Evolution of the Hedgehog Gene Family

Effective intercellular communication is an important feature in the development of multicellular organisms. Secreted hedgehog (hh) protein is essential for both long- and short-range cellular signaling required for body pattern formation in animals. In a molecular evolutionary study, we find that the vertebrate homologs of the Drosophila hh gene arose by two gene duplications: the first gave rise to Desert hh, whereas the second produced the Indian and Sonic hh genes. Both duplications occurred before the emergence of vertebrates and probably before the evolution of chordates. The amino-terminal fragment of the hh precursor, crucial in long- and short-range intercellular communication, evolves two to four times slower than the carboxyl-terminal fragment in both Drosophila hh and its vertebrate homologues, suggesting conservation of mechanism of hh action in animals. A majority of amino acid substitutions in the amino- and carboxyl-terminal fragments are conservative, but the carboxyl-terminal domain has undergone extensive insertion-deletion events while maintaining its autocleavage protease activity. Our results point to similarity of evolutionary constraints among sites of Drosophila and vertebrate hh homologs and suggest some future directions for understanding the role of hh genes in the evolution of developmental complexity in animals.     

Evolution of the Vertebrate Resistin Gene Family

Resistin (encoded by Retn) was previously identified in rodents as a hormone associated with diabetes; however human resistin is instead linked to inflammation. Resistin is a member of a small gene family that includes the resistin-like peptides (encoded by Retnl genes) in mammals. Genomic searches of available genome sequences of diverse vertebrates and phylogenetic analyses were conducted to determine the size and origin of the resistin-like gene family. Genes encoding peptides similar to resistin were found in Mammalia, Sauria, Amphibia, and Actinistia (coelacanth, a lobe-finned fish), but not in Aves or fish from Actinopterygii, Chondrichthyes, or Agnatha. Retnl originated by duplication and transposition from Retn on the early mammalian lineage after divergence of the platypus, but before the placental and marsupial mammal divergence. The resistin-like gene family illustrates an instance where the locus of origin of duplicated genes can be identified, with Retn continuing to reside at this location. Mammalian species typically have a single copy Retn gene, but are much more variable in their numbers of Retnl genes, ranging from 0 to 9. Since Retn is located at the locus of origin, thus likely retained the ancestral expression pattern, largely maintained its copy number, and did not display accelerated evolution, we suggest that it is more likely to have maintained an ancestral function, while Retnl, which transposed to a new location, displays accelerated evolution, and shows greater variability in gene number, including gene loss, likely evolved new, but potentially lineage-specific, functions.     

Evolution of a Neuropeptide Family: Gonadotropin-Releasing Hormone

SYNOPSIS. Gonadotropin-releasing hormone (GnRH), a small peptidein the brain, is essential for reproduction. It is now clearthat GnRH is part of a family of closely related molecules.The primary structure has been identified for 4 GnRH molecules:mammalian, chicken I, chicken II and salmon. During evolutionthe molecule has been conserved in length, terminal amino acidstructure, 70–90% of amino acid sequence and the His²Trp³residues,residues, which are important in the release of gonadotropin.Alterations have occurred in positions 5, 7 and 8, regions thoughtto be involved in receptor binding. The receptors for GnRH haveapparently evolved also in that the mammalian and avian receptorsvary considerably in their ability to bind different GnRH molecules.Other GnRH family members have been distinguished indirectlyby chromatographic or immunological means; 3 different GnRH-likemolecules are present, respectively, in lamprey, sturgeon andsalmon (a second form). Several GnRH-like molecules includingthose in chondrichthyes have not yet been distinguished fromthe proposed salmon II molecule. The lamprey GnRH-like moleculemay be a nodal point inthe analysis of the ancestral molecule;hagfish do not contain a detectable GnRH molecule. The elucidationof the GnRH precursor molecule in human placenta showed thepresence of a 53-amino-acid gene-related peptide of unknownfunction, but did not reveal the basis for expression of multipleGnRH forms in many nonmammalian species. GnRH has a varietyof novel functions in addition to release of gonadotropin fromthe pituitary. During evolution certain functions such as thosein the retina and sympathetic ganglia have apparently disappearedin amniotes, but GnRH placental functions have appeared in mammals.     

