Vitro culture of axe-head glochidia in pink heelsplitter Potamilus alatus and mechanism of its high host specialists.

The basal media M199 or MEM was utilized in the classical method of vitro culture of glochidia where 1-5% CO2 was required to maintain stable physiological pH for completion of non-parasitic metamorphosis. The classical method encounters a great challenge to those glochidia which undergo development of visceral tissue but significantly increase in size during metamorphosis. The improved in vitro culture techniques and classical methods were firstly compared for non-parasitic metamorphosis and development of glochidia in pink heelsplitter. Based on the improved method, the optimal vitro culture media was further selected from 14 plasmas or sera, realizing the non-parasitic metamorphosis of axe-head glochidia for the first time. The results showed that addition of different plasma (serum) had significant effect on glochidial metamorphosis in pink heelsplitter. Only glochidia in the skewband grunt and red drum groups could complete metamorphosis, the metamorphosis rate in skewband grunt was 93.3±3.1% at 24±0.5°C, significantly higher than in marine and desalinated red drum. Heat-inactivated treatment on the plasma of yellow catfish and Barbus capito had significant effect on glochidia survival and shell growth. The metamorphosis rate also varied among different gravid period, and generally decreased with gravid time. Further comparison of free amino acid and fatty acid indicated that the taurine of high concentration was the only amino acid that might promote the rapid growth of glochidial shell, and the lack of adequate DPA and DHA might be an important reason leading to the abnormal foot and visceral development. Combined with our results of artificial selection of host fish, we tentatively established the mechanism of its host specialists in pink heelsplitter for the first time. This is the first report on non-parasite metamorphosis of axe-head glochidia based on our improved vitro culture method, which should provide important reference to fundamental theory research of glochidia metamorphosis and also benefit for better understand of mechanism of host specialists and generalists of Unionidae species.

[Complement system and diabetic retinopathy].

The biological activities of complement system, which are activated mainly through classical pathway, alternative pathway and mannose-binding lectin pathway, include cytotoxicity, bacteriolysis, sterilization, cell regulation, immune adherence, neutralization and dissolution of virus and inflammatory mediators. It is well known that diabetic retinopathy (DR) is one of the common complications of diabetes mellitus and is the leading cause of blindness among working-age adults in the developed countries and regions, but the mechanism underlying its pathogenesis is not yet fully understood. Until now, numbers of studies showed that the activation of complement system is involved in the pathogenesis of DR. Naturally, these finding paves a way for the prevention and treatment of DR in the future.