Genome-wide analysis of the Chinese sturgeon sox gene family: identification, characterisation and expression profiles of different tissues

Role of Sox3 in Estradiol-Induced Sex Reversal in Pelodiscus sinensis

The Chinese soft-shelled turtle Pelodiscus sinensis, an economically important species in China, exhibits significant sexual dimorphism. Males are more valuable than females owing to their wider calipash and faster growth. Estradiol (E2)-induced sex reversal is used to achieve all-male breeding of turtles; however, the mechanism of this sex reversal remains unclear. In this study, we characterized the Sox3 gene, whose expression level was high in the gonads and brain and exhibited significant sexual dimorphism in the ovary. During embryonic development, Sox3 was highly expressed at the initiation of ovarian differentiation. E2 and Sox3-RNAi treatment before sexual differentiation led to 1352, 908, 990, 1011, and 975 differentially expressed genes in five developmental stages, respectively, compared with only E2 treatment. The differentially expressed genes were clustered into 20 classes. The continuously downregulated and upregulated genes during gonadal differentiation were categorized into Class 0 (n = 271) and Class 19 (n = 606), respectively. KEGG enrichment analysis showed that Sox3 significantly affected sexual differentiation via the Wnt, TGF-β, and TNF signaling pathways and mRNA surveillance pathway. The expression of genes involved in these signaling pathways, such as Dkk4, Nog, Msi1, and Krt14, changed significantly during gonadal differentiation. In conclusion, the deletion of Sox3 may lead to significant upregulation of the mRNA surveillance pathway and TNF and Ras signaling pathways and downregulation of the Wnt and TGF-β signaling pathways, inhibiting E2-induced sex reversal. These findings suggest that Sox3 may play a certain promoting effect during E2-induced sex reversal in P. sinensis.

Genome-Wide Identification, Evolutionary and Mutational Analysis of the Buffalo Sox Gene Family

The Sox gene family constitutes transcription factors with a conserved high mobility group box (HMG) that regulate a variety of developmental processes, including sex differentiation, neural, cartilage, and early embryonic development. In this study, we systematically analyzed and characterized the 20 Sox genes from the whole buffalo genome, using comparative genomic and evolutionary analyses. All the buffalo Sox genes were divided into nine sub-groups, and each gene had a specific number of exons and introns, which contributed to different gene structures. Molecular phylogeny revealed more sequence similarity of buffalo Sox genes with those of cattle. Furthermore, evolutionary analysis revealed that the HMG domain remained conserved in the all members of the Sox gene family. Similarly, all the genes are under strong purifying selection pressure; seven segmental duplications occurred from 9.65 to 21.41 million years ago (MYA), and four potential recombination breakpoints were also predicted. Mutational analysis revealed twenty non-synonymous mutations with potential effects on physiological functions, including embryonic development and cell differentiation in the buffalo. The present study provides insights into the genetic architecture of the Sox gene family in buffalo, highlights the significance of mutations, and provides their potential utility for marker-assisted selection for targeted genetic improvement in buffalo.

Identification and functional analysis of Dmrt1 gene and the SoxE gene in the sexual development of sea cucumber, Apostichopus japonicus

Members of the Doublesex and Mab-3-related transcription factor (Dmrt) gene family handle various vital functions in several biological processes, including sex determination/differentiation and gonad development. Dmrt1 and Sox9 (SoxE in invertebrates) exhibit a very conserved interaction function during testis formation in vertebrates. However, the dynamic expression pattern and functional roles of the Dmrt gene family and SoxE have not yet been identified in any echinoderm species. Herein, five members of the Dmrt gene family (Dmrt1, 2, 3a, 3b and 5) and the ancestor SoxE gene were identified from the genome of Apostichopus japonicus. Expression studies of Dmrt family genes and SoxE in different tissues of adult males and females revealed different expression patterns of each gene. Transcription of Dmrt2, Dmrt3a and Dmrt3b was higher expressed in the tube feet and coelomocytes instead of in gonadal tissues. The expression of Dmrt1 was found to be sustained throughout spermatogenesis. Knocking-down of Dmrt1 by means of RNA interference (RNAi) led to the downregulation of SoxE and upregulation of the ovarian regulator foxl2 in the testes. This indicates that Dmrt1 may be a positive regulator of SoxE and may play a role in the development of the testes in the sea cucumber. The expression level of SoxE was higher in the ovaries than in the testes, and knocking down of SoxE by RNAi reduced SoxE and Dmrt1 expression but conversely increased the expression of foxl2 in the testes. In summary, this study indicates that Dmrt1 and SoxE are indispensable for testicular differentiation, and SoxE might play a functional role during ovary differentiation in the sea cucumber.

