Workable male sterility systems for hybrid rice: Genetics, biochemistry, molecular biology, and utilization

Huang, Jianzhong; Zhiguo, E; Zhang, Huali; Shu, Qingyao

doi:10.1186/s12284-014-0013-6

Cited by 101 publications

(81 citation statements)

References 85 publications

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“…PTGMS rice was first adopted for farming in 1995, and its planting area quickly increased and almost covered 20% of rice fields in China by 2012 (1,3). In fact, the highest yielding varieties currently cultivated in China are mostly PTGMS hybrids (1,3). Nonetheless, the PTGMS system also has intrinsic problems primarily in that its fertility is regulated by environmental conditions (5).…”

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confidence: 99%

“…Because PTGMS traits are controlled by nuclear recessive genes and male fertility can be restored by any normal rice cultivars (5-8), broader genetic resources can be explored for strong heterosis (1,5). PTGMS rice was first adopted for farming in 1995, and its planting area quickly increased and almost covered 20% of rice fields in China by 2012 (1,3). In fact, the highest yielding varieties currently cultivated in China are mostly PTGMS hybrids (1,3).…”

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confidence: 99%

“…Defects in any of these events can lead to male sterility. More than 40 nuclear genes required for male fertility have been identified in rice (3,9,10), but these genes have not been tapped for hybrid production because of the inability to propagate pure male sterile seeds on a production scale. Here we isolated a nuclear gene, Oryza sativa No Pollen 1 (OsNP1), essential for pollen development and male fertility in rice.…”

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confidence: 99%

“…CMS is correlated to aberrant, often chimeric, mitochondrial genes absent in maintainer lines, and the male sterility can be suppressed by Rf genes in restorer lines (2). CMS hybrid varieties have been deployed for commercial production since the 1970s and covered ∼40% of rice growing areas in China in 2012 (3). Despite the wide application, CMS systems suffer from several intrinsic problems, including the narrow germplasm resources of restorer lines, the poor genetic diversity between the CMS lines and restorer lines, the instability of male sterility under certain weather conditions, the negative impact of aberrant mitochondrial genes on hybrid performance, and the difficulty to breed new traits into the parental lines (1,3,4).…”

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confidence: 99%

“…CMS hybrid varieties have been deployed for commercial production since the 1970s and covered ∼40% of rice growing areas in China in 2012 (3). Despite the wide application, CMS systems suffer from several intrinsic problems, including the narrow germplasm resources of restorer lines, the poor genetic diversity between the CMS lines and restorer lines, the instability of male sterility under certain weather conditions, the negative impact of aberrant mitochondrial genes on hybrid performance, and the difficulty to breed new traits into the parental lines (1,3,4). These problems limit further improvement in CMS hybrid breeding, which is believed to be the reason that CMS varieties reached a yield plateau in the last 20 y (1, 3).…”

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confidence: 99%

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Construction of a male sterility system for hybrid rice breeding and seed production using a nuclear male sterility gene

Chang¹,

Chen²,

Wang³

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

201

203

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The breeding and large-scale adoption of hybrid seeds is an important achievement in agriculture. Rice hybrid seed production uses cytoplasmic male sterile lines or photoperiod/thermo-sensitive genic male sterile lines (PTGMS) as female parent. Cytoplasmic male sterile lines are propagated via cross-pollination by corresponding maintainer lines, whereas PTGMS lines are propagated via self-pollination under environmental conditions restoring male fertility. Despite huge successes, both systems have their intrinsic drawbacks. Here, we constructed a rice male sterility system using a nuclear gene named Oryza sativa No Pollen 1 (OsNP1). OsNP1 encodes a putative glucose–methanol–choline oxidoreductase regulating tapetum degeneration and pollen exine formation; it is specifically expressed in the tapetum and miscrospores. The osnp1 mutant plant displays normal vegetative growth but complete male sterility insensitive to environmental conditions. OsNP1 was coupled with an α-amylase gene to devitalize transgenic pollen and the red fluorescence protein (DsRed) gene to mark transgenic seed and transformed into the osnp1 mutant. Self-pollination of the transgenic plant carrying a single hemizygous transgene produced nontransgenic male sterile and transgenic fertile seeds in 1:1 ratio that can be sorted out based on the red fluorescence coded by DsRed. Cross-pollination of the fertile transgenic plants to the nontransgenic male sterile plants propagated the male sterile seeds of high purity. The male sterile line was crossed with ∼1,200 individual rice germplasms available. Approximately 85% of the F1s outperformed their parents in per plant yield, and 10% out-yielded the best local cultivars, indicating that the technology is promising in hybrid rice breeding and production.

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confidence: 99%