Abstract
Large-scale application of the doubled haploid (DH) technology by in vivo haploid induction has greatly improved the efficiency of maize breeding. While the haploid induction rate and the efficiency of identifying haploid plants have greatly improved in recent years, the low efficiency of doubling of haploid plants has remained and currently presents the main limitation to maize DH line production. In this study, we aimed to assess the available genetic variation for haploid male fertility (HMF), i.e., the production of fertile pollen on haploid plants, and to investigate the underlying genetic architecture. To this end, a diversity panel of 481 maize inbred lines was crossed with “Mo17” and “Zheng58,” the F1 hybrids subjected to haploid induction, and resulting haploid plants assessed for male fertility in two environments. Across both genetic backgrounds, we observed a large variation of HMF ranging from zero to ~60%, with a mean of 18%, and a heritability of 0.65. HMF was higher in the “Mo17” than in the “Zheng58” background and the correlation between both genetic backgrounds was 0.68. Genome-wide association mapping identified only few putative QTL that jointly explained 22.5% of the phenotypic variance. With the exception of one association explaining 11.77% of the phenotypic variance, all other putative QTL were of minor importance. A genome-wide prediction approach further corroborated the quantitative nature of HMF in maize. Analysis of the 14 significantly associated SNPs revealed several candidate genes. Collectively, our results illustrate the large variation of HMF that can be exploited for maize DH breeding. Owing to the apparent genetic complexity of this trait, this might best be achieved by rapid recurrent phenotypic selection coupled with marker-assisted selection for individual QTL.
Highlights
Maize (Zea mays L.) is one of the most important food, feed and industrial crops worldwide
We chose this experimental design, as the doubled haploid (DH) production in applied maize breeding programs is based on heterozygous plants and this setup is most realistic for practical maize breeding
We identified three polymorphisms in Absence of first division1 (Afd1) that resulted in a premature stop codon or an amino acid exchange, none of them was significantly associated with haploid male fertility (HMF) in this panel
Summary
Maize (Zea mays L.) is one of the most important food, feed and industrial crops worldwide. With the growing demand for production, maize breeders continue to explore and improve modern breeding techniques. One of these is the doubled haploid (DH) technology, the large-scale application of which has greatly improved the efficiency of maize breeding in recent years, as it enables the rapid generation of completely homozygous lines. Eder and Chalyk (2002) reported that with the colchicine-induced genome doubling 49% of the treated haploid plants produced fertile pollen and 27% produced viable seeds. This approach, is time consuming, costly and colchicine itself is a hazardous chemical. Exploiting spontaneous genome doubling for doubled haploid generation may allow to forgo the use of artificial treatments and at the same time increase the efficiency of DH production (Kleiber et al, 2012)
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