人猿超科和旧大陆猴7种高等灵长类FKN全基因序列的测定及进化分析

测定人猿超科(人、黑猩猩、大猩猩、红毛猩猩和长臂猿)和旧大陆猴(猕猴和叶猴)7种高等灵长类FKN全基因序列, 探讨其系统进化分析。用简并引物PCR(Degenerated PCR)法分别扩增FKN的3个外显子, 其产物经琼脂糖凝胶回收、纯化后测序, 然后用BioEdit软件剪切拼接FKN基因全序列, 用DNAStar比对后比较基因和氨基酸序列同源性, Mega软件重构FKN基因进化树, 应用Datamonkey分析FKN的负选择位点。序列分析发现人猿超科较旧大陆猴FKN基因除了有散在的点突变外, 还有一明显的30 bp的核苷酸缺失突变; 人FKN基因序列与黑猩猩、大猩猩、红毛猩猩、长臂猿、猕猴和叶猴的同源性分别是99.2%、98.4%、98.1%、96.5%、95.9%和93.8%, 由此推导的氨基酸序列同源性分别是98.5%、98.0%、97.7%、94.7%、93.7%和90.5%; FKN基因进化树表明人与黑猩猩关系更近, FKN基因进化和通常认为的物种进化一致; Datamonkey分析结果显示FKN存在3个负选择位点53Q、84D、239N。成功获得人、黑猩猩、大猩猩、红毛猩猩、长臂猿、猕猴和叶猴7种高等灵长类物种FKN全基因序列, 为后续探讨FKN在高等灵长类物种进化过程中免疫学功能演变及其结构与功能的关系奠定基础。     

基于孕激素受体基因的类人猿亚目的分子系统学研究

通过对类人猿亚目中部分种类的孕激素受体基因进行分析,重建类人猿亚目的 系统发育关系.扩增并测定了来源于14个属的类人猿亚目物种的孕激素受体编码区序列,并基于这一序列数据,分别采用邻接法、最大简约法和最大似然法重建了系统发育关系.除了阔鼻下目,3种方法构建的系统发生树的拓扑结构类似且各节点支持率高.重建的人猿超科和猴超科内部亲缘关系支持多数人所认可的分类系统.本研究为黑猩猩和人的姐妹群关系提供了证据,提示黑猩猩比大猩猩或其他猿猴更接近人类.阔鼻下目中蜘蛛猴科、卷尾猴科和僧面猴科三者之间的系统发育关系在本研究中未得到很好辨析.     

猩猩和它的亲属

讲到猩猩,可以有两种含意,狭义的就是专指猩猩(Pongo)一种动物,广义的则可泛指属于猩猩科(Pongidae)的各种动物,包括猩猩、大猩猩(Gorilla)和两种黑猩猩(Pan)。中文     

腊玛古猿是人类的祖先吗?

凡是参观过博物馆的人类起源和进化的展览、或读过与此有关的科普书的人们,都会见过类似图1那样的人、猿进化系统图。从这个图上我们可以看出,腊玛古猿和西瓦古猿是两个完全不同的类型,前者代表人科的最早成员,是人类的直接祖先;后者属于猿科,是现代大猿类(黑猩猩,大猩猩和猩猩)的共     

人类的近亲——黑猩猩

在智力发展的阶梯上,黑猩猩可能是地球上仅次于人的最富有智慧的动物。在四种类人猿中,黑猩猩和大猩猩一起是与人最接近的;由于前者比较驯服,能够与实验者合作参加解谜一类实验,所以是极受欢迎的实验动物。人类学家和灵长类学家、心理学家想从黑猩猩身上,找寻人类起源和行为(包括学习、记忆、劳动和社会生活等)发展进化的线索,这样,黑猩猩自然就身价百倍,引起了科学界的广泛注意。与人何其相似黑猩猩又叫黑猿,学名为Pantroglodytes,属于猩猩科。它体毛黑色,眉嵴显著,脸面长而颚部前突。黑猩猩的两耳特别大,仅凭此点就     

腊玛古猿和西瓦古猿的形态特征及其系统关系——颅骨的形态与比较

本文通过具体的形态比较指出,禄丰腊玛古猿和西瓦古猿应为同一类型的雌雄个体,它们与现代猩猩比较相似,而与大猩猩和黑猩猩差别较大,因此,它们可看作是猩猩的祖先。猩猩这一支大约是在一千二百万年前开始从人猿超科的进化主干上分化出来的。     

