Accession-specific Parent-of-origin Dependent and Independent Genome Dosage Effects on Salt Tolerance in

Overview

Journal R Soc Open Sci

Specialty Science

Date 2024 May 9

PMID 38721127

Authors

Brendan F Hallahan

Luis Felipe Quiroz

Galina Brychkova

Peter C McKeown

Charles Spillane

Affiliations

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Abstract

Improving the salt stress tolerance of crops is an important goal in plant breeding. Changes in the number of chromosome sets (i.e. ploidy level) cause genome dosage effects which can result in enhanced or novel traits. Maternal inheritance versus paternal inheritance of the same chromosome sets can have differential epigenetic effects on traits of F1 offspring. Hence, genome dosage effects can be parent-of-origin independent or dependent. The model plant displays both genome dosage and parent-of-origin effects on plant growth under non-stress conditions. Using an isogenic ploidy series of diploid, triploid and tetraploid lines, we investigate the extent of genome dosage effects and their parent-of-origin dependency on salt stress tolerance of seedlings across 10 different accessions (genetic backgrounds). We detected genome dosage effects on salt stress tolerance for tetraploid lines in five accessions. In addition, through the generation of isogenic reciprocal F1 triploid lines, both parent-of-origin dependent and independent genome dosage effects on salt stress tolerance were detected. Thus, our results indicate not only that genome dosage balance effects can have significant impacts on abiotic stress tolerance in but also that parent-of-origin specific genome dosage effects can affect salt stress tolerance in plants.

Citing Articles

Accession-specific parent-of-origin dependent and independent genome dosage effects on salt tolerance in .

Hallahan B, Quiroz L, Brychkova G, McKeown P, Spillane C R Soc Open Sci. 2024; 11(5):231766.

PMID: 38721127 PMC: 11076124. DOI: 10.1098/rsos.231766.

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