The Variegated Tomato Mutant is Linked to Photosystem Assembly

Overview

Journal Comput Struct Biotechnol J

Specialty Biotechnology

Date 2024 Nov 25

PMID 39582891

Authors

Micha Wijesingha Ahchige

Josef Fisher

Ewelina Sokolowska

Rafe Lyall

Nicola Illing

Aleksandra Skirycz

Dani Zamir

Saleh Alseekh

Alisdair R Fernie

Affiliations

Soon will be listed here.

Abstract

The recently described tomato mutant, which has a variegated leaf phenotype, has been shown to affect canalization of yield. The corresponding protein is orthologous to AtSCO2 -SNOWY COTYLEDON 2, which has suggested roles in thylakoid biogenesis. Here we characterize the mutant through a multi-omics approach, by comparing mutant to wild-type tissues. While white leaves are devoid of chlorophyll, green leaves of the mutant appear wild-type-like, despite an impaired protein function. Transcriptomic data suggest that green mutant leaves compensate for this impaired protein function by upregulation of transcription of photosystem assembly and photosystem component genes, thereby allowing adequate photosystem establishment, which is reflected in their wild-type-like proteome. White leaves, however, likely fail to reach a certain threshold enabling this overcompensation, and plastids get trapped in an undeveloped state, while additionally suffering from high light stress, indicated by the overexpression of ELIP homolog genes. The metabolic profile of white and to a lesser degree also green tissues revealed upregulation of amino acid levels, that was at least partially mediated by transcriptional and proteomic upregulation. These combined changes are indicative of a stress response and suggest that white tissues behave as carbon sinks. In summary, our work demonstrates the relevance of the SCO2 protein in both photosystem assembly and as a consequence in the canalization of yield.

Citing Articles

Embracing plant plasticity or robustness as a means of ensuring food security.

Alseekh S, Klemmer A, Yan J, Guo T, Fernie A Nat Commun. 2025; 16(1):461.

PMID: 39774717 PMC: 11706996. DOI: 10.1038/s41467-025-55872-4.

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