Hemagglutination with Nebraska calf diarrhea virus

Characterization of bovine rotavirus isolates from diarrheic calves in Türkiye

BACKGROUND

Neonatal calf diarrhea, which is the most common cause in calf deaths, leads to significant economic losses in dairy farming around the world. Diarrhea develops due to infectious and non-infectious reasons. Group A Rotaviruses (RVA) are the leading and predisposing factor for acute neonatal gastroenteritis.

METHODS AND RESULTS

In this study, 20 diarrheic fecal samples were collected from one farm in Balıkesir province of Turkey. During virus isolation, a total of 2 stool samples were detected to produce cytopathogenic effects in MA-104 cell line. The two samples (RV-36, RV-38) were tested positive with antigen ELISA kits detecting RVA antigens. In order to detect the presence of rotavirus viral nucleic acid in cell supernatants, VP6 gene region-specific RT-PCR test was performed and the samples RV-36 and RV-38 were positive for RVA viral nucleic acid. By RT-PCR using genotype specific primers, both the isolates RV-36 and RV-38 formed amplicons compatible with G10 and P[11] genotypes of RVA. RVA nucleic acids segments were also visualized by poliacrilamide gel electrophoresis (PAGE) method. The phylogenetic tree constructed according to the VP6 gene region showed that these isolates were in the Rotavirus A group and in the I2 cluster same as other bovine and some human RVA isolates.

CONCLUSION

Succesful isolation of RVA G10P[11] was echieved in the cattle farm. As rotaviruses play the most important role in the etiology of diarrhea in newborn calves respected genotype G10P[11] should be considered in selection of the vaccines applied to the dams. Those isolates can be further evaluated as vaccine candidate.

A long-term animal experiment indicating persistent infection of bovine coronavirus in cattle

A long-term animal experiment involving inoculation with bovine coronavirus (BCoV) was conducted to verify its persistent infection in cattle. Three colostrum-deprived Holstein calves were housed separately in individual rooms of a high-containment facility and inoculated with the BCoV strain Kumamoto/1/07. Until the end of the experiment (1,085, 700 and 280 days, respectively), viral RNAs were detected sporadically by RT-PCR and nested PCR from plasma, nasal discharge, and feces. Seroconversion and titer changes were validated by hemagglutination inhibition tests and neutralization tests. Among the samples, nasal discharge showed a higher viral positivity than feces, which seemed to be associated with positive detection in the plasma. These data demonstrate the existence of persistent infection of BCoV in the respiratory tissues of cattle.

Isolation and identification of group A rotaviruses among neonatal diarrheic calves, Morocco

Background

Group A rotaviruses (RVA) are the main cause of neonatal calve diarrhea (NCD) in Morocco. In this study, we isolated RVA strains from NCD clinical samples in order to support RVA disease control in Morocco. This isolation process constitutes a first step toward vaccine development.

Methods

Thirteen fecal samples were obtained from calves with a single episode of neonate calf diarrhea at three different dairies and two samples were collected from field during a severe NCD outbreak. Diagnosis of RVA infection was based on fecal immune-chromatographic rapid test and further evaluated for their hemagglutination (HA) activity. RVA isolation was carried out on MA104 cells after inoculates were treated with different concentrations of trypsin TPCK. All RVA isolates were confirmed by LSI VetMAX™ Triplex Ruminant Rotavirus & Coronavirus Real-Time PCR kit. G and P typing were determined by direct sequencing of the VP4 and VP7 amplicons.

Results

RVA isolation was achieved for nine clinical samples following one or two passages (60 %) and was properly depended on HA activity and trypsin treatment of inoculates. The first sign of CPE detected consisted of increased cell granularity, obscure cell boundaries, cell rounding, and eventual degeneration and detachment of cells. At lower TPCK concentration (3–10 μg/inoculum), no changes at the cellular level were observed, while cells activated with 25–30 μg of trypsin/inoculums, they degenerated and trypsin cytotoxicity was enhanced. Appreciable changes in cell’s morphology were detected with optimal trypsin concentration of 15–20 μg trypsin/inoculums. Data from qRT-PCR confirmed that unsuccessful cultivations have No-Ct, and all nine isolates have Ct values ranged between 12.17 and 24.69. Analysis sequencing revealed that field isolates were of G6 P[5] serotype and isolates from the dairy NCD samples were of G10 P[14] serotype.

Conclusions

To our knowledge, this is the first study in Morocco which reports the circulation of G10P[14] in NCD on dairy farms and G6P[5] in the field. Our study constitutes a crucial and a necessary step allowing preventive and veterinary medicine to support RVA disease controls in the country.

