A new link between stress response and nucleolar function during pollen development in <i><scp>A</scp>rabidopsis</i> mediated by <scp>AtREN</scp>1 protein

Reňák, David; Gibalová, Antónia; Šolcová, Katarzyna; Honys, David

doi:10.1111/pce.12186

Cited by 30 publications

(17 citation statements)

References 97 publications

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“…We originally considered that heat would induce the expression of these TaHsf genes and that their upregulated expression would lead to the upregulation of other fertility-related genes, thereby ensuring fertility. However, we found that some genes had pollen-specific expression-related binding sites based on our predictions of the ciselements, and previous studies have shown that the AT2G26150 and AT4G13980 genes are critical during pollen reproduction [53,54]. Our analysis of the TaHsfs related to wheat fertility provides a basis for future investigations of the important roles of TaHsfs in the fertility regulation mechanism.…”

Section: Discussionsupporting

confidence: 64%

Genome-wide investigation of heat shock transcription factor family in wheat (Triticum aestivum L.)

Song

Yang

et al. 2019

Preprint

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Background: Heat shock transcription factors (HSFs) play crucial roles in resisting heat stress and regulating plant development. Investigating the HSF family is essential for understanding the fertility conversion mechanism in thermo-sensitive male sterile wheat. Previous studies have investigated the HSF family in wheat but it is necessary to conduct more in-depth and systematic analyses based on the newly published reference genome. Results: In the present study, 61 wheat Hsf (TaHsf) genes were identified using two main strategies and renamed based on their physical locations on chromosomes. According to the gene structure and phylogenetic analyses, the 61 TaHsf genes were classified into three categories and eleven subclasses. The genes were unequally distributed on 21 chromosomes, including two pairs of tandem duplication genes and 52 TaHsf segmental duplication genes. According to the cis-elements identified, most of the TaHsfs can be activated by Ca++ and MYB, and they respond to drought, light, copper, and other stresses as well as heat shock. RNA-seq analysis indicated that the A2 class TaHsf genes exhibited persistently upregulated expression levels in the leaves/shoots, roots (except in the vegetative growth and reproductive growth stages), spikes, and grains in wheat under normal conditions. The A and B class TaHsf genes were positively regulated during the resistance to heat, whereas the C class genes were involved in drought regulation in wheat. Only the A and B class TaHsf genes were upregulated under fertile conditions in thermo-sensitive male sterile wheat. Conclusion: In this study, 61 wheat Hsf genes were identified based on the complete wheat reference genome. This comprehensive analysis provides novel insights into the TaHsf genes, including their diverse functions and involvement in metabolic pathways.

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Section: Discussionsupporting

confidence: 64%

Genome-wide investigation of heat shock transcription factor family in wheat (Triticum aestivum L.)

Song

Yang

et al. 2019

Preprint

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“…In plants, transcription factor HSFs are expressed in male reproductive cells during heat stress. In particular, AtHsfA2 (AT2G26150) and AtHsfA5 (AT4G13980) were identified as critical during pollen reproduction in Arabidopsis [67,68]. Five class A Hsfs and three class B Hsfs are up-regulated in rice spikes [40].…”

Section: Discussionmentioning

confidence: 99%

Genome-Wide Investigation of Heat Shock Transcription Factor Family in Wheat (Triticum aestivum L.) and Possible Roles in Anther Development

Yang

Gan

et al. 2020

IJMS

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Heat shock transcription factors (HSFs) play crucial roles in resisting heat stress and regulating plant development. Recently, HSFs have been shown to play roles in anther development. Thus, investigating the HSF family members and identifying their protective roles in anthers are essential for the further development of male sterile wheat breeding. In the present study, 61 wheat HSF genes (TaHsfs) were identified in the whole wheat genome and they are unequally distributed on 21 chromosomes. According to gene structure and phylogenetic analyses, the 61 TaHsfs were classified into three categories and 12 subclasses. Genome-wide duplication was identified as the main source of the expansion of the wheat HSF gene family based on 14 pairs of homeologous triplets, whereas only a very small number of TaHsfs were derived by segmental duplication and tandem duplication. Heat shock protein 90 (HSP90), HSP70, and another class of chaperone protein called htpG were identified as proteins that interact with wheat HSFs. RNA-seq analysis indicated that TaHsfs have obvious period- and tissue-specific expression patterns, and the TaHsfs in classes A and B respond to heat shock, whereas the C class TaHsfs are involved in drought regulation. qRT-PCR identified three TaHsfA2bs with differential expression in sterile and fertile anthers, and they may be candidate genes involved in anther development. This comprehensive analysis provides novel insights into TaHsfs, and it will be useful for understanding the mechanism of plant fertility conversion.

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“…In Arabidopsis, the inhibition of RBF or RP gene expression induces a wide variety of plant growth and developmental phenotypes, including embryo lethality, delayed flowering time, and abnormal leaf and root phenotypes (Supplemental Data Sets 3 and 4). Cytological investigations have shown that the nucleolus becomes larger in tormoz (Griffith et al, 2007), nof1 (Harscoët et al, 2010), apum23 (Abbasi et al, 2010), rid2 (Ohbayashi et al, 2011;Shinohara et al, 2014), ren1 (Reňák et al, 2014), la1 (Fleurdepine et al, 2007), and domino1 (Lahmy et al, 2004) compared with wild-type plants. By contrast, the nucleolus is small in fem111 (Portereiko et al, 2006) and disorganized in nuc1 (Pontvianne et al, 2007) plants.…”

Section: Ribosome Response Pathwaymentioning

confidence: 99%

Ribosome Biogenesis in Plants: From Functional 45S Ribosomal DNA Organization to Ribosome Assembly Factors

2019

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The transcription of 18S, 5.8S, and 18S rRNA genes (45S rDNA), cotranscriptional processing of pre-rRNA, and assembly of mature rRNA with ribosomal proteins are the linchpins of ribosome biogenesis. In yeast (Saccharomyces cerevisiae) and animal cells, hundreds of pre-rRNA processing factors have been identified and their involvement in ribosome assembly determined. These studies, together with structural analyses, have yielded comprehensive models of the pre-40S and pre-60S ribosome subunits as well as the largest cotranscriptionally assembled preribosome particle: the 90S/small subunit processome. Here, we present the current knowledge of the functional organization of 45S rDNA, pre-rRNA transcription, rRNA processing activities, and ribosome assembly factors in plants, focusing on data from Arabidopsis (Arabidopsis thaliana). Based on yeast and mammalian cell studies, we describe the ribonucleoprotein complexes and RNA-associated activities and discuss how they might specifically affect the production of 40S and 60S subunits. Finally, we review recent findings concerning pre-rRNA processing pathways and a novel mechanism involved in a ribosome stress response in plants

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A new link between stress response and nucleolar function during pollen development in Arabidopsis mediated by AtREN1 protein

Cited by 30 publications

References 97 publications

Genome-wide investigation of heat shock transcription factor family in wheat (Triticum aestivum L.)

Genome-wide investigation of heat shock transcription factor family in wheat (Triticum aestivum L.)

Genome-Wide Investigation of Heat Shock Transcription Factor Family in Wheat (Triticum aestivum L.) and Possible Roles in Anther Development

Ribosome Biogenesis in Plants: From Functional 45S Ribosomal DNA Organization to Ribosome Assembly Factors

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