Comprehensive Transcriptome Analysis of Gonadal and Somatic Tissues for Identification of Sex-Related Genes in the Largemouth Bass Micropterus salmoides

Largemouth bass (Micropterus salmoides) is an economically important fish. It can spawn many times during a breeding season, and there are no obvious morphological characteristics to distinguish male and female juvenile fish. So far, little is known about the genes regulating their sexual development in this species. Here, we performed RNA sequencing (RNA-Seq) analysis of the testis, ovary, and somatic tissue to identify sex-related genes in the largemouth bass. A total of 51,672 unigenes were obtained via the transcriptome analysis, and 5900 differential expression genes (DEGs), including 3028 up-regulated and 2872 down-regulated DEGs, were obtained in the somatic tissue, testis, and ovary. DEGs were retrieved by making comparisons: somatic tissue vs testis (1733-up and 1382-down), testis vs ovary (841-up and 807-down), and ovary vs somatic tissue (454-up and 683-down). Finally, functional annotation identified 22 key sex-related DEGs, including 13 testis-biased DEGs (dmrt1, cyp11b1, sox9, spata4, spata22, spata17, fshr, fem-1a, wt1, daz1, amh, vasa, and piwi1) and 9 ovary-biased DEGs (foxl2, gdf9, zp3, sox3, cyp19a, bmp15, fem-1b, fig. la, and piwi2). This result was further confirmed by the tissue expression detection via RT-PCR and RT-qPCR. Protein-protein interacting (PPI) network analysis revealed that the testis-specific dmrt1 interacts directly with the testis-biased DEGs (cyp11b1 and spata4) and the ovary-biased DEGs (foxl2, gdf9, zp3, sox3, cyp19a, and bmp15), suggesting that the dmrt1 as a sex-determining gene can play a dual role through inducing the testis-biased DEGs and inhibiting the ovary-biased DEGs during the testicular development. Our present results provide useful molecular data for a better understanding of sexual development in the largemouth bass.

sox19 regulates ovarian steroidogenesis in common carp

In teleost, ovarian steroidogenesis governed by the neuroendocrine system is also regulated by several transcription factors of gonadal origin. Investigating the synchronized interactions between the transcriptional and the hormonal factors is vital to comprehend the mechanisms that lead to gonadal differentiation. This study signifies the role of sry-related box (sox) 19 in ovarian steroidogenesis regulation of the common carp, Cyprinus carpio. Analysis of tissue distribution displayed higher sox19 expression in brain and ovary, and gonadal ontogeny showed higher expression of sox19 at 80 days post hatch (dph). Higher sox19 mRNA expression during spawning and increase of sox19 post human chorionic gonadotropin induction substantiate gonadotropin dependency. Estradiol-17β treatment but not 17α-methyl-di-hydroxy-testosterone to 50 dph common carp for inducing mono-sex, elevated sox19 expression substantially. Sox19 protein was observed in granulosa cells of the follicular layer in common carp ovary. Higher sox19 expression was detected in isolated granulosa and theca cells, in vitro. Transient gene silencing with sox19-siRNA caused downregulation of various ovary-related genes including those specific to activator protein-1 factors, fibroblast growth factors, wnt-signaling, steroidogenic genes along with certain transcription factors. Serum 17α, 20β-dihydroxy-4-pregnen-3-one and estradiol-17β reduced significantly post sox19 silencing, in vivo. Concomitantly, a decrease in aromatase activity was detected post sox19-siRNA treatment, in vivo. This study demonstrates the impact of sox19 in the regulation of common carp ovarian growth and steroidogenesis.

