Tubulin pseudogenes as markers for hominoid divergence

Processed pseudogenes arise via unimolecular events that result in the integration of nonfunctional (and therefore non-selected) regions of DNA into the germ line. The sequence of such pseudogenes can be used as a novel form of evolutionary clock: the older a particular pseudogene, the more mutations it has acquired relative to the selectively constrained functional gene from which it was originally derived. We have used specific beta-tubulin gene probes to assay for the presence of fully sequenced processed pseudogenes in genomic DNA from various hominoid species. The data suggest that orangutan is more closely related to human, chimpanzee and gorilla than is generally believed.     

Evolutionary conservation and disease gene association of the human genes composing pseudogenes

Pseudogenes, the 'genomic fossils' present portrayal of evolutionary history of human genome. The human genes configuring pseudogenes are also now coming forth as important resources in the study of human protein evolution. In this communication, we explored evolutionary conservation of the genes forming pseudogenes over the genes lacking any pseudogene and delving deeper, we probed an evolutionary rate difference between the disease genes in the two groups. We illustrated this differential evolutionary pattern by gene expressivity, number of regulatory miRNA targeting per gene, abundance of protein complex forming genes and lesser percentage of protein intrinsic disorderness. Furthermore, pseudogenes are observed to harbor sequence variations, over their entirety, those become degenerative disease-causing mutations though the disease involvement of their progenitors is still unexplored. Here, we unveiled an immense association of disease genes in the genes casting pseudogenes in human. We interpreted the issue by disease associated miRNA targeting, genes containing polymorphisms in miRNA target sites, abundance of genes having disease causing non-synonymous mutations, disease gene specific network properties, presence of genes having repeat regions, affluence of dosage sensitive genes and the presence of intrinsically unstructured protein regions.     

DNA methylation profiling of pseudogene-parental gene pairs and two gene families

A substantial proportion of human genes contain tissue-specifically DNA-methylated regions (TDMRs). However, little is known about the evolutionary conservation of differentially methylated loci, how they evolve, and the signals that regulate them. We have studied TDMR conservation in the PLG and TBX gene families and in 32 pseudogene–parental gene pairs. Among the members of the recently evolved PLG gene family, 5′-UTR methylation is conserved and inversely correlated with the cognate gene expression, indicating as well a conserved regulatory role of DNA methylation. Conversely, many genes of the much older TBX family display complementary tissue-specific methylation, suggesting an epigenetic complementation in the evolution of this gene family. Similar to gene families, unprocessed pseudogenes arose from gene duplications and we found TDMR conservation in some pseudogene–parental gene pairs displaying short evolutionary distances. However, for the majority of unprocessed pseudogenes and for all processed pseudogenes examined, we found that tissue-specific methylation arose de novo after gene duplication.     

Molecular structures of human argininosuccinate synthetase pseudogenes. Evolutionary and mechanistic implications

In the human genome there is one expressed gene for argininosuccinate synthetase and 14 pseudogenes. A cDNA coding for human argininosuccinate synthetase was used to screen a human genomic library. Twenty-five unique genomic clones were isolated and extensively characterized. At least seven clones represented processed argininosuccinate synthetase pseudogenes that lost the introns in the expressed gene. Restriction mapping demonstrated that these processed pseudogenes were located in distinct regions of the human genome. Complete nucleotide sequences of two processed pseudogenes, psi AS-1 and psi AS-3, and a partial sequence of psi AS-7 were determined. Both psi AS-1 and psi AS-3 had an adenine-rich region at their 3' end and were flanked by distinct imperfect direct repeats. A comparison of these pseudogene sequences to that of the cDNA demonstrated that psi AS-1 and psi AS-3 were 93% homologous to the cDNA, whereas psi AS-7 was 89% homologous to the cDNA. Therefore, it is estimated that psi AS-1 and psi AS-3 were created 10-11 million years ago, whereas psi AS-7 arose approximately 21 million years ago. We have estimated the evolutionary rate for the expressed argininosuccinate synthetase gene based on the sequences of psi AS-1 and psi AS-3. These data indicate that the expressed argininosuccinate synthetase gene is evolving at a rate similar to that of the beta-globin gene and much faster than the alpha-tubulin gene. Furthermore, a comparison of the sequences of psi AS-1 and psi AS-3 suggests the possibility that these pseudogenes arose from a common intermediate.     

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.     

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.     

