Defying Mendel’s laws: sulfurea paramutation unveils new principles of 
epigenetic inheritance in tomato

Martinho, C

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Defying Mendel’s laws: sulfurea paramutation unveils new principles of epigenetic inheritance in tomato

Martinho, C. (2022). Defying Mendel’s laws: sulfurea paramutation unveils new principles of epigenetic inheritance in tomato. Talk presented at GDCB Seminar: Iowa State University. Ames, IA, USA. 2022-11-29.

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Item Permalink: https://hdl.handle.net/21.11116/0000-000F-219A-E Version Permalink: https://hdl.handle.net/21.11116/0000-000F-219B-D

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https://www.gdcb.iastate.edu/event/2022/gdcb-seminar-defying-mendels-laws-sulfurea-paramutation-unveils-new-principles (Abstract) Open Access status unknown

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Martinho, C¹, Author

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1Department Algal Development and Evolution, Max Planck Institute for Biology Tübingen, Max Planck Society, ou_3371686

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Abstract: Paramutation represents a clear exception to the principles of inheritance established by Gregor Mendel in the 19th century. It involves the transfer of repressive epigenetic marks from a silent to an active allele and thereby violates Mendel’s first law of independent allele segregation. It is best known from conspicuous pigmentation phenotypes in maize but the paramutation phenomena was also reported across diverse plant and animal species. Paramutation-like events are common in tomato hybrids suggesting that paramutation may be less exceptional and rather a frequently co-occurring process during cross-hybridization.
In this talk I will show how a classic example of paramutation sulfurea (sulf) – an understudied locus associated with a chlorosis phenotype and aberrant segregation patterns. Sulf was employed to dissect the epigenetic- and transgenerational mechanisms underlying paramutation in tomato plants. Our results show that the DNA- and histone-methyl transferases CMT3 and KYP are required for the maintenance of paramutation and that there is a change in chromatin architecture associated with the silent epiallele. We further demonstrate that in tomato the developmental and transgenerational maintenance of paramutation is independent of sRNAs, a mechanism previously suggested to explain the trans-communication between homologues across mitotic and meiotic divisions in maize. I will therefore present a revised model to explain the maintenance of paramutation in plants by integrating existing concepts into a revised framework of non-Mendelian heredity.

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Dates: Published Online: 2022-11

Publication Status: Published online

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Title: GDCB Seminar: Iowa State University

Place of Event: Ames, IA, USA

Start-/End Date: 2022-11-29

Invited: Yes

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