红毛猩猩会“算计”

红毛猩猩属猿族,与大猩猩、黑猩猩及矮黑猩猩一起被称为“人类最直系的亲属”。目前,红毛猩猩在全世界只剩下不到3万只,主要在印度尼西亚的婆罗洲低地和苏门答腊洲地区生活。     

我所认识的三位"猿姑娘"——纪念古道尔考察野生黑猩猩60周年

正在动物界,和人类最接近的物种要数黑猩猩、大猩猩和猩猩了。其中,黑猩猩和人在基因结构上的相似程度竟达到96%以上。对于这三种类人猿的研究和保护自然成了世人瞩目的重大课题。她们原本是很普通的女性不入猿穴,焉知猿情。从20世纪60年代起,先后有三位考察家勇敢地踏进非洲、亚洲人迹罕至的密林,闯入猿群内部探索其行为的奥秘,最终成为猿群的知己。而这三位都不是男子而是     

牙齿珐琅质揭示的秘密

牙齿珐琅质层的厚度,被认为在古人类学研究方面有特殊的意义。珐琅质厚的属于人科,珐琅质薄的则属于猿类。近年来这一简单等式已被推翻。英国科学家劳·马丁在他的著作中,揭示了珐琅质形态的秘密。现代人的牙齿珐琅质很厚,而黑猩猩和大猩猩的较薄。以人类为     

程序性细胞死亡基因PDCD4的系统发育分析

程序性细胞死亡-4 (programmed cell death 4, PDCD4)基因是抑癌基因,在多种人肿瘤组织细胞中低表达甚至表达缺失,在肿瘤的发生、发展过程中发挥着重要的作用(孙玮等, 2007)。对从NCBI上下载的包括人、黑猩猩、大猩猩等12种哺乳类物种的序列进行分析,引用Blast+、MCScanX (Wang et al., 2012)、Colinearscan等生物信息学工具对核苷酸序列进行同源性共线性分析。用CLUSTALX (Thompson et al., 1997)软件进行多序列比对,基于最大似然法(ML)、最大简约法(MP)和邻接法(NJ)算法,使用系统发育分析软件MEGA7.0软件构建PDCD4基因的系统发育树,3种建树算法得到的拓扑结构基本一致。系统发育树表明:人、黑猩猩、大猩猩、苏门答腊猩猩和白颊长臂猿聚在一支,亲缘关系较近;家鼠、大白鼠、野猪和狗聚为一支;狒狒、猕猴和狨猴聚为一支。PDCD4基因的系统发育树与基于化石证据的物种树的一致,说明该基因的进化是伴随物种分歧一同发生的,是个相对古老的基因,有助于解决动物起源的相关信息和动物物种分化的相关问题。     

Evolution of the Tyrosinase Related Gene (TYRL) in Primates

Tyrosinase is the major enzyme responsible for the formation of melanin pigment and is found throughout the animal kingdom. In humans, the tyrosinase gene (TYR) maps to the long arm of chromosome 11 at band q14→q21, while a tyrosinase related gene (TYRL) maps to the short arm of chromosome 11 at pll.2°Cen. We and others have found that the TYRL locus contains sequences that are similar to exons IV and V of the authentic tyrosinase gene but lacks sequences of exons I, II, and III. In an attempt to understand the evolution of the human tyrosinase gene, we have analyzed TYR and TYRL in primates and have found that exons IV and V of the chimpanzee and gorilla TYR are very similar to the human, with the gorilla sequence being more similar than the chimpanzee. We have also found that the gorilla but not the chimpanzee contains a TYRL locus similar to the human TYRL locus.     

Comparative studies on an antigenicity of plasma proteins from humans and apes by ELISA: a close relationship of chimpanzee and human

1. Antigenic differences between human and ape plasma proteins were quantitatively investigated by enzyme-linked immunosorbent assay (ELISA) using antisera against human and chimpanzee plasmas. 2. With anti-human plasma serum, both the chimpanzee and gorilla were very close to the human, although the chimpanzee was slightly closer to the human than to the gorilla; relative immunological distance (relative ID) of the chimpanzee was 71, while that of the gorilla was 74. 3. With anti-chimpanzee plasma serum, the chimpanzee was found to be closely related to the human; relative ID of the chimpanzee was 58, while that of the gorilla was 75. 4. From these a molecular phylogeny for humans and apes was deduced; among living apes, the chimpanzee is the most closely related species to the human.     

