Optimal age of the donor graft tissue in relation to cultured pearl phenotypes in the mollusc, Pinctada margaritifera

Research progress on formation mechanism of pearl

Pearls are deeply cherished for their rich color and gorgeous luster, and their quality directly affects their value. Currently, the evaluation of pearl quality is mainly based on four aspects: color, shape, size and smoothness. The quality of pearls is influenced by a variety of factors, categorized into internal factors, such as the structural composition of the nacreous layer and genetic factors of the mussels, and external factors, including the aquaculture environment. Existing research results indicates that genetic factors are the dominant factor controlling the pearl quality. However, the macromolecules such as metal ions, organic pigments and various physical and chemical factors in the aquaculture water environment will also significantly impact pearl quality. Among these, matrix proteins are organic macromolecules found in the nacreous layer that play an important role in pearl quality. They participate in the deposition of calcium carbonate and the construction of the organic framework, affecting the pearls' size and shape. The color of pearls is influenced by the deposition of metal ions, the transport of organic pigments and the regulation of microstructure.

Towards a better understanding of allograft-induced stress response in the pearl oyster Pinctada fucata martensii: Insights from iTRAQ-based comparative proteomic analysis

Implantation of a spherical nucleus into a recipient oyster is a critical step in artificial pearl production. The implanted nucleus is known to trigger cellular stress responses at several levels, yet the molecular mechanism underpinning physiological adaptation of the pearl oysters to nucleus implantation is still poorly understood. In this study, we took advantage of the iTRAQ-based proteomics and LC-MS/MS approach to look into allograft induced gene regulation at the protein expression level in the pearl oyster Pinctada fucata martensii, across a period of 30 days following nucleus implantation. A wide variety of proteins, including a group of immune-related proteins such as E3 ubiquitin-ligase and heat shock proteins, exhibited differential expression in response to the surgical operation. Further comparisons between different sampling points revealed that GO terms including "translation" and "oxidation-reduction process" and KEGG pathways including "glycolysis/gluconeogenesis" and "pyruvate metabolism" were significantly enriched at several time points, indicating the important roles of these molecular events in the stress response of pearl oysters to nucleus implantation. In addition, considerable discrepancy between protein expression level and gene transcript abundancy was identified, as only a few genes showed at least 2-fold expression changes at both proteomic and transcriptomic levels. The result implies that post-transcriptional gene regulation for the key proteins may represent an important aspect of allograft-induced stress response in the pearl oysters. Taken together, the data obtained would contribute to a deeper understanding of the molecular mechanisms enabling stress adaptation of the pearl oysters in response to nucleus implantation.

Whole transcriptome sequencing and biomineralization gene architecture associated with cultured pearl quality traits in the pearl oyster, Pinctada margaritifera

Background

Cultured pearls are unique gems produced by living organisms, mainly molluscs of the Pinctada genus, through the biomineralization properties of pearl sac tissue. Improvement of P. margaritifera pearl quality is one of the biggest challenges that Polynesian research has faced to date. To achieve this goal, a better understanding of the complex mechanisms related to nacre and pearl formation is essential and can now be approached through the use of massive parallel sequencing technologies. The aim of this study was to use RNA-seq to compare whole transcriptome expression of pearl sacs that had producing pearls with high and low quality. For this purpose, a comprehensive reference transcriptome of P. margaritifera was built based on multi-tissue sampling (mantle, gonad, whole animal), including different living stages (juvenile, adults) and phenotypes (colour morphotypes, sex).

Results

Strikingly, few genes were found to be up-regulated for high quality pearls (n = 16) compared to the up-regulated genes in low quality pearls (n = 246). Biomineralization genes up-regulated in low quality pearls were specific to prismatic and prism-nacre layers. Alternative splicing was further identified in several key biomineralization genes based on a recent P. margaritifera draft genome.

Conclusion

This study lifts the veil on the multi-level regulation of biomineralization genes associated with pearl quality determination.

Electronic supplementary material

The online version of this article (10.1186/s12864-019-5443-5) contains supplementary material, which is available to authorized users.