Intraluminal proteolytic activation plays an important role in replication of type 1 reovirus in the intestines of neonatal mice.

Oral inoculation of suckling mice with reovirus serotype 1 (strain Lang) results in the conversion of intact virions to intermediate subviral particles (ISVPs) in the intestinal lumen. Digestion of virus in vitro with chymotrypsin or trypsin reveals two distinct forms of ISVPs, while the predominant species of ISVPs found in the small intestinal lumen appears to be identical to the chymotrypsin product. The in vivo conversion of virions to ISVPs was blocked by pretreatment of mice with protease inhibitors, resulting in inefficient replication of reovirus in intestinal tissue. The early inhibition of viral replication in suckling mice pretreated with protease inhibitors was not observed when suckling mice were inoculated with ISVPs generated by in vitro digestion with either chymotrypsin or trypsin. However, replication was decreased during secondary rounds of replication in mice receiving repeated doses of protease inhibitors, suggesting that luminal proteolytic digestion is important in rendering progeny virions infectious in the gut.     

Infectious subvirion particles of reovirus type 3 Dearing exhibit a loss in infectivity and contain a cleaved sigma 1 protein.

Mammalian reoviruses exhibit differences in the capacity to grow in intestinal tissue: reovirus type 1 Lang (T1L), but not type 3 Dearing (T3D), can be recovered in high titer from intestinal tissue of newborn mice after oral inoculation. We investigated whether in vitro protease treatment of virions of T1L and T3D, using conditions to generate infectious subvirion particles (ISVPs) as occurs in the intestinal lumen of mice (D. K. Bodkin, M. L. Nibert, and B. N. Fields, J. Virol. 63:4676-4681, 1989), affects viral infectivity. Chymotrypsin treatment of T1L was associated with a 2-fold increase in viral infectivity, whereas identical treatment of T3D resulted in a 10-fold decrease in infectivity. Using sodium dodecyl sulfate-polyacrylamide gel electrophoresis, we found that loss of T3D infectivity was correlated with cleavage of its sigma 1 protein. We used reassortant viruses to identify viral determinants of infectivity loss and sigma 1 cleavage and found that both phenotypes segregate with the sigma 1-encoding S1 gene. Comparable results were obtained when trypsin treatment of virions of T1L and T3D was used. In experiments to determine the fate of sigma 1 fragments following cleavage, the capacity of anti-sigma 1 monoclonal antibody G5 to neutralize infectivity of T3D ISVPs was significantly decreased in comparison with its capacity to neutralize infectivity of virions, suggesting that a sigma 1 domain bound by G5 is lost from viral particles after proteolytic digestion. In contrast to the decrease in infectivity, chymotrypsin treatment of T3D virions leading to generation of ISVPs resulted in a 10-fold increase in their capacity to produce hemagglutination, indicating that a domain of sigma 1 important for binding to sialic acid remains associated with viral particles after sigma 1 cleavage. Neuraminidase treatment of L cells substantially decreased the yield of T3D ISVPs in comparison with the yield of virions, indicating that a sigma 1 domain important for binding sialic acid also can mediate attachment of T3D ISVPs to L cells and lead to productive infection. These results suggest that cleavage of T3D sigma 1 protein following oral inoculation of newborn mice is at least partly responsible for the decreased growth of T3D in the intestine and provide additional evidence that T3D sigma 1 contains more than a single receptor-binding domain.     

Growth and survival of reovirus in intestinal tissue: role of the L2 and S1 genes.

Reovirus serotype 1 Lang can be recovered in high titer from the intestines of neonatal mice up to day 8 after peroral inoculation. By contrast, reovirus serotype 3 Dearing cannot be recovered from intestinal tissue past day 4 after peroral inoculation. This difference between the two reoviruses was mapped by using reassortants generated from nonmutagenized laboratory stocks. When the L2 and S1 genes of reovirus serotype 3 Dearing were present in reassortants, the reassortants behaved like serotype 3 Dearing in exhibiting a decreased capacity to be recovered from intestinal tissue. Likewise, viruses which contained the L2 and S2 genes from serotype 1 Lang exhibited an enhanced capacity to grow and survive, which is characteristic of serotype 1 Lang. Thus, the capacity of reovirus to survive in intestinal tissue was determined by the L2 and S1 genes.     