Evolution of the Metazoan-Specific Importin α Gene Family

Importin αs are import receptors for nuclear localization signal-containing proteins. Most animal importin αs assort into α1, α2, and α3 groups. Studies in Drosophila melanogaster, Caenorhabditis elegans, and mouse suggest that the animal importin α gene family evolved from ancestral plant-like genes to serve paralog-specific roles in gametogenesis. To explore this hypothesis we extended the phylogenetic analysis of the importin α gene family to nonbilateral animals and investigated whether animal-like genes occur in premetazoan taxa. Maximum likelihood analysis suggests that animal-like importin α genes occur in the Choanoflaggelate Monosiga brevicollis and the amoebozoan Dictyostelium; however, both of these results are caused by long-branch attraction effects. The absence of animal-like α genes in premetazoan taxa is consistent with the hypothesis that they duplicated and then specialized to function in animal gametogenesis. The gene structures of the importin αs provide insight into how the animal importin α gene family may have evolved from the most likely ancestral gene. Interestingly, animal α1s are more similar to plant and fungal α1-like sequences than they are to animal α2s or α3s. We show that animal α1 genes share most of their introns with plant α1-like genes, and α2s and α3s share many more intron positions with each other than with the α1s. Together, phylogenetics and gene structure analysis suggests a parsimonious path for the evolution of the mammalian importin α gene family from an ancestral α1-like progenitor. Finally, these results establish a rational basis for a unified nomenclature of the importin α gene family.     

Pattern of Nucleotide Substitutions in Growth Hormone-Prolactin Gene Family: A Paradigm for Evolution by Gene Duplication

The growth hormone-prolactin gene family in mammals is an interesting example of evolution by gene duplication. Divergence among members of duplicated gene families and among species was examined by using reported gene sequences of growth hormone, prolactin and their receptors. Sequence divergence among species was found to show a general tendency in which a generation-time effect is pronounced for synonymous substitutions but not so for nonsynonymous substitutions. Divergence among duplicated genes is characterized by the relatively high rate of nonsynonymous substitutions, i.e., the rate is close to that of synonymous ones. In view of the stage- and tissue-specific expression of duplicated genes, some of the amino acid substitutions among duplicated genes is likely to be caused by positive Darwinian selection.     

Unc5基因家族多样性进化的研究

Uncoordinated-5(Unc5)基因家族属于经典的轴突导向基因家族。为了探讨Unc5的进化和分化规律,首先通过序列比对和蛋白质结构预测鉴定了Unc5基因家族成员的起源和分布,再利用PAML和DIVERGE软件分析了各基因亚型的进化选择压力和功能歧化。结果表明,Unc5基因家族在脊椎动物中受到了不同程度的选择压力,其中Unc5C基因型受到了纯化选择作用,而Unc5A、Unc5B和Unc5D基因型受到了正选择作用,并且在这3个基因型中分别检测到了8个、1个和6个正选择位点。此外,DIVERGE软件检测出38个I型功能歧化位点和97个Ⅱ型功能歧化位点。这些正选择位点和功能分歧位点为进一步研究Unc5蛋白的结构和功能提供了参考和依据。     

miR-34基因家族的分子进化

根据miRNA基因在进化中高度保守的特点,利用生物信息学方法在目前已测序的动物物种中搜寻参与哺乳动物早期发育调控的mir-34基因的同源序列,在33个不同的动物物种中获得了miR-34基因的54条同源序列,其中18条为新发现的序列。表明miR-34是高度保守的,广泛存在于后生动物中。目前发现的mir-34基因80%位于基因间隔区,少数位于蛋白编码基因的内含子区和3′UTR上。不同动物中,mir-34基因成熟序列的同源性为68%,前体序列为38.89%。在无脊椎动物中只有一个mir-34,而在几乎所有的脊椎动物中都有mir-34a,mir-34b,mir-34c,形成miR-34基因家族。系统进化分析表明,脊椎动物中miR-34基因家族是通过基因的串联和局部重复形成的,这个过程中伴随着个别碱基的变异。     

人生长素基因的合成及克隆

根据人生长素基因的氨基酸序列,选择大肠杆菌所偏好的密码子,人工设计并合成了20个寡核苷酸片断。通过重叠区扩增法,利用PCR成功地合成了人生长激素基因的全序列。经克隆测序,证明已成功地实现了人生长素基因的合成及克隆。     