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。     

Structure and organization of the bovine beta-globin genes

Genomic clones spanning the entire cow beta-globin gene locus have been isolated and characterized. These clones demonstrate that the linkage of embryonic-like (epsilon) genes and pseudogenes (psi) to the previously described fetal (gamma) and adult (beta) genes is as follows: 5'-epsilon 3-epsilon 4-psi 3-beta-epsilon 1-epsilon 2-psi 1- psi 2-gamma-3'. Present data indicate that, like that of the goat, the fetal and adult genes arose via block duplication of an ancestral four- gene set: epsilon-epsilon-psi-beta. This duplication event preceded the divergence of cows and goats, which occurred greater than or equal to 18-20 Myr ago. However, cows do not have the additional four-gene block containing a preadult/stress globin gene (beta C). Furthermore, the cow fetal cluster contains an extra beta-like pseudogene, which apparently arose by a small-scale duplication. The fixation of this duplication may indicate a possible evolutionary role for pseudogenes.      

Cryptic genes: Evolutionary puzzles

Many microorganisms carry genes that have the potential to code for specific functions but remain inactive during the normal lifetime of the organism. Such genes have been termed cryptic genes and their activation usually requires a mutational event. They are different from pseudogenes which arise as a result of duplication of a functional gene but remain inactivated because of the accumulation of multiple mutations. This review is an attempt to examine some of the well-characterized cryptic genetic systems inEscherichia coli in an effort to understand their functional and evolutionary significance.     

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.     

The vestigial olfactory receptor subgenome of odontocete whales: phylogenetic congruence between gene-tree reconciliation and supermatrix methods

The macroevolutionary transition of whales (cetaceans) from a terrestrial quadruped to an obligate aquatic form involved major changes in sensory abilities. Compared to terrestrial mammals, the olfactory system of baleen whales is dramatically reduced, and in toothed whales is completely absent. We sampled the olfactory receptor (OR) subgenomes of eight cetacean species from four families. A multigene tree of 115 newly characterized OR sequences from these eight species and published data for Bos taurus revealed a diverse array of class II OR paralogues in Cetacea. Evolution of the OR gene superfamily in toothed whales (Odontoceti) featured a multitude of independent pseudogenization events, supporting anatomical evidence that odontocetes have lost their olfactory sense. We explored the phylogenetic utility of OR pseudogenes in Cetacea, concentrating on delphinids (oceanic dolphins), the product of a rapid evolutionary radiation that has been difficult to resolve in previous studies of mitochondrial DNA sequences. Phylogenetic analyses of OR pseudogenes using both gene-tree reconciliation and supermatrix methods yielded fully resolved, consistently supported relationships among members of four delphinid subfamilies. Alternative minimizations of gene duplications, gene duplications plus gene losses, deep coalescence events, and nucleotide substitutions plus indels returned highly congruent phylogenetic hypotheses. Novel DNA sequence data for six single-copy nuclear loci and three mitochondrial genes (> 5000 aligned nucleotides) provided an independent test of the OR trees. Nucleotide substitutions and indels in OR pseudogenes showed a very low degree of homoplasy in comparison to mitochondrial DNA and, on average, provided more variation than single-copy nuclear DNA. Our results suggest that phylogenetic analysis of the large OR superfamily will be effective for resolving relationships within Cetacea whether supermatrix or gene-tree reconciliation procedures are used.     

Evolutionary History of Eukaryotic α-Glucosidases from the α-Amylase Family

Although some α-glucosidases from the α-amylase family (glycoside hydrolase family GH13) have been studied extensively, their exact number, organization on the chromosome, and orthology/paralogy relationship were unknown. This was true even for important disease vectors where gut α-glucosidase is known to be receptor for the Bin toxin used to control the population of some mosquito species. In some cases orthologs from related species were studied intensively, while potentially important paralogs were omitted. We have, therefore, used a bioinformatics approach to identify all family GH13 α-glucosidases from the selected species from Metazoa (including three mosquito species: Aedes aegypti, Anopheles gambiae, and Culex quinquefasciatus) as well as from Fungi in an effort to characterize their arrangement on the chromosome and evolutionary relationships among orthologs and among paralogs. We also searched for pseudogenes and genes coding for enzymatically inactive proteins with a possible new function. We have found GH13 α-glucosidases mostly in Arthropoda and Fungi where they form gene families, as a result of multiple lineage-specific gene duplications. In mosquito species we have identified 14 α-glucosidase (Aglu) genes of which only five have been biochemically characterized so far, two are putative pseudogenes and the rest remains uncharacterized. We also revealed quite a complex evolutionary history of the eukaryotic α-glucosidases probably involving multiple losses of genes or horizontal gene transfer from bacteria.