A comparison of TSPY genes from Y-chromosomal DNA of the great apes and humans: Sequence,evolution, and phylogeny

The genes for testis-specific protein Y (TSPY) were sequenced from chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla), orangutan (Pongo pygmaeus), and baboon (Papio hamadryas). The sequences were compared with each other and with the published human sequence. Substitutions were detected at 144 of the 755 nucleotide positions compared. In overviewing five sequences, one deletion in human, four successive nucleotide insertions in orangutan, and seven deletions/insertions in baboon sequence were noted. The present sequences differed from that of human by 1.9% (chimpanzee), 4.0% (gorilla), 8.2% (orangutan), and 16.8% (baboon), respectively. The phylogenetic tree constructed by the neighbor-joining method suggests that human and chimpanzee are more closely related to each other than either of them is to gorilla, and this result is also supported by maximum likelihood and strict consensus maximum parsimony trees. The number of nucleotide substitutions per site between human and chimpanzee, gorilla, and orangutan for TSPY intron were 0.024, 0.048, and 0.094, respectively. The rates of nucleotide substitutions per site per year were higher in the TSPY intron than in the TSPY exon, and higher in the TSPY intron than in the ZFY (Zinc Finger Y) intron in human and apes. © 1996 Wiley-Liss, Inc.     

A comparative study on testicular microstructure and relative sperm production in gorillas, chimpanzees, and orangutans

We performed histological analyses for comparing testicular microstructure between the gorilla, chimpanzee, and orangutan. Testicular samples were obtained by autopsy or biopsy from 10 gorillas, 11 chimpanzees, and 7 orangutans from several zoos and institutes. The seminiferous epithelia were thick in the chimpanzee and orangutan but thin in the gorilla. Leydig cells in the interstitial tissue were abundant in the gorilla. The acrosomic system was extremely well developed in the orangutans. Our study reveals that the cycle of seminiferous epithelium in orangutan testis can be divided into ten stages, whereas that in human, chimpanzee, and gorilla testes can be divided into only six stages. Phylogenetic analyses of the number of divisions may indicate that the seminiferous epithelium of our common ancestor has changed since the orangutan diverged from it. Furthermore, we performed comparative analyses of testicular microstructure to estimate relative sperm production among these three animals, and proposed a new indicator (namely the spermatogenic index, SI) closely related to sperm production. The SI indicated that a chimpanzee usually produces about 223 times more sperm than a gorilla and about 14 times more than an orangutan. Our data demonstrate the significance of the SI for estimating sperm production, thus aiding our understanding of the reproductive strategy as well as testis weight and relative testis size in investigated primates.     

The tyrosinase gene in gorillas and the albinism of 'Snowflake'

The sequence of the tyrosinase (Tyr) gene coding tracts has been obtained for the gorilla (Gorilla gorilla gorilla). The five exons of the gene were sequenced in three gorillas and in a normally pigmented human. The tyrosinase gene has been found to be a very conserved locus with a very low substitution rate. Some nucleotide and amino acid differences were found between the gorilla and human tyrosinase coding sequences. One of the gorillas included in the study is the only known case of albinism in a gorilla ('Snowflake'). Mutations of the TYR gene lead to Oculocutaneous Albinism type 1 (OCA1), the most common type of albinism in humans (OMIM accession number 203100). The TYR gene encodes the tyrosinase enzyme (E.C. 1.14.18.1), whose activity was found to be completely lacking in 'Snowflake', indicating that a mutation in the Tyr gene is the likely cause of his albinism. Nonetheless, no nucleotide changes were detected that could account for the lack of Tyr product or tyrosinase activity in Snowflake, and explanations of these findings are discussed.     

