MSH1 Is a Plant Organellar DNA Binding and Thylakoid Protein under Precise Spatial Regulation to Alter Development

Virdi, Kamaldeep S.; Wamboldt, Yashitola; Kundariya, Hardik; Laurie, John D.; Keren, Ido; Kumar, K. R. Sunil; Block, Anna; Basset, Gilles J.; Luebker, Steve; Elowsky, Christian; Day, Philip M; Roose, Johnna L.; Bricker, Terry M.; Elthon, Thomas E.; Mackenzie, Sally A.

doi:10.1016/j.molp.2015.10.011

Cited by 56 publications

(95 citation statements)

References 61 publications

(91 reference statements)

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“…In Arabidopsis msh1 T-DNA insertion lines, phenotypes include leaf variegation, reduced growth rate, delayed flowering, extended juvenility, altered floral morphology, aerial rosettes and enhanced secondary growth (Xu et al, 2012). These mutants also show tolerance to heat, high light and drought stress (Shedge et al, 2010;Virdi et al, 2016;Xu et al, 2011). These pleiotropic phenotypes are largely attributed to depletion of MSH1 from plastids, evidenced by hemi-complementation analysis (Xu et al, 2012), and the msh1-triggered plastid changes condition genomewide methylome repatterning (Virdi et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

An epigenetic breeding system in soybean for increased yield and stability

Raju

Shao

Sanchez

et al. 2018

Plant Biotechnology Journal

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SummaryEpigenetic variation has been associated with a wide range of adaptive phenotypes in plants, but there exist few direct means for exploiting this variation. RNAi suppression of the plant‐specific gene, MutS HOMOLOG1 (MSH1), in multiple plant species produces a range of developmental changes accompanied by modulation of defence, phytohormone and abiotic stress response pathways along with methylome repatterning. This msh1‐conditioned developmental reprogramming is retained independent of transgene segregation, giving rise to transgene‐null ‘memory’ effects. An isogenic memory line crossed to wild type produces progeny families displaying increased variation in adaptive traits that respond to selection. This study investigates amenability of the MSH1 system for inducing agronomically valuable epigenetic variation in soybean. We developed MSH1 epi‐populations by crossing with msh1‐acquired soybean memory lines. Derived soybean epi‐lines showed increase in variance for multiple yield‐related traits including pods per plant, seed weight and maturity time in both glasshouse and field trials. Selected epi‐F2:4 and epi‐F2:5 lines showed an increase in seed yield over wild type. By epi‐F2:6, we observed a return of MSH1‐derived enhanced growth back to wild‐type levels. Epi‐populations also showed evidence of reduced epitype‐by‐environment (e × E) interaction, indicating higher yield stability. Transcript profiling of epi‐lines identified putative signatures of enhanced growth behaviour across generations. Genes related to cell cycle, abscisic acid biosynthesis and auxin response, particularly SMALL AUXIN UP RNAs (SAURs), were differentially expressed in epi‐F2:4 lines that showed increased yield when compared to epi‐F2:6. These data support the potential of MSH1‐derived epigenetic variation in plant breeding for enhanced yield and yield stability.

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Section: Introductionmentioning

confidence: 99%

An epigenetic breeding system in soybean for increased yield and stability

Raju

Shao

Sanchez

et al. 2018

Plant Biotechnology Journal

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“…It should be noted that tissue-specific gene expression analyses distinguishing epidermal and mesophyll tissues were never reported and that the results in all studies to date, thus, represent a mixture of both cell types. This is critical with respect to the notion that recent studies suggest a specific sensor function for epidermal chloroplasts (Virdi et al, 2015, 2016). Targeted research on this special type of chloroplasts will be required in order to understand their detailed physiological function.…”

Section: Introductionmentioning

confidence: 99%

Regulatory Shifts in Plastid Transcription Play a Key Role in Morphological Conversions of Plastids during Plant Development

et al. 2017

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Plastids display a high morphological and functional diversity. Starting from an undifferentiated small proplastid, these plant cell organelles can develop into four major forms: etioplasts in the dark, chloroplasts in green tissues, chromoplasts in colored flowers and fruits and amyloplasts in roots. The various forms are interconvertible into each other depending on tissue context and respective environmental condition. Research of the last two decades uncovered that each plastid type contains its own specific proteome that can be highly different from that of the other types. Composition of these proteomes largely defines the enzymatic functionality of the respective plastid. The vast majority of plastid proteins is encoded in the nucleus and must be imported from the cytosol. However, a subset of proteins of the photosynthetic and gene expression machineries are encoded on the plastid genome and are transcribed by a complex transcriptional apparatus consisting of phage-type nuclear-encoded RNA polymerases and a bacterial-type plastid-encoded RNA polymerase. Both types recognize specific sets of promoters and transcribe partly over-lapping as well as specific sets of genes. Here we summarize the current knowledge about the sequential activity of these plastid RNA polymerases and their relative activities in different types of plastids. Based on published plastid gene expression profiles we hypothesize that each conversion from one plastid type into another is either accompanied or even preceded by significant changes in plastid transcription suggesting that these changes represent important determinants of plastid morphology and protein composition and, hence, the plastid type.

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“…Previous studies have shown that msh1 mutants are more tolerant to drought, high light, and heat stress (Shedge et al, 2010; Virdi et al, 2016; Xu et al, 2011). We tested for other abiotic stress effects, focusing first on salt and freezing temperature.…”

Section: Resultsmentioning

confidence: 99%

“…Arabidopsis msh1 mutants display a range of altered phenotypes that include variegation, dwarfing, delayed maturity transition, delayed flowering, and partial male sterility (Xu et al, 2011). The msh1 mutants display higher tolerance to heat, high light, and drought stress (Shedge et al, 2010; Virdi et al, 2016; Xu et al, 2011), particularly in individuals showing stronger developmental phenotypes. MSH1 phenotypes are conserved between monocots and eudicots.…”

Section: Introductionmentioning

confidence: 99%