Abstract
During the evolutionary transition from land to water, cetaceans have undergone numerous critical challenges, with osmoregulation being the major one. Two subspecies of the narrow-ridged finless porpoise (Neophocaena asiaeorientalis), the freshwater Yangtze finless porpoise (N. a. asiaeorientalis, NAA) and the marine East Asian finless porpoise (N. a. sunameri, NAS), provide excellent subjects to understand the genetic basis of osmoregulatory divergence between freshwater and marine mammals. The kidney plays an important and well-established role in osmoregulation in marine mammals and thus, herein, we utilized RNA-seq to characterize the renal transcriptome and preliminarily analyze the divergence between the NAA and the NAS. Approximately 48.98 million clean reads from NAS and 49.40 million clean reads from NAA were obtained by RNA-Seq. And 73,449 (NAS) and 68,073 (NAA) unigenes were assembled. Among these annotations, 22,231 (NAS) and 21,849 (NAA) unigenes were annotated against the NCBI nr protein database. The ion channel complex GO term and four pathways were detected as relevant to osmoregulation by GO and KEGG pathway classification of these annotated unigenes. Although the endangered status of the study species prevented analysis of biological replicates, we identified nine differentially expressed genes (DEGs) that may be vital in the osmoregulation of the narrow-ridged finless porpoise and worthwhile for future studies. Of these DEGs, the differential expression and distribution of the aquaporin-2 (AQP2) in the collecting duct were verified using immunohistochemical experiments. Together, this work is the first report of renal transcriptome sequencing in cetaceans, and it will provide a valuable resource for future molecular genetics studies on cetacean osmoregulation.
Highlights
Osmotic stress was one of the most critical challenges for cetaceans, which underwent an evolutionary transition from land to water approximately 50 million years ago [1,2]
The assembled unigenes have been deposited in the NCBI Transcriptome Shotgun Assembly (TSA) database under the accession number of GBYL00000000 for NAA and GBYP00000000 for NAS
We found that the Gene Ontology (GO) term integral to membrane showed the most significant enrichment and presented the greatest number of differentially expressed genes (DEGs) among the enriched GO terms (Figure 3), with 163 DEGs being significantly enriched in this term
Summary
Osmotic stress was one of the most critical challenges for cetaceans, which underwent an evolutionary transition from land to water approximately 50 million years ago [1,2]. Studies on the osmoregulatory mechanisms in cetaceans have been focused on the renal structure [5], the concentrations of ions in serum and urine [6], and the experiments of drinking, fasting and feeding [3]. These studies provided significant contributions to understand the water and electrolyte metabolism and the renal function in cetaceans, but the genetic basis of osmoregulation in cetaceans for adapting to the distinct marine or freshwater environments remains poorly explored [7]
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