Predominance of canine parvovirus (CPV) in unvaccinated cat populations and emergence of new antigenic types of CPVs in cats

Serological, sequence, and in vitro host range analyses of feline parvovirus (FPV) isolates in Vietnam and Taiwan revealed that more than 80% of the isolates were of the canine parvovirus (CPV) type, rather than feline panleukopenia virus (FPLV). Although parvovirus isolates from three Vietnamese leopard cats were genetically related to CPV type 2a or 2b, they had a natural mutation of VP2 residue 300 Gly to an Asp, resulting in remarkable changes in their antigenic properties. These results indicated the possibility that CPV-2a/2b-type viruses can spread in cats more efficiently than conventional FPLV under natural conditions and that CPV-2a/2b viruses are further evolving in cats.     

Evaluation of the antigenic relationships among canine parvovirus type 2 variants

The antigenic relationships among the original canine parvovirus type 2 (CPV-2) and the variants CPV-2a, -2b, and -2c were evaluated. Cross-antigenic evaluation revealed clear differences among the CPV variants, which were more appreciable by serum neutralization (SN) than by hemagglutination inhibition. Antigenic differences were found mostly between the original CPV-2 and the variants, but they were also observed among the variants CPV-2a, -2b, and -2c. The variant CPV-2c exhibited a unique antigenic pattern, since it was poorly recognized by the sera of animals immunized with CPV-2, CPV-2a, and CPV-2b. However, animals immunized with CPV-2c exhibited higher SN titers to CPV-2b than to the homologous virus CPV-2c. The observed antigenic differences might drive selection of CPV strains by generating differential immune pressure in the canine population, which raises concerns about vaccine efficacy.     

Mapping specific functions in the capsid structure of canine parvovirus and feline panleukopenia virus using infectious plasmid clones.

DNA sequences between 0 and 98.8 genome map units (m.u.) from canine parvovirus (CPV) and feline panleukopenia virus (FPV) were cloned into plasmid vectors to form infectious molecular clones. Those plasmids were transfected into permissive cells and viruses recovered were shown to contain intact genomes, having regenerated the complete viral 5' ends up to 100 m.u. The viruses derived from the plasmids were compared to the original viruses, and shown to be indistinguishable in antigenic type, hemagglutination (HA) type and host range. The plasmid origin of the viruses was shown by preparing recombinant clones between CPV and FPV, and demonstrating the recombinant nature of the resulting viruses by restriction mapping and by sequencing viral DNA across the recombination sites. The sequences of our wild-type isolates CPV-d and FPV-b were completed, revealing 50 nucleotide sequence differences, of which 16 determined coding changes--5 in NS-1,2 in NS-2, and 9 in VP-2 protein. The sequences of the 5' ends (95.3-100 m.u.) of both viruses were also determined. Analysis of recombinant viruses mapped both CPV- and FPV-specific antigenic epitopes, the pH dependence of HA, and sequences affecting canine host range of the viruses within the VP-1 and VP-2 structural protein genes. Most of the specific changes were shown to be either on, or within one amino acid of, the surface of the virus capsid, indicating that the exposed surface of the parvovirus capsid plays an important role in determining a number of virus functions. The specific epitopes were affected by differences in a raised area on the capsid ("threefold spike"), while the pH dependence of HA difference was adjacent to a depression in the surface of the capsid at the twofold axis of symmetry.     

Isolation of canine parvovirus from a cat manifesting clinical signs of feline panleukopenia.

Twenty-seven feline parvovirus (FPV) isolates were recovered from cats clinically diagnosed with feline panleukopenia (FPL) for assessing antigenic and genomic properties of FPL viruses (FPLV) recently prevalent among cats in Japan. All isolates, with the exception of one novel isolate, FPV-314, possessed homologous properties, and their subgroups in FPVs were identified as FPLV. The FPV-314 isolate, which was from a 1.5-year-old cat which manifested clinical signs of FPL and died on the 13th day after the first medical examination, was finally identified as canine parvovirus (CPV) because it lacked a specific antigenic epitope commonly detected in FPLV and mink enteritis virus and because the nucleotide sequence of the capsid protein gene was almost identical to those of CPV-2a and -2b antigenic type strains recently prevalent among dogs in Japan. The present result together with our previous findings (M. Mochizuki, R. Harasawa, and H. Nakatani. Vet. Microbiol. 38:1-10, 1993) indicates the possibility that CPV and FPLV undergo mutual interspecies transmission between dogs and cats, and it is postulated that they may cause disease in some adventitious hosts.     

