Literature DB >> 26307377

Global Transcriptome Profiling of Developing Leaf and Shoot Apices Reveals Distinct Genetic and Environmental Control of Floral Transition and Inflorescence Development in Barley.

Benedikt Digel1, Artem Pankin2, Maria von Korff3.   

Abstract

Timing of the floral transition and inflorescence development strongly affect yield in barley (Hordeum vulgare). Therefore, we examined the effects of daylength and the photoperiod response gene PHOTOPERIOD1 (Ppd-H1) on barley development and analyzed gene expression changes in the developing leaves and main shoot apices (MSAs) of barley by RNA sequencing. The daylength sensitivity of MSA development had two phases, floret primordia initiated under long and short days, whereas successful inflorescence development occurred only under long days. The transcripts associated with floral transition were largely regulated independently of photoperiod and allelic variation at Ppd-H1. The photoperiod- and Ppd-H1-dependent differences in inflorescence development and flower fertility were associated with the induction of barley FLOWERING LOCUS T orthologs: FT1 in leaves and FT2 in MSAs. FT1 expression was coregulated with transcripts involved in nutrient transport, carbohydrate metabolism, and cell cycle regulation, suggesting that FT1 might alter source-sink relationships. Successful inflorescence development correlated with upregulation of FT2 and transcripts related to floral organ development, phytohormones, and cell cycle regulation. Identification of photoperiod and stage-specific transcripts gives insights into the regulation of reproductive development in barley and provides a resource for investigation of the complexities of development and yield in temperate grasses.
© 2015 American Society of Plant Biologists. All rights reserved.

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Year:  2015        PMID: 26307377      PMCID: PMC4815099          DOI: 10.1105/tpc.15.00203

Source DB:  PubMed          Journal:  Plant Cell        ISSN: 1040-4651            Impact factor:   11.277


  68 in total

1.  Analysis of the Arabidopsis shoot meristem transcriptome during floral transition identifies distinct regulatory patterns and a leucine-rich repeat protein that promotes flowering.

Authors:  Stefano Torti; Fabio Fornara; Coral Vincent; Fernando Andrés; Karl Nordström; Ulrike Göbel; Daniela Knoll; Heiko Schoof; George Coupland
Journal:  Plant Cell       Date:  2012-02-07       Impact factor: 11.277

Review 2.  Auxin regulation of Arabidopsis flower development involves members of the AINTEGUMENTA-LIKE/PLETHORA (AIL/PLT) family.

Authors:  Beth A Krizek
Journal:  J Exp Bot       Date:  2011-04-21       Impact factor: 6.992

3.  Orchestration of the floral transition and floral development in Arabidopsis by the bifunctional transcription factor APETALA2.

Authors:  Levi Yant; Johannes Mathieu; Thanh Theresa Dinh; Felix Ott; Christa Lanz; Heike Wollmann; Xuemei Chen; Markus Schmid
Journal:  Plant Cell       Date:  2010-07-30       Impact factor: 11.277

4.  Temporal regulation of shoot development in Arabidopsis thaliana by miR156 and its target SPL3.

Authors:  Gang Wu; R Scott Poethig
Journal:  Development       Date:  2006-08-16       Impact factor: 6.868

5.  A physical, genetic and functional sequence assembly of the barley genome.

Authors:  Klaus F X Mayer; Robbie Waugh; John W S Brown; Alan Schulman; Peter Langridge; Matthias Platzer; Geoffrey B Fincher; Gary J Muehlbauer; Kazuhiro Sato; Timothy J Close; Roger P Wise; Nils Stein
Journal:  Nature       Date:  2012-10-17       Impact factor: 49.962

6.  The microRNA-regulated SBP-Box transcription factor SPL3 is a direct upstream activator of LEAFY, FRUITFULL, and APETALA1.

Authors:  Ayako Yamaguchi; Miin-Feng Wu; Li Yang; Gang Wu; R Scott Poethig; Doris Wagner
Journal:  Dev Cell       Date:  2009-08       Impact factor: 12.270

7.  SHORT VEGETATIVE PHASE reduces gibberellin biosynthesis at the Arabidopsis shoot apex to regulate the floral transition.

Authors:  Fernando Andrés; Aimone Porri; Stefano Torti; Julieta Mateos; Maida Romera-Branchat; José Luis García-Martínez; Fabio Fornara; Veronica Gregis; Martin M Kater; George Coupland
Journal:  Proc Natl Acad Sci U S A       Date:  2014-06-16       Impact factor: 11.205

8.  High-Resolution Genotyping of Wild Barley Introgression Lines and Fine-Mapping of the Threshability Locus thresh-1 Using the Illumina GoldenGate Assay.