Proteolytic processing of reovirus is required for adherence to intestinal M cells.

Reovirus adheres specifically to apical membranes of mouse intestinal M cells and exploits M-cell transepithelial transport activity to enter Peyer's patch mucosa, where replication occurs. Proteolytic conversion of native reovirus to intermediate subviral particles (ISVPs) occurs in the intestine, but it is not known whether conversion is essential for interaction of virus with M cells. We tested the capacity of native virions, ISVPs, and cores (that lack outer capsid proteins) to bind to intestinal epithelial cells in vivo and found that only ISVPs adhered to M cells. Thus, intraluminal conversion of native reovirus to ISVPs is a prerequisite for M-cell adherence, and outer capsid proteins unique to ISVPs (either sigma 1 or products of mu 1) mediate interaction of virus with M-cell apical membranes.     

Brain- and intestine-specific variants of reovirus serotype 3 strain dearing are selected during chronic infection of severe combined immunodeficient mice.

Mutants of mammalian reoviruses, enteric double-stranded-RNA-containing viruses that spread systemically after primary replication in intestinal tissue, have been extensively studied as models of viral pathogenesis. While reovirus serotype 3 strain Dearing (T3D) causes acute encephalitis in newborn mice, adult severe combined immunodeficient (SCID) mice develop chronic infection with T3D, with some mice living more than 100 days after infection (B. L. Haller, M. L. Barkon, G. P. Vogler, and H. W. Virgin IV, J. Virol. 69:357-364, 1995). To determine whether organ-specific reovirus variants are selected during chronic infection, we characterized the pathogenetic properties of two variants of T3D isolated 87 days after intraperitoneal infection of adult SCID mice. A brain-specific variant (T3DvBr) (i) grew to a higher titer than T3D in SCID mouse brain (but not intestine) after intraperitoneal inoculation, (ii) killed adult SCID mice faster than T3D, and (iii) grew well in neonatal NIH Swiss [NIH(s)] mouse brain tissue after intramuscular but not peroral inoculation. An intestine-specific variant (T3DvInt) (i) grew to a higher titer than T3D in SCID mouse intestine (but not brain) after intraperitoneal inoculation, (ii) killed SCID mice with kinetics equivalent to those of T3D, (iii) was much less virulent than T3D in neonatal NIH(s) mice, (iv) grew better than T3D in intestines after intramuscular or peroral inoculation into neonatal NIH(s) mice, and (v) grew poorly in brain tissue of neonatal NIH(s) mice after intramuscular inoculation. During prolonged infection of SCID mice, organ-specific variants of T3D, which are more efficient than wild-type T3D at one specific stage in reovirus pathogenesis, are selected.     

Group A Rotavirus Infection and Age-Dependent Diarrheal Disease in Rats: a New Animal Model To Study the Pathophysiology of Rotavirus Infection

