Litcius/Paper detail

De Novo Shoot Regeneration Controlled by HEN1 and TCP3/4 in Arabidopsis

Woorim Yang, Myunghwan Choi, Bosl Noh, Yoo‐Sun Noh

2020Plant and Cell Physiology33 citationsDOIOpen Access PDF

Abstract

Plants have the ability to regenerate whole plant body parts, including shoots and roots, in vitro from callus derived from a variety of tissues. However, the underlying mechanisms for this de novo organogenesis, which is based on the totipotency of callus cells, are poorly understood. Here, we report that a microRNA (miRNA)-mediated posttranscriptional regulation plays an important role in de novo shoot regeneration. We found that mutations in HUA ENHANCER 1 (HEN1), a gene encoding a small RNA methyltransferase, cause cytokinin-related defects in de novo shoot regeneration. A hen1 mutation caused a large reduction in the miRNA319 (miR319) level and a subsequent increase in its known target (TCP3 and TCP4) transcript levels. TCP transcription factors redundantly inhibited shoot regeneration and directly activated the expression of a negative regulator of cytokinin response ARABIDOPSIS THALIANA RESPONSE REGULATOR 16 (ARR16). A tcp4 mutation at least partly rescued the shoot-regeneration defect and derepression of ARR16 in hen1. These findings demonstrate that the miR319-TCP3/4-ARR16 axis controls de novo shoot regeneration by modulating cytokinin responses.

Topics & Concepts

ArabidopsisBiologyCytokininRegeneration (biology)ShootRegulatormicroRNACallusOrganogenesisCell biologyArabidopsis thalianaGeneticsGeneBotanyMutantAuxinPlant Molecular Biology ResearchPlant Reproductive BiologyPlant Gene Expression Analysis