DNA methylation changes detected by methylation-sensitive amplified polymorphism in the Pacific oyster (<Emphasis Type="Italic">Crassostrea gigas</Emphasis>) in response to salinity stress

Salinity is a considerable factor to the survival and distribution for a majority of marine organisms, the drawbacks of which are becoming a serious issue of aquaculture. DNA methylation, an extensively studied epigenetic modification in eukaryotes, plays a significant role in the regulation of gene expression in responding to environmental changes and triggering evolutionary consequences. The Pacific oyster Crassostrea gigas, as a eurythermal and euryhaline species, is considered to be tolerant to salinity fluctuation. In this study, fluorescent-labeled methylation-sensitive amplified polymorphism (F-MSAP) analysis was used to investigate the frequency and variation of DNA methylation in C. gigas under different salinity and time. The results showed that total methylation level was generally on a downward trend. At lower salinity, the total methylation level decreased at the earlier process and then increased during experiment process, but continued to shrink at the rest salinity. Fully methylation tended to better reflect the dynamics of total methylation. Recovery treatment showed that the extent and pattern of DNA methylation were difficult to return to the normal level in this research. The sequencing and BLAST analysis indicated that in salt stress most of the selected bands were closely related to the metabolism of nucleic acids and proteins, tropomyosin, and cellular transport, effecting on different biological processes of C. gigas. This work provides useful data to further elucidate the molecular mechanisms of salt stress response and tolerance in invertebrates.     

Expression and DNA methylation pattern of reproduction-related genes in partially fertile triploid Pacific oysters <Emphasis Type="Italic">Crassostrea gigas</Emphasis>

Partial or complete sterility is an obvious feature in triploid Pacific oyster (Crassostrea gigas) which contributes to improving rearing performances. Despite the significance of sterility, the molecular mechanism behind it remains elusive and related research was limited. This study focused on six reproduction-related genes and compared their different behavior in gene expression and DNA methylation pattern between triploid and diploid oysters in order to provide more molecular information. The gonadal development of triploid oyster was examined by histology before molecular analysis. Gametogenesis disturbance was observed in triploid oysters at different development stages (stage II and III) with more serious impairment in females. QPCR showed significant gene expression difference between diploid and triploid in two genes: putative Vg and cgER. Gene expression of putative Vg was delayed in triploids while for cgER triploid oyster showed higher expression and the difference was significant at stage III. DNA methylation pattern of these two genes were further investigated by bisulfite sequencing. Between diploid and triploid oysters, no difference was observed in total methylation level but some individual loci showed different patterns: significantly high methylation rate of loci 2284 in cgER was observed in triploid oyster which has a higher expression of this gene. This study indicated that putative Vg and cgER might play a role in partial sterile in triploid C. gigas. Gene expression could be regulated by the methylation pattern at specific individual locus, which deserves equivalent attention as well as total DNA methylation level.     

A preliminary integrated genetic map distinguishes every chromosome pair and locates essential genes related to abiotic adaptation of <Emphasis Type="Italic">Crassostrea angulata</Emphasis>/<Emphasis Type="Italic">gigas</Emphasis>

Background

The re-sequencing of C. angulata has revealed many polymorphisms in candidate genes related to adaptation to abiotic stress that are not present in C. gigas; these genes, therefore, are probably related to the ability of this oyster to retain high concentrations of toxic heavy metals. There is, in addition, an unresolved controversy as to whether or not C. angulata and C. gigas are the same species or subspecies. Both oysters have 20 metacentric chromosomes of similar size that are morphologically indistinguishable. From a genomic perspective, as a result of the great variation and selection for heterozygotes in C. gigas, the assembly of its draft genome was difficult: it is fragmented in more than seven thousand scaffolds.

Results

In this work sixty BAC sequences of C. gigas downloaded from NCBI were assembled in BAC-contigs and assigned to BACs that were used as probes for mFISH in C. angulata and C. gigas. In addition, probes of H3, H4 histone, 18S and 5S rDNA genes were also used. Hence we obtained markers identifying 8 out the 10 chromosomes constituting the karyotype. Chromosomes 1 and 9 can be distinguished morphologically. The bioinformatic analysis carried out with the BAC-contigs annotated 88 genes. As a result, genes associated with abiotic adaptation, such as metallothioneins, have been positioned in the genome. The gene ontology analysis has also shown many molecular functions related to metal ion binding, a phenomenon associated with detoxification processes that are characteristic in oysters. Hence the provisional integrated map obtained in this study is a useful complementary tool for the study of oyster genomes.

Conclusions

In this study 8 out of 10 chromosome pairs of Crassostrea angulata/gigas were identified using BAC clones as probes. As a result all chromosomes can now be distinguished. Moreover, FISH showed that H3 and H4 co-localized in two pairs of chromosomes different that those previously escribed. 88 genes were annotated in the BAC-contigs most of them related with Molecular Functions of protein binding, related to the resistance of the species to abiotic stress. An integrated genetic map anchored to the genome has been obtained in which the BAC-contigs structure were not concordant with the gene structure of the C. gigas scaffolds displayed in the Genomicus database.

