Sequence-based prediction of transcription upregulation by auxin in plants

Пономаренко, П. М.; Пономаренко, М. П.

doi:10.1142/s0219720015400090

Cited by 16 publications

(10 citation statements)

References 59 publications

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“…Additionally, we compiled a set of SNPs in the TBP-binding sites associated with human diseases [ 54 ], including the AIDS pandemic [ 55 ], and with commercially important traits of plants and animals [ 56 ]. Then, we confirmed the three-step predictions by means of these SNPs [ 57 ] and by means of transcriptomes of the human brain [ 58 ], the auxin response in plants [ 59 , 60 ], and the data from 68 independent experiments (for review, see [ 61 ]). To finalize this comprehensive verification of the three-step model of TBP binding to a promoter [ 47 , 49 ], we created a freely available Web service [ 62 ] for users who wish to apply this bioinformatics application to data on the TBP/promoter-complexes in humans: http://beehive.bionet.nsc.ru/cgi-bin/mgs/tatascan/start.pl .…”

Section: Introductionsupporting

confidence: 57%

How to Use SNP_TATA_Comparator to Find a Significant Change in Gene Expression Caused by the Regulatory SNP of This Gene’s Promoter via a Change in Affinity of the TATA-Binding Protein for This Promoter

Пономаренко

Рассказов

Arkova

et al. 2015

BioMed Research International

118

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The use of biomedical SNP markers of diseases can improve effectiveness of treatment. Genotyping of patients with subsequent searching for SNPs more frequent than in norm is the only commonly accepted method for identification of SNP markers within the framework of translational research. The bioinformatics applications aimed at millions of unannotated SNPs of the “1000 Genomes” can make this search for SNP markers more focused and less expensive. We used our Web service involving Fisher's Z-score for candidate SNP markers to find a significant change in a gene's expression. Here we analyzed the change caused by SNPs in the gene's promoter via a change in affinity of the TATA-binding protein for this promoter. We provide examples and discuss how to use this bioinformatics application in the course of practical analysis of unannotated SNPs from the “1000 Genomes” project. Using known biomedical SNP markers, we identified 17 novel candidate SNP markers nearby: rs549858786 (rheumatoid arthritis); rs72661131 (cardiovascular events in rheumatoid arthritis); rs562962093 (stroke); rs563558831 (cyclophosphamide bioactivation); rs55878706 (malaria resistance, leukopenia), rs572527200 (asthma, systemic sclerosis, and psoriasis), rs371045754 (hemophilia B), rs587745372 (cardiovascular events); rs372329931, rs200209906, rs367732974, and rs549591993 (all four: cancer); rs17231520 and rs569033466 (both: atherosclerosis); rs63750953, rs281864525, and rs34166473 (all three: malaria resistance, thalassemia).

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Section: Introductionsupporting

confidence: 57%

How to Use SNP_TATA_Comparator to Find a Significant Change in Gene Expression Caused by the Regulatory SNP of This Gene’s Promoter via a Change in Affinity of the TATA-Binding Protein for This Promoter

Пономаренко

Рассказов

Arkova

et al. 2015

BioMed Research International

118

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“…In Arabidopsis, AtWOX11 and AtWOX12, orthologs of rice WOX6 and WOX11, respectively, are reported to play roles in root development (Liu et al, 2014;Hu and Xu, 2016;Sheng et al, 2017). We found that both WOX6 and WOX11 contain auxin response elements, TGTCNC (Ponomarenko and Ponomarenko, 2015), in their promoter regions (Supplemental Figure 9). We further verified that WOX6 and WOX11 were not only responsive to NAA treatment, but also displayed an asymmetrical expression pattern like that of IAA20 during shoot gravitropism under light ( Figures 6C and 6D).…”