Role of sialic acids in rotavirus infection

Rotaviruses are the leading cause of childhood diarrhea. The entry of rotaviruses into the host cell is a complex process that includes several interactions of the outer layer proteins of the virus with different cell surface molecules. The fact that neuraminidase treatment of the cells, or preincubation of the virus with sialic acid-containing compounds decrease the infectivity of some rotavirus strains, suggested that these viruses interact with sialic acid on the cell surface. The infectivity of some other rotavirus strains is not affected by neuraminidase treatment of the cells, and therefore they are considered neuraminidase-resistant. However, the current evidence suggests that even these neuraminidase-resistant strains might interact with sialic acids located in context different from that of the sialic acids used by the neuraminidase-sensitive strains. This review summarizes our current knowledge of the rotavirus-sialic acid interaction, its structural basis, the specificity with which distinct rotavirus isolates interact with sialic acid-containing compounds, and also the potential use of these compounds as therapeutic agents.

Hemagglutinin activity of two distinct genogroups of feline and canine rotavirus strains

Genomes of hemagglutinating strains of feline and canine rotaviruses, were much more closely related to each other than to non-hemagglutinating strains. The Cat2 feline rotavirus appears to derive from reassortment between hemagglutinating and non-hemagglutinating strains.

Hemagglutination by a human rotavirus isolate as evidence for transmission of animal rotaviruses to humans

Human rotavirus strain Ro1845, which was isolated in 1985 from an Israeli child with diarrhea, has a hemagglutinin that is capable of agglutinating erythrocytes from guinea pigs, sheep, chickens, and humans (group O). Hemagglutination was inhibited after incubation with hyperimmune sera or in the presence of glycophorin, the erythrocyte receptor for animal rotaviruses. These results suggest that Ro1845 is an animal rotavirus that infected a human child.

Comparison of human, simian, and bovine rotaviruses for requirement of sialic acid in hemagglutination and cell adsorption

Human rotaviruses (Wa, KUN, MO) showed hemagglutination (HA) only with fixed 1-day-old chicken erythrocytes, and their HA activities were completely destroyed by trypsin activation of virions. Simian SA-11 and bovine NCDV had HA activities not only against fixed erythrocytes but also against fresh erythrocytes from various species. Their HA activities against fixed erythrocytes were also inhibited by trypsin activation, but those against fresh erythrocytes were not. Neuraminidase treatment of fixed erythrocytes did not inhibit HA by trypsin-untreated rotaviruses. In contrast, HA of fresh human erythrocytes by SA-11 and NCDV was completely inhibited by neuraminidase treatment of erythrocytes or glycophorin A, the major erythrocyte sialoglycoprotein. Adsorption and infection of SA-11 and NCDV to monkey kidney MA104 cells were also inhibited by neuraminidase treatment of cells. Adsorption and infection of human rotaviruses were not, however, affected by treatment of cells with neuraminidase from Vibrio cholerae or Arthrobacter ureafaciens or with potassium periodate. Therefore, HA of fixed chicken erythrocytes by trypsin-untreated human and animal rotaviruses may be independent of sialic acids, whereas that of fresh erythrocytes by SA-11 and NCDV is sialic acid dependent and probably mediated by glycophorin A. Sialic acids also constitute an essential part of the cellular receptors for SA-11 and NCDV, whereas those for human rotaviruses were quite resistant to treatments known to destroy major types of sialic acids.

Isolation and characterization of rotavirus from feral pigeon in mammalian cell cultures

Avian rotaviruses were isolated from feral pigeon faeces treated with trypsin using roller tube cultures of mammalian cells. Two pigeon strains, designated as strains PO-8 and PO-13, produced a marked cytopathic effect (CPE), small intracytoplasmic inclusion bodies and high titres of infectious particles in infected MA-104 and MDBK cell lines without cell adaptation and roller drum apparatus. The pigeon rotaviruses shared a common group specific antigen with the Lincoln strain of bovine rotavirus by indirect immunofluorescence, but differed from both the Lincoln strain and the Wa strain of human rotavirus in neutralization tests. The RNA segment profile of this virus on polyacrylamide gel electrophoresis differed from that of group A mammalian rotaviruses. The results of a serological survey suggested that antibody to pigeon rotaviruses was widespread in avian species in Japan.

