounds of whole-genome duplication that occurred during early vertebrate evolution.     

Characterization of a microsomal retinol dehydrogenase gene from amphioxus: retinoid metabolism before vertebrates

Amphioxus, a member of the subphylum Cephalochordata, is thought to be the closest living relative to vertebrates. Although these animals have a vertebrate-like response to retinoic acid, the pathway of retinoid metabolism remains unknown. Two different enzyme systems - the short chain dehydrogenase/reductases and the cytosolic medium-chain alcohol dehydrogenases (ADHs) - have been postulated in vertebrates. Nevertheless, recent data show that the vertebrate-ADH1 and ADH4 retinol-active forms originated after the divergence of cephalochordates and vertebrates. Moreover, no data has been gathered in support of medium-chain retinol active forms in amphioxus. Then, if the cytosolic ADH system is absent and these animals use retinol, the microsomal retinol dehydrogenases could be involved in retinol oxidation. We have identified the genomic region and cDNA of an amphioxus Rdh gene as a preliminary step for functional characterization. Besides, phylogenetic analysis supports the ancestral position of amphioxus Rdh in relation to the vertebrate forms.     

Exploring developmental, functional, and evolutionary aspects of amphioxus sensory cells

Amphioxus has neither elaborated brains nor definitive sensory organs, so that the two may have evolved in a mutually affecting manner and given rise to the forms seen in extant vertebrates. Clarifying the developmental and functional aspects of the amphioxus sensory system is thus pivotal for inferring the early evolution of vertebrates. Morphological studies have identified and classified amphioxus sensory cells; however, it is completely unknown whether the morphological classification makes sense in functional and evolutionary terms. Molecular markers, such as gene expression, are therefore indispensable for investigating the developmental and functional aspects of amphioxus sensory cells. This article reviews recent molecular studies on amphioxus sensory cells. Increasing evidence shows that the non-neural ectoderm of amphioxus can be subdivided into molecularly distinct subdomains by the combinatorial code of developmental cues involving the RA-dependent Hox code, suggesting that amphioxus epithelial sensory cells developed along positional information. This study focuses particularly on research involving the molecular phylogeny and expression of the seven-transmembrane, G protein-coupled receptor (GPCR) genes and discusses the usefulness of this information for characterizing the sensory cells of amphioxus.     

The amphioxus Hairy family: differential fate after duplication

Vertebrate Hairy genes are highly pleiotropic and have been implicated in numerous functions, such as somitogenesis, neurogenesis and endocrine tissue development. In order to gain insight into the timing of acquisition of these roles by the Hairy subfamily, we have cloned and studied the expression pattern of the Hairy gene(s) in amphioxus. The cephalochordate amphioxus is widely believed to be the living invertebrate more closely related to vertebrates, the genome of which has not undergone the massive gene duplications that took place early during vertebrate evolution. Surprisingly, we have isolated eight Hairy genes from the 'pre-duplicative' amphioxus genome. In situ hybridisation on amphioxus embryos showed that Hairy genes had experienced a process of subfunctionalisation that is predicted in the DDC model (for duplication-degeneration-complementation). Only the summation of four out of the eight Amphi-Hairy genes expression resembles the expression pattern of vertebrate Hairy genes, i.e. in the central nervous system, presomitic mesoderm, somites, notochord and gut. In addition, Amphi-Hairy genes expression suggest that amphioxus early somites are molecularly prefigured in an anteroposterior sequence in the dorsolateral wall of the archenteron, and the presence of a midbrain/hindbrain boundary. The expansion of the amphioxus Hairy subfamily request for caution when deducing the evolutionary history of a gene family in chordates based in the singularity of the amphioxus genome. Amphioxus may resemble the ancestor of the vertebrates, but it is not the ancestor, only its closest living relative, a privileged position that should not assume the freezing of its genome.     

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.