人类和黑猩猩Y染色体结构和基因含量的差异性

解读人类和黑猩猩之间的差异性对于研究人类的进化历史具有非常重要的意义。人类和黑猩猩Y染色体相继测序完毕,利用dot-plot程序可以分析它们之间的差异性。研究结果显示,人类和黑猩猩MSY区在结构和基因含量上有很大的差异,人类MSY常染色质主要由扩增序列、X退化序列和X转座序列组成,而黑猩猩MSY常染色质主要由扩增序列和X退化序列组成。黑猩猩的MSY区含有19个回文序列,而人类只有8个回文序列。黑猩猩MSY区的基因只包含了人类MSY区基因的三分之二。通过分析可以推测,黑猩猩和人类MSY之间的显著差异主要来源于四个因素的协同作用:MSY在精子生成中的主要作用;MSY区内频繁的异常重组;减数分裂交叉重组中的"遗传便车"效应;配偶行为引起的精子的竞争。综合比较黑猩猩和人类Y染色体结构和基因含量将对研究Y染色体的进化历史及其动力产生非常重要的意义。     

果蝇基因组中回文序列的分布

回文序列(palindrome)是与基因表达调控、DNA复制和重组密切相关的重要DNA模体.例如,回文序列常存在于基因表达顺式作用元件中,参与基因表达调控;回文序列也可作为限制性内切酶的识别位点或结构信号,诱导重组的发生,而重组作为选择的途径,反过来可能会调节回文序列在染色体上的分布.在全基因组范围内研究回文序列的分布...     

性染色体与精子功能研究进展

最新研究表明：Y染色体上男性特有序列(MSY)是一个包含不同DNA序列的嵌合体,包含多个回文序列。回文序列上经常发生臂间基因交换,使Y染色体具有自我保护能力。女性失活X染色体上有15%的基因逃离失活进行表达,可能在男女性别不同和女性个体间差异中起决定作用。精子在受精时,是一个综合运输体,不仅仅只向卵子转移DNA,还有RNA和蛋白质。     

回文序列诱导突变的机制及人类相关疾病

在原核和真核生物基因组中, 含有回文序列的区域高度可变且稳定性差, 主要原因是回文序列能形成发卡或十字形二级结构, 然后通过滑动错配、单链复性以及非同源末端连接(Non-homologous end joining, NHEJ)等机制导致缺失突变或染色体易位的发生。在人类基因组中, 回文序列较普遍存在于基因表达调控的重要作用元件中, 它诱导的缺失和易位突变还与男性不育、地中海贫血等多种疾病的发生、发展密切相关。文章综合近几年国内外相关文献, 初步阐释回文序列诱导突变的类型和可能机制, 及其与人类疾病的关系, 为进一步探讨回文序列在基因表达调控、基因突变及人类疾病中的作用及功能等相关研究提供参考。     

人类Y染色体的演化

人类Y染色体由于其性别决定的特殊功能和独有的进化史一直以来都备受关注。Y染色体起源于常染色体,经历了严重的退化过程。由于其缺乏重组,蛋白编码基因少,重复序列多所以研究进展缓慢。近年来,随着比较基因组及测序技术的快速发展,对人类Y染色体最终命运的争论不断加剧,Y染色体的研究正逐步成为热点。文章综述了人类Y染色体的结构、遗传特点、起源及进化过程,并根据目前的研究进展对Y染色体的最终命运进行了讨论,提出了作者的一些看法,以期为从事遗传及性染色体进化的研究者提供参考。     

Y染色体的分子结构和多态性研究与应用

人类Y染色体是最小的近端着丝粒染色体,作为男性所特有的染色体,在减数分裂的过程中几乎不与X染色体发生交换重组,故呈现出单倍型遗传,而Y特异区DNA序列的改变构成了人类Y染色体的多态性.其异常通常会导致各种遗传效应.综述了Y染色体的分子结构及其遗传多态性的最新研究和应用.     

