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2 results

  • Characterization of novel low-molecular-weight glutenin subunit genes from the diploid wild wheat relative Aegilops umbellulata

  • Wenyang Wang, Wenjun Ji, Lihua Feng, Shunzong Ning, Zhongwei Yuan, Ming Hao, Lianquan Zhang, Zehong Yan, Bihua Wu, Dengcai Liu, Lin Huang
  • Journal:
    Plant Genetic Resources / Volume 20 / Issue 1 / February 2022
    Published online by Cambridge University Press:
    12 May 2022, pp. 1-6

  • Low molecular weight glutenin subunits (LWM-GSs) play a crucial role in determining wheat flour processing quality. In this work, 35 novel LMW-GS genes (32 active and three pseudogenes) from three Aegilops umbellulata (2n = 2x = 14, UU) accessions were amplified by allelic-specific PCR. We found that all LMW-GS genes had the same primary structure shared by other known LMW-GSs. Thirty-two active genes encode 31 typical LMW-m-type subunits. The MZ424050 possessed nine cysteine residues with an extra cysteine residue located in the last amino acid residue of the conserved C-terminal III, which could benefit the formation of larger glutenin polymers, and therefore may have positive effects on dough properties. We have found extensive variations which were mainly resulted from single-nucleotide polymorphisms (SNPs) and insertions and deletions (InDels) among the LMW-GS genes in Ae. umbellulata. Our results demonstrated that Ae. umbellulata is an important source of LMW-GS variants and the potential value of the novel LMW-GS alleles for wheat quality improvement.

  • Development and characterization of Triticum turgidumAegilops umbellulata amphidiploids

  • Zhongping Song, Shoufen Dai, Yanni Jia, Li Zhao, Liangzhu Kang, Dengcai Liu, Yuming Wei, Youliang Zheng, Zehong Yan
  • Journal:
    Plant Genetic Resources / Volume 17 / Issue 1 / February 2019
    Published online by Cambridge University Press:
    18 September 2018, pp. 24-32

  • The U genome of Aegilops umbellulata is an important basic genome of genus Aegilops. Direct gene transfer from Ae. umbellulata into wheat is feasible but not easy. Triticum turgidumAe. umbellulata amphidiploids can act as bridges to circumvent obstacles involving direct gene transfer. Seven T. turgidumAe. umbellulata amphidiploids were produced via unreduced gametes for spontaneous doubling of chromosomes of triploid T. turgidumAe. umbellulata F1 hybrid plants. Seven pairs of U chromosomes of Ae. umbellulata were distinguished by fluorescence in situ hybridization (FISH) probes pSc119.2/(AAC)5 and pTa71. Polymorphic FISH signals were detected in three (1U, 6U and 7U) of seven U chromosomes of four Ae. umbellulata accessions. The chromosomes of the tetraploid wheat parents could be differentiated by probes pSc119.2 and pTa535, and identical FISH signals were observed among the three accessions. All the parental chromosomes of the amphidiploids could be precisely identified by probe combinations pSc119.2/pTa535 and pTa71/(AAC)5. The T. turgidumAe. umbellulata amphidiploids possess valuable traits for wheat improvement, such as strong tillering ability, stripe rust resistance and seed size-related traits. These materials can be used as media in gene transfers from Ae. umbellulata into wheat.