Molecular characterization of canine parvovirus-2 variants circulating in Tunisia

Canine parvovirus type 2 (CPV2) emerged in 1978 as a highly contagious and very serious disease in dogs. The characterization of CPV2 antigenic types is exclusively based on the identification of the amino acid residue at position 426 of the capsid protein VP2. Currently, three antigenic types CPV-2a (asparagine N⁴²⁶), CPV-2b (aspartic acid D⁴²⁶) and CPV-2c (glutamic acid E⁴²⁶) are circulating worldwide. In Tunisia, despite the fact that many clinical and few serological investigations clearly indicate that CPV is widespread and of major concerns in the local dog population, no molecular and antigenic type characterization of circulating variants has been carried out. This investigation showed that most of clinically presumed CPV infections were confirmed by classical or real-time PCR. When no real-time PCR facilities were affordable, classical PCR as reported here in association with restriction fragment length polymorphism (RFLP) with MboI and MboII can be very useful for screening and diagnosing CPV infections. A total of 50 variants were characterized by sequencing and an almost even representation of the different antigenic types, including CPV-2c and slightly more type 2b, were evidenced. Characterization of the Tunisian variants by MGB probe assays as reported was inefficient for most of CPV-2a variants because of their typical nucleotide mutation C¹²⁶⁹. Phylogenetic analysis showed that the Tunisian variants underwent evolution for a relatively long period of time inside the country. The analysis also showed some crossings of the different antigenic types, leaving both genotypic and phenotypic characteristic mutations.     

Evolution of CPV-2 and Implicance for Antigenic/Genetic Characterization

A few amino acid differences in the viral protein VP2 account for important antigenic and biological changes among feline parvovirus (FPV), canine parvovirus (CPV-2) and CPV-2 variants 2a and 2b. Several pieces of evidence suggest that CPV-2 is still evolving as additional amino acid changes occurred within the main antigenic regions of CPV-2 capsid, altering the antigenic profile of the virus and stressing the need for implementing the diagnostic assays.     

Development and characterization of monoclonal antibodies to chicken riboflavin carrier protein

Several monoclonal antibodies (MAbs) specific to chicken riboflavin carrier protein (cRCP) were developed and characterized. Of the several MAbs analyzed, four were directed against nonoverlapping epitopes as demonstrated by MAb inhibition assay. Many of these epitopes appeared to be in close proximity and only three were situated at distinct part of the molecule as revealed by sandwich assay. A combination of chemical modification, peptide cleavage by chemical and enzymatic methods, was used to analyze the possible antigenic structure recognized by these MAbs. An assembled epitope spanning the region 22-87 forms the antigenic site recognized by 4999.1; while MAb 5555.3 interacted with the C-terminal peptide 203-219.     

An analysis of the properties of monoclonal antibodies directed to epitopes on influenza virus hemagglutinin

