LIPOPHAGY: a novel form of steroidogenic activity within the LEYDIG cell during the reproductive cycle of turtle.

BACKGROUND: Steroidogenesis is an indispensable process that is indirectly associated with spermatogenesis in the Leydig cell (LC) to utilize the lipid droplets (LDs) that are critical to maintaining normal testosterone synthesis. The regulation of LD mobilization, known as lipophagy, in the LC is still largely unknown. METHOD: In the present study, the LC of the Chinese soft-shelled turtle was investigated to identify the steroidogenic activity and lipophagy during the annual reproductive cycle by light microscopy, immunohistochemistry (IHC), immunofluorescence (IF), and transmission electron microscopy (TEM). RESULTS: The LC showed a dynamic steroidogenic function with strong activity of 3ß-HSD, vimentin and tubular ER during hibernation by IHC and TEM. The tubulo-vesicular ER had a weak immunopositive reaction for 3ß-HSD in the LC during reproductive phase, suggesting persistent steroidogenic activity. ORO staining and TEM demonstrated that a larger number of LDs had accumulated in the LC during hibernation than in the reproductive phase. These LDs existed in close association with mitochondria and lysosomes by being dynamically surrounded by intermediate filaments to facilitate LD utilization. Lysosomes were found directly attached to large LDs, forming an autophagic tube and engulfing LDs, suggesting that micro-lipophagy occurs during hibernation. Furthermore, the IHC of ATG7 (Autophagy Related Gene 7) and the IF of the LC3 (Microtubule-associated protein light chain 3), p62 (Sequestosome-1 (SQSTM1) and LAMP1(Lysosomal-associated membrane protein 1) results demonstrated strong expression, and further confirmation by TEM showed the existence of an autophagosome and an autolysosome and their fusion during the hibernation season. CONCLUSION: In conclusion, the present study provides clear evidence of LD consumption in the LC by lipophagy, lysosome and mitochondria during the hibernation period, which is a key aspect of steroidogenesis in the Chinese soft-shelled turtle.

The dynamic distribution of duck Tembusu virus in the spleen of infected shelducks.

BACKGROUND: Duck Tembusu virus (DTMUV) is a novel member of Flavivirus. The isolated and purified DTMUV strain XZ-2012 was used as a strain model, to intramuscularly inject the six-month egg-laying shelducks with the infective dose of 104TCID50. The dynamic distribution of the virus in spleen at different time post-infection (pi) was studied using RT-PCR, RT-qPCR, ELISA, immunofluorescence and transmission electron microscopy (TEM). RESULT: The results showed that the virus occurred in the spleen after 2 hpi and lasted up to 18 dpi. The registered viral load increased from 2 hpi to 3 dpi, and then it diminished from 6 dpi to 18 dpi with a slight rise at 12 dpi. From 2 hpi to 6 dpi the DTMUV particles were mostly distributed in the periellipsoidal lymphatic sheath (PELS) of spleen white pulp, few being found in the sheathed capillary. From 9 dpi to 18 dpi, the DTMUV particles were migrating into periarterial lymphatic sheaths (PALS) around the central artery through the red pulp. Under TEM, the virus particles could be observed mostly in lymphocytes and macrophages. CONCLUSION: It was suggested that DTMUV invaded lymphocytes and macrophages of the spleen at 2 hpi and replicated significantly from 1 dpi to 3 dpi, being eliminated from 9 dpi to 18 dpi. This is the first study on the dynamic distribution of DTMUV from invasion to elimination in duck spleen conducted by molecular and morphological methods. It could provide theoretical basis for the occurrence, development and detoxification of the virus in the organs of the immune system.

In vivo cellular and molecular study on duck spleen infected by duck Tembusu virus.