Group A rotaviruses are major pathogens causing acute gastroenteritis in children and animals. To determine if group A rotavirus replicates and induces disease in rats, antibody-negative Lewis neonatal or adult rats were inoculated orally with tissue culture-adapted human (Wa, WI61, and HAL1166), simian (rhesus rotavirus [RRV] and SA11), bovine (WC3), lapine (ALA), or porcine (OSU) rotavirus strains, wild-type murine (EC(wt)) rotavirus strain, or phosphate-buffered saline (PBS). Rotavirus infection in rats was evaluated by (i) clinical findings, (ii) virus antigen shedding or infectious virus titers in the feces or intestinal contents measured by enzyme-linked immunosorbent assay or fluorescent-focus assay, (iii) histopathological changes in the small intestine, (iv) distribution of rotavirus antigen in small-intestine sections by immunofluorescence, and (v) growth rate. Rotavirus infection of 5-day-old but not > or =21-day-old rats resulted in diarrhea that lasted from 1 to 10 days postinoculation. The severity of disease and spread of infection to naIve littermates differed depending on the virus strain used for inoculation. The duration of virus antigen shedding following infection was considerably prolonged (up to 10 days) in neonatal rats compared to that in 21-day-old rats (1 or 2 days). Based on lack of virus antigen shedding and disease induction, the murine EC(wt) rotavirus was the only strain tested that did not infect rats. Histopathological changes in the small-intestine mucosa of 5-day-old RRV-inoculated rats but not of PBS-inoculated rats was limited to extensive enterocyte vacuolation in the ileum. In RRV-inoculated neonatal rats, rotavirus antigen was detected in the epithelial cells on the upper half of the intestinal villi of the jejunum and ileum. In addition, infection of neonatal rats with RRV but not with PBS resulted in reduced weight gain. Rats infected with group A rotaviruses provide a new animal model with unique features amenable to investigate rotavirus pathogenesis and the molecular mechanisms of intestinal development, including physiological factors that may regulate age-dependent rotavirus-induced diarrhea.     

An Adenovirus Isolated from the Feces of Mice

Experimental infection of an inbred strain of DK1 mice was carried out with a mouse adenovirus strain K87, isolated from the feces of apparently healthy DK1 mice. Strain K87 was orally administered to four-week-old mice and the virus was recovered from their feces for at least 3 weeks. The highest virus titers in the feces were observed between 1 and 2 weeks after inoculation. In 7-week-old mice the period of virus excretion was about one week shorter. When neonatal or 2-week-old mice were administered virus orally, somewhat irregular results but similar to those from the 4 or 7-week-old mice were obtained. In these infected mice, virus growth was detected in the intestinal tract but not in oropharyngeal washings, nasal tissue, lung, spleen or urine. After inoculation through several parenteral routes, the virus was also detected in the feces and virus growth seemed to be limited mainly to the intestinal tract. No clinical manifestations were observed in any infected mice. When the virus was almost undetectable in the mice infected either orally or parenterally, the virus was readministered orally, but no further virus was recovered in the feces. Neutralizing antibody in the serum was detected 3 weeks after primary inoculation. Induction of immunological tolerance was examined by inoculating mice in utero 2–4 days before birth, but no evidence of induced tolerance was obtained. The use of the adenovirus strain K87-mouse system as a model system for the study of the infectious process and immune mechanisms is suggested because strain K87 has a tissue tropism analogous to many human adenoviruses.     

A glycosyl hydrolase activity of mammalian reovirus sigma1 protein can contribute to viral infection through a mucus layer

The mammalian reovirus sigma1 protein is responsible for viral attachment to host cells and hemagglutination properties of the virus. In the present study, sequence similarity between sigma1 and chicken-type lysozymes prompted us to investigate additional functions of the sigma1 protein. Expression in Pichia pastoris yeast cells showed that sigma1 can actually cleave lysozyme substrates, including complex sugars found in bacterial cell walls. Replacement by site-directed mutagenesis of acidic amino acid residues in sigma1 by their respective isosteric, uncharged, amino acid residues has allowed us to identify Glu36 and Asp54 as the catalytic pair involved in sigma1-mediated glycosidase activity. The enzyme appears inactive in virions but its activity is unmasked upon generation of infectious subviral particles (ISVPs) by partial proteolytic removal of the outer capsid proteins. Purified sigma1 protein and ISVPs can also hydrolyze mucins, heavily glycosylated glycoproteins that are a major component of the mucus layer overlaying the intestinal epithelium. Furthermore, reovirus infection of epithelial Madin Darby canine kidney cells was inhibited tenfold in cells expressing mucin at their apical surface, while this inhibition was overcome by ISVPs. Unmasking of sigma1 mucinolytic activity in the intestine, consecutive to proteolytic cleavage of virions to ISVPs, thus likely contributes to the known increase in infectivity of reovirus ISVPs compared to complete virions. This work presents the first evidence that some mammalian viruses have evolved mechanisms to facilitate their penetration through the protective barrier of the mucus layer in the intestinal tract.     

