Two distinct nanovirus species infecting faba bean in Morocco

Using monoclonal antibodies raised against a Faba bean necrotic yellows virus (FBNYV) isolate from Egypt and a Faba bean necrotic stunt virus (FBNSV) isolate from Ethiopia, a striking serological variability among nanovirus isolates from faba bean in Morocco was revealed. To obtain a better understanding of this nanovirus variability in Morocco, the entire genomes of two serologically contrasting isolates referred to as Mor5 and Mor23 were sequenced. The eight circular ssDNA components, each identified from Mor5- and Mor23-infected tissues and thought to form the complete nanovirus genome, ranged in size from 952 to 1,005 nt for Mor5 and from 980 to 1,004 nt for Mor23 and were structurally similar to previously described nanovirus DNAs. However, Mor5 and Mor23 differed from each other in overall nucleotide and amino acid sequences by 25 and 26%, respectively. Mor23 was most closely related to typical FBNYV isolates described earlier from Egypt and Syria, with which it shared a mean amino acid sequence identity of about 94%. On the other hand, Mor5 most closely resembled a FBNSV isolate from Ethiopia, with which it shared a mean amino acid sequence identity of approximately 89%. The serological and genetic differences observed for Mor5 and Mor23 were comparable to those observed earlier for FBNYV, FBNSV, and Milk vetch dwarf virus. Following the guidelines on nanovirus species demarcation, this suggests that Mor23 and Mor5 represent isolates of FBNYV and FBNSV, respectively. This is the first report not only on the presence of FBNSV in a country other than Ethiopia but also on the occurrence and complete genome sequences of members of two nanovirus species in the same country, thus providing evidence for faba bean crops being infected by members of two distinct nanovirus species in a restricted geographic area.     

Comparison of genetic groups determined by molecular and immunological analyses of Giardia isolated from animals and humans in Switzerland and Australia

 Nine axenic isolates of Giardia originating from four different host species in Switzerland were subjected to genetic analysis using the polymerase chain reaction (PCR) to amplify segments of genes encoding different trophozoite variant surface proteins (VSPs). Three genotypes were identified on the basis of product yield, size, and restriction-fragment-length polymorphisms (RFLPs). Five G. duodenalis isolates (O1, B1, B2, B3-1A1 and C1 – from a sheep, three calves and a dog, respectively) were classified as belonging to genetic group I of Andrews et al. (1989). DNA amplified from the VSP genes tsp11, tsa417 and vsp1267 of these isolates was indistinguishable in size and restriction characteristics from that amplified from group-I Giardia isolated from humans in Australia. One human-derived Swiss isolate (H2-17A1), typed as belonging to genetic group II, yielded a vsp1267-specific PCR product that was indistinguishable by size or restriction sites from the equivalent 1.6-kb product amplified from human-derived Australian group-II organisms. This isolate also yielded 1.8-kb tsp11 and 0.52-kb tsa417/tsp11-like PCR products possessing RFLPs typical of group-II organisms. Three isolates (O2-4A1, O3 and H3-15K2 – originating from two sheep and a human, respectively) represent a novel genotype that is closely related to genetic groups I and II. These three isolates exhibited identical RFLPs in their tsp11 PCR products and failed to yield a vsp1267 PCR product. An antiserum specific for the 90-kDa VSP of the sheep-derived clone O2-4A1 reacted strongly by immunofluorescence and on Western blots with surface proteins from the O2, O3 and H3 isolates only – consistent with the genetic classification determined above. The data provide no evidence for the occurrence of host-specific genotypes. Received: 13 January 1995 / Accepted: 20 May 1995     

Comparison of genetic groups determined by molecular and immunological analyses of giardia isolated from animals and humans in switzerland and australia

Nine axenic isolates of Giardia originating from four different host species in Switzerland were subjected to genetic analysis using the polymerase chain reaction (PCR) to amplify segments of genes encoding different trophozoite variant surface proteins (VSPs). Three genotypes were identified on the basis of product yield, size, and restriction-fragment-length polymorphisms (RFLPs). Five G. duodenalis isolates (01, Bl, B2, B3-1A1 and Cl — from a sheep, three calves and a dog, respectively) were classified as belonging to genetic group I of Andrews et al. (1989). DNA amplified from the VSP genes tsp11, tsa417 and vsp1267 of these isolates was indistinguishable in size and restriction characteristics from that amplified from group-I Giardia isolated from humans in Australia. One human-derived Swiss isolate (H2-17A1), typed as belonging to genetic group II, yielded a vsp1267-specific PCR product that was indistinguishable by size or restriction sites from the equivalent 1.6-kb product amplified from human-derived Australian group-II organisms. This isolate also yielded 1.8-kb tspll and 0.52-kb tsa417/tsp11-like PCR products possessing RFLPs typical of group-II organisms. Three isolates (O2-4A1, 03 and H3-15K2 — originating from two sheep and a human, respectively) represent a novel genotype that is closely related to genetic groups I and II. These three isolates exhibited identical RFLPs in their tspll PCR products and failed to yield a vsp1267 PCR product. An antiserum specific for the 90-kDa VSP of the sheep-derived clone O2-4A1 reacted strongly by immunofluorescence and on Western blots with surface proteins from the 02, 03 and H3 isolates only — consistent with the genetic classification determined above. The data provide no evidence for the occurrence of hostspecific genotypes.     

