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The mitochondrial protease AtFTSH4 safeguards Arabidopsis shoot apical meristem function.


ABSTRACT: The shoot apical meristem (SAM) ensures continuous plant growth and organogenesis. In LD 30?°C, plants lacking AtFTSH4, an ATP-dependent mitochondrial protease that counteracts accumulation of internal oxidative stress, exhibit a puzzling phenotype of premature SAM termination. We aimed to elucidate the underlying cellular and molecular processes that link AtFTSH4 with SAM arrest. We studied AtFTSH4 expression, internal oxidative stress accumulation, and SAM morphology. Directly in the SAM we analysed H2O2 accumulation, mitochondria behaviour, and identity of stem cells using WUS/CLV3 expression. AtFTSH4 was expressed in proliferating tissues, particularly during the reproductive phase. In the mutant, SAM, in which internal oxidative stress accumulates predominantly at 30?°C, lost its meristematic fate. This process was progressive and stage-specific. Premature meristem termination was associated with an expansion in SAM area, where mitochondria lost their functionality. All these effects destabilised the identity of the stem cells. SAM termination in ftsh4 mutants is caused both by internal oxidative stress accumulation with time/age and by the tissue-specific role of AtFTSH4 around the flowering transition. Maintaining mitochondria functionality within the SAM, dependent on AtFTSH4, is vital to preserving stem cell activity throughout development.

SUBMITTER: Dolzblasz A 

PROVIDER: S-EPMC4913265 | biostudies-literature | 2016 Jun

REPOSITORIES: biostudies-literature

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The mitochondrial protease AtFTSH4 safeguards Arabidopsis shoot apical meristem function.

Dolzblasz Alicja A   Smakowska Elwira E   Gola Edyta M EM   Sokołowska Katarzyna K   Kicia Marta M   Janska Hanna H  

Scientific reports 20160620


The shoot apical meristem (SAM) ensures continuous plant growth and organogenesis. In LD 30 °C, plants lacking AtFTSH4, an ATP-dependent mitochondrial protease that counteracts accumulation of internal oxidative stress, exhibit a puzzling phenotype of premature SAM termination. We aimed to elucidate the underlying cellular and molecular processes that link AtFTSH4 with SAM arrest. We studied AtFTSH4 expression, internal oxidative stress accumulation, and SAM morphology. Directly in the SAM we an  ...[more]

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