A single mutation in the carboxy terminus of reovirus outer-capsid protein sigma 3 confers enhanced kinetics of sigma 3 proteolysis,resistance to inhibitors of viral disassembly,and alterations in sigma 3 structure

Mammalian reoviruses undergo acid-dependent proteolytic disassembly within endosomes, resulting in formation of infectious subvirion particles (ISVPs). ISVPs are obligate intermediates in reovirus disassembly that mediate viral penetration into the cytoplasm. The initial biochemical event in the reovirus disassembly pathway is the proteolysis of viral outer-capsid protein sigma 3. Mutant reoviruses selected during persistent infection of murine L929 cells (PI viruses) demonstrate enhanced kinetics of viral disassembly and resistance to inhibitors of endocytic acidification and proteolysis. To identify sequences in sigma 3 that modulate acid-dependent and protease-dependent steps in reovirus disassembly, the sigma 3 proteins of wild-type strain type 3 Dearing; PI viruses L/C, PI 2A1, and PI 3-1; and four novel mutant sigma 3 proteins were expressed in insect cells and used to recoat ISVPs. Treatment of recoated ISVPs (rISVPs) with either of the endocytic proteases cathepsin L or cathepsin D demonstrated that an isolated tyrosine-to-histidine mutation at amino acid 354 (Y354H) enhanced sigma 3 proteolysis during viral disassembly. Yields of rISVPs containing Y354H in sigma3 were substantially greater than those of rISVPs lacking this mutation after growth in cells treated with either acidification inhibitor ammonium chloride or cysteine protease inhibitor E64. Image reconstructions of electron micrographs of virus particles containing wild-type or mutant sigma 3 proteins revealed structural alterations in sigma 3 that correlate with the Y354H mutation. These results indicate that a single mutation in sigma 3 protein alters its susceptibility to proteolysis and provide a structural framework to understand mechanisms of sigma 3 cleavage during reovirus disassembly.     

Adult worms of the rodent intestinal nematode,Strongyloides venezuelensis,successfully invade chick intestinal mucosa

In order to study the mucosal invasion of a rodent intestinal nematode in bird intestine, chicks were infected with the intestinal nematode of rodents, Strongyloides venezuelensis, by subcutaneous larva inoculation and adult worm implantation. No evidence was obtained for larvae reaching the lungs or the intestine after infective larva inoculation. Adult worms implanted in the small intestine invaded the mucosa and remained there at least for 24 h, whereas those implanted in the caecum were trapped by mucus, and did not invade the mucosa. Mucosal invasion of adult worms in the small intestine was confirmed by histological examination. The number of adult worms in the intestinal mucosal tissue dropped rapidly within the first 24 h, which was associated with infiltrating granulocytes around the worms. The present study suggests that S. venezuelensis adult worms are able to invade the intestinal tissue of chicks, which do not belong to the vertebrate class of its normal definitive host, but that they are eliminated rapidly by mucosal defense system of the bird.     