Gorilla and orangutan c-myc nucleotide sequences: Inference on hominoid phylogeny

The nucleotide sequences of the gorilla and orangutan myc loci have been determined by the dideoxy nucleotide method. As previously observed in the human and chimpanzee sequences, an open reading frame (ORF) of 188 codons overlapping exon 1 could be deduced from the gorilla sequence. However, no such ORF appeared in the orangutan sequence.The two sequences were aligned with those of human and chimpanzee as hominoids and of gibbon and marmoset as outgroups of hominoids. The branching order in the evolution of primates was inferred from these data by different methods: maximum parsimony and neighborjoining.Our results support the view that the gorilla lineage branched off before the human and chimpanzee diverged and strengthen the hypothesis that chimpanzee and gorilla are more related to human than is orangutan. Correspondence to: F. Galibert     

A comparison of the small ribosomal RNA genes from the mitochondrial DNA of the great apes and humans: sequence, structure, evolution, and phylogenetic implications

Restriction endonuclease fragments produced by EcoRI/AvaI or KpnI digestion and containing the small (12S) ribosomal RNA (rRNA) genes from the mitochondrial DNAs (mtDNAs) of the common chimpanzee, pygmy chimpanzee, gorilla, and orangutan were inserted into the plasmids pBR322 or pADD1. After species verification the inserted fragments were digested with SauIIIA, subcloned into M13mp7 vectors, and sequenced. The small rRNA gene sequences were compared with each other and with the published human sequence (Anderson et al. 1981). Substitutions were detected at 118 of the 955 nucleotide positions compared. Pairwise, the sequence differences ranged from 1% (between the chimpanzee species) to 9% (comparisons involving the orangutan); the proportion that were transitions ranged from 87% to 100%. Deletions and/or additions were noted at seven locations. With respect to evolutionary sequence lability, kinetic analysis indicated the presence of at least two classes of nucleotide positions; the more labile class occurs in sequences thought to form self-complementary duplexes (stems) in the mature rRNA. The high frequency of compensating substitutions, which maintain base-pairing within these sequences, corroborates their inferred structure. Phylogenetic inferences drawn from the sequence comparisons support the notion of an approximately equidistant relationship among chimpanzees, gorilla, and man, with the orangutan much less closely related. However, inference from a shared deletion suggests that the gorilla and the chimpanzees may be more closely related to one another than they are to man.     

Concerted evolution of the primate immunoglobulin alpha-gene through gene conversion.

We determined four nucleotide sequences of the hominoid immunoglobulin alpha (C alpha) genes (chimpanzee C alpha 2, gorilla C alpha 2, and gibbon C alpha 1 and C alpha 2 genes), which made possible the examination of gene conversions in all hominoid C alpha genes. The following three methods were used to detect gene conversions: 1) phenetic tree construction; 2) detection of a DNA segment with extremely low variability between duplicated C alpha genes; and 3) a site by site search of shared nucleotide changes between duplicated C alpha genes. Results obtained from method 1 indicated a concerted evolution of the duplicated C alpha genes in the human, chimpanzee, gorilla, and gibbon lineages, while results obtained from method 2 suggested gene conversions in the human, gorilla, and gibbon C alpha genes. With method 3 we identified clusters of shared nucleotide changes between duplicated C alpha genes in human, chimpanzee, gorilla, and gibbon lineages, and in their hypothetical ancestors. In the present study converted regions were identified over the entire C alpha gene region excluding a few sites in the coding region which have escaped from gene conversion. This indicates that gene conversion is a general phenomenon in evolution, that can be clearly observed in non-functional regions.     

Phylogenetic isolation of a human alu flounder gene: Drift to new subfamily identity

A severe bottleneck in the size of the PV Alu subfamily in the common ancestor of human and gorilla has been used to isolate an Alu source gene. The human PV Alu subfamily consists of about one thousand members which are absent in gorilla and chimpanzee DNA. Exhaustive library screening shows that there are as few as two PV Alus in the gorilla genome. One is gorilla-specific, i.e., absent in the orthologous loci in both human and chimpanzee, suggesting the independent retrotranspositional activity of the PV subfamily in the gorilla lineage. The second of these two gorilla PV Alus is present in both human and chimpanzee DNAs and is the single PV Alu known to precede the radiation of these three species. The orthologous Alu in gibbon DNA resembles the next older Alu subfamily. Thus, this Alu locus is originally templated by a non-PV source gene and acquired characteristic PV sequence variants by mutational drift in situ, consequently becoming the first member and presumptive founder of this PV subfamily. Correspondence to: C.W. Schmid