Section: Wox6 and Wox11 Are Downstream Targets Of Auxin In Determininmentioning

confidence: 81%

A Core Regulatory Pathway Controlling Rice Tiller Angle Mediated by the LAZY1-Dependent Asymmetric Distribution of Auxin

et al. 2018

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Tiller angle in cereals is a key shoot architecture trait that strongly influences grain yield. Studies in rice () have implicated shoot gravitropism in the regulation of tiller angle. However, the functional link between shoot gravitropism and tiller angle is unknown. Here, we conducted a large-scale transcriptome analysis of rice shoots in response to gravistimulation and identified two new nodes of a shoot gravitropism regulatory gene network that also controls rice tiller angle. We demonstrate that HEAT STRESS TRANSCRIPTION FACTOR 2D (HSFA2D) is an upstream positive regulator of the LAZY1-mediated asymmetric auxin distribution pathway. We also show that two functionally redundant transcription factor genes, () and , are expressed asymmetrically in response to auxin to connect gravitropism responses with the control of rice tiller angle. These findings define upstream and downstream genetic components that link shoot gravitropism, asymmetric auxin distribution, and rice tiller angle. The results highlight the power of the high-temporal-resolution RNA-seq data set and its use to explore further genetic components controlling tiller angle. Collectively, these approaches will identify genes to improve grain yields by facilitating the optimization of plant architecture.

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“…This refined auxin‐responsive motif was more predictive of auxin responsiveness compared with using the canonical DR5 motif within the first 500 bp of the promoter sequence; however, it has not been functionally tested in vivo . Modelling of auxin responses based on promoter motifs is not only powerful in confirming known AuxREs, but correlations using 111 natural or artificially tested AuxREs showed a positive correlation between auxin inducibility and the abundance of five trinucleotides and five β ‐helical DNA features around these known AuxREs, confirming that in addition to ARF sequence specificity, TATA‐binding protein affinity for DNA and nucleosomal packing is also important in modelling auxin response at the promoter level (Ponomarenko & Ponomarenko ). Enigmatically, many auxin‐regulated genes lack AuxREs in their promoters (Goda et al .…”

Section: Auxin Response Factor Target Sequences and Binding Specificitymentioning

confidence: 99%

Auxin response factors

Chandler

2016

Plant Cell & Environment

245

188

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Auxin signalling involves the activation or repression of gene expression by a class of auxin response factor (ARF) proteins that bind to auxin response elements in auxin-responsive gene promoters. The release of ARF repression in the presence of auxin by the degradation of their cognate auxin/indole-3-acetic acid repressors forms a paradigm of transcriptional response to auxin. However, this mechanism only applies to activating ARFs, and further layers of complexity of ARF function and regulation are being revealed, which partly reflect their highly modular domain structure. This review summarizes our knowledge concerning ARF binding site specificity, homodimer and heterodimer multimeric ARF association and cooperative function and how activator ARFs activate target genes via chromatin remodelling and evolutionary information derived from phylogenetic comparisons from ARFs from diverse species. ARFs are regulated in diverse ways, and their importance in non-auxin-regulated pathways is becoming evident. They are also embedded within higher-order transcription factor complexes that integrate signalling pathways from other hormones and in response to the environment. The ways in which new information concerning ARFs on many levels is causing a revision of existing paradigms of auxin response are discussed.

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Sequence-based prediction of transcription upregulation by auxin in plants

Cited by 16 publications

References 59 publications

How to Use SNP_TATA_Comparator to Find a Significant Change in Gene Expression Caused by the Regulatory SNP of This Gene’s Promoter via a Change in Affinity of the TATA-Binding Protein for This Promoter

How to Use SNP_TATA_Comparator to Find a Significant Change in Gene Expression Caused by the Regulatory SNP of This Gene’s Promoter via a Change in Affinity of the TATA-Binding Protein for This Promoter

A Core Regulatory Pathway Controlling Rice Tiller Angle Mediated by the LAZY1-Dependent Asymmetric Distribution of Auxin

Auxin response factors

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