Shiguo Li

In-depth proteomic analysis of shell matrix proteins of Pinctada fucata

The shells of pearl oysters, Pinctada fucata, are composed of calcite and aragonite and possess remarkable mechanical properties. These shells are formed under the regulation of macromolecules, especially shell matrix proteins (SMPs). Identification of diverse SMPs will lay a foundation for understanding biomineralization process. Here, we identified 72 unique SMPs using liquid chromatography-tandem mass spectrometry (LC-MS/MS) analysis of proteins extracted from the shells of P. fucata combined with a draft genome. Of 72 SMPs, 17 SMPs are related to both the prismatic and nacreous layers. Moreover, according to the diverse domains found in the SMPs, we hypothesize that in addition to controlling CaCO3 crystallization and crystal organization, these proteins may potentially regulate the extracellular microenvironment and communicate between cells and the extracellular matrix (ECM). Immunohistological localization techniques identify the SMPs in the mantle, shells and synthetic calcite. Together, these proteomic data increase the repertoires of the shell matrix proteins in P. fucata and suggest that shell formation in P. fucata may involve tight regulation of cellular activities and the extracellular microenvironment.

Transcriptome and biomineralization responses of the pearl oyster Pinctada fucata to elevated CO2 and temperature.

Ocean acidification and global warming have been shown to significantly affect the physiological performances of marine calcifiers; however, the underlying mechanisms remain poorly understood. In this study, the transcriptome and biomineralization responses of Pinctada fucata to elevated CO2 (pH 7.8 and pH 7.5) and temperature (25 °C and 31 °C) are investigated. Increases in CO2 and temperature induced significant changes in gene expression, alkaline phosphatase activity, net calcification rates and relative calcium content, whereas no changes are observed in the shell ultrastructure. “Ion and acid-base regulation” related genes and “amino acid metabolism” pathway respond to the elevated CO2 (pH 7.8), suggesting that P. fucata implements a compensatory acid-base mechanism to mitigate the effects of low pH. Additionally, “anti-oxidation”-related genes and “Toll-like receptor signaling”, “arachidonic acid metabolism”, “lysosome” and “other glycan degradation” pathways exhibited responses to elevated temperature (25 °C and 31 °C), suggesting that P. fucata utilizes anti-oxidative and lysosome strategies to alleviate the effects of temperature stress. These responses are energy-consuming processes, which can lead to a decrease in biomineralization capacity. This study therefore is important for understanding the mechanisms by which pearl oysters respond to changing environments and predicting the effects of global climate change on pearl aquaculture.

Interactive Effects of Seawater Acidification and Elevated Temperature on the Transcriptome and Biomineralization in the Pearl Oyster Pinctada fucata

Interactive effects of ocean acidification and ocean warming on marine calcifiers vary among species, but little is known about the underlying mechanisms. The present study investigated the combined effects of seawater acidification and elevated temperature (ambient condition: pH 8.1 × 23 °C, stress conditions: pH 7.8 × 23 °C, pH 8.1 × 28 °C, and pH 7.8 × 28 °C, exposure time: two months) on the transcriptome and biomineralization of the pearl oyster Pinctada fucata, which is an important marine calcifier. Transcriptome analyses indicated that P. fucata implemented a compensatory acid-base mechanism, metabolic depression and positive physiological responses to mitigate the effects of seawater acidification alone. These responses were energy-expensive processes, leading to decreases in the net calcification rate, shell surface calcium and carbon content, and changes in the shell ultrastructure. Elevated temperature (28 °C) within the thermal window of P. fucata did not induce significant enrichment of the sequenced genes and conversely facilitated calcification, which was detected to alleviate the negative effects of seawater acidification on biomineralization and the shell ultrastructure. Overall, this study will help elucidate the mechanisms by which pearl oysters respond to changing seawater conditions and predict the effects of global climate change on pearl aquaculture.

Morphology and classification of hemocytes in Pinctada fucata and their responses to ocean acidification and warming.

