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Unraveling the Contribution of MulSOS2 in Conferring Salinity Tolerance in Mulberry ( Morus atropurpurea Roxb).

Hai-Rui WangSheng-Mei HanDong-Hao WangZhen-Rui ZhaoHui LingYun-Na YuZhao-Yang LiuYing-Ping GaiXian-Ling Ji
Published in: International journal of molecular sciences (2024)
Salinity is one of the most serious threats to sustainable agriculture. The Salt Overly Sensitive (SOS) signaling pathway plays an important role in salinity tolerance in plants, and the SOS2 gene plays a critical role in this pathway. Mulberry not only has important economic value but also is an important ecological tree species; however, the roles of the SOS2 gene associated with salt stress have not been reported in mulberry. To gain insight into the response of mulberry to salt stress, SOS2 (designated MulSOS2 ) was cloned from mulberry ( Morus atropurpurea Roxb), and sequence analysis of the amino acids of MulSOS2 showed that it shares some conserved domains with its homologs from other plant species. Our data showed that the MulSOS2 gene was expressed at different levels in different tissues of mulberry, and its expression was induced substantially not only by NaCl but also by ABA. In addition, MulSOS2 was exogenously expressed in Arabidopsis, and the results showed that under salt stress, transgenic MulSOS2 plants accumulated more proline and less malondialdehyde than the wild-type plants and exhibited increased tolerance to salt stress. Moreover, the MulSOS2 gene was transiently overexpressed in mulberry leaves and stably overexpressed in the hairy roots, and similar results were obtained for resistance to salt stress in transgenic mulberry plants. Taken together, the results of this study are helpful to further explore the function of the MulSOS2 gene, which provides a valuable gene for the genetic breeding of salt tolerance in mulberry.
Keyphrases
  • genome wide
  • copy number
  • genome wide identification
  • signaling pathway
  • transcription factor
  • microbial community
  • climate change
  • stress induced
  • wild type
  • heat stress
  • cell proliferation
  • diabetic rats
  • endothelial cells