Summary Monoclonal antibodies (MAbs) specific for the hemagglutinin (HA) of the H3 subtype of influenza A virus were grouped according to their inability to bind to particular MAb-selected neutralization escape mutants of the virus having an amino acid substitution in one of the five postulated antigenic sites on the molecule. Additional residues critical to the binding of the MAbs were deduced from their patterns of reactivity with a panel of field strains and receptor mutants of the H3 subtype. The relationship of these residues to the actual epitopes recognized by the MAbs was inferred from their location on the three-dimensional structure of the HA molecule. In this way it was generally possible to identify a number of residues that are critical to the integrity of the epitope recognized by each of the MAbs examined. It was found that: (1) Several of these epitopes appear to be discontinuous and some may depend on residues contributed by more than one monomer. For example, residue 205, in the interface between monomers of the HA, was found to affect the integrity of the epitopes for several MAbs, possibly by stabilizing the conformation of residues around the receptor-binding pocket and/or in site B on the adjacent monomer. The activity of these particular MAbs was greatly decreased if the virus was exposed to pH 5. (2) All the MAbs tested neutralized viral infectivity and inhibited hemagglutination, although the single MAb directed to site C, which is the most distant from the receptor-binding site, was the least efficient. (3) Hemagglutination inhibition, and particularly neutralization tests, were more discriminating than ELISA in discerning subtle differences between the corresponding epitopes recognized by MAbs on different field strains. (4) Efficiency of neutralization of infectivity did not correlate consistently with hemagglutination inhibiting efficiency; MAbs postulated to bind to epitopes close to the receptor-binding pocket were very efficient at inhibiting hemagglutination, whereas neutralization efficiency tended to be more influenced by the affinity of binding of the MAb. (5) A MAb binding to any particular epitope could affect the binding of a second MAb directed to an epitope within the same or even a different antigenic site. The observed effect was most commonly inhibition of binding, which was not always reciprocal; enhancement of binding was also observed with certain combinations of MAbs. The relative affinity of the MAbs, in addition to steric constraints, were shown to be important factors in the ability to compete for interaction with HA.     

Epitope mapping of horseradish peroxidase with use of monoclonal antibodies.

Nine mouse monoclonal antibodies (MAbs) to horseradish peroxidase (HRP) were used to develop an epitope map of the enzyme. The results of a competitive binding assay indicated three distinct patterns of reactivity. Two groups of MAbs (I and III) recognized epitopes located in separate antigenic regions on the molecule; another (II) bound to sites that overlapped with epitopes in either region I or III. Further definition of these regions was obtained by analyzing the MAbs for their binding to isolated heme, other peroxidases and heme-containing proteins, and to denatured and apo-HRP. None of the group I MAbs bound heme, suggesting that this region was removed from the active site of the enzyme. All of the group II and III MAbs bound heme as well as the other peroxidases and heme-containing proteins, indicating that they recognized heme-associated epitopes at or near the active site. Only one MAb (2A2) in groups II and III bound to apo-HRP but not to denatured HRP; it was also the only MAb in the entire panel that inhibited the catalytic activity of HRP. This suggests that the epitope recognized by 2A2 involves both the heme moiety and a conformationally dependent protein determinant near the active site.     

Antigenic structure and variation of canine parvovirus type-2, feline panleukopenia virus, and mink enteritis virus

The antigenic structure and variation of canine parvovirus type-2 (CPV), feline panleukopenia virus (FPV), mink enteritis virus (MEV), and a closely related virus of raccoons (RPV) was investigated using a panel of 13 monoclonal antibodies (mAb) formed against CPV and 8 mAb formed against FPV. Each mAb both neutralized and inhibited the hemagglutination of the homologous virus. All mAb tested immunoprecipitated the two capsid proteins. Five mAb were specific for the CPV isolates and one reacted with the FPV, MEV, and RV isolates, but not the CPV. Another mAb reacted only with certain FPV and MEV isolates. The remaining 14 mAb reacted with most parvoviral isolates from the four animal species. Antigenic variation was observed both within and between the parvovirus isolates from each species. The 12 MEV isolates could be grouped into three antigenic types based on their reactivity with the panel of mAb. Antigenic variants of either CPV or FPV were readily selected with several mAb. Analysis of these variant viruses by direct serological tests and competition radioimmune assays between different mAb revealed that the capsid surface contained at least two determinants, each being comprised of many different but overlapping epitopes.     

A canine parvovirus mutant is spreading in Italy

By antigenic and genetic characterization of canine parvovirus type 2 (CPV-2) strains collected in 2001 and 2002 in Italy, it was possible to observe the spread of viruses with an unusual mutation, Glu-426, affecting a major antigenic epitope of CPV-2. Out of 67 strains analyzed, 49 (73.13%) were characterized as CPV-2a, 6 (8.95%) were characterized as CPV-2b, and 12 (17.91%) were characterized as the Glu-426 mutant.     