牦牛和水牛全基因组微卫星分布规律及其比较分析

微卫星(simple sequence repeats,SSRs)广泛分布于原核生物和真核生物基因组中,包括编码区和非编码区,是最常用的分子标记。本文利用生物信息学方法搜索和统计了牦牛和水牛全基因组中完整型SSRs序列,并对其生物信息学特征进行比较分析。牦牛和水牛全基因组中SSRs总数量分别为968 134个和1 052 443个,占其全基因组长度的比例分别为5.80‰和5.69‰。牦牛和水牛全基因组SSRs总丰度(366.01 vs 371.07个/Mb)和总密度(5 686.00 vs 5 799.34 bp/Mb)基本接近。牦牛和水牛全基因组SSRs丰富度分布模式如下:单核苷酸SSRs二核苷酸SSRs三核苷酸SSRs五核苷酸SSRs四核苷酸SSRs六核苷酸SSRs,这6种重复类型SSRs特征相互比较有显著差异,而相同重复类型SSRs特征基本一致。水牛第1条染色体上SSRs数量最多(72 934个),其次依次是第2、3、4条染色体,而较少的是第23、24条染色体,其所有染色体上SSRs丰度不存在显著差异(p0.05)。牦牛和水牛SSRs序列随着重复单元中核苷酸数量的增加,而其重复拷贝数逐渐下降。牦牛全基因组和水牛各染色体上各重复类型优势SSRs序列基本一致,并与普通牛、绵羊全基因组中不同重复类型SSRs优势序列相一致。     

限制酶AluI显带和CA_3/DA/DAPI染色表达的家猪染色体结构异染色质

采用限制酶AluI显带、CA_(?)/DA/DAPI荧光染色和常规C带技术研究了家猪染色体着丝粒结构异染色质,结果表明:着丝粒结构异染色质至少可被区分为3类,并且在染色体组内各有其特异的染色体分布。将家猪染色体DA/DAPI荧光带和限制酶AluI显带与人类染色体比较,发现家猪13—18号端着丝粒染色体显带特征与人染色体1,9、16、Y一致。提示家猪13—18号端着丝粒区结构异染色质存在与人类随体DNA相似的DNA组成。     

垂穗披碱草与达乌里披碱草基因组细胞遗传学比较

采用顺序FISH-GISH技术,12个重复序列探针,包括9个三核苷酸简单重复序列、2个卫星DNA重复序列pSc119.2和pAs1以及5S rDNA,通过重复序列的物理定位对达乌里披碱草和垂穗披碱草基因组中部分重复序列的分布特征进行了比较分析,为进一步研究垂穗披碱草和达乌里披碱草的物种形成及演化提供新的分子细胞遗传学证据。结果表明:(1)所有的序列在这2个物种的染色体上都能产生可检测的杂交信号,且在2个物种中(AAC)_(10)、(ACT)_(10)、(CAT)_(10)都表现为共分布,(AAG)_(10)与(AGG)_(10)表现为近似共分布;2个物种的H基因组除5S rDNA序列外,其他序列都产生强烈且丰富的杂交位点,St与Y基因组不同重复序列探针的荧光位点数目有所差别,表现为5S rDNA、pSc119.2、(AAC)_(10)、(CAT)_(10)、(ACT)_(10)、(CAC)_(10)探针的信号位点较少或无信号,其余的探针信号位点稍多。(2)达乌里披碱草的第2对染色体上具有(AAC)_(10)、(CAT)_(10)、(ACT)_(10)的杂交位点、第6对染色体上具有(CAC)_(10)的杂交位点,而在垂穗披碱草的St基因组中未观察到上述序列杂交位点;达乌里披碱草St基因组仅有第4对染色体的端部具有pSc119.2杂交位点,而在垂穗披碱草St基因组中的pSc119.2杂交位点位于第5对染色体长臂的间隔区;相对于达乌里披碱草,垂穗披碱草St和Y基因组染色体含有更多的重复序列杂交位点。(3)达乌里披碱草的H/Y基因组间易位在不同材料间是稳定存在的,达乌里披碱草基因组相对稳定,不同材料间H基因组重复序列杂交信号多态性高于St和Y基因组;垂穗披碱草基因组的变异较大,不同材料间St和Y基因组重复序列杂交信号多态性高于H基因组。研究认为,垂穗披碱草和达乌里披碱草的H基因组均起源于布顿大麦,St基因组可能起源于不同的拟鹅观草属物种;与达乌里披碱草相比垂穗披碱草St与Y基因组可能具有更高的染色体结构变异性,而垂穗披碱草St与Y基因组变异较大的原因可能是与同区域分布的含StY基因组的物种发生了种间渗透杂交。     

