Wheat Ms2 encodes for an orphan protein that confers male sterility in grass species

Ni, Fei; Qin, Juan; Hao, Qunqun; Lyu, Bo; Luo, Ming‐Cheng; Wang, Yan; Chen, Fengjuan; Wang, Shuyun; Zhang, Chaozhong; Epstein, Lynn; Zhao, Xiangyu; Wang, Honggang; Zhang, Xiansheng; Chen, Cuixia; Sun, Lei; Fu, Daolin

doi:10.1038/ncomms15121

Cited by 106 publications

(67 citation statements)

References 50 publications

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“…Which is part of a suite of stable genic male sterility (GMS) loci ( MS1–MS5 ) identified thus far in wheat (Driscoll, ; Fossati & Ingold, ; Pugsley & Oram, ; Sasakuma, Maan, & Williams, ; Zhou, Wang, Feng, Ji, & Wang, ), the five mutants identified contained ms1 and ms5 which are recessive mutants (Klindworth, Williams, & Maan, ; Sasakuma et al, ), and Ms2 , Ms3 , and Ms4 which are dominant mutants (Maan, Carlson, Williams, & Yang, ; Maan & Kianian, ; Qi & Gill, ). Currently, only one dominant gene, Ms2 , and one recessive mutant have been cloned in wheat (Ni et al, ; Tucker, Baumann, & Kouidri, ; Wang et al, ; Xia et al, ), with Ms2 mutants being widely used for wheat breeding and potentially for hybrid wheat breeding (Ni et al, ). Other genes involved in male sterility in wheat include the genes Ms26 and Ms45 which are involved in the formation of the pollen cell wall similar to ms1 which is a transcription factor and regulates the post‐meiotic development of the anther (Dong et al, ; Singh, Kumar, Thilges, Cho, & Cigan, ; Tucker et al, ; Wang et al, ).…”

Section: Introductionmentioning

confidence: 99%

Identification of genes involved in male sterility in wheat (Triticum aestivum L.) which could be used in a genic hybrid breeding system

et al. 2020

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Wheat is grown on more land than any other crop in the world. Current estimates suggest that yields will have to increase sixty percent by 2050 to meet the demand of an ever‐increasing human population; however, recent wheat yield gains have lagged behind other major crops such as rice and maize. One of the reasons suggested for the lag in yield potential is the lack of a robust hybrid system to harness the potential yield gains associated with heterosis, also known as hybrid vigor. Here, we set out to identify candidate genes for a genic hybrid system in wheat and characterize their function in wheat using RNASeq on stamens and carpels undergoing meiosis. Twelve genes were identified as potentially playing a role in pollen viability. CalS5‐ and RPG1‐like genes were identified as pre‐ and post‐meiotic genes for further characterization and to determine their role in pollen viability. It appears that all three homoeologues of both CalS5 and RPG1 are functional in wheat as all three homoeologues need to be knocked out in order to cause male sterility. However, one functional homoeologue is sufficient to maintain male fertility in wheat.

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Section: Introductionmentioning

confidence: 99%

Identification of genes involved in male sterility in wheat (Triticum aestivum L.) which could be used in a genic hybrid breeding system

et al. 2020

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“…Relatively few plant orphan genes have been studied in depth. Recent studies revealed that orphan genes are important players in key agronomic traits, including Ms2 that confers male sterility in wheat (Ni et al ., ), QQS (Qua‐Quine Starch) that regulates carbon and nitrogen partitioning across species (Li et al ., ) and TaFROG ( Triticum aestivum Fusarium Resistance Orphan Gene) that enhances wheat resistance to disease (Perochon et al ., ).…”

Section: Introductionmentioning

confidence: 99%

A wheat NAC interacts with an orphan protein and enhances resistance to Fusarium head blight disease

