Establishing targeted carp TLR22 gene disruption via homologous recombination using CRISPR/Cas9.

Recent advances in gene editing techniques have not been exploited in farmed fishes. We established a gene targeting technique, using the CRISPR/Cas9 system in Labeo rohita, a farmed carp (known as rohu). We demonstrated that donor DNA was integrated via homologous recombination (HR) at the site of targeted double-stranded nicks created by CRISPR/Cas9 nuclease. This resulted in the successful disruption of rohu Toll-like receptor 22 (TLR22) gene, involved in innate immunity and exclusively present in teleost fishes and amphibians. The null mutant, thus, generated lacked TLR22 mRNA expression. Altogether, this is the first evidence that the CRISPR/Cas9 system is a highly efficient tool for targeted gene disruption via HR in teleosts for generating model large-bodied farmed fishes.

Identification of Deleterious Mutations in Myostatin Gene of Rohu Carp (Labeo rohita) Using Modeling and Molecular Dynamic Simulation Approaches.

The myostatin (MSTN) is a known negative growth regulator of skeletal muscle. The mutated myostatin showed a double-muscular phenotype having a positive significance for the farmed animals. Consequently, adequate information is not available in the teleosts, including farmed rohu carp, Labeo rohita. In the absence of experimental evidence, computational algorithms were utilized in predicting the impact of point mutation of rohu myostatin, especially its structural and functional relationships. The four mutations were generated at different positions (p.D76A, p.Q204P, p.C312Y, and p.D313A) of MSTN protein of rohu. The impacts of each mutant were analyzed using SIFT, I-Mutant 2.0, PANTHER, and PROVEAN, wherein two substitutions (p.D76A and p.Q204P) were predicted as deleterious. The comparative structural analysis of each mutant protein with the native was explored using 3D modeling as well as molecular-dynamic simulation techniques. The simulation showed altered dynamic behaviors concerning RMSD and RMSF, for either p.D76A or p.Q204P substitution, when compared with the native counterpart. Interestingly, incorporated two mutations imposed a significant negative impact on protein structure and stability. The present study provided the first-hand information in identifying possible amino acids, where mutations could be incorporated into MSTN gene of rohu carp including other carps for undertaking further in vivo studies.

The ß-actin gene promoter of rohu carp (Labeo rohita) drives reporter gene expressions in transgenic rohu and various cell lines, including spermatogonial stem cells.

We previously characterized the ß-actin gene promoter of Indian domesticated rohu carp (Labeo rohita) and made a reporter construct via fusion to green fluorescence protein (GFP) cDNA. In this study, the same construct was used to breed transgenic rohu fish. About 20% of the transgenic offspring showed ubiquitous expression of the reporter GFP gene. In a few of the transgenic fish, we documented massive epithelial and/or muscular expression with visible green color under normal light. The expression of GFP mRNA was higher in the muscle tissue of transgenic fish than in that of non-transgenic fish. A highly efficient nucleofection protocol was optimized to transfect proliferating spermatogonial cells of rohu using this reporter construct. The ß-actin promoter also drove expressions in HEK293 (derived from human embryonic kidney cells), K562 (human leukemic cells) and SF21 (insect ovarian cells) lines. These findings imply conserved regulatory mechanisms of ß-actin gene expression across eukaryotes. Furthermore, the isolated ß-actin promoter with consensus regulatory elements has the potential to be used in generating transgenic carp with genes of interest and in basic biology research.

First evidence of molecular characterization of rohu carp Sox2 gene being expressed in proliferating spermatogonial cells.

Because little is known about the function of Sox2 (Sry-related box-2) in teleosts, the objective of this study was to clone and characterize Sox2 complementary DNA (cDNA) from the testis of Indian major carp, Labeo rohita (rohu). The full-length cDNA contained an open reading frame of 936 nucleotides bearing the typical structural features. Phylogenetically, Sox2 of L rohita was most closely related to freshwater counterparts than marine water. The sequence information of cDNA and genomic DNA together revealed that the Sox2 gene is encoded by an uninterrupted exon. Furthermore, comparative mRNA expression profile in various organs including proliferating spermatogonial stem cells (SSCs) suggested about the participatory role of Sox2 during fish male germ cell development and maintenance of stem cells. In support, we have also provided evidence that Sox2 protein is indeed present in rohu SSCs by Western blot analysis. The evolutionarily conserved high-mobility group box domain indicated its possible involvement in common networking pathways for stem cell maintenance and pluripotency between mammals and nonmammals. Our findings could be the first step toward the use of Sox2 as a potential biomarker for proliferating SSCs and understanding the transcriptional regulatory network involved during male germ cell development and maintenance in fish species.

