假基因的组成、分布及其分子进化

假基因(pseudogene)是指基因组中与正常基因序列相似, 但是缺乏功能的DNA 序列。通过序列同源性搜索, 可以收集基因组中假基因的群体特性、染色体分布和同源家族等特性。假基因很好地保留了数百万年前基因组中祖先基因的分子记录, 被视为“基因化石”, 因此假基因在进化和比较基因组学中是重要的资源。应用假基因和基因比较体系, 可以探究生物基因的进化史和基因组稳定性。如: 用Ka/Ks比值确定假基因的自然选择压、物种亲缘关系和进化距离, 分析假基因自身的进化趋势, 探讨DNA 突变的成因等。     

假基因的组成、分布及其分子进化

假基因（pseudogene）是指基因组中与正常基因序列相似,但是缺乏功能的DNA序列.通过序列同源性搜索,可以收集基因组中假基因的群体特性、染色体分布和同源家族等特性.假基因很好地保留了数百万年前基因组中祖先基因的分子记录,被视为＂基因化石＂,因此假基因在进化和比较基因组学中是重要的资源.应用假基因和基因比较体系,可以探究生物基因的进化史和基因组稳定性.如：用Ka/Ks比值确定假基因的自然选择压、物种亲缘关系和进化距离,分析假基因自身的进化趋势,探讨DNA突变的成因等.     

Pseudogene: lessons from PCR bias,identification and resurrection

Pseudogenes are fragments of non-functional genomic DNA with high sequences similarity to normal functional genes. They are a kind of non-coding DNA produced by gene duplications or retrotranspositions. Pseudogenes exist in human genome at a large quantity which is nearly as much as that of normal functional genes. They could cause PCR bias in molecular biology experiments and confuse related analysis. On the other hand, pesudogenes are important elements in genomics study for getting an integral picture of genome annotation. They give diverse information of evolutionary history and are regarded as genome fossils. Worldwide research project “encyclopedia of DNA elements”(ENCODE) founded in recent years have enhanced our understanding of pseudogenes. Approaches established to identify pseudogenes include PseudoPipe, HAVANA method, PseudoFinder, RetroFinder, GIS-PET method and consensus method. This paper discuss pseudogenes with respect to the formation mechanisms, distribution, and problems for PCR, importance and identification of pseudogenes. Furthermore, potential resurrection of pseudogenes and their potential function are discussed.     

Insights into the genomic features and evolutionary impact of the genes configuring duplicated pseudogenes in human

Pseudogenes, regarded as ‘genomic fossils’, are DNA sequences resembling functional genes in perspective of sequence homology but completely non-functional. In this study, we explored the unique characteristic features of human genes, configuring classical duplicated pseudogenes. We found that progenitors of duplicated pseudogenes are characterized by a high expressivity, and ability to encode hub-proteins in association with a high evolutionary rate. Such unusual features are endorsed by longer protein length, elevated CpG content, and a high recombination rate. The non-functionalization of their duplicated copies can be attributed to the overabundance of gene paralog number in concert with functional redundancy.     

Large-scale analysis of pseudogenes in the human genome

Pseudogenes are considered as genomic fossils: disabled copies of functional genes that were once active in the ancient genome. Recently, whole-genome computational approaches have revealed thousands of pseudogenes in the genomes of the human and other eukaryotes. Identification of these pseudogenes can improve the accuracy of gene annotation. It also offers new insight on the evolutionary history and the stability of the genome as a whole.     

