Genome-wide Analysis of the SCAMPs Gene Family of Soybean and Functional Identification of GmSCAMP5 in Salt Tolerance

Overview

Journal BMC Plant Biol

Publisher Biomed Central

Specialty Biology

Date 2023 Dec 7

PMID 38062393

Authors

Min Wang

Chuanrong He

Guangcheng Shi

Qiukai Yin

Hanyue Zhang

Wanmin Yang

Aiqin Yue

Lixiang Wang

Weijun Du

Affiliations

Soon will be listed here.

Abstract

The effect of salt damage on plants is mainly caused by the toxic effect of Na. Studies showed that the secretory carrier membrane proteins were associated with the Na transport. However, the salt tolerance mechanism of secretory carrier protein (SCAMP) in soybean was yet to be defined. In this study, ten potential SCAMP genes distributed in seven soybean chromosomes were identified in the soybean genome. The phylogenetic tree of SCAMP domain sequences of several plants can divide SCAMPs into two groups. Most GmSCAMPs genes contained multiple Box4, MYB and MYC cis-elements indicated they may respond to abiotic stresses. We found that GmSCAMP1, GmSCAMP2 and GmSCAMP4 expressed in several tissues and GmSCAMP5 was significantly induced by salt stress. GmSCAMP5 showed the same expression patterns under NaCl treatment in salt-tolerant and salt-sensitive soybean varieties, but the induced time of GmSCAMP5 in salt-tolerant variety was earlier than that of salt-sensitive variety. To further study the effect of GmSCAMP5 on the salt tolerance of soybean plants, compared to GmSCAMP5-RNAi and EV-Control plants, GmSCAMP5-OE had less wilted leave and higher SPAD value. Compared to empty vector control, less trypan blue staining was observed in GmSCAMP5-OE leaves while more staining in GmSCAMP5-RNAi leaves. The Na of GmSCAMP5-RNAi plants leaves under NaCl stress were significantly higher than that in EV-Control plants, while significantly lower Na in GmSCAMP5-OE plants than in that EV-Control plants. The contents of leaves K of GmSCAMP5-RNAi, EV-Control, and GmSCAMP5-OE plants under NaCl stress were opposite to that of leaves Na content. Finally, salt stress-related genes NHX1, CLC1, TIP1, SOD1, and SOS1 in transformed hairy root changed significantly compared with the empty control. The research will provide novel information for study the molecular regulation mechanism of soybean salt tolerance.

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