Hemocytes play important roles in the innate immune response and biomineralization of bivalve mollusks. However, the hemocytes in pearl oysters are poorly understood. In the present study, we investigated the morphology and classification of hemocytes in the pearl oyster, Pinctada fucata. Three types of hemocytes were successfully obtained by light microscopy, electron microscopy and flow cytometry methods: small hyalinocytes, large hyalinocytes and granulocytes. The small hyalinocytes are the major hemocyte population. Morphological analyses indicated that these hemocytes have species-specific characterizations. In addition, we assessed the potential effects of ocean acidification (OA) and ocean warming (OW) on the immune parameters and calcium homeostasis of the hemocytes. OA and OW (31 °C) altered pH value of hemolymph, increased the total hemocyte count, total protein content, and percentage of large hyalinocytes and granulocytes, while it decreased the neutral red uptake ability, suggesting active stress responses of P. fucata to these stressors. Exposure to OW (25 °C) resulted in no significant differences, indicating an excellent immune defense to heat stress at this level. The outflow of calcium from hemocytes to hemolymph was also determined, implying the potential impact of OA and OW on hemocyte-mediated biomineralization. This study, therefore, provides insight into the classification and characterization of hemocyte in the pearl oyster, P. fucata, and also reveals the immune responses of hemocytes to OA and OW, which are helpful for a comprehensive understanding of the effects of global climate change on pearl oysters.

Extensible byssus of Pinctada fucata : Ca 2+ -stabilized nanocavities and a thrombospondin-1 protein

The extensible byssus is produced by the foot of bivalve animals, including the pearl oyster Pinctada fucata, and enables them to attach to hard underwater surfaces. However, the mechanism of their extensibility is not well understood. To understand this mechanism, we analyzed the ultrastructure, composition and mechanical properties of the P. fucata byssus using electron microscopy, elemental analysis, proteomics and mechanical testing. In contrast to the microstructures of Mytilus sp. byssus, the P. fucata byssus has an exterior cuticle without granules and an inner core with nanocavities. The removal of Ca2+ by ethylenediaminetetraacetic acid (EDTA) treatment expands the nanocavities and reduces the extensibility of the byssus, which is accompanied by a decrease in the β-sheet conformation of byssal proteins. Through proteomic methods, several proteins with antioxidant and anti-corrosive properties were identified as the main components of the distal byssus regions. Specifically, a protein containing thrombospondin-1 (TSP-1), which is highly expressed in the foot, is hypothesized to be responsible for byssus extensibility. Together, our findings demonstrate the importance of inorganic ions and multiple proteins for bivalve byssus extension, which could guide the future design of biomaterials for use in seawater.

Interactive effects of seawater acidification and elevated temperature on biomineralization and amino acid metabolism in the mussel Mytilus edulis

ABSTRACT Seawater acidification and warming resulting from anthropogenic production of carbon dioxide are increasing threats to marine ecosystems. Previous studies have documented the effects of either seawater acidification or warming on marine calcifiers; however, the combined effects of these stressors are poorly understood. In our study, we examined the interactive effects of elevated carbon dioxide partial pressure (PCO2) and temperature on biomineralization and amino acid content in an ecologically and economically important mussel, Mytilus edulis. Adult M. edulis were reared at different combinations of PCO2 (pH 8.1 and 7.8) and temperature (19, 22 and 25°C) for 2 months. The results indicated that elevated PCO2 significantly decreased the net calcification rate, the calcium content and the Ca/Mg ratio of the shells, induced the differential expression of biomineralization-related genes, modified shell ultrastructure and altered amino acid content, implying significant effects of seawater acidification on biomineralization and amino acid metabolism. Notably, elevated temperature enhanced the effects of seawater acidification on these parameters. The shell breaking force significantly decreased under elevated PCO2, but the effect was not exacerbated by elevated temperature. The results suggest that the interactive effects of seawater acidification and elevated temperature on mussels are likely to have ecological and functional implications. This study is therefore helpful for better understanding the underlying effects of changing marine environments on mussels and other marine calcifiers. Summary: The interactive effects of climate stressors on marine calcifiers highlight the negative effect of elevated temperature based on seawater acidification.

The transcription factor Pf‐POU3F4 regulates expression of the matrix protein genes Aspein and Prismalin‐14 in pearl oyster (Pinctada fucata)

