Copy number variation of the restorer Rf4 underlies human selection of three-line hybrid rice breeding

Identification of a gene coding for a pentatricopeptide repeat protein as a candidate responsible for the Ms2, a novel restorer-of-fertility locus in onion (Allium cepa L.)

Ms and Ms2 are restorer-of-fertility loci in onion (Allium cepa L.); additionally, Ms2 is responsible for unstable male fertility in some accessions. Although a candidate gene was previously reported for the Ms locus, the gene responsible for the Ms2 locus remains unidentified. A 12.5 Mb genomic region harboring the Ms2 locus was initially obtained from onion whole genome sequences using two flanking markers to identify candidates. This region was further delimited to 3.19 Mb via fine mapping using 12 recombinants and 11 additional markers. A gene coding for a pentatricopeptide repeat (PPR) protein was identified within the 3.19 Mb region and designated AcPPR876. Phylogenetic analysis showed that AcPPR876 and four homologs belonged to the Rf-like PPR gene family. Polymorphic sequences between male fertile (MF) and male sterile (MS) AcPPR876 alleles were concentrated in the 5' region of the gene. Among them, a 446 bp insertion was identified at the putative promoter region of the MF allele. Although overall AcPPR876 transcription levels were very low, transcription levels of the MF allele were generally higher than those of the MS allele. A simple PCR marker was developed using the 446 bp insertion to perform Ms2 locus genotyping in the diverse onion germplasm. Although the dominant Ms2 allele was not found in any of the 250 domestic breeding lines, 29 out of 108 exotic accessions were shown to contain the dominant Ms2 alleles. Overall, the AcPPR876 gene is proposed as a strong candidate for the Ms2 locus.

Supplementary Information

The online version contains supplementary material available at 10.1007/s11032-025-01561-5.

Past and future of cytoplasmic male sterility and heterosis breeding in crop plants

Plant breeding needs to embrace genetic innovations to ensure stability in crop yields under fluctuating climatic conditions. Development of commercial hybrid varieties has proven to be a sustainable and economical alternative to deliver superior yield, quality and resistance with uniformity in a number of food crops. Cytoplasmic male sterility (CMS), a maternally inherited inability to produce functional pollen, facilitates a three-line system for efficient hybrid seed production strategies in crops. The CMS system has illustrated its potential as a robust pollination control mechanism to support the billion-dollar seed industry. In plants, CMS arises due to a genomic conflict between mitochondrial open reading frames (orfs) and nuclear-encoding restoration-of-fertility (Rf) genes, leading to floral abnormalities and pollen sterility. Research on pollen sterility and fertility restoration provides deeper insights into cytoplasmic-nuclear interplay in plants and elucidates key molecular targets for hybrid breeding in crops. More recently, programmable gene editing (e.g., TALEN, CRISPR-Cas) has emerged as a promising tool to functionally validate CMS and Rf genes and obviate the need for pollen donors or Rf-genes for hybrid breeding. Modern genomic prediction models have allowed establishment of high-performing heterotic groups and patterns for sustaining long-term gain in hybrid breeding. This article reviews latest discoveries elucidating the molecular mechanisms behind CMS and fertility restoration in plants. We then present our perspective on how evolving genetic technologies are contributing to advance fundamental knowledge of the CMS-Rf genetic system for producing crop hybrids with high heterosis.

Insights into heterosis from histone modifications in the flag leaf of inter-subspecific hybrid rice

BACKGROUND

Inter-subspecific hybrid rice represents a significant breakthrough in agricultural genetics, offering higher yields and better resilience to various environmental stresses. While the utilization of these hybrids has shed light on the genetic processes underlying hybridization, understanding the molecular mechanisms driving heterosis remains a complex and ongoing challenge. Here, chromatin immunoprecipitation-sequencing (ChIP-seq) was used to analyze genome-wide profiles of H3K4me3 and H3K27me3 modifications in the inter-subspecific hybrid rice ZY19 and its parents, Z04A and ZHF1015, then combined them with the transcriptome and DNA methylation data to uncover the effects of histone modifications on gene expression and the contribution of epigenetic modifications to heterosis.

RESULTS

In the hybrid, there were 8,126 and 1,610 different peaks for H3K4me3 and H3K27me3 modifications when compared to its parents, respectively, with the majority of them originating from the parental lines. The different modifications between the hybrid and its parents were more frequently observed as higher levels in the hybrid than in the parents. In ZY19, there were 476 and 84 allele-specific genes with H3K4me3 and H3K27me3 modifications identified, representing 7.9% and 12% of the total analyzed genes, respectively. Only a small portion of genes that showed differences in parental H3K4me3 and H3K27me3 modifications which demonstrated allele-specific histone modifications (ASHM) in the hybrid. The H3K4me3 modification level in the hybrid was significantly lower compared to the parents. In the hybrid, DNA methylation occurs more frequently among histone modification target genes. Additionally, over 62.58% of differentially expressed genes (DEGs) were affected by epigenetic variations. Notably, there was a strong correlation observed between variations in H3K4me3 modifications and gene expression levels in the hybrid and its parents.

CONCLUSION

These findings highlight the substantial impact of histone modifications and DNA methylation on gene expression during hybridization. Epigenetic variations play a crucial role in controlling the differential expression of genes, with potential implications for heterosis.

A historical review of hybrid rice breeding

The development of germplasm resources and advances in breeding methods have led to steady increases in yield and quality of rice (Oryza sativa L.). Three milestones in the recent history of rice breeding have contributed to these increases: dwarf rice breeding, hybrid rice breeding, and super rice breeding. On the 50th anniversary of the success of three-line hybrid rice, we highlight important scientific discoveries in rice breeding that were made by Chinese scientists and summarize the broader history of the field. We discuss the strategies that could be used in the future to optimize rice breeding further in the hope that China will continue to play a leading role in international rice breeding.

Unveiling a half-century mystery of molecular bases for three-line hybrid rice breeding system

Hybrid rice derived from Wild Abortive (WA) cytoplasmic male sterility type three-line systems is widely used in production. The fertility restoration gene Rf4 can reduce WA352c transcript levels in a dose-dependent manner. A two-copy haplotype of Rf4 (H1) is identified as the most valuable haplotype for future hybrid rice breeding.