Analysis of Ribosomal Protein Gene Structures: Implications for Intron Evolution

Yoshihama, Maki; Nakao, Akihiro; Nguyen, Hung D.; Kenmochi, Naoya

doi:10.1371/journal.pgen.0020025.eor

Cited by 7 publications

(10 citation statements)

References 24 publications

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“…Roy and Hartl (2006) studied two relatively closely related Plasmodium species and found a very slow rate of intron loss and possibly no gain during ∼100 Myr of evolution. On the other hand, these results contrast with estimates from fungi (Nielsen et al 2004) and more distantly related eukaryotic clades (Fedorov et al 2002;Rogozin et al 2003;Babenko et al 2004;Roy and Gilbert 2005c;Yoshihama et al 2006), which suggest prevalence of intron gain over intron loss over periods >200 Myr.…”

Section: Rates Of Intron Loss and Gaincontrasting

confidence: 87%

“…However, ours and other studies in closely related species show a pattern of recurrent intron loss, particularly in highly expressed housekeeping genes that are most likely to recombine with their reverse transcribed cDNA. Because of their high degree of conservation at both sequence and functional levels, such genes are the ones most often used in gene structure comparisons (Rogozin et al 2003;Yoshihama et al 2006). The process of loss is likely to be much more accelerated in organisms with high reproductive rates and large population sizes where selection for reduced transcript length, rather than genetic drift, will lead to fixation of losses in populations.…”

Section: Rates Of Intron Loss and Gainmentioning

confidence: 99%

“…It is also likely to be rapid in species with short introns, where recombination with intronless substrates is more efficient. In the presence of recurrent parallel loss, studies using parsimony methods and large evolutionary distances (Rogozin et al 2003;Coghlan and Wolfe 2004;Yoshihama et al 2006) will certainly underestimate the rate of loss and overestimate the rate of intron gains. Even maximum likelihood approaches (Nguyen et al 2005;Roy and Gilbert 2005a;Csuros 2006) are not fully immune to this error and will overestimate the gain rate particularly if they fail to account for the rate variation among sites (Yang 1996), which we have shown to occur in the case of intron loss.…”

Section: Rates Of Intron Loss and Gainmentioning

confidence: 99%

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Characterization of intron loss events in mammals

Coulombe-Huntington

Majewski²

2006

Genome Res.

140

151

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The exon/intron structure of eukaryotic genes differs extensively across species, but the mechanisms and relative rates of intron loss and gain are still poorly understood. Here, we used whole-genome sequence alignments of human, mouse, rat, and dog to perform a genome-wide analysis of intron loss and gain events in >17,000 mammalian genes. We found no evidence for intron gain and 122 cases of intron loss, most of which occurred within the rodent lineage. The majority (68%) of the deleted introns were extremely small (<150 bp), significantly smaller than average. The intron losses occurred almost exclusively within highly expressed, housekeeping genes, supporting the hypothesis that intron loss is mediated via germline recombination of genomic DNA with intronless cDNA. This study constitutes the largest scale analysis for intron dynamics in vertebrates to date and allows us to confirm and extend several hypotheses previously based on much smaller samples. Our results in mammals show that intron gain has not been a factor in the evolution of gene structure during the past 95 Myr and has likely been restricted to more ancient history.[Supplemental material is available online at www.genome.org.]Reconstructing the evolutionary history of spliceosomal introns remains one of the most fervently debated topics in eukaryotic evolution (Roy and Gilbert 2006). The long-standing debate over the introns-early versus introns-late hypotheses (Stoltzfus 1994;de Souza et al. 1998) contrasts the ideas of introns either originating in the early RNA world or evolving from an expansion of group II self-splicing introns in an early eukaryotic ancestor (Cavalier-Smith 1991). Understanding the natural history of introns is essential to understanding their function: Are introns simply selfish DNA elements that have been maintained in large genomes akin to retrotransposons, or do they serve a function, such as promoting recombination (Comeron and Kreitman 2000) and alternative splicing (AS) (Kim et al. 2004), resulting in increased proteome diversity and complexity?Evolutionary investigations of the dynamics of intron gains and losses are generally hampered by the limited availability of high-quality data on the sequence and structure of gene orthologs from diverse species. To date, we have been unable to utilize the entire gene complements of most organisms in question, and the data sets commonly used range from hundreds (Rogozin et al. 2003) to at most a thousand genes (Roy et al. 2003) or several thousand introns (Nielsen et al. 2004).Here, we make use of the complete, high-quality genomic sequences of four mammalian species-human, mouse, rat, and dog-to investigate intron gain and loss dynamics in mammals. We utilize a gene mapping technique to map annotated reference human genes onto genome-wide, multispecies sequence alignments, allowing us to investigate the predicted intron-exon boundaries of 152,146 introns within 17,242 autosomal genes. A recent study that considered a much smaller number of mammalian genes (Roy et al. 2003) u...

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Section: Rates Of Intron Loss and Gaincontrasting

confidence: 87%

Section: Rates Of Intron Loss and Gainmentioning

confidence: 99%

Section: Rates Of Intron Loss and Gainmentioning

confidence: 99%

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Characterization of intron loss events in mammals

Coulombe-Huntington

Majewski²

2006

Genome Res.