石刁柏核质体DNA的生物信息学分析及染色体定位

在植物基因组中, 叶绿体DNA (cpDNA)序列可以向核基因组转移成为核质体DNA (NUPT)。NUPTs在植物染色体(包括性染色体)的演化过程中具有重要作用, 但目前相关研究比较缺乏。以雌雄异株植物石刁柏(Asparagus officinalis)为材料, 采用生物信息学方法对其核基因组NUPTs进行注释及分析, 并选取叶绿体基因组反向重复区(IR) 2个片段进行染色体定位。结果表明, 石刁柏核基因组中有2 239个NUPTs序列的插入, 总长度为565 970 bp, 占核基因组的0.047%。不同染色体上插入的NUPTs数量存在较大差异, Y染色体上的NUPTs数量、密度及总长度均高于其它染色体, 表明NUPTs在石刁柏性(Y)染色体上累积的更多。石刁柏叶绿体基因组中的IR区、大单拷贝区(LSC)和小单拷贝区(SSC)序列均能够向核基因组转移, 但IR区序列转移频率更高。此外, 对2个IR区的叶绿体序列进行荧光原位杂交, 其中AocpIR1主要分布在所有染色体的着丝粒部位, 而AocpIR2特异性分布在Y染色体上。研究结果为深入揭示石刁柏基因组的结构及其性染色体的演化奠定了坚实的基础。     

Large DNA palindromes as a common form of structural chromosome aberrations in human cancers

Breakage-fusion-bridge cycles contribute to chromosome aberrations and generate large DNA palindromes that facilitate oncogene amplification in cancer cells. At the molecular level, large DNA palindrome formation is initiated by chromosome breaks, and genomic architecture such as short inverted repeat sequences facilitates this process in mammalian cells. However, the prevalence of DNA palindromes in cancer cells is currently unknown. To determine the prevalence of DNA palindromes in human cancer cells, we have developed a new microarray-based approach called Genome-wide Analysis of Palindrome Formation (GAPF, Tanaka et al., Nat Genet 2005; 37: 320-7). This approach is based on a relatively simple and efficient method to purify "snap-back DNA" from large DNA palindromes by intramolecular base-pairing, followed by elimination of single-stranded DNA by nuclease S1. Comparison of Genome-wide Analysis of Palindrome Formation profiles between cancer and normal cells using microarray can identify genome-wide distributions of somatic palindromes. Using a human cDNA microarray, we have shown that DNA palindromes occur frequently in human cancer cell lines and primary medulloblastomas. Significant overlap of the loci containing DNA palindromes between Colo320DM and MCF7 cancer cell lines suggests regions in the genome susceptible to chromosome breaks and palindrome formation. A subset of loci containing palindromes is associated with gene amplification in Colo320DM, indicating that the location of palindromes in the cancer genome serves as a structural platform that supports subsequent gene amplification.     

Recombination Dynamics of a Human Y-Chromosomal Palindrome: Rapid GC-Biased Gene Conversion,Multi-kilobase Conversion Tracts,and Rare Inversions

The male-specific region of the human Y chromosome (MSY) includes eight large inverted repeats (palindromes) in which arm-to-arm similarity exceeds 99.9%, due to gene conversion activity. Here, we studied one of these palindromes, P6, in order to illuminate the dynamics of the gene conversion process. We genotyped ten paralogous sequence variants (PSVs) within the arms of P6 in 378 Y chromosomes whose evolutionary relationships within the SNP-defined Y phylogeny are known. This allowed the identification of 146 historical gene conversion events involving individual PSVs, occurring at a rate of 2.9–8.4×10⁻⁴ events per generation. A consideration of the nature of nucleotide change and the ancestral state of each PSV showed that the conversion process was significantly biased towards the fixation of G or C nucleotides (GC-biased), and also towards the ancestral state. Determination of haplotypes by long-PCR allowed likely co-conversion of PSVs to be identified, and suggested that conversion tract lengths are large, with a mean of 2068 bp, and a maximum in excess of 9 kb. Despite the frequent formation of recombination intermediates implied by the rapid observed gene conversion activity, resolution via crossover is rare: only three inversions within P6 were detected in the sample. An analysis of chimpanzee and gorilla P6 orthologs showed that the ancestral state bias has existed in all three species, and comparison of human and chimpanzee sequences with the gorilla outgroup confirmed that GC bias of the conversion process has apparently been active in both the human and chimpanzee lineages.     