Marked endotheliotropism of highly pathogenic avian influenza virus H5N1 following intestinal inoculation in cats

Highly pathogenic avian influenza virus (HPAIV) H5N1 can infect mammals via the intestine; this is unusual since influenza viruses typically infect mammals via the respiratory tract. The dissemination of HPAIV H5N1 following intestinal entry and associated pathogenesis are largely unknown. To assess the route of spread of HPAIV H5N1 to other organs and to determine its associated pathogenesis, we inoculated infected chicken liver homogenate directly into the intestine of cats by use of enteric-coated capsules. Intestinal inoculation of HPAIV H5N1 resulted in fatal systemic disease. The spread of HPAIV H5N1 from the lumen of the intestine to other organs took place via the blood and lymphatic vascular systems but not via neuronal transmission. Remarkably, the systemic spread of the virus via the vascular system was associated with massive infection of endothelial and lymphendothelial cells, resulting in widespread hemorrhages. This is unique for influenza in mammals and resembles the pathogenesis of HPAIV infection in terrestrial poultry. It contrasts with the pathogenesis of systemic disease from the same virus following entry via the respiratory tract, where lesions are characterized mainly by necrosis and inflammation and are associated with the presence of influenza virus antigen in parenchymal, not endothelial cells. The marked endotheliotropism of the virus following intestinal inoculation indicates that the pathogenesis of systemic influenza virus infection in mammals may differ according to the portal of entry.     

Growth Characteristics of Cytomegalovirus in Human Fibroblasts with Demonstration of Protein Synthesis Early in Viral Replication

In high-multiplicity infection of human fibroblasts, human cytomegalovirus of WI-38 human diploid cells produced early cell rounding 6 to 24 h after inoculation. This early cell rounding was caused only by inoculation with infectious virions. Inhibitors of protein synthesis, but not DNA inhibitors, prevented this cytopathic effect. Apparently, a new protein is synthesized in infected fibroblasts from about 2 h postinoculation. Infectivity of cell-associated and supernatant infectious virus reached maximal levels at 5 to 7 and 10 days postinoculation, respectively. Synthesis of DNA, infectious virus, complement-fixing antigen, and precipitin antigen all began between 24 and 48 h, with the bulk of synthesis occurring 48 to 96 h postinoculation.     

The acquirement of growth ability for third-stage larvae of Strongyloides ratti during the head-passage in the rat

The role of larval passage through the head in the course of the migration of Strongyloides ratti in rats was investigated. Third-stage larvae (L3) recovered from various portions of donor rats were re-injected into the skin, cranial cavity and small intestine of recipient rats to check their ability for further growth. Cultured L3 (L3c) and the L3 recovered from the skin of donor rats (L3s) did not survive in the small intestine after intestinal inoculation. However, intestinal inoculation of L3 recovered from the head of donor rats (L3h) revealed growth to the adult stage. Cultured L3 injected into the cranial cavity of rats also became adult worms in the small intestine. L3 incubated in the cranial cavity for more than 24 h could grow in the small intestine of the recipient rats. These experiments suggest that S. ratti L3 acquire their ability to mature in the small intestine during their migration through the head of rats.     

Circulating immunoglobulin G can play a critical role in clearance of intestinal reovirus infection.

Reoviruses are encapsidated double-stranded RNA viruses that cause systemic disease in mice after peroral (p.o.) inoculation and primary replication in the intestine. In this study, we define components of the immune system involved in the clearing of reovirus from the proximal small intestine. The intestines of immunocompetent adult CB17, 129, and C57BL/6 mice were cleared of reovirus serotype 3 clone 9 (T3C9) within 7 days of p.o. inoculation. Antigen-specific lymphocytes were important for the clearance of intestinal infection, since severe combined immunodeficient (SCID) mice failed to clear T3C9 infection. To define specific immune components required for intestinal clearance, reovirus infection of mice with null mutations in the immunoglobulin M (IgM) transmembrane exon (MuMT; B cell and antibody deficient) or beta 2 microglobulin gene (beta 2-/-; CD8 deficient) was evaluated. beta 2-/- mice cleared reovirus infection with normal kinetics, while MuMT mice showed delayed clearance of T3C9 7 to 11 days after p.o. inoculation. Adoptive transfer of splenic lymphocytes from reovirus-immune CB17 mice inhibited growth of T3C9 in CB17 SCID mouse intestine 11 days after p.o. inoculation. The efficiency of viral clearance by adoptively transferred cells was significantly diminished by depletion of B cells prior to adoptive transfer. Results in SCID and MuMT mice demonstrate an important role for B cells or IgG in clearance of reovirus from the intestines. Polyclonal reovirus-immune rabbit serum, protein A-purified immune IgG, and murine monoclonal IgG2a antibody specific for reovirus outer capsid protein sigma 3 administered intraperitoneally all normalized clearance of reovirus from intestinal tissue in MuMT mice. This result demonstrates an IgA-independent role for IgG in the clearance of intestinal virus infection. Polyclonal reovirus-immune serum also significantly decreased reovirus titers in the intestines of SCID mice, demonstrating a T-cell-independent role for antibody in the clearance of intestinal reovirus infection. B cells and circulating IgG play an important role in the clearance of reovirus from intestines, suggesting that IgG may play a more prominent functional role at mucosal sites of primary viral replication than was previously supposed.     

