Origin and evolution of new exons in rodents

Wen Wang; Hongkun Zheng; Shuang Yang; Haijing Yu; Jun Li; Huifeng Jiang; Jianning Su; Lei Yang; Jianguo Zhang; Jason McDermott; Ram Samudrala; Jian Wang; Huanming Yang; Jun Yu; Karsten Kristiansen; Gane Ka-Shu  Wong; Jun Wang

doi:10.1101/gr.3929705

Origin and evolution of new exons in rodents

Wen Wang^*
, Hongkun Zheng
, Shuang Yang
, Haijing Yu
, Jun Li
, Huifeng Jiang
, Jianning Su
, Lei Yang
, Jianguo Zhang
, Jason McDermott
, Ram Samudrala
, Jian Wang
, Huanming Yang
, Jun Yu
, Karsten Kristiansen
, Gane Ka-Shu Wong^*
, Jun Wang^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

88 Citations (Scopus)

Abstract

Gene number difference among organisms demonstrates that new gene origination is a fundamental biological process in evolution. Exon shuffling has been universally observed in the formation of new genes. Yet to be learned are the ways new exons originate and evolve, and how often new exons appear. To address these questions, we identified 2695 newly evolved exons in the mouse and rat by comparing the expressed sequences of 12,419 orthologous genes between human and mouse, using 743,856 pig ESTs as the outgroup. The new exon origination rate is about 2.71 × 10^-3 per gene per million years. These new exons have markedly accelerated rates both of nonsynonymous substitutions and of insertions/deletions (indels). A much higher proportion of new exons have K_a/K_s ratios >1 (where K_a is the nonsynonymous substitution rate and K_s is the synonymous substitution rate) than do the old exons shared by human and mouse, implying a role of positive selection in the rapid evolution. The majority of these new exons have sequences unique in the genome, suggesting that most new exons might originate through "exonization" of intronic sequences. Most of the new exons appear to be alternative exons that are expressed at low levels.

Original language	English
Pages (from-to)	1258-1264
Journal	Genome Research
Volume	15
Issue number	9
Online published	Aug 2005
DOIs	https://doi.org/10.1101/gr.3929705
Publication status	Published - Sept 2005
Externally published	Yes

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title = "Origin and evolution of new exons in rodents",

abstract = "Gene number difference among organisms demonstrates that new gene origination is a fundamental biological process in evolution. Exon shuffling has been universally observed in the formation of new genes. Yet to be learned are the ways new exons originate and evolve, and how often new exons appear. To address these questions, we identified 2695 newly evolved exons in the mouse and rat by comparing the expressed sequences of 12,419 orthologous genes between human and mouse, using 743,856 pig ESTs as the outgroup. The new exon origination rate is about 2.71 × 10-3 per gene per million years. These new exons have markedly accelerated rates both of nonsynonymous substitutions and of insertions/deletions (indels). A much higher proportion of new exons have Ka/Ks ratios >1 (where Ka is the nonsynonymous substitution rate and Ks is the synonymous substitution rate) than do the old exons shared by human and mouse, implying a role of positive selection in the rapid evolution. The majority of these new exons have sequences unique in the genome, suggesting that most new exons might originate through {"}exonization{"} of intronic sequences. Most of the new exons appear to be alternative exons that are expressed at low levels. ",

author = "Wen Wang and Hongkun Zheng and Shuang Yang and Haijing Yu and Jun Li and Huifeng Jiang and Jianning Su and Lei Yang and Jianguo Zhang and Jason McDermott and Ram Samudrala and Jian Wang and Huanming Yang and Jun Yu and Karsten Kristiansen and Wong, \{Gane Ka-Shu\} and Jun Wang",

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T1 - Origin and evolution of new exons in rodents

AU - Wang, Wen

AU - Zheng, Hongkun

AU - Yang, Shuang

AU - Yu, Haijing

AU - Li, Jun

AU - Jiang, Huifeng

AU - Su, Jianning

AU - Yang, Lei

AU - Zhang, Jianguo

AU - McDermott, Jason

AU - Samudrala, Ram

AU - Wang, Jian

AU - Yang, Huanming

AU - Yu, Jun

AU - Kristiansen, Karsten

AU - Wong, Gane Ka-Shu

AU - Wang, Jun

PY - 2005/9

Y1 - 2005/9

N2 - Gene number difference among organisms demonstrates that new gene origination is a fundamental biological process in evolution. Exon shuffling has been universally observed in the formation of new genes. Yet to be learned are the ways new exons originate and evolve, and how often new exons appear. To address these questions, we identified 2695 newly evolved exons in the mouse and rat by comparing the expressed sequences of 12,419 orthologous genes between human and mouse, using 743,856 pig ESTs as the outgroup. The new exon origination rate is about 2.71 × 10-3 per gene per million years. These new exons have markedly accelerated rates both of nonsynonymous substitutions and of insertions/deletions (indels). A much higher proportion of new exons have Ka/Ks ratios >1 (where Ka is the nonsynonymous substitution rate and Ks is the synonymous substitution rate) than do the old exons shared by human and mouse, implying a role of positive selection in the rapid evolution. The majority of these new exons have sequences unique in the genome, suggesting that most new exons might originate through "exonization" of intronic sequences. Most of the new exons appear to be alternative exons that are expressed at low levels.

AB - Gene number difference among organisms demonstrates that new gene origination is a fundamental biological process in evolution. Exon shuffling has been universally observed in the formation of new genes. Yet to be learned are the ways new exons originate and evolve, and how often new exons appear. To address these questions, we identified 2695 newly evolved exons in the mouse and rat by comparing the expressed sequences of 12,419 orthologous genes between human and mouse, using 743,856 pig ESTs as the outgroup. The new exon origination rate is about 2.71 × 10-3 per gene per million years. These new exons have markedly accelerated rates both of nonsynonymous substitutions and of insertions/deletions (indels). A much higher proportion of new exons have Ka/Ks ratios >1 (where Ka is the nonsynonymous substitution rate and Ks is the synonymous substitution rate) than do the old exons shared by human and mouse, implying a role of positive selection in the rapid evolution. The majority of these new exons have sequences unique in the genome, suggesting that most new exons might originate through "exonization" of intronic sequences. Most of the new exons appear to be alternative exons that are expressed at low levels.

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DO - 10.1101/gr.3929705

M3 - RGC 21 - Publication in refereed journal

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SN - 1088-9051

VL - 15

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JO - Genome Research

JF - Genome Research

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Origin and evolution of new exons in rodents

Abstract

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