First report of an epidemic of diarrhoea in human neonates involving the new rotavirus and biological characteristics of the epidemic virus strain (KMB/R85)

An outbreak of diarrhoea in neonates occurred at the nurseries of the Department of Obstetrics of Zhao Tong Regional Hospital, Yunnan Province, from the middle of August to the end of November, 1985. Fifty-one percent of children were affected 2-8 days after birth. The clinical symptoms were mild; patients mainly had diarrhoea and did not vomit. Rotaviruses were detected in 66.7% by RNA PAGE and in 72.7% by EM. The virus strain designated as KMB/R85 had a typical morphology, which was indistinguishable from that of infantile rotaviruses by EM. The viral RNA genome was composed of 11 segments. The buoyant density in CsCl was 1.377 g/cm3. The KMB/R85 strain possessed a hemagglutinin for rhesus monkey erythrocytes. By ELISA, IEM, and HAI, it was found that KMB/R85 strain did not possess the common group antigen shared by group A rotaviruses and was antigenically similar to the Chinese adult diarrhoea rotavirus (serogroup B).

Characterization of monoclonal antibodies against human rotavirus hemagglutinin

Three monoclonal antibodies capable of specifically inhibiting hemagglutination of human rotavirus were produced. Their hemagglutination inhibition (HI) activity was specific to the homologous strain (KUN) used for immunization. The monoclonal antibodies with HI activity were highly effective in neutralizing the infectivity of the KUN strain. These antibodies reacted with Vp80, and 80,000 molecular weight (MW) protein present in the viral outer shell. It was confirmed by immunoblotting assay with the monoclonal antibodies that the antigenic site of human rotavirus hemagglutinin (HA) resides on Vp80 and on its smaller trypsin cleavage products Vp30 (MW 30,000) and Vp24 (MW 24,000). Immunofluorescence studies using the antibodies revealed that the HA antigen of the KUN strain developed at the final stage of virus maturation.

Hemagglutination by human rotavirus strains

Human rotavirus isolates, KUN , MO, and Wa strains were found to agglutinate erythrocytes of the day-old chicken and adult goose, optimally at pH 6.6. Only those fractions containing double-shelled rotavirus particles isolated by isopycnic centrifugation in cesium chloride had hemagglutinating activity. Trypsin treatment decreased the hemagglutination titer of human rotavirus strains and conversely increased their infectivity. Hemagglutination inhibition tests with antisera against type-specific antigens demonstrable by neutralization showed no type specificity.

Identification of the rotaviral gene that codes for hemagglutination and protease-enhanced plaque formation

Temperature-sensitive mutants of bovine rotavirus, UK Compton strain, and rhesus monkey rotavirus, MMU18006 strain, were used to derive 16 reassortants by coinfection of MA104 cells. The parental viruses differed phenotypically in their neutralization specificity, their ability to hemagglutinate, and their requirement for exogenous trypsin for infectivity. When the reassortants were assayed for neutralization specificity and hemagglutination, four phenotypes were observed, indicating that these two rotaviral functions segregated independently. Protease-enhanced infectivity phenotype segregated with the HA phenotype indicating that these two functions were manifestations of the same gene product. In order to determine the gene responsible for these rotaviral functions, the reassortants were genotyped by hybridizing 32P-labeled parental transcripts and denatured reassortant genomic RNAs and analyzing the resulting hybrids by gel electrophoresis. The fourth RNA segment was clearly shown to code for HA and protease enhanced plaque formation in MA104 cells. The neutralization antigen was linked to the eighth and ninth RNA segments that comigrated during gel electrophoresis and thus could not be differentiated.

Attachment of SA-11 rotavirus to erythrocyte receptors

Treatment of human group O and sheep erythrocytes with receptor-destroying enzyme rendered them inagglutinable by simian rotavirus SA-11. The erythrocyte receptors were also removed by periodate oxidation and markedly reduced by incubation with a high concentration of trypsin, but they were not altered by infectivity-enhancing concentrations of trypsin, p-hydroxymercuribenzoate, or sodium sulfite (Na2SO3). Hemagglutinating activity of the virus particles was destroyed by periodate oxidation at 37 degrees C, p-hydroxymercuribenzoate, and a high concentration of trypsin and decreased by Na2SOa but was not altered by incubation with receptor-destroying enzyme, infectivity-enhancing concentrations of trypsin, or periodate oxidation at 4 degrees C. These results indicate that neuraminic acid-containing receptor substances are involved in the interaction of the virus with human and sheep erythrocytes, and suggest that SA-11-erythrocyte union involves carbohydrate on the surface of erythrocytes but not on the virion. Sensitivities of the SA-11 hemagglutinin to alcohols and repeated freeze-thaw cycles were also investigated.

Comparison of hemagglutination-inhibition, complement-fixation and enzyme-linked immunosorbent assay for quantitation of human rotavirus antibodies

The hemagglutination-inhibition test for detecting rotavirus antibody was evaluated by using simian rotavirus SA-11 as hemagglutinating antigen. Results show that the test is as sensitive as either complement fixation or the enzyme-linked immunosorbent assay for detecting antibody to rotavirus in human sera.