FRUCTOKINASE‐LIKE PROTEIN 1 interacts with TRXz to regulate chloroplast development in rice

Publisher: John Wiley & Sons Inc

E-ISSN: 1744-7909|60|2|94-111

ISSN: 1672-9072

Source: JOURNAL OF INTEGRATIVE PLANT BIOLOGY (ELECTRONIC), Vol.60, Iss.2, 2018-02, pp. : 94-111

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Abstract

Abstract

Chloroplast genes are transcribed by the plastid‐encoded RNA polymerase (PEP) or nucleus‐encoded RNA polymerase. FRUCTOKINASE‐LIKE PROTEINS (FLNs) are phosphofructokinase‐B (PfkB)‐type carbohydrate kinases that act as part of the PEP complex; however, the molecular mechanisms underlying FLN activity in rice remain elusive. Previously, we identified and characterized a heat‐stress sensitive albino (hsa1) mutant in rice. Map‐based cloning revealed that HSA1 encodes a putative OsFLN2. Here, we further demonstrated that knockdown or knockout of the OsFLN1, a close homolog of HSA1/OsFLN2, considerably inhibits chloroplast biogenesis and the fln1 knockout mutants, created by clustered regularly interspaced short palindromic repeats (CRISPR) and CRISPR‐associate protein 9, exhibit severe albino phenotype and seedling lethality. Moreover, OsFLN1 localizes to the chloroplast. Yeast two‐hybrid, pull‐down and bimolecular fluorescence complementation experiments revealed that OsFLN1 and HSA1/OsFLN2 interact with THIOREDOXINZ (OsTRXz) to regulate chloroplast development. In agreement with this, knockout of OsTRXz resulted in a similar albino and seedling lethality phenotype to that of the fln1 mutants. Quantitative reverse transcription polymerase chain reaction and immunoblot analysis revealed that the transcription and translation of PEP‐dependent genes were strongly inhibited in fln1 and trxz mutants, indicating that loss of OsFLN1, HSA1/OsFLN2, or OsTRXz function perturbs the stability of the transcriptionally active chromosome complex and PEP activity. These results show that OsFLN1 and HSA1/OsFLN2 contribute to chloroplast biogenesis and plant growth.

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