Abstract
The exploitation of male sterility systems has enabled the commercialization of heterosis in rice, with greatly increased yield and total production of this major staple food crop. Hybrid rice, which was adopted in the 1970s, now covers nearly 13.6 million hectares each year in China alone. Various types of cytoplasmic male sterility (CMS) and environment-conditioned genic male sterility (EGMS) systems have been applied in hybrid rice production. In this paper, recent advances in genetics, biochemistry, and molecular biology are reviewed with an emphasis on major male sterility systems in rice: five CMS systems, i.e., BT-, HL-, WA-, LD- and CW- CMS, and two EGMS systems, i.e., photoperiod- and temperature-sensitive genic male sterility (P/TGMS). The interaction of chimeric mitochondrial genes with nuclear genes causes CMS, which may be restored by restorer of fertility (Rf) genes. The PGMS, on the other hand, is conditioned by a non-coding RNA gene. A survey of the various CMS and EGMS lines used in hybrid rice production over the past three decades shows that the two-line system utilizing EGMS lines is playing a steadily larger role and TGMS lines predominate the current two-line system for hybrid rice production. The findings and experience gained during development and application of, and research on male sterility in rice not only advanced our understanding but also shed light on applications to other crops.Electronic supplementary materialThe online version of this article (doi:10.1186/s12284-014-0013-6) contains supplementary material, which is available to authorized users.
Highlights
The exploitation of male sterility systems has enabled the commercialization of heterosis in rice, with greatly increased yield and total production of this major staple food crop
This paper aims to analyze different male sterility (MS) systems that have been explored in hybrid rice production and summarize the latest understanding of their genetics, biochemistry, and biology
We describe the dynamics of different MS systems in hybrid rice production in China over the past 30 years
Summary
Selected from F2 male sterile plants in the progeny of Wanhui 88 (indica) x Neihui 92–4 (indica) nucleus. Genes underpinning EGMS in rice During the past 20 years, a number of EGMS lines have been identified that show genic MS under different conditions: long day (PGMS) or short day (reverse PGMS, rPGMS), high temperature (TGMS) or low temperature (rTGMS), and either long day or high temperature In all these cases, the pollen fertility of EGMS systems is sporophytically controlled by nuclear gene (s), and the loci that control PGMS or TGMS, including rPGMS or rTGMS, have been mapped to different chromosomes (Si et al 2012; Sheng et al 2013; Zhang et al 2013). These observations suggest different mechanisms of male fertility restoration be deployed by the two Rf genes: RF4 may cleave the WA352 transcript and RF3 may suppress its translation In this regard, RF4 may function like that of RF1B, which mediates the degradation of atp6-orf mRNA, whereas RF3’s mode of action would be distinctly different from those of RF1A and RF1B (see above). Xu et al (2013) demonstrated that DNA methylation was markedly affected by male-sterile cytoplasms
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