Production and partial characterization of monoclonal antibodies to four Chlamydia psittaci isolates.

Monoclonal antibodies (MAbs) were produced to four Chlamydia psittaci isolates: NJ1 and TT3 from turkeys, VS1 from a parakeet, and B577 from an ovine abortion. MAbs were tested for reactivity with each isolate by the indirect immunofluorescent antibody technique and for neutralization by an inclusion reduction neutralization technique in tissue culture. Two genus-specific and 14 serovar-specific MAbs were produced. Genus-specific MAbs reacted with all avian and mammalian isolates; however, each failed to neutralize its homologous chlamydial isolate. Turkey isolates NJ1 and TT3 were antigenically similar; serovar-specific MAbs produced to each reacted equally with both isolates yet showed little or no reaction with other serovars. Serovar-specific MAbs to the parakeet and abortion isolates were distinct; no cross-reactions were seen with other serovars. None of the serovar-specific MAbs reacted with an ovine arthritis isolate. Of the 14 serovar-specific MAbs, 13 partially neutralized homologous strains with or without the addition of complement. Because of the high specificity, the serovar-specific MAbs used with the immunofluorescence technique provided a rapid and precise method to identify three serovars of C. psittaci.     

Comparative immunological characterization of type-specific and conserved B-cell epitopes of pinniped,felid and canid herpesviruses

Summary Murine monoclonal antibodies (MAbs) were generated against phocid herpesviruses (PhHV 2557/Han88 and 7848/Han90) isolated from European harbour seals (Phoca vitulina), and against strains of both felid (FHV strain FVR 605) and canid herpesviruses (CHV isolate 5105/Han89). MAbs were characterized with respect to certain biological properties and used to outline antigenicity profiles of isolates of PhHV (n=8), FHV (n=7) and CHV (n=3) in enzyme immunoassays employing fixed infected cells. A close antigenic relationship between herpesviruses derived from pinnipeds and terrestrial carnivores became evident: The majority of the MAbs was directed against epitopes which were expressed by at least two of the viral species tested. A number of MAbs detected epitopes which were conserved between all isolates of PhHV, FHV and CHV. A few MAbs recognized type-specific B-cell epitopes and facilitated the identification of single viral species. Moreover, the PhHV isolate 7848/Han90 was antigenically distinguishable both from seven other phocid herpesvirus isolates and from FHV or CHV. PhHV 7848/Han90 proved to be antigenically distinct from all other viruses tested when examined by cross neutralization utilizing various reconvalescent and hyperimmune sera. Although more data are needed to ensure that PhHV 7848/Han90 indeed is a new genuine seal herpesvirus, the preliminary clustering of two groups of phocid herpesvirus isolates, tentatively designated PhHV-1 (type isolate 2557/Han88) and PhHV-2 (represented by 7848/Han90), seems to be justified. By using selected MAbs an unambiguous identification and typing of herpesvirus isolates derived from marine mammals and terrestrial carnivores is significantly facilitated.     

Detection and subgrouping of Cucumber mosaic virus isolates by TAS-ELISA and immunocapture RT-PCR

Eight mouse hybridoma cell lines secreting monoclonal antibodies (MAbs) against Cucumber mosaic virus (CMV) were produced. Analysis of the specificities of the MAbs against CMV isolates by triple antibody sandwich (TAS)-ELISA demonstrated that four MAbs were specific for subgroup I (S-I) isolates and two for subgroup II (S-II) isolates, whereas another two MAbs could detect both S-I and S-II isolates. TAS-ELISA and immunocapture RT-PCR (IC-RT-PCR) methods were then established for reliable and efficient detection and subgrouping of CMV isolates using the produced MAbs. When 197 field samples collected from six provinces in China were tested by TAS-ELISA, 130 samples were found to be infected by CMV. Among them, 121 samples were infected by S-I isolates (93.1%) and another nine samples by S-II isolates (6.9%). In IC-RT-PCR using the MAbs and specific primers in the region of the coat protein (CP) gene, samples shown to contain S-I isolates by TAS-ELISA gave one specific band about 500 nucleotides in length, whereas samples containing S-II isolates produced a single band with the length of approximately 600 nucleotides. The validity and reliability of the results of TAS-ELISA and IC-RT-PCR was confirmed by sequencing and phylogenetic analysis of nearly full-length CP genes of the isolates.     