First evidence of comparative responses of Toll-like receptor 22 (TLR22) to relatively resistant and susceptible Indian farmed carps to Argulus siamensis infection.

Toll-like receptor 22 (TLR22) is present in teleost but not in mammals. Among Indian farmed carps, Catla catla is relatively more resistant than Labeo rohita to Argulus siamensis lice infection. TLR22 is believed to be associated with innate immunity against ectoparasite infection. To investigate the TLR22 mediated immunity against argulosis, we have cloned and characterized TLR22 genes of L. rohita (rTLR22) and C. catla (cTLR22). The full-length cDNAs of rTLR22 and cTLR22 contained an open reading frame of 2838 and 2841 nucleotides, respectively; bearing the typical structural features. Phylogenetically rTLR22/cTLR22 was most closely related to Cyprinus carpio (common carp) counterpart, having highest sequence identity of 86.0%. The TIR domain remained highly conserved with 90% identity within freshwater fishes. The sequence information of cDNA and genomic DNA together revealed that the rTLR22/cTLR22 genes are encoded by uninterrupted exons. The co-habitation challenge study with A. siamensis infection confirmed that C. catla is comparatively more resistant than L. rohita. Further, comparative mRNA expression profile in immune relevant tissues also suggested about the participatory role of TLR22 during lice infection. However, TLR22 might not solely be involved in conferring relative resistance among carp species against argulosis.

Gene structure and identification of minimal promoter of Pou2 expressed in spermatogonial cells of rohu carp, Labeo rohita.

Mammalian Pou5f1 is a known transcriptional regulator involving maintenance of embryonic and spermatogonial stem cells. Little is known about teleost Pou2, an ortholog of mammalian Pou5f1. Evidences of discrepancy in expression pattern between fish species were documented. To better understand, we have cloned and characterized Pou2 gene of farmed rohu carp, Labeo rohita. It contained five exons with an open reading frame of 1419 bp long, translatable to 472 aa. A bipartite DNA binding domain termed POU domain, comprising of POU-specific and POU-homeo sub-domains, was identified. Rohu Pou2 is highly conserved with zebrafish counterpart, as evidenced by 92% overall sequence identity of deduced protein. The POU domain remained highly conserved (showing more than 90% identities) within fish species. Even though there is a divergence between Pou2 and Pou5f1, the common POU-specific domain remained conserved throughout eukaryotes indicating their possible involvements in common trans-activation pathway(s) between mammals and non-mammals. In support, we have provided evidence that Pou2 is indeed abundantly expressed in proliferating rohu spermatogonial cells and hence participates in stem cell maintenance. Its mRNA accumulation in the ovary supported about its maternal transmission with possible regulatory roles during embryogenesis. The 5'-flanking region (~2.7 kb) of rohu Pou2 was sequenced and computational analysis detected several putative regulatory elements. These elements have been conserved among fish species analysed. Luciferase assay identified a mammalian-type 'TATA-less promoter' capable of driving Pou2 gene transcription. These findings will help for future studies in elucidating participatory role of fish Pou2 in male germ cell development.

Identification and characterization of differentially expressed transcripts in the gills of freshwater prawn (Macrobrachium rosenbergii) under salt stress.

The giant freshwater prawn, Macrobrachium rosenbergii, is an economically important species. It is a euryhaline shrimp, surviving in wide-range salinity conditions. A change in gene expression has been suggested as an important component for stress management. To better understand the osmoregulatory mechanisms mediated by the gill, a subtractive and suppressive hybridization (SSH) tool was used to identify expressed transcripts linked to adaptations in saline water. A total of 117 transcripts represented potentially expressed under salinity conditions. BLAST analysis identified 22% as known genes, 9% as uncharacterized showing homologous to unannotated ESTs, and 69% as unknown sequences. All the identified known genes representing broad spectrum of biological pathways were particularly linked to stress tolerance including salinity tolerance. Expression analysis of 10 known genes and 7 unknown/uncharacterized genes suggested their upregulation in the gills of prawn exposed to saline water as compared to control indicating that these are likely to be associated with salinity acclimation. Rapid amplification of cDNA ends (RACE) was used for obtaining full-length cDNA of MRSW-40 clone that was highly upregulated during salt exposure. The sequenced ESTs presented here will have potential implications for future understanding about salinity acclimation and/or tolerance of the prawn.