ABSTRACT
Viruses, such as white spot syndrome virus, and bacteria, such as Vibrio species, wreak havoc in shrimp aquaculture [C. M. Escobedo-Bonilla et al., J. Fish. Dis. 31, 1-18 (2008)]. As the main portal of entry for shrimp-related pathogens remain unclear, infectious diseases are difficult to prevent and control. Because the cuticle is a strong pathogen barrier, regions lacking cuticular lining, such as the shrimp's excretory organ, "the antennal gland," are major candidate entry portals [M. Corteel et al., Vet. Microbiol. 137, 209-216 (2009)]. The antennal gland, up until now morphologically underexplored, is studied using several imaging techniques. Using histology-based three-dimensional technology, we demonstrate that the antennal gland resembles a kidney, connected to a urinary bladder with a nephropore (exit opening) and a complex of diverticula, spread throughout the cephalothorax. Micromagnetic resonance imaging of live shrimp not only confirms the histology-based model, but also indicates that the filling of the diverticula is linked to the molting cycle and possibly involved therein. Based on function and complexity, we propose to rename the antennal gland as the "nephrocomplex." By an intrabladder inoculation, we showed high susceptibility of this nephrocomplex to both white spot syndrome virus and Vibrio infection compared to peroral inoculation. An induced drop in salinity allowed the virus to enter the nephrocomplex in a natural way and caused a general infection followed by death; fluorescent beads were used to demonstrate that particles may indeed enter through the nephropore. These findings pave the way for oriented disease control in shrimp.
Subject(s)
Molting/physiology , Penaeidae/microbiology , Penaeidae/virology , Sebaceous Glands/microbiology , Sebaceous Glands/pathology , Animals , Aquaculture , Salinity , Sebaceous Glands/diagnostic imaging , Sebaceous Glands/virology , Vibrio/pathogenicity , Vibrio Infections/pathology , Vibrio Infections/veterinary , Virus Internalization , White spot syndrome virus 1/pathogenicityABSTRACT
One of the most characteristic pathological changes in cats that have succumbed to feline infectious peritonitis (FIP) is a multifocal granulomatous phlebitis. Although it is now well established that leukocyte extravasation elicits the inflammation typically associated with FIP lesions, relatively few studies have aimed at elucidating this key pathogenic event. The upregulation of adhesion molecules on the endothelium is a prerequisite for stable leukocyte-endothelial cell (EC) adhesion that necessarily precedes leukocyte diapedesis. Therefore, the present work focused on the expression of the EC adhesion molecules and possible triggers of EC activation during the development of FIP. Immunofluorescence analysis revealed that the endothelial expression of P-selectin, E-selectin, intercellular adhesion molecule 1 (ICAM-1) and vascular cell adhesion molecule 1 (VCAM-1) was elevated in veins close to granulomatous infiltrates in the renal cortex of FIP patients compared to non-infiltrated regions and specimens from healthy cats. Next, we showed that feline venous ECs become activated when exposed to supernatant from feline infectious peritonitis virus (FIPV)-infected monocytes, as indicated by increased adhesion molecule expression. Active viral replication seemed to be required to induce the EC-stimulating activity in monocytes. Finally, adhesion assays revealed an increased adhesion of naive monocytes to ECs treated with supernatant from FIPV-infected monocytes. Taken together, our results strongly indicate that FIPV activates ECs to increase monocyte adhesion by an indirect route, in which proinflammatory factors released from virus-infected monocytes act as key intermediates.