Spectrum of monoclonal antibodies to coxsackievirus B-3 includes type- and group-specific antibodies.

Fifteen monoclonal antibodies (MAbs) made to coxsackievirus B-3 were tested against a panel of enteroviruses by indirect immunofluorescence. The MAbs included seven which reacted with coxsackievirus B-3 only, five which reacted with more than one enterovirus included in the panel, one which reacted with broad enteroviral specificity and did not react with any heterologous virus (group specific), and two which reacted with all enteroviruses tested and at least one heterologous virus. The group-specific MAb identified 44 of 45 clinical isolates as enteroviruses, while the two broadly reactive MAbs reacted with all 45 of the clinical isolates. These MAbs are potentially important diagnostic reagents for grouping and typing enteroviruses by indirect immunofluorescence.     

Antigenic relationships between field isolates of morbilliviruses from different carnivores

Summary The antigenic relationships between PDV and isolates of morbilliviruses from carnivores suffering from distemper were investigated. Fourteen isolates, originating from terrestrial carnivores and harbour seals from 1985–1991 from Denmark, Norway, Greenland, and the U.S.A. were reacted in IFA and ELISA with monoclonal antibodies (MAbs) directed against four virion proteins (NP, P, F, and H). The MAbs comprised a newly completed panel of 36 anti-PDV MAbs and 39 previously developed anti-CDV MAbs. The antigenic make-up of the isolates separated them into the CDV prototype group and the PDV prototype group, having the antigenic characteristics of the reference vaccine strains of CDV and the Danish PDV isolate, respectively. The minor antigenic variations within the CDV group contrasted markedly to the differences encountered between the CDV and PDV group. The PDV group included isolates made in 1988 from diseased seals of Danish and Norwegian waters and isolates made in 1989 from distemper outbreaks in Danish mink farms. In contrast, the other distemper isolates investigated, including isolates from 1986 from a corresponding Danish mink farm, revealed the antigenic characteristics of CDV. Our results strongly indicate that PDV was recently transmitted from diseased seals to terrestrial carnivores causing distemper epizootics among farmed mink.     

Serological Specificities of Murine Hybridoma Monoclonal Antibodies against Neisseria meningitidis Serogroups B, C, Y, and W135 and Evaluation of Their Usefulness as Serogrouping Reagents by Indirect Whole-Cell Enzyme-Linked Immunosorbent Assay

Murine hybridoma monoclonal antibodies (MAbs) were produced against the capsular antigens of serogroups B, C, Y, and W135 meningococci. Each serogroup-specific MAb reacted with the extracted capsular polysaccharide from its homologous serogroup only and did not react with capsules from the other three serogroups. The application of these MAbs for serogroup identification of meningococci was demonstrated by their abilities to correctly identify 183 clinical isolates of 185 meningococci recovered from individual invasive meningococcal disease (IMD) patients during routine surveillance in 2002. The remaining two meningococci were identified by PCR grouping as C in one case and Y in another, but neither isolate was positive by bacterial agglutination using rabbit antisera or by enzyme-linked immunosorbent assay using MAbs. The specificities of the anti-Y and anti-W135 MAbs were further assessed by tests with 37 serogroup W135 and 106 serogroup Y meningococci recovered from IMD cases during 1999 to 2001 and 2003. All 143 meningococci except one serogroup Y isolate were correctly identified by positive reactions with the corresponding MAbs that identified their homologous serogroups. The single serogroup Y isolate was received as nonagglutinable and tested as negative with both rabbit anti-Y antiserum and anti-Y MAb but was positive for the serogroup Y-specific siaD gene. The advantage of using MAbs for serogrouping of meningococci is discussed.     

