Abstract
To identify cytoplasmic male sterility (CMS)-associated genes in tomato, we determined the genome sequences of mitochondria and chloroplasts in three CMS tomato lines derived from independent asymmetric cell fusions, their nuclear and cytoplasmic donors, and male fertile weedy cultivated tomato and wild relatives. The structures of the CMS mitochondrial genomes were highly divergent from those of the nuclear and cytoplasmic donors, and genes of the donors were mixed up in these genomes. On the other hand, the structures of CMS chloroplast genomes were moderately conserved across the donors, but CMS chloroplast genes were unexpectedly likely derived from the nuclear donors. Comparative analysis of the structures and contents of organelle genes and transcriptome analysis identified three genes that were uniquely present in the CMS lines, but not in the donor or fertile lines. RNA-sequencing analysis indicated that these three genes transcriptionally expressed in anther, and identified different RNA editing levels in one gene, orf265, that was partially similar to ATP synthase subunit 8, between fertile and sterile lines. The orf265 was a highly potential candidate for CMS-associated gene. This study suggests that organelle reorganization mechanisms after cell fusion events differ between mitochondria and chloroplasts, and provides insight into the development of new F1 hybrid breeding programs employing the CMS system in tomato.
Highlights
Introductioncytoplasmic male sterility (CMS) plants cannot produce seeds by self-pollination due to a lack of male fertility; pollen from other plants is always required for these plants to produce seeds
Cytoplasmic male sterility (CMS) is broadly found in the kingdom of Plantae[1]
A total of 10.5 Gb reads per sample were obtained from three cytoplasmic male sterility (CMS) tomato lines (‘CMS[MSA1]’, ‘CMS[O]’, and ‘CMS[P]’), three nuclear donors (‘Sekai-ichi’, ‘O’, and ‘P’), and one cytoplasmic donor (S. acaule)
Summary
CMS plants cannot produce seeds by self-pollination due to a lack of male fertility; pollen from other plants is always required for these plants to produce seeds. CMS is caused by the incompatibility of interactions of genetic information between nuclei and organelles, especially mitochondria[1]. The genes in nuclei and organelles are called restore of fertility (RF) genes and CMS-associated genes, respectively. CMS plants have been used as materials for studies of interactions between nuclear and cytoplasmic genes. CMS is used in breeding programs to produce F1 hybrid seeds[1], in which cytoplasmic and pollen donors are employed as maternal and paternal parents, respectively. CMS plants can be artificially generated by recurrent backcrossing or transgenic approaches[2,3], which leads to incompatibility between nuclei and organelles.
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