Subject(s)
Cell Adhesion Molecules/genetics , Coronavirus, Feline/physiology , Endothelial Cells/virology , Feline Infectious Peritonitis/virology , Kidney Cortex/virology , Monocytes/virology , Animals , Cats , Cell Adhesion , Cell Adhesion Molecules/immunology , Cells, Cultured , Coronavirus, Feline/genetics , E-Selectin/genetics , E-Selectin/immunology , Endothelial Cells/cytology , Endothelial Cells/immunology , Feline Infectious Peritonitis/genetics , Feline Infectious Peritonitis/immunology , Feline Infectious Peritonitis/physiopathology , Intercellular Adhesion Molecule-1/genetics , Intercellular Adhesion Molecule-1/immunology , Kidney Cortex/cytology , Kidney Cortex/immunology , Monocytes/immunology , P-Selectin/genetics , P-Selectin/immunology , Up-Regulation , Vascular Cell Adhesion Molecule-1/genetics , Vascular Cell Adhesion Molecule-1/immunologyABSTRACT
The replication cycle of white spot syndrome virus (WSSV) was investigated in secondary cell cultures from the lymphoid organ of Litopenaeus vannamei. The secondary cells formed a confluent monolayer at 24âh post-reseeding, and this monolayer could be maintained for 10âdays with a viability of 90 %. Binding of WSSV to cells reached a maximum (73 ± 3 % of cells and 4.84 ± 0.2 virus particles per virus-binding cell) at 120âmin at 4 °C. WSSV entered cells by endocytosis. The co-localization of WSSV and early endosomes was observed starting from 30âmin post-inoculation (p.i.). Double indirect immunofluorescence staining showed that all cell-bound WSSV particles entered these cells in the period between 0 and 60âmin p.i. and that the uncoating of WSSV occurred in the same period. After 1âh inoculation at 27 °C, the WSSV nucleocapsid protein VP664 and envelope protein VP28 started to be synthesized in the cytoplasm from 1 and 3âh p.i., and were transported into nuclei from 3 and 6âh p.i., respectively. The percentage of cells that were VP664- and VP28-positive in their nuclei peaked (50 ± 4 %) at 12âh p.i. Quantitative PCR showed that WSSV DNA started to be synthesized from 6âh p.i. In vivo titration of the supernatants showed that the progeny WSSV were released from 12âh p.i. and peaked at 18âh p.i. In conclusion, the secondary cell cultures from the lymphoid organ were proven to be ideal for examination of the replication cycle of WSSV.
Subject(s)
Cell Culture Techniques/methods , Penaeidae/virology , Virus Replication , White spot syndrome virus 1/physiology , Animals , Cell Culture Techniques/instrumentation , Cell Nucleus/virology , Lymphoid Tissue/virology , Nucleocapsid Proteins/genetics , Nucleocapsid Proteins/metabolism , Viral Envelope Proteins/genetics , Viral Envelope Proteins/metabolism , White spot syndrome virus 1/geneticsABSTRACT
A stable culture of primary porcine enterocytes is necessary to study porcine enteric virus replication characteristics. Because the direct cultivation of primary porcine enterocytes is difficult, alternatives have to be considered. As subepithelial myofibroblasts secrete extracellular matrix and growth factors contributing to the attachment, proliferation and differentiation of epithelial cells, co-cultures of primary porcine enterocytes (ileocytes and colonocytes) with myofibroblasts were developed and evaluated for their susceptibility to enteric viruses. First, it was demonstrated that the co-cultured ileocytes and colonocytes were susceptible to an archival rotavirus strain RVA/pig-tc/BEL/RV277/1977/G1P[7] and different other rotavirus genotypes (fecal samples containing G5P[7], G5P[13], G9P[23], G4P[6]). Next, the TGEV Purdue strain infected both ileocytes and colonocytes whereas the Miller strain only infected ileocytes. Last, the PEDV CV777 Vero adapted and non-adapted (fecal suspension) strains could infect co-cultured ileocytes but not colonocytes. The infectivity of the CV777 Vero adapted strain was higher when the cells were cultured without fetal bovine serum and the CV777 fecal suspension only infected the ileocytes cultured without fetal bovine serum. In conclusion, a novel co-culture of porcine enterocytes with myofibroblasts was established, which can be used for the investigation of the replication of enteric viruses.