140

151

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“…3). This general strategy can be modified to account for the possibility that general preferences in intron insertion (e.g., into protosplice sites) and/or intron phase biases (reviewed in Rogozin et al 2012) could lead to independent intron insertions occurring at homologous positions in different lineages (Sverdlov et al 2005;Yoshihama et al 2006). Avariety of studies have shown that genes from intron-rich species from any major eukaryotic supergroup share a significant number of intron positions with other groups (Fedorov et al 2002;Rogozin et al 2003;Csurös et al 2008Csurös et al , 2011.…”

Section: Reconstruction Of Intron-exon Structures In Lecamentioning

confidence: 99%

Origin of Spliceosomal Introns and Alternative Splicing

Irimia

Roy

2014

Cold Spring Harbor Perspectives in Biology

130

121

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In this work we review the current knowledge on the prehistory, origins, and evolution of spliceosomal introns. First, we briefly outline the major features of the different types of introns, with particular emphasis on the nonspliceosomal self-splicing group II introns, which are widely thought to be the ancestors of spliceosomal introns. Next, we discuss the main scenarios proposed for the origin and proliferation of spliceosomal introns, an event intimately linked to eukaryogenesis. We then summarize the evidence that suggests that the last eukaryotic common ancestor (LECA) had remarkably high intron densities and many associated characteristics resembling modern intron-rich genomes. From this intronrich LECA, the different eukaryotic lineages have taken very distinct evolutionary paths leading to profoundly diverged modern genome structures. Finally, we discuss the origins of alternative splicing and the qualitative differences in alternative splicing forms and functions across lineages. SURPRISES AND MYSTERIES OF INTRONS AND INTRON EVOLUTIONW ith mid-20th century breakthroughs, molecular cell biology finally seemed to obey a relatively simple logic. Genetic information was encoded in DNA genes (Avery et al. 1944;Watson and Crick 1953), which were transcribed into RNA and subsequently translated into functional proteins (Crick 1958). However, a most unexpected finding "interrupted" this logic. The coding information of DNA genes was sometimes broken into pieces separated by sequences whose sole apparent purpose was to generate an extra RNA sequence that then had to be removed to generate intact proteincoding messenger RNAs. The initial findings in viruses (Berget et al. 1977;Chow et al. 1977) were soon extended to many cellular genes. With the advent of large-scale sequencing projects, it became clear that one kind of intron (the spliceosomal introns), as well as the cellular machinery that removes them (the spliceosome), are ubiquitous in eukaryotic genomes. For example, the average human transcript contains 9 introns, totaling several hundred thousand introns across the genome and comprising a quarter of the DNA content of each cell (Lander et al. 2001;Venter et al. 2001). Moreover, functions for some introns began to

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“…Ribosomal protein is a group of organella involving in cell structure and cell cycle, and possess the important ability to control cell growth, differentiation and adherence. The ribosomal protein is certainly related to cell energy or substance metabolism, and has critical physiological roles in nutrient transport [31] . HBV PS1TP5 protein also interacts with Homo sapiens inositol monophosphatase 2 (IMPA2), Homo sapiens solute carrier family 7 member 5 (SLC7A5), Homo sapiens cytochrome c oxidase subunit 8A, Homo sapiens enolase 1, Homo sapiens H3 histone family 3B, Human cytoskeletal gamma-actin gene, Homo sapiens eukaryotic translation elongation factor 1, Homo sapiens epoxide hydrolase 1, Homo sapiens dehydrogenase 1, Homo sapiens signal sequence receptor-β, Homo sapiens β5-microtubulin and Homo sapiens pyruvate dehydrogenase.…”

Section: Discussionmentioning

confidence: 99%

Screening and cloning for proteins transactivated by the PS1TP5 protein of hepatitis B virus: A suppression subtractive hybridization study

Zhang¹

2007

WJG

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AIM:To clone and identify human genes transactivated by PS1TP5 by constructing a cDNA subtractive library with suppression subtractive hybridization (SSH) technique. METHODS:SSH and bioinformatics techniques were used for screening and cloning of the target genes transactivated by PS1TP5 protein. The mRNA was isolated from HepG2 cells transfected with pcDNA3.1(-)-myc-his(A)-PS1TP5 and pcDNA3.1(-)-myc-his(A) empty vector, respectively, and SSH technique was employed to analyze the differentially expressed DNA sequence between the two groups. After digestion with restriction enzyme Rsa Ⅰ, small size cDNAs were obtained. Then tester cDNA was divided into two groups and ligated to the specific adaptor 1 and adaptor 2, respectively. The tester cDNA was hybridized with driver cDNA twice and subjected to nested PCR for two times, and then subcloned into T/A plasmid vectors to set up the subtractive library. Amplification of the library was carried out with E. coli strain DH5α. The cDNA was sequenced and analyzed in GenBank with Vector NTI 9.1 and NCBI BLAST software after PCR amplification. RESULTS:The subtractive library of genes transactivated by PS1TP5 was constructed successfully. The amplified library contained 90 positive clones. Colony PCR showed that 70 clones contained 200-1000-bp inserts. Sequence analysis was performed in 30 clones randomly, and the full-length sequences were obtained by bioinformatics technique. Altogether 24 coding sequences were obtained, which consisted of 23 known and 1 unknown.One novel gene with unknown functions was found and named as PS1TP5TP1 after being electronically spliced, and deposited in GenBank (accession number: DQ487761). CONCLUSION:PS1TP5 is closely correlated with immunoregulation, carbohydrate metabolism, signal t ra n s d u c t i o n , f o r m a t i o n m e c h a n i s m o f h e p a t i c fibrosis, and occurrence and development of tumor. Understanding PS1TP5 transactive proteins may help to bring some new clues for further studying the biological functions of pre-S1 protein.

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Analysis of Ribosomal Protein Gene Structures: Implications for Intron Evolution

Cited by 7 publications

References 24 publications

Characterization of intron loss events in mammals

Characterization of intron loss events in mammals

Origin of Spliceosomal Introns and Alternative Splicing

Screening and cloning for proteins transactivated by the PS1TP5 protein of hepatitis B virus: A suppression subtractive hybridization study

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