The Important Role of Sex-Related Sox Family Genes in the Sex Reversal of the Chinese Soft-Shelled Turtle (Pelodiscus sinensis)

The Chinese soft-shelled turtle Pelodiscus sinensis shows obvious sexual dimorphism. The economic and nutrition value of male individuals are significantly higher than those of female individuals. Pseudo-females which are base to all-male breeding have been obtained by estrogen induction, while the gene function and molecular mechanism of sex reversal remain unclear in P. sinensis. Here, comparative transcriptome analyses of female, male, and pseudo-female gonads were performed, and 14,430 genes differentially expressed were identified in the pairwise comparison of three groups. GO and KEGG analyses were performed on the differentially expressed genes (DEGs), which mainly concentrated on steroid hormone synthesis. Furthermore, the results of gonadal transcriptome analysis revealed that 10 sex-related sox genes were differentially expressed in males vs. female, male vs. pseudo-female, and female vs. pseudo-female. Through the differential expression analysis of these 10 sox genes in mature gonads, six sox genes related to sex reversal were further screened. The molecular mechanism of the six sox genes in the embryo were analyzed during sex reversal after E₂ treatment. In mature gonads, some sox family genes, such as sox9sox12, and sox30 were highly expressed in the testis, while sox1, sox3, sox6, sox11, and sox17 were lowly expressed. In the male embryos, exogenous estrogen can activate the expression of sox3 and inhibit the expression of sox8, sox9, and sox11. In summary, sox3 may have a role in the process of sex reversal from male to pseudo-female, when sox8 and sox9 are inhibited. Sox family genes affect both female and male pathways in the process of sex reversal, which provides a new insight for the all-male breeding of the Chinese soft-shelled turtle.

Response to comment on "Nuclear receptor PXR targets AKR1B7 to protect mitochondrial metabolism and renal function in AKI"

The nuclear pregnane X receptor protects against bilateral renal ischemia/reperfusion-induced acute kidney injury in mice.

Genome wide identification, phylogeny, and synteny analysis of sox gene family in common carp (Cyprinus carpio)

•

27 SOX (high-mobility group HMG-box) genes were identified in the C. carp genome.

•

SOX genes ranging from 3496 (SOX6) to 924bp (SOX17b) which coded with putative protein series from 307 to 509 amino acids.

•

Gene ontology revealed SOX proteins maximum involvement is in metabolic process 49.796 %.

•

Chromosomal location and synteny analysis display all SOX gene are located on different chromosomes.

Common carp (Cyprinus carpio) is a commercial fish species valuable for nutritious components and plays a vital role in human healthy nutrition. The SOX (SRY-related genes systematically characterized by a high-mobility group HMG-box) encoded important gene regulatory proteins, a family of transcription factors found in a broad range of animal taxa and extensively known for its contribution in multiple developmental processes including contribution in sex determination across phyla. In our current study, we initially accomplished a genome-wide analysis to report the SOX gene family in common carp fish based on available genomic sequences of zebrafish retrieved from gene repository databases, we focused on the global identification of the Sox gene family in Common carp among wide range of vertebrates and teleosts based on bioinformatics tools and techniques and explore the evolutionary relationships. In our results, a total of 27 SOX (high-mobility group HMG-box) domain genes were identified in the C. carp genome. The full length sequences of SOX genes ranging from 3496 (SOX6) to 924bp (SOX17b) which coded with putative proteins series from 307 to 509 amino acids and all gene having exon number expect SOX9 and SOX13. All the SOX proteins contained at least one conserved DNA-binding HMG-box domain and two (SOX7 and SOX18) were found C terminal. The Gene ontology revealed SOX proteins maximum involvement is in metabolic process 49.796 %, average in biological regulation 45.188 %, biosynthetic process (19.992 %), regulation of cellular process 39.68, 45.508 % organic substance metabolic process, multicellular organismal process 23.23 %,developmental process 21.74 %, system development 16.59 %, gene expression 16.05 % and 14.337 % of RNA metabolic process. Chromosomal location and syntanic analysis show all SOX gene are located on different chromosomes and apparently does not fallow the unique pattern. The maximum linkage of chromosome is (2) on Unplaced Scaffold region. Finally, our results provide important genomic suggestion for upcoming studies of biochemical, physiological, and phylogenetic understanding on SOX genes among teleost.

