Comprehensive genome-wide analysis of polyamine and ethylene pathway genes in Cleistogenes songorica and CsSAMDC2 function in response to abiotic stress

Polyamine and ethylene pathway genes (PEGs) are widely involved in regulating plant abiotic stresses. However, the PEGs in Cleistogenes songorica have not yet been thoroughly studied. In the present study, 17 polyamine-, 12 ethylene- and 6 S-adenosylmethionine (SAM)- related genes were identified at the genome-wide level in C. songorica. Phylogenetic analysis showed that genes in the ethylene and polyamine pathways and SAM family genes were not clearly separated. Promoter regions of these genes were rich in stress-related cis-regulatory elements. Several PEG and SAM genes coexpressed together and were responsive to abiotic stress treatment. In particular, qRT-PCR analysis showed that the expression of CsSAMDC2 increased under salt, dehydration and ABA treatment conditions. Arabidopsis plants transformed with CsSAMDC2 driven by a stress-inducible RD29A or constitutive promoter 35S exhibited enhanced dehydration tolerance and maintained higher chlorophyll content and photosynthetic capacity. The expression of CsSAMDC2 was generally higher in lines harboring RD29A:: CsSAMDC2 compared to 35 S::CsSAMDC2 lines under drought stress treatment. Seed germination of RD29A:: CsSAMDC2 or 35 S::CsSAMDC2 transgenic plants under salt stress treatment was superior to their wild-type counterparts, and the leaves of the transgenic plants exhibited a more compact structure. In addition, under salt stress, application of ABA improved lateral root development of RD29A::CsSAMDC2 Arabidopsis plants. The qRT-PCR analysis indicated that the expression of well-known abiotic stress-responsive genes AtPEGs, AtERF1 and AtRD29A, increased in both RD29A::CsSAMDC2 and 35 S::CsSAMDC2 transgenic Arabidopsis after drought, salt stress and salt stress plus ABA treatments. Our results suggest that CsSAMDC2 enhances drought and salt tolerance in Arabidopsis and therefore may contribute to abiotic stress tolerance in forage and food crops.