猪生长激素基因表达质粒的构建及其转基因动物研究

将猪生长激素基因（ＰＧＨ）克隆到质粒ｐＵＣ１９上,经酶切分析,确定其酶切图谱．把ＰＧＨ转录起始位点以前的序列切掉,换上羊ＭＴ－１ａ基因的启动子,构建成可以调控的表达载体ｐＳＭＴＰＧＨ,用于转基因动物的研究．采用微注射法将线状ｐＳＭＴＰＧＨ导入猪、鼠和金鱼的受精卵中,得到了相应的转基因动物．对这些动物鉴定分析表明,外源基因整合率因动物不同而异,但该基因在这３种动物中的整合率均在９％以上,其生长速度都高于对照组．     

Molecular Evolution of the Plant R Regulatory Gene Family

Anthocyanin pigmentation patterns in different plant species are controlled in part by members of the myc-like R regulatory gene family. We have examined the molecular evolution of this gene family in seven plant species. Three regions of the R protein show sequence conservation between monocot and dicot R genes. These regions encode the basic helix-loop-helix domain, as well as conserved N-terminal and C-terminal domains; mean replacement rates for these conserved regions are 1.02 X 10(-9) nonsynonymous nucleotide substitutions per site per year. More than one-half of the protein, however, is diverging rapidly, with nonsynonymous substitution rates of 4.08 X 10(-9) substitutions per site per year. Detailed analysis of R homologs within the grasses (Poaceae) confirm that these variable regions are indeed evolving faster than the flanking conserved domains. Both nucleotide substitutions and small insertion/deletions contribute to the diversification of the variable regions within these regulatory genes. These results demonstrate that large tracts of sequence in these regulatory loci are evolving at a fairly rapid rate.     

斜带石斑鱼生长激素/催乳素家族基因cDNAs的分子克隆及其进化意义

从斜带石斑鱼垂体提取总。RNA,再取其50ng合成SMART cDNA。从所构建的垂体SMART cDNA质粒文库中筛选到生长激素／催乳素基因家族的2个成员的全长cDNA片段：生长激素(GH)基因全长为938bp,编码204个氨基酸;催乳素基因(PRI．)全长为1429bp,编码212个氨基酸。采用计算机软件Mega 2和CLUSTAL W1．64b对9种鱼的生长激素／催乳素基因家族的3个成员(GH、PRL和生长催乳素SL)的氨基酸序列进行系统分析,构建NJ分支系统树,对于序列中的插入／缺失位点则采用Pairaise Deletion,1000次自展(Bootstrap)分析计算各节点支持率。根据3个基因的氨基酸序列构建的系统树表明,石斑鱼与金头鲷、金鲈和牙鲆聚成一类,虹鳟与大马哈鱼聚成一类,鲫鱼与鲶鱼聚成一类,鳗鲡成另外一类。根据石斑鱼全长cDNA推断的氨基酸序列比较表明,SL相对GH和PRL有较高的保守性。石斑鱼的GH、PRL和SL的氨基酸同源性在24％～31％,但其C-端的氨基酸同源性较高,尤其是C-端的3个Cys是严格保守的。其中SL与GH的同源性(30．8％)高于与PRL的同源性(25．6％),GH和PRL的同源性最低(24．1％)。     

Episodic Molecular Evolution of Pituitary Growth Hormone in Cetartiodactyla

The sequence of growth hormone (GH) is generally strongly conserved in mammals, but episodes of rapid change occurred during the evolution of primates and artiodactyls, when the rate of GH evolution apparently increased substantially. As a result the sequences of higher primate and ruminant GHs differ markedly from sequences of other mammalian GHs. In order to increase knowledge of GH evolution in Cetartiodactyla (Artiodactyla plus Cetacea) we have cloned and characterized GH genes from camel (Camelus dromedarius), hippopotamus (Hippopotamus amphibius), and giraffe (Giraffa camelopardalis), using genomic DNA and a polymerase chain reaction technique. As in other mammals, these GH genes comprise five exons and four introns. Two very similar GH gene sequences (encoding identical proteins) were found in each of hippopotamus and giraffe. The deduced sequence for the mature hippopotamus GH is identical to that of dolphin, in accord with current ideas of a close relationship between Cetacea and Hippopotamidae. The sequence of camel GH is identical to that reported previously for alpaca GH. The sequence of giraffe GH is very similar to that of other ruminants but differs from that of nonruminant cetartiodactyls at about 18 residues. The results demonstrate that the apparent burst of rapid evolution of GH occurred largely after the separation of the line leading to ruminants from other cetartiodactyls.     