Reliability of mitochondrial DNA in an acanthocephalan: the problem of pseudogenes

The utility of mitochondrial DNA as a molecular marker for evolutionary studies is well recognized. However, several problems can arise when using mitochondrial DNA, one of which is the presence of nuclear mitochondrial pseudogenes, or Numts. Pseudogenes of cytochrome oxidase I were preferentially amplified from Acanthocephalus lucii (Acanthocephala) using a universal PCR approach. To verify the presence and abundance of pseudogenes, length heterogeneity analysis of the PCR fragments was performed. PCR products obtained with universal primers often contained fragments of different sizes. Cloned sequences from universal PCR products nearly always contained sequence abnormalities such as indels and/or stop codons. Based on these sequences, new primers were developed to specifically target mitochondrial DNA. Sequences obtained with these specific primers lacked abnormalities. Phylogenetic analysis produced a single most parsimonious tree in which pseudogenes obtained with universal primers grouped together as did putative mitochondrial DNA sequences obtained with specific primers. The pattern of codon bias observed in the pseudogenes suggests a single nuclear integration event from the mitochondria. This is the first reported occurrence of pseudogenes in an acanthocephalan, and it demonstrates the potential dangers associated with the use of universal primers.     

Vertebrate pseudogenes

Pseudogenes are commonly encountered during investigation of the genomes of a wide range of life forms. This review concentrates on vertebrate, and in particular mammalian, pseudogenes and describes their origin and subsequent evolution. Consideration is also given to pseudogenes that are transcribed and to the unusual group of genes that exist at the interface between functional genes and non-functional pseudogenes. As the sequences of different genomes are characterised, the recognition and interpretation of pseudogene sequences will become more important and have a greater impact in the field of molecular genetics.     

PseudoPipe: an automated pseudogene identification pipeline

MOTIVATION: Mammalian genomes contain many 'genomic fossils' i.e. pseudogenes. These are disabled copies of functional genes that have been retained in the genome by gene duplication or retrotransposition events. Pseudogenes are important resources in understanding the evolutionary history of genes and genomes. RESULTS: We have developed a homology-based computational pipeline ('PseudoPipe') that can search a mammalian genome and identify pseudogene sequences in a comprehensive and consistent manner. The key steps in the pipeline involve using BLAST to rapidly cross-reference potential "parent" proteins against the intergenic regions of the genome and then processing the resulting "raw hits" -- i.e. eliminating redundant ones, clustering together neighbors, and associating and aligning clusters with a unique parent. Finally, pseudogenes are classified based on a combination of criteria including homology, intron-exon structure, and existence of stop codons and frameshifts.     

Pseudogenes: Pseudo or Real Functional Elements?

Pseudogenes are genomic remnants of ancient protein-coding genes which have lost their coding potentials through evolution. Although broadly existed, pseudogenes used to be considered as junk or relics of genomes which have not drawn enough attentions of biologists until recent years. With the broad applications of high-throughput experimental techniques, growing lines of evidence have strongly suggested that some pseudogenes possess special functions, including regulating parental gene expression and participating in the regulation of many biological processes. In this review, we summarize some basic features of pseudogenes and their functions in regulating development and diseases. All of these observations indicate that pseudogenes are not purely dead fossils of genomes, but warrant further exploration in their distribution, expression regulation and functions. A new nomenclature is desirable for the currently called ‘pseudogenes’ to better describe their functions.     

The β-esterase Gene Cluster of Drosophila melanogaster: is ψEst-6 a Pseudogene, a Functional Gene, or both?