Duck Tembusu virus (DTMUV) is a novel member of flavivirus with the highest viral loads in the spleen. Six-month egg-laying shelducks were intramuscularly injected with DTMUV strain XZ-2012. Morphological analysis revealed the presence of vacuolar degeneration in the periellipsoidal lymphatic sheaths (PELS) of spleen white pulp following infection, especially from 12 hpi to 3 dpi. Ultrastructural images showed an obvious swelling of cells and their mitochondria and endoplasmic reticulum. Using RNA-seq analysis, the expression levels of RIG-I like receptors (RLRs), downstream IRF7 and proinflammatory cytokines IL-6 from RIG-I signaling pathway were non-apparently upregulated at 2 hpi and apparently at 3 dpi, while MHC-II expression was obviously downregulated at 2 hpi. The expression levels of downstream antiviral cytokines type-I IFNs, anti-inflammatory cytokines IL-10, cell adhesion molecules (CAMs), chemokines and their receptors associated with lymphocyte homing were significantly upregulated at 3 dpi. The population of lymphocyte was increased at 6 dpi. The immune function of spleen was recovered starting from 9 dpi. These findings of this study suggest that DTMUV invaded into the spleen via RIG-I signaling pathway and enhanced immune evasion by inhibiting MHC-II expression during the early stage of infection. Additionally, DTMUV induced PELS lesions through activating IL-6 expression. Furthermore, DTMUV increased the expression levels of RLRs, antiviral type-I IFNs, lymphocyte homing-related genes and proteins as well as the number of lymphocytes in the infected duck spleen. Taken altogether, this study provides new insights into the cellular and molecular mechanisms of DTMUV infection in duck spleen.

The novel histological evidence of the blood-spleen barrier in duck (Anas platyrhynchos).

To identify the existence and composition of the blood-spleen barrier (BSB) in ducks, the microanatomical structures of the duck spleen were investigated by light and transmission electron microscopy, silver staining, enzymatic histochemistry and intravenous injection of ink. The endothelial cells of the sheathed capillaries were cuboidal-shaped and surrounded by an ellipsoid consisting of reticular cells, similar to high endothelial venules (HEVs). After ink injection, carbon particles were initially restricted to the ellipsoid and later trapped in the periellipsoidal lymphatic sheaths (PELS), and then transferred to the periarteriolar lymphatic sheaths (PALS) and splenic nodules over time. Reticular fibers were primarily distributed at the basement membrane of the sheathed capillaries and the periphery of the PELS. Macrophages were primarily distributed at the border between red pulp and PELS. These results suggested that the BSB was present in the ellipsoid and PELS and consisted of the mechanical barrier composed of endothelial cells of the sheathed capillaries, reticular cells and reticular fibers and the biological barrier composed of ellipsoid-associated macrophages. In conclusion, the BSB was identified in the duck spleen for the first time, including cuboidal endothelial cells, ellipsoid-associated macrophages, reticular cells and fibers, and resisting circulating pathogen invasions. The study of BSB in ducks provides a theoretical foundation for the structural composition of the avian immune system.

In vivo dynamic distribution of multivesicular bodies and exosomes in spleen of DTMUV infected duck.

Exosomes are vesicles secreted by the multivesicular bodies (MVBs), which have been shown to mediate immunity regulation and virus transmission. In this study, the dynamic distribution and function of the MVBs and their exosomes was investigated through morphological characterization and molecular analyses in duck spleens infected with duck Tembusu virus (DTMUV) at different times post infection (1hpi, 2hpi, 12hpi, 24hpi). CD63, the marker of MVBs and exosomes, was distributed in the sheathed capillaries and the periellipsoidal lymphatic sheaths (PELS) of the white pulp. The numbers of MVBs and their exosomes were dramatically increased at 2 hpi, and with the increasing infection time, the numbers of MVBs and their exosomes were gradually decreased. DTMUV proteins were associated with exosomes according to double label immunofluorescence results. Ultrastructural characterization by transmission electron microscopy revealed four developing stages of MVBs containing exosomes were detected in high endothelial cells of the sheathed capillaries, lymphocytes and the ellipsoid-associated macrophages in PELS. Free exosomes were observed in the extracellular matrix and the blood vessels. Genes and proteins related to the endocytosis pathway were obviously up-regulated at 2 hpi as confirmed by RT-qPCR and western blotting. We speculated that DTMUV mediates host invasion through the endocytosis pathway by utilizing MVBs and their exosomes. The in vivo distribution pattern of MVBs and their exosomes in DTMUV infected spleens is shown for the first time in this study. This report could lay the foundations for understanding the infection mechanism of DTMUV.