啮齿目泌乳刺激素基因家族的分子进化研究

在大鼠基因组数据库中搜索得到两个泌乳刺激素基因家族的新成员。进一步分析显示该基因家族起源于啮齿目和其他哺乳动物分歧之后,而且大部分基因座位的重排在大、小鼠分歧之前已经完成。但PL-Ⅰ和PL-Ⅱ基因簇却是例外,它们在基因树上以物种特异的方式聚类。结合基因转换的检验、染色体上相对位置比较和基因重复时间估计的结果,认为啮齿目PL-Ⅰ和PL-Ⅱ基因是物种特异的,它们由一系列在大、小鼠分歧之后发生的基因重复事件形成。结果还揭示了在啮齿目泌乳刺激素基因家族进化过程中持续不断的发生了基因重复和基因分化事件。     

Molecular Evolution of Prolactin Gene Family in Rodents

In this study, we identified two novel members of prolactin gene family in rat by blast searches against the published genomic database. A further analysis showed that gene duplications leading to PRL gene family in rodents occurred after rodents diverged from other mammals. Major reorganization of the gene loci in rodents was largely completed before the split of rat and mouse. But PL-I and PL-II genes are the exceptions, which have clustered in a species-specific manner in the phylogenetic tree. By combining results from gene conversion testing, relative chromosomal location comparison and estimated time for gene duplication, we believe that rodent PL-I and PL-II genes are species-specific and are the results of serial duplications which occurred after the divergence of mouse and rat. Our analysis also reveals that continual gene duplication and divergence occurred during the evolution of rodent PRL gene family.     

Expression of Porcine Growth Hormone Gene in CHO Cell

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促葡萄糖转运蛋白基因家族的分子进化研究

葡萄糖转运蛋白是一个在结构上相似功能上不同的多基因家族（ＧＬＵＴ１－ＧＬＵＴ５）。由于这一组蛋白和体内的葡萄糖利用有关,因此被认为是糖尿病胰岛素抵抗（抗性）的一个候选基因。本文比较了不同种生物这一基因家族的氨基酸和核苷酸顺序;推测了亲水性和疏水性分布;计算了蛋白质和核苷酸的进化距离,并在此基础上构建了分子进化树。研究表明：这一基因家族具有高度的同源性、极为相似的亲水性和疏水性分布以及结构的对称性。提示这一基因家族起源于一个共同的祖先并可能通过基因的重复而形成。这一进化机制可能有利于氨基酸结构的稳定及抵抗突变的作用。由于邻元法构建的进化树其分支长度存在差异,提示在这一基因家族的进化过程中,各分支上的进化速率并不相同。蛋白质进化距离和核苷酸进化距离所构建进化树的差异提示了在基因组中可能存在隐匿替换。两种方法构建的进化树都提示了ＧＬＵＴ１、３、４在结构和功能上要更为保守。     

Multiple Inter-Kingdom Horizontal Gene Transfers in the Evolution of the Phosphoenolpyruvate Carboxylase Gene Family

Pepcase is a gene encoding phosphoenolpyruvate carboxylase that exists in bacteria, archaea and plants,playing an important role in plant metabolism and development. Most plants have two or more pepcase genes belonging to two gene sub-families, while only one gene exists in other organisms. Previous research categorized one plant pepcase gene as plant-type pepcase (PTPC) while the other as bacteria-type pepcase (BTPC) because of its similarity with the pepcase gene found in bacteria. Phylogenetic reconstruction showed that PTPC is the ancestral lineage of plant pepcase, and that all bacteria, protistpepcase and BTPC in plants are derived from a lineage of pepcase closely related with PTPC in algae. However, their phylogeny contradicts the species tree and traditional chronology of organism evolution. Because the diversification of bacteria occurred much earlier than the origin of plants, presumably all bacterialpepcase derived from the ancestral PTPC of algal plants after divergingfrom the ancestor of vascular plant PTPC. To solve this contradiction, we reconstructed the phylogeny of pepcase gene family. Our result showed that both PTPC and BTPC are derived from an ancestral lineage of gamma-proteobacteriapepcases, possibly via an ancient inter-kingdom horizontal gene transfer (HGT) from bacteria to the eukaryotic common ancestor of plants, protists and cellular slime mold. Our phylogenetic analysis also found 48other pepcase genes originated from inter-kingdom HGTs. These results imply that inter-kingdom HGTs played important roles in the evolution of the pepcase gene family and furthermore that HGTsare a more frequent evolutionary event than previouslythought.