Epitope mosaic on the surface proteins of orthopoxviruses

Epitopes on the surface components of orthopoxviruses were analyzed with monoclonal antibodies (MAbs) against monkeypox and vaccinia viruses by enzyme-linked immunosorbent assay (ELISA), Western blotting (WB), radioimmunoprecipitation (RIP), and competitive binding inhibition assay (CBIA). When compared by ELISA, three vaccinia virus strains exhibited a similar reactivity to 99 tested MAbs despite their remote passage history. All five isolates of monkeypox virus closely resembled one another, irrespective of the host species (human, monkey, squirrel) from which they were isolated. Taterapox virus reacted similar to vaccinia virus against 97 of the 99 tested MAbs, and reacted with 2 MAbs which were cross-reactive with monkeypox and mousepox. Mousepox and cowpox viruses reacted with these MAbs in a species-specific manner: MAbs reactive to cowpox virus distinctly differ from those reactive to mousepox virus. Of the 99 tested MAbs, 32 reacted with all the 11 tested orthopoxviruses, indicating that the corresponding epitopes existed in all the viruses. Fifty-four MAbs reacted with two or more virus species and were classified as partially common MAbs. Eight MAbs were apparently type-specific for monkeypox, and five were specific for vaccinia and taterapox viruses. No strain-specific epitope was detected. Sera of monkeypox-infected patients, when analyzed by CBIA, interfered with the binding of monkeypox-specific MAb H12C1 but not of vaccinia-specific MAb G6C6. Sera of monkeypox-infected patients who had been vaccinated competed against both MAbs, demonstrating the original antigenic sin phenomenon. The two MAbs could distinguish between the sera of monkeypox patients and those of vaccinated persons. However, the serum of a smallpox patient was competitive against these apparently vaccinia- or monkeypox-specific MAbs. Three of the eight monkeypox-specific epitopes were recognized by the above CBIA test, which suggests that they also exist in smallpox virus. The mosaic-like combination of common epitopes and the small number of type-specific epitopes manifested the antigenic characteristics of orthopox viruses. The species boundary was obscured due to the partially common epitopes, but the total composition of epitopes was stable enough to maintain the antigenic species-specificity. The mutual relationship of the orthopoxviruses was visualized in a three-dimensional network.     

Phylodynamics analysis of canine parvovirus in Uruguay: evidence of two successive invasions by different variants

Canine parvovirus (CPV) comprises three antigenic variants (2a, 2b, and 2c) with different frequencies and genetic variability among countries. Current CPV populations are considered to be spatially structured with relatively little movement of viruses between geographical areas. Here we describe the evolution and population dynamics of CPV in Uruguay from 2006–2011 using full-length capsid viral protein 2 (VP2) sequences. CPV-2c was the predominant variant in Uruguay for 4 years (2006–2009). The estimated time to the most recent common ancestor suggested that the CPV-2c variant appeared in Uruguay around 2004–2005. Comparative phylogenetic analysis revealed that South American CPV-2c strains did not emerge de novo but may have a European origin. In 2010, a remarkable epidemiological change occurred as a consequence of the emergence of a novel CPV-2a strain in the previously homogeneous CPV-2c population. The frequency of the novel CPV-2a strain increased to 85 % in 2011, representing the first example of a CPV-2a strain replacing a predominant CPV-2c strain in a dog population. The CPV-2a strains detected in 2010–2011 were not phylogenetically related to any other strain collected on the American continent but were identical to Asiatic strains, suggesting that its emergence was a consequence of a migration event. Taken together, our findings suggest that in the last decade, Uruguay has experienced two successive invasions by CPV-2c and CPV-2a variants of European and Asiatic origins, respectively. These results support the hypothesis that CPV invasion events are not rare in certain geographic regions and indicate that some current strains may exhibit an unexpectedly high invasion and replacement capability.     

Characterization of monoclonal antibodies against the Escherichia coli hemolysin.