Evolution of Genomic Structures on Mammalian Sex Chromosomes

Throughout mammalian evolution, recombination between the two sex chromosomes was suppressed in a stepwise manner. It is thought that the suppression of recombination led to an accumulation of deleterious mutations and frequent genomic rearrangements on the Y chromosome. In this article, we review three evolutionary aspects related to genomic rearrangements and structures, such as inverted repeats (IRs) and palindromes (PDs), on the mammalian sex chromosomes. First, we describe the stepwise manner in which recombination between the X and Y chromosomes was suppressed in placental mammals and discuss a genomic rearrangement that might have led to the formation of present pseudoautosomal boundaries (PAB). Second, we describe ectopic gene conversion between the X and Y chromosomes, and propose possible molecular causes. Third, we focus on the evolutionary mode and timing of PD formation on the X and Y chromosomes. The sequence of the chimpanzee Y chromosome was recently published by two groups. Both groups suggest that rapid evolution of genomic structure occurred on the Y chromosome. Our re-analysis of the sequences confirmed the species-specific mode of human and chimpanzee Y chromosomal evolution. Finally, we present a general outlook regarding the rapid evolution of mammalian sex chromosomes.     

Effects of palindrome size and sequence on genetic stability in the bacteriophage phi X174 genome

By inserting palindromes of varying length and sequence into a non-essential region of the bacteriophage phi X174 genome we have investigated the effect of palindrome size and sequence on their genetic stability. Multimers of increasing size of the EcoRI linker CCGAATTCGG (E), the BamHI linker CCGGATCCGG (B) or mixtures of both (E, B) were inserted into the PvuII site of a previously constructed bacteriophage strain phi X174 J-F ins6. The largest inserts that could be maintained in the genome without significant loss of genetic stability were 2B, 4E, and 4(E, B), respectively. Polymers exceeding this size could be inserted but resulted in rapid and precise deletion from the phage genome, whereby nB was more unstable than nE, and nE was more unstable than n(E, B). Analysis of the resulting deletion mutants provided evidence for two different types of deletions. The more frequent deletion arose from either type palindrome and removed nucleotides in blocks of ten base-pairs (one linker unit), but only from the palindromic sequence, and always left at least an 18 base-pair long palindrome (one linker plus 8 neighboring base-pairs) behind. The less frequently occurring deletions arose only from nB type palindromes, removing the complete palindromic sequence plus adjacent nucleotides. At least the first type of deletion occurred in the absence of recA activity. Our results show a correlation between the sequence, as well as size, and the genetic stability of palindromes, i.e. sequences that could decrease the stability of a cruciform increased their genetic stability. This supports the theory that palindrome deletion occurs via extrusion of the palindrome into a cruciform or cruciform-like structure.     

＂Micro-deletions＂ of the human Y chromosome and their relationship with male infertility

The Y chromosome evolves from an autochromosome and accumulates male-related genes including sex-determining region of Y-chromosome (SRY) and several spermatogenesis-related genes.The human Y chromosome (60 Mb long) is largely composed of repeti-tive sequences that give it a heterochromatic appearance,and it consists of pseudoautosomal,euchromatic,and heterochromatic regions.Located on the two extremities of the Y chromosome,pseudoautosomal regions 1 and 2 (PAR1 and PAR2,2.6 Mb and 320 bp long,re-spectively) are homologs with the termini of the X chromosome.The euchromatic region and some of the repeat-rich heterochromatic parts of the Y chromosome are called "male-specific Y" (MSY),which occupy more than 95% of the whole Y chromosome.After evolu-tion,the Y chromosome becomes the smallest in size with the least number of genes but with the most number of copies of genes that are mostly spermatogenesis-related.The Y chromosome is characterized by highly repetitive sequences (including direct repeats,inverted repeats,and palindromes) and high polymorphism.Several gene rearrangements on the Y chromosome occur during evolution owing to its specific gene structure.The consequences of such rearrangements are not only loss but also gain of specific genes.One hundred and fifty three haplotypes have been discovered in the human Y chromosome.The structure of the Y chromosome in the GenBank belongs to haplotype R1.There are 220 genes (104 coding genes,111 pseudogenes,and 5 other uncategorized genes) according to the most recent count.The 104 coding genes encode a total of about 48 proteins/protein families (including putative proteins/protein families).Among them,16 gene products have been discovered in the azoospermia factor region (AZF) and are related to spermatogenesis.It has been dis-covered that one subset of gene rearrangements on the Y chromosome,"micro-deletions",is a major cause of male infertility in some populations.However,controversies exist about different Y chromosome haplotypes.Six AZFs of the Y chromosome have been discov-ered including AZFa,AZFb,AZFc,and their combinations AZFbc,AZFabc,and partial AZFc called AZFc/gr/gr.Different deletions in AZF lead to different content spermatogenesis loss from teratozoospermia to infertility in different populations depending on their Y hap-lotypes.This article describes the structure of the human Y chromosome and investigates the causes of micro-deletions and their relation-ship with male infertility from the view of chromosome evolution.After analysis of the relationship between AZFc and male infertility,we concluded that spermatogenesis is controlled by a network of genes,which may locate on the Y chromosome,the autochromosomes,or even on the X chromosome.Further investigation of the molecular mechanisms underlying male fertility/infertifity will facilitate our knowledge of functional genomics.     