Pseudogenes have been defined as non-functional sequences of genomic DNA that are originally derived from functional genes, but exhibit degenerative features such as premature stop codons and frameshifts that prevent their expression. However, there is increasing evidence that pseudogenes are often evolutionarily conserved and may have retained some functional role or acquired new ones. Pseudogenes may exhibit non-functional features as well as functional ones. We investigate, as a model case, the beta-esterase gene cluster of Drosophila melanogaster that includes the Est-6 gene and the psiEst-6 putative pseudogene. We study four samples derived from natural populations of east Africa (Zimbabwe), Europe (Spain), North America (California), and South America (Venezuela). The level of nucleotide diversity is higher in Africa than in the non-African populations. There is twice more nucleotide diversity in psiEst-6 than in Est-6. Linkage disequilibrium within the beta-esterase gene cluster is strong in non-African samples, but much lower in Africa. The population recombination rate is the same for psiEst-6 and Est-6 in Africa, but significantly different in non-African samples. Intragenic gene conversion events are detected within Est-6 and, with much higher incidence, within psiEst-6; intergenic gene conversion events are rare. The extensive intragenic gene conversion within psiEst-6 can be explained by the invasion of retrotransposons that promote a form of homology-dependent gene conversion upon excision. Tests of neutrality with recombination are significant for the beta-esterase gene cluster in the non-African populations but not in Africa. The Est-6 gene sequences exhibit a well-known allozyme dimorphic structure. The sequences of psiEst-6 are also dimorphic in North and South America, but they do not correspond at all (South America) or only imperfectly (North America) to the Est-6 allozyme dimorphism. Sequence dimorphism is less pronounced in the European and African samples. We suggest that demographic history (bottleneck and admixture of genetically differentiated populations) is the major factor shaping the nucleotide pattern in the beta-esterase gene cluster. However, there are some clear indications of positive selection shaping the distribution of nucleotide polymorphism within the cluster. Intergenic epistatic selection may play an important role in the evolution of the beta-esterase gene cluster, preserving psiEst-6 from degenerative destruction and reflecting its functional interaction with Est-6. The Est-6 gene cluster of D. melanogaster represents an example of a functionally interacting complex ('intergene') in which two components (Est-6 and psiEst-6) or more are required to perform the final function.     

人类基因组上的假基因

假基因是基因组上与编码基因序列非常相似的非功能性基因组DNA拷贝,一般情况都不被转录,且没有明确生理意义。假基因根据其来源可分为复制假基因和已加工假基因。迄今为止,明确鉴定的人类假基因多为已加工假基因,有8000个之多。在Swiss-Prot/TrEMBL收录的编码蛋白质的将近25500个基因序列中,约10％在基因组中有一个或多个近全长已加工假基因。其余的功能基因都没有已加工假基因。核糖体蛋白基因具有最多数量的已加工假基因,约有l700个(占已加工假基因数的22％),少数基因,如cyclophilinA、肌动蛋白(actin)、角蛋白(keratin)、GAPDH、细胞色素C(cytochromec)和nucleophosmin等则有很多份已加工假基因。总体上讲,假基因在人类染色体上的分布与染色体长度成比例,但已加工假基因在GC含量为41％～46％的染色体区域密度最高。已加工假基因的拷贝数和功能基因在生殖器官中的表达高度一致,说明许多假基因发生在胚胎阶段,另外也和基因中GC含量和基因大小密切相关。假基因的准确鉴定对基因组进化、分子医学研究和医学应用具有重要意义。     

Comprehensive analysis of amino acid and nucleotide composition in eukaryotic genomes,comparing genes and pseudogenes

Based on searches for disabled homologs to known proteins, we have identified a large population of pseudogenes in four sequenced eukaryotic genomes—the worm, yeast, fly and human (chromosomes 21 and 22 only). Each of our nearly 2500 pseudogenes is characterized by one or more disablements mid-domain, such as premature stops and frameshifts. Here, we perform a comprehensive survey of the amino acid and nucleotide composition of these pseudogenes in comparison to that of functional genes and intergenic DNA. We show that pseudogenes invariably have an amino acid composition intermediate between genes and translated intergenic DNA. Although the degree of intermediacy varies among the four organisms, in all cases, it is most evident for amino acid types that differ most in occurrence between genes and intergenic regions. The same intermediacy also applies to codon frequencies, especially in the worm and human. Moreover, the intermediate composition of pseudogenes applies even though the composition of the genes in the four organisms is markedly different, showing a strong correlation with the overall A/T content of the genomic sequence. Pseudogenes can be divided into ‘ancient’ and ‘modern’ subsets, based on the level of sequence identity with their closest matching homolog (within the same genome). Modern pseudogenes usually have a much closer sequence composition to genes than ancient pseudogenes. Collectively, our results indicate that the composition of pseudogenes that are under no selective constraints progressively drifts from that of coding DNA towards non-coding DNA. Therefore, we propose that the degree to which pseudogenes approach a random sequence composition may be useful in dating different sets of pseudogenes, as well as to assess the rate at which intergenic DNA accumulates mutations. Our compositional analyses with the interactive viewer are available over the web at http://genecensus.org/pseudogene.