A Unifying Theory for GC3 Biology in Plants and Animals

Tatiana Tatarinova; Nickolai Alexandrov; John Bouck; Kenneth Feldmann

A Unifying Theory for GC3 Biology in Plants and Animals

Tatiana Tatarinova, Nickolai Alexandrov, John Bouck, Kenneth Feldmann

Faculty of Computing, Engineering and Science

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

There is a well-documented bias for cytosine and guanine at the third position in a subset of transcripts within a single organism; it is present in some plant species and warm-blooded vertebrates. We demonstrated that in certain organisms the amount of GC at the wobble position (GC3) can be used to distinguish two classes of genes. We highlight the following features of genes with high GC3content: they (1) provide more targets for methylation, (2) exhibit more variable expression, (3) more frequently possess certain transcription factor binding sites, (4) are predominant in certain classes of genes and (5) have a GC3 content that increases from 5'to 3'. These observations led us to formulate a hypothesis to explain GC3 bimodality in grasses and later extend it to other species. High levels of GC3 typify a class of genes regulated through DNA methylation or are a legacy of accelerated evolution through gene conversion.

Original language	English
Title of host publication	N/A
Publication status	E-pub ahead of print - 18 Jul 2011
Event	ISMB/ECCB 2011 - Location unknown - please update Duration: 18 Jul 2011 → 18 Jul 2011

Conference

Conference	ISMB/ECCB 2011
Period	18/07/11 → 18/07/11

Keywords

evolution

Cite this

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title = "A Unifying Theory for GC3 Biology in Plants and Animals",

abstract = "There is a well-documented bias for cytosine and guanine at the third position in a subset of transcripts within a single organism; it is present in some plant species and warm-blooded vertebrates. We demonstrated that in certain organisms the amount of GC at the wobble position (GC3) can be used to distinguish two classes of genes. We highlight the following features of genes with high GC3content: they (1) provide more targets for methylation, (2) exhibit more variable expression, (3) more frequently possess certain transcription factor binding sites, (4) are predominant in certain classes of genes and (5) have a GC3 content that increases from 5'to 3'. These observations led us to formulate a hypothesis to explain GC3 bimodality in grasses and later extend it to other species. High levels of GC3 typify a class of genes regulated through DNA methylation or are a legacy of accelerated evolution through gene conversion.",

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author = "Tatiana Tatarinova and Nickolai Alexandrov and John Bouck and Kenneth Feldmann",

year = "2011",

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note = " ISMB/ECCB 2011 ; Conference date: 18-07-2011 Through 18-07-2011",

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T1 - A Unifying Theory for GC3 Biology in Plants and Animals

AU - Tatarinova, Tatiana

AU - Alexandrov, Nickolai

AU - Bouck, John

AU - Feldmann, Kenneth

PY - 2011/7/18

Y1 - 2011/7/18

N2 - There is a well-documented bias for cytosine and guanine at the third position in a subset of transcripts within a single organism; it is present in some plant species and warm-blooded vertebrates. We demonstrated that in certain organisms the amount of GC at the wobble position (GC3) can be used to distinguish two classes of genes. We highlight the following features of genes with high GC3content: they (1) provide more targets for methylation, (2) exhibit more variable expression, (3) more frequently possess certain transcription factor binding sites, (4) are predominant in certain classes of genes and (5) have a GC3 content that increases from 5'to 3'. These observations led us to formulate a hypothesis to explain GC3 bimodality in grasses and later extend it to other species. High levels of GC3 typify a class of genes regulated through DNA methylation or are a legacy of accelerated evolution through gene conversion.

AB - There is a well-documented bias for cytosine and guanine at the third position in a subset of transcripts within a single organism; it is present in some plant species and warm-blooded vertebrates. We demonstrated that in certain organisms the amount of GC at the wobble position (GC3) can be used to distinguish two classes of genes. We highlight the following features of genes with high GC3content: they (1) provide more targets for methylation, (2) exhibit more variable expression, (3) more frequently possess certain transcription factor binding sites, (4) are predominant in certain classes of genes and (5) have a GC3 content that increases from 5'to 3'. These observations led us to formulate a hypothesis to explain GC3 bimodality in grasses and later extend it to other species. High levels of GC3 typify a class of genes regulated through DNA methylation or are a legacy of accelerated evolution through gene conversion.

KW - evolution

M3 - Conference contribution

BT - N/A

T2 - ISMB/ECCB 2011

Y2 - 18 July 2011 through 18 July 2011

ER -

A Unifying Theory for GC3 Biology in Plants and Animals

Abstract

Conference

Keywords

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Cite this