Matrix proteins play key roles in shell formation in the pearl oyster, but little is known about how these proteins are regulated. Here, two POU domain family members, Pf‐POU2F1 and Pf‐POU3F4, were cloned and characterized. Functional domain analysis revealed that both them have conserved POUS and POUH domains; these domains are important for transcription factor function. The tissue distributions of Pf‐POU2F1 and Pf‐POU3F4 mRNAs in pearl oyster revealed different expression patterns, and the expression of Pf‐POU3F4 mRNA was relatively high in the mantle. The promoters of the matrix protein genes Aspein and Prismalin‐14 were cloned using genome‐walking PCR. Relatively high transcriptional activities of these promoters were detected in HEK‐293T cells. In transient co‐transfection assays, Pf‐POU3F4 greatly up‐regulated the promoter activities of the Aspein and Prismalin‐14 genes in a dose‐dependent manner. Structural integrity of Pf‐POU3F4 was essential for its activation function. One region of the Aspein gene promoter, −181 to −77 bp, and two binding sites in the Prismalin‐14 gene promoter, −359 to −337 bp and −100 to −73 bp, were required for activation of Pf‐POU3F4. An electrophoresis mobility shift assay demonstrated that Pf‐POU3F4 directly bound these sites. Pf‐POU3F4 knockdown led to a decrease in Aspein and Prismalin‐14 gene expression. Furthermore, expression levels for the Pf‐POU3F4 gene were similar to those of the Aspein and Prismalin‐14 genes during five development stages. Taken together, these results suggest that the transcription factor Pf‐POU3F4 regulates expression of the matrix protein genes Aspein and Prismalin‐14 in pearl oyster.

Cloning and mineralization-related functions of the calponin gene in Chlamys farreri.

Calponin is a widely distributed protein which is associated with the bio-mineralization process in vertebrates. Recently, a new type of calponin has been found in shellfish; the present study aimed to determine if this gene in shellfish functions in bio-mineralization, one of the most important processes in a mollusks growth. We chose Chlamys farreri, a seashell species with great economic value, as the object of the study and obtained its full-length cDNA to study the function of calponin by gene expression analysis, shell notching experiment and RNA interference assays. Calponin in C. farreri is a basic protein that is highly conserved among mollusk species. Except for high expression in the adductor muscle and foot, which correlated with its function of regulating muscle contraction, the calponin gene was expressed more in the mantle than in other tissues. The expression of the gene was induced by shell notching and an RNA interference assay showed that inhibition of calponin expression caused the growth of irregular mineral crystals on the shell. Further analysis indicated that calponin might function by regulating the expression of other mineralization-related genes. Calponin is a mineralization-related protein in C. farreri that might influence mineral crystal growth by affecting the expressions of other proteins, such as matrix proteins and mineralization-regulating proteins.

Calcium carbonate mineralization mediated by in vitro cultured mantle cells from Pinctada fucata

Formation of the molluscan shell is believed to be an extracellular event mediated by matrix proteins. We report calcium carbonate mineralization mediated by Pinctada fucata mantle cells. Crystals only appeared when mantle cells were present in the crystallization solution. These crystals were piled up in highly ordered units and showed the typical characteristics of biomineralization products. A thin organic framework was observed after dissolving the crystals in EDTA. Some crystals had etched surfaces with a much smoother appearance than other parts. Mantle cells were observed to be attached to some of these smooth surfaces. These results suggest that mantle cells may be directly involved in the nucleation and remodeling process of calcium carbonate mineralization. Our result demonstrate the practicability of studying the mantle cell mechanism of biomineralization and contribute to the overall understanding of the shell formation process.

Identification and expression characterization of three Wnt signaling genes in pearl oyster (Pinctada fucata).

The Wnt signaling pathway plays an important role in animal development and in the biomineralization process. At present, although the biomineralization mechanism in pearl oyster (Pinctada fucata) has been extensively studied, there is little research on the Wnt signaling pathway in pearl oyster. To understand the potential role of the Wnt signaling pathway in pearl oyster, we cloned and sequenced three genes from the Wnt signaling pathway in pearl oyster that encode the following proteins: β-catenin, Dishevelled (Dvl) and T-cell factor (TCF). Genomic structure analysis revealed that Pf-β-catenin genomic DNA contained 15 exons, Pf-Dvl genomic DNA contained 16 exons, and Pf-TCF genomic DNA contained 7 exons. Their deduced amino acid sequences all showed the highest identity with homologs in Crassostrea gigas. Yeast two-hybrid analysis verified that Pf-β-catenin interacted with Pf-TCF. These three genes were ubiquitously expressed in seven pearl oyster tissues analyzed with the highest expression in the gill and a certain amount of expression in the mantle, a tissue related to shell formation. After shell notching, the dynamic changes in expression of these three genes showed that they reached a maximum at 4days, indicating their response to shell regeneration. All three genes were constitutively expressed during five developmental stages of the pearl oyster, with high levels at the early embryonic development stage. Taken together, these results suggested that Pf-β-catenin, Pf-Dvl and Pf-TCF might participate in shell formation and early embryonic and larval development in the pearl oyster.