Regulates Inflorescence Architecture and Development in Bread Wheat ()

Overview

Journal Plant Cell

Publisher Oxford University Press

Specialties Biology
Cell Biology

Date 2018 Feb 16

PMID 29444813

Citations 107

Authors

Laura E Dixon

Julian R Greenwood

Stefano Bencivenga

Peng Zhang

James Cockram

Gregory Mellers

Kerrie Ramm

Colin Cavanagh

Steve M Swain

Scott A Boden

Affiliations

Soon will be listed here.

Abstract

The flowers of major cereals are arranged on reproductive branches known as spikelets, which group together to form an inflorescence. Diversity for inflorescence architecture has been exploited during domestication to increase crop yields, and genetic variation for this trait has potential to further boost grain production. Multiple genes that regulate inflorescence architecture have been identified by studying alleles that modify gene activity or dosage; however, little is known in wheat. Here, we show () regulates inflorescence architecture in bread wheat () by investigating lines that display a form of inflorescence branching known as "paired spikelets." We show that TB1 interacts with FLOWERING LOCUS T1 and that increased dosage of alters inflorescence architecture and growth rate in a process that includes reduced expression of meristem identity genes, with allelic diversity for found to associate genetically with paired spikelet development in modern cultivars. We propose coordinates formation of axillary spikelets during the vegetative to floral transition and that alleles known to modify dosage or function of could help increase wheat yields.

Citing Articles

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