Twelve monoclonal antibodies (MAbs) produced against the Escherichia coli hemolysin (HlyA) encoded by the hemolysin recombinant plasmid pWAM04 were studied. HlyA derivatives from recombinant strains with different plasmids encoding HlyA amino-terminal and carboxy-terminal truncates, HlyA in-frame deletions, and HlyA frameshift mutations were used in immunoblots to localize the antigenic determinants for the anti-HlyA MAbs. The mapping of the MAb epitopes was also facilitated by immunoblotting analysis of HlyA polypeptide fragments derived by cyanogen bromide cleavage. The HlyA epitopes for 11 of the MAbs were mapped to relatively small linear regions of the cytolysin ranging from 28 to 160 amino acids. Five of the MAbs (C10, G8, E2, B7, and D12) neutralized HlyA hemolytic activity to varying degrees. The epitopes for these neutralizing MAbs were found to reside within the following HlyA regions: C10 and G8, amino acids 2 to 160; E2, amino acids 161 to 194; B7, amino acids 518 to 598; and D12, amino acids 626 to 726. Hemolytically active HlyA was dependent on the action of the hlyC gene product. The D12 MAb recognized only HlyA produced by strains with an intact hlyC function. MAb A10 recognized an epitope within the HlyA region from amino acids 728 to 829 where a glycine-rich repeat domain exists; however, this MAb did not neutralize HlyA hemolytic activity. A HlyA domain map showing the anti-HlyA epitope location was constructed.     

Characterization of neutralizing monoclonal antibody escape mutants of Hantaan virus 76118

Summary.  Neutralizing monoclonal antibody (MAb) escape mutants of Hantaan virus were generated using MAbs to envelope protein G1 (16D2) and G2 (11E10). The mutant viruses (mu16D2 and mu11E10), lacked reactivity only to the selecting MAb, or a MAb belonging to the same antigenic site. Both mutants had a single amino acid (a.a.) substitution. The a.a. substitution, found in mu16D2, was different from that found in another mutant selected with the same MAb (16D2). Although MAb 11E10 immunoprecipitated G2 protein, a deduced a.a. substitution was located in the G1 region. These results suggest that antigenic sites defined by neutralizing MAbs are composed of discontinuous epitopes over the G1 and G2 proteins. Mutant 11E10 showed a significant decrease in virulence in suckling mice. A virulence revertant of mu11E10, selected through passages in suckling mice brain, showed exactly the same deduced a.a. sequence as mu11E10 and still was not neutralized by MAb 11E10. Since mutant 16D2 was virulent for suckling mice, neutralization related epitopes found with MAbs 11E10 and 16D2 were independent of pathogenicity in BALB/c mice. Accepted August 13, 1997 Received March 17, 1997     

Detection and genetic characterization of canine parvoviruses and coronaviruses in southern Ireland

Canine parvovirus (CPV) and canine coronavirus (CCoV) are considered the main pathogens responsible for acute gastroenteritis in dogs. From a collection of 250 samples, seven CPV strains and three CCoV strains were identified in symptomatic Irish dogs. Samples were screened for the viruses using polymerase chain reaction (PCR) and typed via DNA sequence analysis. Three CPV strains were characterized as CPV-2a, while four others were characterized as CPV-2b. To date, CPV-2c remains unreported in Ireland. Two CCoV strains were characterized as CCoV-II and one as CCoV-I. In the case of one sample, PH4/09/Ire, a mixed infection with CPV and CCoV was detected.     

Analysis of Linear B-Cell Epitopes of the Nucleoprotein of Ebola Virus That Distinguish Ebola Virus Subtypes

Ebola virus consists of four genetically distinguishable subtypes. We developed monoclonal antibodies (MAbs) to the nucleoprotein (NP) of Ebola virus Zaire subtype and analyzed their cross-reactivities to the Reston and Sudan subtypes. We further determined the epitopes recognized by these MAbs. Three MAbs reacted with the three major subtypes and recognized a fragment containing 110 amino acids (aa) at the C-terminal extremity. They did not show specific reactivities to any 10-aa short peptides in Pepscan analyses, suggesting that these MAbs recognize conformational epitope(s) located within this region. Six MAbs recognized a fragment corresponding to aa 361 to 461 of the NP. Five of these six MAbs showed specific reactivities in Pepscan analyses, and the epitopes were identified in two regions, aa 424 to 430 and aa 451 to 455. Three MAbs that recognized the former epitope region cross-reacted with all three subtypes, and one that recognized the same epitope region was Zaire specific. One MAb, which recognized the latter epitope region, was reactive with Zaire and Sudan subtypes but not with the Reston subtype. These results suggest that Ebola virus NP has at least two linear epitope regions and that the recognition of the epitope by MAbs can vary even within the same epitope region. These MAbs showing different subtype specificities might be useful reagents for developing an immunological system to identify Ebola virus subtypes.     

