A Combined Transcriptome - MiRNAome Approach Revealed That a Gene is Differentially Targeted by a Novel MiRNA in an Apomictic Genotype of

Overview

Journal Front Plant Sci

Date 2022 Oct 17

PMID 36247597

Authors

Maria Cielo Pasten

Jose Carballo

Jimena Gallardo

Diego Zappacosta

Juan Pablo Selva

Juan Manuel Rodrigo

Viviana Echenique

Ingrid Garbus

Affiliations

Soon will be listed here.

Abstract

Weeping lovegrass ( [Shrad.] Nees) is a perennial grass typically established in semi-arid regions, with good adaptability to dry conditions and sandy soils. This polymorphic complex includes both sexual and apomictic cytotypes, with different ploidy levels (2x-8x). Diploids are known to be sexual, while most polyploids are facultative apomicts, and full apomicts have also been reported. Plant breeding studies throughout the years have focused on achieving the introgression of apomixis into species of agricultural relevance, but, given the complexity of the trait, a deeper understanding of the molecular basis of regulatory mechanisms of apomixis is still required. Apomixis is thought to be associated with silencing or disruption of the sexual pathway, and studies have shown it is influenced by epigenetic mechanisms. In a previous study, we explored the role of miRNA-mRNA interactions using two contrasting phenotypes. Here, the sexual OTA-S, the facultative Don Walter and the obligate apomictic Tanganyika cDNA and sRNA libraries were inquired, searching for miRNA discovery and miRNA expression regulation of genes related to the reproductive mode. This allowed for the characterization of seven miRNAs and the validation of their miRNA-target interactions. Interestingly, a gene was found to be repressed in the apomictic cultivar Tanganyika, targeted by a novel miRNA that was found to be overexpressed in this genotype, suggestive of an involvement in the reproductive mode expression. Our work provided additional evidence of the contribution of the epigenetic regulation of the apomictic pathway.

Citing Articles

Differentially methylated genes involved in reproduction and ploidy levels in recent diploidized and tetraploidized Eragrostis curvula genotypes.

Carballo J, Achilli A, Hernandez F, Bocchini M, Pasten M, Marconi G Plant Reprod. 2023; 37(2):133-145.

PMID: 38055074 PMC: 11180019. DOI: 10.1007/s00497-023-00490-7.

From tetraploid to diploid, a pangenomic approach to identify genes lost during synthetic diploidization of .

Carballo J, Bellido A, Selva J, Zappacosta D, Gallo C, Albertini E Front Plant Sci. 2023; 14:1133986.

PMID: 36993842 PMC: 10040859. DOI: 10.3389/fpls.2023.1133986.

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