Global Transcriptome Analysis Reveals Distinct Expression Among Duplicated Genes During Sorghum-interaction

Overview

Journal BMC Plant Biol

Publisher Biomed Central

Specialty Biology

Date 2012 Jul 31

PMID 22838966

Citations 31

Authors

Hiroshi Mizuno

Hiroyuki Kawahigashi

Yoshihiro Kawahara

Hiroyuki Kanamori

Jun Ogata

Hiroshi Minami

Takeshi Itoh

Takashi Matsumoto

Affiliations

Soon will be listed here.

Abstract

Background: Sorghum (Sorghum bicolor L. Moench) is a rich source of natural phytochemicals. We performed massive parallel sequencing of mRNA to identify differentially expressed genes after sorghum BTx623 had been infected with Bipolaris sorghicola, a necrotrophic fungus causing a sorghum disease called target leaf spot.

Result: Seventy-six-base-pair reads from mRNAs of mock- or pathogen-infected leaves were sequenced. Unannotated transcripts were predicted on the basis of the piling-up of mapped short reads. Differentially expressed genes were identified statistically; particular genes in tandemly duplicated putative paralogs were highly upregulated. Pathogen infection activated the glyoxylate shunt in the TCA cycle; this changes the role of the TCA cycle from energy production to synthesis of cell components. The secondary metabolic pathways of phytoalexin synthesis and of sulfur-dependent detoxification were activated by upregulation of the genes encoding amino acid metabolizing enzymes located at the branch point between primary and secondary metabolism. Coordinated gene expression could guide the metabolic pathway for accumulation of the sorghum-specific phytochemicals 3-deoxyanthocyanidin and dhurrin. Key enzymes for synthesizing these sorghum-specific phytochemicals were not found in the corresponding region of the rice genome.

Conclusion: Pathogen infection dramatically changed the expression of particular paralogs that putatively encode enzymes involved in the sorghum-specific metabolic network.

Citing Articles

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