     

Trojan Horse Strategy for Non-invasive Interference of <Emphasis Type="Italic">Clock</Emphasis> Gene in the Oyster <Emphasis Type="Italic">Crassostrea gigas</Emphasis>

RNA interference is a powerful method to inhibit specific gene expression. Recently, silencing target genes by feeding has been successfully carried out in nematodes, insects, and small aquatic organisms. A non-invasive feeding-based RNA interference is reported here for the first time in a mollusk bivalve, the pacific oyster Crassostrea gigas. In this Trojan horse strategy, the unicellular alga Heterocapsa triquetra is the food supply used as a vector to feed oysters with Escherichia coli strain HT115 engineered to express the double-stranded RNA targeting gene. To test the efficacy of the method, the Clock gene, a central gene of the circadian clock, was targeted for knockout. Results demonstrated specific and systemic efficiency of the Trojan horse strategy in reducing Clock mRNA abundance. Consequences of Clock disruption were observed in Clock-related genes (Bmal, Tim1, Per, Cry1, Cry2, Rev.-erb, and Ror) and triploid oysters were more sensitive than diploid to the interference. This non-invasive approach shows an involvement of the circadian clock in oyster bioaccumulation of toxins produced by the harmful alga Alexandrium minutum.     

Genome-wide identification,systematic analysis and characterization of <Emphasis Type="Italic">SRO</Emphasis> family genes in maize (<Emphasis Type="Italic">Zea mays</Emphasis> L.)

SIMILAR TO RCD ONE (SRO) is a small plant-specific gene family, which play essential roles in plant growth and development as well as in abiotic stresses. However, the function of SROs in maize is still unknown. In our study, six putative SRO genes were isolated from the maize genome. A systematic analysis was performed to characterize the ZmSRO gene family. The ZmSRO gene family was divided into two groups according to the motif and intron/exon analysis. Phylogenetic analysis of them with other plants showed that the clades of SROs along with the divergence of monocot and dicot and ZmSROs were more closely with OsSROs. Many abiotic stress response and hormone-induced cis-regulatory elements were identified from the promoter region of ZmSROs. Furthermore, RNA-seq analysis indicated that SRO genes were widely expressed in different tissues and development stages in maize, and the expression divergence was also obviously observed. Analyses of expression in response to PEG6000 and NaCl treatment, in addition to exogenous application of ABA and GA hormones showed that the majority of the members display stress-induced expression patterns. Taken together, our results provide valuable reference for further functional analysis of the SRO gene family in maize, especially in abiotic stress responses.     

Molecular cloning and functional characterization of a Cu/Zn superoxide dismutase gene (<Emphasis Type="Italic">CsCSD1</Emphasis>) from <Emphasis Type="Italic">Cucumis sativus</Emphasis>

Superoxide dismutase (SOD) proteins, which are widely present in the plant kingdom, play vital roles in response to abiotic stress. However, the functions of cucumber SOD genes in response to environmental stresses remain poorly understood. In this study, a SOD gene CsCSD1 was identified and functionally characterized from cucumber (Cucumis sativus). The CsCSD1 protein was successfully expressed in E. coli, and its overexpression significantly improved the tolerance of host E. coli cells to salinity stress. Besides, overexpression of CsCSD1 enhanced salinity tolerance during germination and seedling development in transgenic Arabidopsis plants. Further analyses showed that the SOD and CAT (catalase) activities of transgenic plants were significantly higher than those of wild-type (WT) plants under normal growth conditions as well as under NaCl treatment. In addition, the expression of stress-response genes RD22, RD29B and LEA4-5 was significantly elevated in transgenic plants. Our results demonstrate that the CsCSD1 gene functions in defense against salinity stress and may be important for molecular breeding of salt-tolerant plants.     

The Voltage-Dependent Anion Channel (VDAC) of Pacific Oysters <Emphasis Type="Italic">Crassostrea gigas</Emphasis> Is Upaccumulated During Infection by the Ostreid Herpesvirus-1 (OsHV-1): an Indicator of the Warburg Effect

Voltage-dependent anion channel (VDAC) is a key mitochondrial protein. VDAC drives cellular energy metabolism by controlling the influx and efflux of metabolites and ions through the mitochondrial membrane, playing a role in its permeabilization. This protein exerts a pivotal role during the white spot syndrome virus (WSSV) infection in shrimp, through its involvement in a particular metabolism that plays in favor of the virus, the Warburg effect. The Warburg effect corresponds to an atypical metabolic shift toward an aerobic glycolysis that provides energy for rapid cell division and resistance to apoptosis. In the Pacific oyster Crassostrea gigas, the Warburg effect occurs during infection by Ostreid herpesvirus (OsHV-1). At present, the role of VDAC in the Warburg effect, OsHV-1 infection and apoptosis is unknown. Here, we developed a specific antibody directed against C. gigas VDAC. This tool allowed us to quantify the tissue-specific expression of VDAC, to detect VDAC oligomers, and to follow the amount of VDAC in oysters deployed in the field. We showed that oysters sensitive to a mortality event in the field presented an accumulation of VDAC. Finally, we propose to use VDAC quantification as a tool to measure the oyster susceptibility to OsHV-1 depending on its environment.