A lymphatic mechanism of rotavirus extraintestinal spread in the neonatal mouse

We used the neonatal mouse model of rotavirus infection and virus strains SA11-clone 4 (SA11-Cl4) and Rhesus rotavirus (RRV) to examine the mechanism of the extraintestinal spread of viruses following oral inoculation. The spread-competent viruses, RRV and reassortant R7, demonstrated a temporal progression from the intestine, to the terminal ileum, to the mesenteric lymph nodes (MLN), and to the peripheral tissues. SA11-Cl4 was not found outside the intestine. Reassortant virus S7, which was unable to reach the liver in previous studies (E. C. Mossel and R. F. Ramig, J. Virol. 76:6502-6509, 2002), was recovered from 60% of the MLN, suggesting that there are multiple determinants for the spread of virus from the intestine to the MLN. Phenotypic segregation analysis identified RRV genome segment 6 (VP6) as a secondary determinant of the spread of virus to the MLN (P = 0.02) in reassortant viruses containing segment 7 from the spread-incompetent parent. These data suggest that in the orally infected neonatal mouse, the extraintestinal spread of rotavirus occurs via a lymphatic pathway, and the spread phenotype is primarily determined by NSP3 and can be modified by VP6.     

Differences in susceptibility to peroral inoculation with Bacillus piliformis spores in rats and mice

The median liver lesion producing doses of peroral inoculation with the spores of Tyzzer's organism RJ strain were 10(4. 3) in rats and 10(2. 7) in rats receiving prednisolone treatment for the provocation of Tyzzer's disease. In contrast to rats, liver lesions were detected in few mice inoculated perorally with 10(7) spores. In mice inoculated perorally with 10(7) spores, excretion of infective spores in the feces was detected only on day 1 postinoculation. On the other hand, no difference in susceptibility between rats and mice was detected upon intravenous inoculation with vegetative cells of the RJ strain. These results suggest that germination of the spores in the intestinal tract causes the difference in the susceptibility in rats and mice.     

Isospora (Toxoplasma) gondii: induction of sexuality

The role of the stomach and small intestine of cats and of the parasite's rate of multiplication on induction of sexuality in Isospora (Toxoplasma) gondii was studied by injecting cats either with free cystozoites or proliferative parasites directly into the intestinal lumen, after laparotomy. Oocyst production was similar in cats infected orally with cysts or cystozoites and in cats infected by inoculation into the duodenal lumen with free cystozoites, obtained by either mechanical rupture of by in vitro pepsin/HCl digestion of the cyst wall. When free cystozoites were injected into the lumen of the posterior part of the ileum, cats became seropositive but oocyst excretion during the first 4 weeks after infection was very low or absent; nevertheless a solid immunity to oral challenge was acquired in the former case. If no oocysts at all were produced after primary infection, the intestine remained susceptible to challenge, in spite of previous seroconversion. This lack of protective immunity in the presence of serum antibodies was observed in all cats primarily infected by direct injection of proliferative parasites into the duodenal lumen. It is concluded that previous gametogony rather than previous infection and seroconversion provokes local intestinal immunity against the development of sexual stages after oral challenge; the switch to gametogony of cystozoites is not triggered off by the low pH of the stomach but is probably related to their reduced rate of multiplication.     

