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The piperazine compound ASP activates an auxin response in Arabidopsis thaliana
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The piperazine compound ASP activates an auxin response in Arabidopsis thaliana
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Journal Article
The piperazine compound ASP activates an auxin response in Arabidopsis thaliana
2020
Overview
Background
Auxins play key roles in the phytohormone network. Early auxin response genes in the
AUX/IAA, SAUR,
and
GH3
families show functional redundancy, which makes it very difficult to study the functions of individual genes based on gene knockout analysis or transgenic technology. As an alternative, chemical genetics provides a powerful approach that can be used to address questions relating to plant hormones.
Results
By screening a small-molecule chemical library of compounds that can induce abnormal seedling and vein development, we identified and characterized a piperazine compound 1-[(4-bromophenoxy) acetyl]-4-[(4-fluorophenyl) sulfonyl] piperazine (ASP). The
Arabidopsis DR5::GFP
line was used to assess if the effects mentioned were correlated with the auxin response, and we accordingly verified that ASP altered the auxin-related pathway. Subsequently, we examined the regulatory roles of ASP in hypocotyl and root development, auxin distribution, and changes in gene expression. Following ASP treatment, we detected hypocotyl elongation concomitant with enhanced cell elongation. Furthermore, seedlings showed retarded primary root growth, reduced gravitropism and increased root hair development. These phenotypes were associated with an increased induction of
DR5::GUS
expression in the root/stem transition zone and root tips. Auxin-related mutants including
tir1–1
,
aux1–7
and
axr2–1
showed phenotypes with different root-development pattern from that of the wild type (Col-0), and were insensitive to ASP. Confocal images of propidium iodide (PI)-stained root tip cells showed no detectable damage by ASP. Furthermore, RT-qPCR analyses of two other genes, namely, Ethylene Response Factor (
ERF115
) and Mediator 18 (
MED18
), which are related to cell regeneration and damage, indicated that the ASP inhibitory effect on root growth was not attributable to toxicity. RT-qPCR analysis provided further evidence that ASP induced the expression of early auxin-response-related genes.
Conclusions
ASP altered the auxin response pathway and regulated
Arabidopsis
growth and development. These results provide a basis for dissecting specific molecular components involved in auxin-regulated developmental processes and offer new opportunities to discover novel molecular players involved in the auxin response.
Publisher
BioMed Central,Springer Nature B.V,BMC
Subject
/ Arabidopsis Proteins - genetics
/ Arabidopsis Proteins - metabolism
/ ASP
/ Auxins
/ Biomedical and Life Sciences
/ Gene Expression Regulation, Plant
/ Genes
/ Genetics
/ Genomics
/ Hair
/ Hormones
/ Indoleacetic Acids - pharmacology
/ Iodides
/ Microbial Genetics and Genomics
/ Mutation
/ Toxicity
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