Abstract
MicroRNAs (miRNAs), a class of small non-coding RNAs, recognize their mRNA targets based on perfect sequence complementarity. MiRNAs lead to broader changes in gene expression after plants are exposed to stress. High-throughput sequencing is an effective method to identify and profile small RNA populations in non-model plants under salt stresses, significantly improving our knowledge regarding miRNA functions in salt tolerance. Cucurbits are sensitive to soil salinity, and the Cucurbita genus is used as the rootstock of other cucurbits to enhance salt tolerance. Several cucurbit crops have been used for miRNA sequencing but salt stress-related miRNAs in cucurbit species have not been reported. In this study, we subjected two Cucurbita germplasm, namely, N12 (Cucurbita. maxima Duch.) and N15 (Cucurbita. moschata Duch.), with different sodium accumulation patterns, to Illumina sequencing to determine small RNA populations in root tissues after 4 h of salt treatment and control. A total of 21,548,326 and 19,394,108 reads were generated from the control and salt-treated N12 root tissues, respectively. By contrast, 19,108,240 and 20,546,052 reads were obtained from the control and salt-treated N15 root tissues, respectively. Fifty-eight conserved miRNA families and 33 novel miRNAs were identified in the two Cucurbita germplasm. Seven miRNAs (six conserved miRNAs and one novel miRNAs) were up-regulated in salt-treated N12 and N15 samples. Most target genes of differentially expressed novel miRNAs were transcription factors and salt stress-responsive proteins, including dehydration-induced protein, cation/H+ antiporter 18, and CBL-interacting serine/threonine-protein kinase. The differential expression of miRNAs between the two Cucurbita germplasm under salt stress conditions and their target genes demonstrated that novel miRNAs play an important role in the response of the two Cucurbita germplasm to salt stress. The present study initially explored small RNAs in the response of pumpkin to salt stress, and provided valuable information on novel miRNAs and their target genes in Cucurbita.
Highlights
MicroRNAs, a class of small non-coding RNAs widely distributed throughout the plant kingdom and highly evolutionarily conserved, recognize their mRNA targets based on perfect sequence complementarity
Almost 80% of Na+ was accumulated in N12 shoots, whereas about 50% Na+ accumulated in N15 roots. These results demonstrated that N12 and N15 exhibited different Na+ accumulation patterns under salt stress conditions; N12 accumulated Na+ in the shoots, whereas N15 accumulated Na+ in the roots
Conserved miRNAs (Tables 4 and 5). These results indicate that novel miRNAs might have an important role in the salt stress responses of the two Cucurbita germplasm
Summary
MicroRNAs (miRNAs), a class of small non-coding RNAs widely distributed throughout the plant kingdom and highly evolutionarily conserved, recognize their mRNA targets based on perfect sequence complementarity. MiRNAs cause either transcriptional or post-transcriptional gene silencing [1, 2]. A total of 13,618 plant miRNAs from 72 species have been deposited in miRBase (miRBase Release20.0, http://www.mirbase.org/ ). MiRNA-mediated gene silencing is a conserved regulatory mechanism underlying plant responses to biotic and abiotic stresses. Most target genes of miRNAs are transcription factors and receptor proteins; miRNAs function as early signaling components that can lead to extensive changes in gene expression after plants are exposed to stress [1, 3,4,5]
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