Rabbit model of rotavirus infection.

A new small animal model was developed to study parameters of rotavirus infections, including the active immune response. Seronegative New Zealand White rabbits (neonatal to 4 months old) were inoculated orally with cultivatable rabbit rotavirus strains Ala, C11, and R2 and with the heterologous simian strain SA11. The course of infection was evaluated by clinical findings, virus isolation (plaque assay and enzyme-linked immunosorbent assay), and serologic response. All four strains of virus were capable of infecting rabbits as determined by isolation of infectious virus from intestinal contents or fecal samples, by seroconversion, or by a combination of these methods. The responses differed depending on the virus strain used for inoculation. Rabbits remained susceptible to primary infection to at least 16 weeks of age (upper limit examined). Virus excretion in intestinal contents was detected from 6 h to 7 days postinoculation. RNA electropherotypes of inocula and viruses isolated from rabbits were the same in all samples tested. Transmission of Ala virus and R2 virus but not SA11 virus from inoculated animals to uninoculated controls also occurred. In a challenge experiment with Ala virus, 74- and 90-day-old rabbits were rechallenged with Ala 5 weeks after a primary infection with Ala. Virus was excreted in feces from 2 to 8 days after the primary infection but was not excreted after challenge. These results indicate that the rabbit provides an ideal model to investigate both the primary and secondary active immune responses to rotavirus infections and to evaluate candidate vaccines.     

Reovirus intermediate subviral particles constitute a strategy to infect intestinal epithelial cells by exploiting TGF‐β dependent pro‐survival signaling

Intestinal epithelial cells (IECs) constitute the primary barrier that separates us from the outside environment. These cells, lining the surface of the intestinal tract, represent a major challenge that enteric pathogens have to face. How IECs respond to viral infection and whether enteric viruses have developed strategies to subvert IECs innate immune response remains poorly characterized. Using mammalian reovirus (MRV) as a model enteric virus, we found that the intermediate subviral particles (ISVPs), which are formed in the gut during the natural course of infection by proteolytic digestion of the reovirus virion, trigger reduced innate antiviral immune response in IECs. On the contrary, infection of IECs by virions induces a strong antiviral immune response that leads to cellular death. Additionally, we determined that virions can be sensed by both TLR and RLR pathways while ISVPs are sensed by RLR pathways only. Interestingly, we found that ISVP infected cells secrete TGF‐β acting as a pro‐survival factor that protects IECs against virion induced cellular death. We propose that ISVPs represent a reovirus strategy to initiate primary infection of the gut by subverting IECs innate immune system and by counteracting cellular‐death pathways.     

Possible immune functions of congerin, a mucosal galectin, in the intestinal lumen of Japanese conger eel

Congerin, a mucosal galectin of the Japanese conger eel, provides chemical fortification through its agglutinating and opsonizing activity. Congerin is produced in the epidermis, and the epithelia of the oral cavity to the esophagus, but not in the stomach or intestine. We hypothesized that congerin secreted from the upper digestive tract can reach and function in the intestinal lumen. We found that congerin possessed marked resistance against digestion by gastric and enteric enzymes of conger eel. It was not degraded until 6h of incubation with stomach extract or intestinal digestion juice. Western blotting demonstrated that congerin essentially remained in the intestinal mucus. The mucus agglutinated rabbit erythrocytes, and the agglutination was hampered by anti-congerin antibody. Furthermore, congerin could bind to some enteric bacteria. These results support the above hypothesis.