Antigenic analysis of avian rotavirus VP6 using monoclonal antibodies

Summary Monoclonal antibodies (MAbs) were prepared to analyze antigens on the major inner capsid protein, VP 6 of avian group A rotavirus. Based on the results of a competitive binding assay using 15 MAbs directed against VP 6 of the PO-13 rotavirus strain, isolated from a pigeon in Japan, it was found that VP 6 of avian rotavirus possesses at least four spatially distinct antigenic sites. Two antigenic sites (I and II) were topologically distinct from the other two (III and IV), which were in close proximity. From the reaction of MAbs in indirect immunofluorescent antibody tests to a series of known rotaviruses, epitopes representing common antigens of all group A rotavirus including avian rotavirus were localized in sites II and III. One epitope in site IV appeared to have a subgroup antigenic specificity that reacted only with rotaviruses belonging to subgroup I. Interestingly, avian rotaviruses isolated from turkeys and chickens in Northern Ireland also reacted only with these subgroup I specific MAbs, but not with subgroup II specific MAb. This indicates that avian rotavirus has subgroup I specific antigen, which is antigenically similar to that of other mammalian rotavirus strains.     

Analysis of linear B-cell epitopes of the nucleoprotein of ebola virus that distinguish ebola virus subtypes

Ebola virus consists of four genetically distinguishable subtypes. We developed monoclonal antibodies (MAbs) to the nucleoprotein (NP) of Ebola virus Zaire subtype and analyzed their cross-reactivities to the Reston and Sudan subtypes. We further determined the epitopes recognized by these MAbs. Three MAbs reacted with the three major subtypes and recognized a fragment containing 110 amino acids (aa) at the C-terminal extremity. They did not show specific reactivities to any 10-aa short peptides in Pepscan analyses, suggesting that these MAbs recognize conformational epitope(s) located within this region. Six MAbs recognized a fragment corresponding to aa 361 to 461 of the NP. Five of these six MAbs showed specific reactivities in Pepscan analyses, and the epitopes were identified in two regions, aa 424 to 430 and aa 451 to 455. Three MAbs that recognized the former epitope region cross-reacted with all three subtypes, and one that recognized the same epitope region was Zaire specific. One MAb, which recognized the latter epitope region, was reactive with Zaire and Sudan subtypes but not with the Reston subtype. These results suggest that Ebola virus NP has at least two linear epitope regions and that the recognition of the epitope by MAbs can vary even within the same epitope region. These MAbs showing different subtype specificities might be useful reagents for developing an immunological system to identify Ebola virus subtypes.     

Antigenic structure of the E2 glycoprotein from transmissible gastroenteritis coronavirus

The antigenic structure of transmissible gastroenteritis (TGE) virus E2 glycoprotein has been defined at three levels: antigenic sites, antigenic subsites and epitopes. Four antigenic sites (A, B, C and D) were defined by competitive radioimmunoassay (RIA) using monoclonal antibodies (MAbs) selected from 9 fusions. About 20% (197) of the hybridomas specific for TGE virus produced neutralizing MAbs specific for site A, which was one of the antigenically dominant determinants. Site A was differentiated in three antigenic subsites: a, b and c, by characterization of 11 MAb resistant (mar) mutants, that were defined by 8, 3, and 3 MAbs, respectively. These subsites were further subdivided in epitopes. A total of 11 epitopes were defined in E2 glycoprotein, eight of which were critical for virus neutralization. Neutralizing MAbs were obtained only when native virus was used to immunize mice, although to produce hybridomas mice immunizations were made with antigen in the native, denatured, or mixtures of native and denatured form. All neutralizing MAbs reacted to conformational epitopes. The antigenic structure of the E2-glycoprotein has been defined with murine MAbs, but the antigenic sites were relevant in the swine, the natural host of the virus, because porcine sera reacted against these sites. MAbs specific for TGE virus site C reacted to non-immune porcine sera. This reactivity was not directed against porcine immunoglobulins. These results indicated that TGE virus contains epitope(s) also present in some non-immunoglobulin component of porcine serum.