Authors:  Inga Schmalenbach; Timothy J March; Thomas Bringezu; Robbie Waugh; Klaus Pillen
Journal:  G3 (Bethesda)       Date:  2011-08-01       Impact factor: 3.154

9.  Effect of read-mapping biases on detecting allele-specific expression from RNA-sequencing data.

Authors:  Jacob F Degner; John C Marioni; Athma A Pai; Joseph K Pickrell; Everlyne Nkadori; Yoav Gilad; Jonathan K Pritchard
Journal:  Bioinformatics       Date:  2009-10-06       Impact factor: 6.937

10.  HvLUX1 is a candidate gene underlying the early maturity 10 locus in barley: phylogeny, diversity, and interactions with the circadian clock and photoperiodic pathways.

Authors:  Chiara Campoli; Artem Pankin; Benedikt Drosse; Cristina M Casao; Seth J Davis; Maria von Korff
Journal:  New Phytol       Date:  2013-06-03       Impact factor: 10.151
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  30 in total

1.  FLOWERING LOCUS T3 Controls Spikelet Initiation But Not Floral Development.

Authors:  Muhammad Aman Mulki; Xiaojing Bi; Maria von Korff
Journal:  Plant Physiol       Date:  2018-09-13       Impact factor: 8.340

2.  The Genetic Control of Reproductive Development under High Ambient Temperature.

Authors:  Mahwish Ejaz; Maria von Korff
Journal:  Plant Physiol       Date:  2016-11-08       Impact factor: 8.340

3.  Processes Underlying a Reproductive Barrier in indica-japonica Rice Hybrids Revealed by Transcriptome Analysis.

Authors:  Yanfen Zhu; Yiming Yu; Ke Cheng; Yidan Ouyang; Jia Wang; Liang Gong; Qinghua Zhang; Xianghua Li; Jinghua Xiao; Qifa Zhang
Journal:  Plant Physiol       Date:  2017-05-08       Impact factor: 8.340

4.  CENTRORADIALIS Interacts with FLOWERING LOCUS T-Like Genes to Control Floret Development and Grain Number.

Authors:  Xiaojing Bi; Wilma van Esse; Mohamed Aman Mulki; Gwendolyn Kirschner; Jinshun Zhong; Rüdiger Simon; Maria von Korff
Journal:  Plant Physiol       Date:  2019-04-19       Impact factor: 8.340

5.  Transcriptome Profiling of Wheat Inflorescence Development from Spikelet Initiation to Floral Patterning Identified Stage-Specific Regulatory Genes.

Authors:  Nan Feng; Gaoyuan Song; Jiantao Guan; Kai Chen; Meiling Jia; Dehua Huang; Jiajie Wu; Lichao Zhang; Xiuying Kong; Shuaifeng Geng; Jun Liu; Aili Li; Long Mao
Journal:  Plant Physiol       Date:  2017-05-17       Impact factor: 8.340

6.  Photoperiod-H1 (Ppd-H1) Controls Leaf Size.

Authors:  Benedikt Digel; Elahe Tavakol; Gabriele Verderio; Alessandro Tondelli; Xin Xu; Luigi Cattivelli; Laura Rossini; Maria von Korff
Journal:  Plant Physiol       Date:  2016-07-25       Impact factor: 8.340

7.  Differential Effects of Day/Night Cues and the Circadian Clock on the Barley Transcriptome.

Authors:  Lukas M Müller; Laurent Mombaerts; Artem Pankin; Seth J Davis; Alex A R Webb; Jorge Goncalves; Maria von Korff
Journal:  Plant Physiol       Date:  2020-03-30       Impact factor: 8.340

8.  Identification and analysis of a differentially expressed wheat RING-type E3 ligase in spike primordia development during post-vernalization.

Authors:  Jae Ho Kim; Irfan Ullah Khan; Cheol Won Lee; Dae Yeon Kim; Cheol Seong Jang; Sung Don Lim; Yong Chan Park; Ju Hee Kim; Yong Weon Seo
Journal:  Plant Cell Rep       Date:  2021-01-10       Impact factor: 4.570

9.  Transcriptome landscape of early inflorescence developmental stages identifies key flowering time regulators in chickpea.

Authors:  Udita Basu; Venkatraman S Hegde; Anurag Daware; Uday Chand Jha; Swarup K Parida
Journal:  Plant Mol Biol       Date:  2022-02-01       Impact factor: 4.076

10.  Genome-Wide Identification of Barley Long Noncoding RNAs and Analysis of Their Regulatory Interactions during Shoot and Grain Development.

Authors:  Sebastian Gasparis; Mateusz Przyborowski; Anna Nadolska-Orczyk
Journal:  Int J Mol Sci       Date:  2021-05-11       Impact factor: 5.923
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