Perochon

Kahla

Vranić

et al. 2019

Plant Biotechnology Journal

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Summary Taxonomically‐restricted orphan genes play an important role in environmental adaptation, as recently demonstrated by the fact that the Pooideae‐specific orphan TaFROG (Triticum aestivum Fusarium Resistance Orphan Gene) enhanced wheat resistance to the economically devastating Fusarium head blight (FHB) disease. Like most orphan genes, little is known about the cellular function of the encoded protein TaFROG, other than it interacts with the central stress regulator TaSnRK1α. Here, we functionally characterized a wheat (T. aestivum) NAC–like transcription factor TaNACL‐D1 that interacts with TaFROG and investigated its’ role in FHB using studies to assess motif analyses, yeast transactivation, protein‐protein interaction, gene expression and the disease response of wheat lines overexpressing TaNACL‐D1. TaNACL‐D1 is a Poaceae‐divergent NAC transcription factor that encodes a Triticeae‐specific protein C‐terminal region with transcriptional activity and a nuclear localisation signal. The TaNACL‐D1/TaFROG interaction was detected in yeast and confirmed in planta, within the nucleus. Analysis of multi‐protein interactions indicated that TaFROG could form simultaneously distinct protein complexes with TaNACL‐D1 and TaSnRK1α in planta. TaNACL‐D1 and TaFROG are co‐expressed as an early response to both the causal fungal agent of FHB, Fusarium graminearum and its virulence factor deoxynivalenol (DON). Wheat lines overexpressing TaNACL‐D1 were more resistant to FHB disease than wild type plants. Thus, we conclude that the orphan protein TaFROG interacts with TaNACL‐D1, a NAC transcription factor that forms part of the disease response evolved within the Triticeae.

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“…Plant male reproduction phase involves a series of developmental stages from stamen primordial meristem to pollen granule formation and pollination, where deletion or abnormality of any gene will lead to MS (Budar & Pelletier, ; Chen & Liu, ). Significant achievements have been obtained on exploring genes, the analysis of molecular mechanism and its application associated with MS in major field crops, such as rice (Chang et al, ; Fan et al, ), wheat (Ni et al, ; Xia et al, ), maize (Zhang, Wu, et al, ) and other crops. In recent years, although some achievements have been made in soybean to explore the fertility genes, their molecular mechanisms, however, detailed research and application of MS still were under progress compared with improvements in related other crops such as wheat and rice.…”

Section: Genetic Mechanism Of Male Sterility In Soybeanmentioning

confidence: 99%

“…NMS used for seed production and hybrid breeding was limited due to the inability to propagate a pure MS line for commercial hybrid seed production. With the advancement of molecular gene cloning, plant transformation and recombinant DNA approaches, researchers and breeders can efficiently develop genetically engineered MS plants (Chang et al, ; Ni et al, ; Xia et al, ; Zhang, Wu, et al, ), which could facilitate the widespread use of the NMS system in commercial crop hybrid production. In summary, plant MS provides not only a key breeding basis for heterosis utilization in crop plants, but also an important material for studying the development of floral organs or stamens (male gametophyte) along with the regulation mechanism of sterile genes (Chen & Liu, ).…”

Section: Introductionmentioning

confidence: 99%

Male sterility in soybean: Occurrence, molecular basis and utilization

Nadeem

Sun

et al. 2019

Plant Breeding

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In plants, male sterility (MS) is a specific breeding target trait. With the advancements in agriculture, utilization of heterosis breeding in hybrid production through MS lines has become the main breeding tool of various cross‐pollinated and even self‐pollinated crops. Soybean is an essential source of oil and protein; however, the low yield is a major factor limiting its development. Soybean MS mainly comprises cytoplasmic‐nuclear MS and nuclear/genic MS (NMS/GMS), which can effectively utilize heterosis to improve soybean yield. This review outlines the recent research progress on the development of new genetically MS lines, exploring the underlying molecular mechanism of MS, identification and cloning of MS and fertility restoration genes, and the application of MS lines. We further discussed and prospected the future developmental scenario direction of the soybean MS, based on the previous studies of other crops sterility system. Moreover, this review also provides comprehensive information for better application of MS to soybean breeding programme.

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Wheat Ms2 encodes for an orphan protein that confers male sterility in grass species

Cited by 106 publications

References 50 publications

Identification of genes involved in male sterility in wheat (Triticum aestivum L.) which could be used in a genic hybrid breeding system

Identification of genes involved in male sterility in wheat (Triticum aestivum L.) which could be used in a genic hybrid breeding system

A wheat NAC interacts with an orphan protein and enhances resistance to Fusarium head blight disease

Male sterility in soybean: Occurrence, molecular basis and utilization

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