The Frequent Transcriptional Readthrough of the Tobacco Tnt1 Retrotransposon and Its Possible Implications for the Control of Resistance Genes

Overview

Journal J Mol Evol

Specialty Biochemistry

Date 2009 Feb 18

PMID 19221683

Citations 10

Authors

Inmaculada Hernandez-Pinzon

Erika de Jesus

Nestor Santiago

Josep M Casacuberta

Affiliations

Soon will be listed here.

Abstract

Retrotransposons are a major component of eukaryote genomes, being especially abundant in plant genomes. They are frequently found inserted in gene-rich regions and have greatly contributed to the evolution of gene coding capacity and regulation. Retrotransposon insertions can influence the expression of neighboring genes in many ways, such as modifying their promoter or terminator sequences and altering their epigenetic control. Plant retrotransposons are highly regulated and their expression is usually associated with stress situations. While the control of transcription of some plant retrotransposons has been analyzed in some detail, little is known about the transcriptional termination of these elements. Here we show that the transcripts of the tobacco retrotransposon Tnt1 display a high variability of polyadenylation sites, only a fraction of them terminating at the major termination site. We also report on the ability of Tnt1 to extend its transcription into flanking genomic sequences and we analyze a particular case in which Tnt1 transcripts include sequences of an oppositely oriented resistance-like gene. The expression of this gene and the neighboring Tnt1 copy generate transcripts overlapping in more that 800 nucleotides, which could anneal and form dsRNAs and enter into silencing regulatory pathways. Resistance gene loci are usually composed of tandem arrays of resistance-like genes, a number of which contain mutations, including retrotransposon insertions, and are considered as to be pseudogenes. Given that plant retrotransposons are usually regulated by stress, the convergent expression of these resistance-like pseudogenes and the interleaving inducible retrotransposons may contribute to the control of plant responses to stress.

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