Origin of modern humans in East Asia: clues from the Y chromosome

East Asia is one of the most important regions for studying modern human origin and evolution. A lot of efforts have been made to detect the genetic diversity and to reconstruct the evolutionary history of East Asians, especially using Y chromosome genetic data, in recent years. The Y chromosome data supports the African origin of modern humans in East Asia and the later migration to East Asia through the southern tropic coastline route, and then the northward migration occurred, leading to peopling of the main continent. The genetic data of the Y chromosome reflects a clear prehistoric evolution and migration course of East Asians. As well, the Y chromosome data of East Asians provides clues to elucidate modern human origins and evolution in the neighboring regions, i.e. America, Oceania and the Pacific Islands.     

Origin of modern humans in East Asia: clues from the Y chromosome

East Asia is one of the most important regions for studying modern human origin and evolution. A lot of efforts have been made to detect the genetic diversity and to reconstruct the evolutionary history of East Asians, especially using Y chromosome genetic data, in recent years. The Y chromosome data supports the African origin of modern humans in East Asia and the later migration to East Asia through the southern tropic coastline route, and then the northward migration occurred, leading to peopling of the main continent. The genetic data of the Y chromosome reflects a clear prehistoric evolution and migration course of East Asians. As well, the Y chromosome data of East Asians provides clues to elucidate modern human origins and evolution in the neighboring regions, i.e. America, Oceania and the Pacific Islands.     

Culture modifies expectations of kinship and sex‐biased dispersal patterns: A case study of patrilineality and patrilocality in tribal yemen

Studies of the impact of post‐marital residence patterns on the distribution of genetic variation within populations have returned conflicting results. These studies have generally examined genetic diversity within and between groups with different post‐marriage residence patterns. Here, we directly examine Y chromosome microsatellite variation in individuals carrying a chromosome in the same Y haplogroup. We analyze Y chromosome data from two samples of Yemeni males: a sample representing the entire country and a sample from a large highland village. Our results support a normative patrilocality in highland Yemeni tribal populations, but also suggest that patrilocality is violated often enough to break down the expected correlation of genetic and geographic distance. We propose that a great deal of variation in male dispersal distance distributions is subsumed under the “patrilocal” label and that few human societies are likely to realize the idealized male dispersal distribution expected under strict patrilocality. In addition, we found almost no specific correspondence between social kinship and genetic patriline at the level of the clan (large, extended patrilineal kinship group) within a large, highland Yemeni village. We discuss ethnographic accounts that offer several cultural practices that explain exceptions to patrilocality and means by which social kinship and genetic patriline may become disentangled. © 2013 Wiley Periodicals, Inc.     

Characterization of frequencies and distribution of single nucleotide insertions/deletions in the human genome

Most of the studies on single nucleotide variations are on substitutions rather than insertions/deletions. In this study, we examined the distribution and characteristics of single nucleotide insertions/deletions (SNindels), using data available from dbSNP for all the human chromosomes. There are almost 300,000 SNindels in the database, of which only 0.8% are validated. They occur at the frequency of 0.887 per 10 kb on average for the whole genome, or approximately 1 for every 11,274 bp. More than half occur in regions with mononucleotide repeats the longest of which is 47 bases. Overall the mononucleotide repeats involving C and G are much shorter than those for A and T. About 12% are surrounded by palindromes. There is general correlation between chromosome size and total number for each chromosome. Inter-chromosomal variation in density ranges from 0.6 to 21.7 per kilobase. The overall spectrum shows very high proportion of SNindel of types -/A and -/T at over 81%. The proportion of -/A and -/T SNindels for each chromosome is correlated to its AT content. Less than half of the SNindels are within or near known genes and even fewer (<0.183%) in coding regions, and more than 1.4% of -/C and -/G are in coding compared to 0.2% for -/A and -/T types. SNindels of -/A and -/T types make up 80% of those found within untranslated regions but less than 40% of those within coding regions. A separate analysis using the subset of 2324 validated SNindels showed slightly less AT bias of 74%, SNindels not within mononucleotide repeats showed even less AT bias at 58%. Density of validated SNindels is 0.007/10 kb overall and 90% are found within or near genes. Among all chromosomes, Y has the lowest numbers and densities for all SNindels, validated SNindels, and SNindels not within repeats.