Molecular cloning, characterization, and expression analysis of a sex-biased transcriptional factor sox9 gene of mud crab Scylla paramamosain

Sox9 gene, a crucial member of the Sox gene family, is present in various organisms and involved in many physiological processes, especially in sex determination and gonad development. In this study, we reported a sox9 gene (designated as Spsox9) from Scylla paramamosain through analyzing published gonad transcriptome data. Meanwhile, the accuracy was validated by PCR technology, and the 3' sequences were cloned with 3' RACE technology. The full-length cDNA of Spsox9 is 2843 bp, consisting of a 243 bp 5' UTR, an 1124 bp 3' UTR, and a 1476 bp ORF encoding 491 amino acids. Furthermore, to better understand its conservation among crustacean species, the sox9 gene ortholog was identified in several other crustaceans species with their published transcriptome data, respectively. All of the Sox9 proteins identified in the current study had the common feature of Sox proteins (HMG domain) and were highly conserved among analyzed crustacean species. In all examined tissues, the Spsox9 was mainly expressed in the gonad (testis and ovary), eyestalk, and cerebral ganglion. During embryo development, Spsox9 was highly expressed in 5 pairs of appendages, 7 pairs of appendages, and eye-pigment formation stage. During ovary development, the expression level of Spsox9 remained stable in the first 4 stages (O1-O4) and decreased in the tertiary vitellogenesis (O5) stage. During testis development, the expression level of Spsox9 was highest in the spermatid stage (T2) and was significantly different from that in the spermatocyte stage (T1) and mature sperm stage (T3) (p < 0.05). In addition, Spsox9 exhibited a sex-biased expression pattern in T1 and O1. These present results indicated that the Spsox9 gene might play crucial roles in the gonad and embryo development of mud crab.

Genome-wide investigation of Dmrt gene family in large yellow croaker (Larimichthys crocea)

The Dmrt (Doublesex and Mab-3 related transcription factor) gene family is a class of crucial transcription factors characterized by a conserved DM (Doublesex/Mab-3) domain. Previous researches indicate this gene family is involved in various physiological processes, especially in sex determination/differentiation and gonad development. Despite the vital roles of the Dmrt gene family in physiological processes, the comprehensive characterization and analysis of the dmrt genes in large yellow croaker (Larimichthys crocea), one of the most commercially important marine fish in China, have not been described. In this study, we performed the first genome-wide systematic analysis of L. crocea dmrt genes through the bioinformatics method. A total of seven members of the Dmrt gene family including Lcdmrt1, Lcdmrt2a, Lcdmrt2b, Lcdmrt3, Lcdmrt4, Lcdmrt5, and Lcdmrt6 were excavated based on the genome data of L. crocea. Further analysis revealed that the dmrt genes of L. crocea were distributed unevenly across four chromosomes. There were three dmrt genes (Lcdmrt1, Lcdmrt2a, and Lcdmrt3) on 3rd chromosome, one (Lcdmrt6) on 13th chromosome, one (Lcdmrt4) on 14th chromosome, two on (Lcdmrt5 and Lcdmrt2b) 17th chromosome. The gene structure analysis indicated that the number of introns of different dmrt genes of L. crocea had some differences: Lcdmrt1 had four introns, Lcdmrt2a, Lcdmrt2b, and Lcdmrt6 had two introns, Lcdmrt3, Lcdmrt4, and Lcdmrt5 had only one intron. The expression pattern analysis with published gonad transcriptome datasets and further confirmed by qRT-PCR revealed that these members of the Dmrt gene family except for Lcdmrt4 were all sexually dimorphic and preferred expressing in testis. Furthermore, the expression pattern analysis also revealed that the expression level of Lcdmrt1 and Lcdmrt6 was significantly higher than that of other members, suggesting that these two genes may play a more important role in testis. Overall, our studies provide a comprehensive insight into the Dmrt gene family members and a basis for the further study of their biological functions in L. crocea.