Genetic variability in the coat protein genes of lettuce big-vein associated virus and Mirafiori lettuce big-vein virus

Summary. Available data suggests that lettuce big-vein disease is caused by the ophiovirus Mirafiori lettuce big-vein virus (MLBVV) but not by the varicosavirus Lettuce big-vein-associated virus (LBVaV), although the latter is frequently associated with the disease. Since the disease occurs worldwide, the putative coat protein (CP) open reading frames of geographically distinct isolates of MLBVV and LBVaV were sequenced. Comparison of both nucleotide and amino acid sequences showed a high level of sequence similarity among LBVaV isolates. Phylogenetic analysis of LBVaV CP nucleotide sequences showed that most of the Spanish isolates clustered in a phylogenetic group whereas English isolates were more similar to the USA isolate. An Australian isolate was closely related to the Dutch isolate. Genetic diversity among MLBVV CP nucleotide sequences was higher ranging from 0.2% to 12%. Phylogenetic analysis of MLBVV CP nucleotide sequences revealed two distinct subgroups. However, this grouping was not correlated with symptom development on lettuce or the geographic origin of the MLBVV isolates. Finally, a quick method based on RFLP analysis of RT-PCR amplicons was developed for assigning MLBVV isolates to the two subgroups.     

Analysis of the biological and molecular variability of Watermelon mosaic virus isolates from Iran

Watermelon mosaic virus (WMV) is one of the most important viruses that causes different symptoms in Cucurbitaceae. WMV is a potyvirus with a worldwide distribution, but occurs most commonly in temperate and Mediterranean regions. Cucurbit species grown in Yazd, Esfahan, West Azerbaijan, Hormozgan, and Kerman provinces were surveyed for the relative incidence of WMV in 2004–2005. A total of 757 symptomatic cucurbit and 31 weed species were collected and assayed for infection with WMV. Of 788 leaf samples from cucurbit and weed plants, 190 samples were positive by double antibody sandwich ELISA (DAS-ELISA) using specific polyclonal antibody. Among the weed species tested only colocynth (Citrullus colocynthis) was found to be infected with WMV. The coat protein (CP) gene from 18 representative isolates was PCR amplified, cloned, sequenced, and compared with the sequences available in GeneBank. Phylogenetic analysis using 778 nucleotide long sequences of the coat protein gene showed that these isolates fell into two; groups I and II. Only one isolates (KER.JI.1) was classified in the group II. This isolate had a wider host range and infected Nicotiana debneyii and Datura metel. None of the other 17 isolates could infect these two species. Members of group I were divided into three subgroups; A, B, and C. The subgroup I_B appears to be a new subgroup comprising only of the Iranian isolates. Phylogenetic analysis based on 200 nucleotides coding for the N-terminal segment of the CP showed that all Iranian isolates except KER.JI.1 clustered with the previously reported WMV strains. All Iranian isolates had a DAG amino acid triplet which is involved in aphid transmissibility. This is the first report on sequence analysis of the nearly full-length CP cDNA clones of WMV isolates from Iran.     

Sequence Divergence of Four Soilborne Sugarbeet-Infecting Viruses

Soilborne viruses are among the most harmful pathogens of sugarbeet (Beta vulgaris L.ssp. vulgaris) but most of them lack information on genetic variability due to paucity of sequence data. Only one isolate of Beet soil borne virus (BSBV; genus Pomovirus), Beet virus Q (BVQ; genus Pomovirus) and Beet soil borne mosaic virus (BSBMV; genus Benyvirus) has been characterised for the coat protein (CP) gene. In this study, the CP gene sequences of three isolates each of BSBV and Beet necrotic yellow vein virus (BNYVV; genus Benyvirus) (France, Germany and USA), two isolates of BVQ (France and Germany), and one isolate of BSBMV (USA) were determined. Phylogenetic analyses including sequences from databanks indicated that the French BNYVV isolate of this study belongs to so-called P-type, the American isolate to A-type and the German isolate to B-type. The CP genes of the three BSBV isolates characterised in this study and the one available from databank were highly identical (98.4–99.0% at nucleotide level; one variable amino acid). The BSBMV isolate studied here differed from the previously characterised isolate for five nucleotides and four amino acids in the CP region. The two BVQ isolates characterised in this study contained three additional nucleotides resulting in an additional amino acid residue (arginine) at CP position 86, as compared to the only isolate available in databank.     

Novel 5-flucytosine-resistant clade of Candida dubliniensis from Saudi Arabia and Egypt identified by Cd25 fingerprinting

DNA fingerprinting of Candida dubliniensis isolates using the species-specific probe Cd25 previously showed that this species consists of two distinct groups, termed Cd25 group I and Cd25 group II. The present study investigated the population structure of 30 C. dubliniensis oral isolates from Saudi Arabia and Egypt using Cd25 fingerprinting and rRNA gene internal transcribed spacer region-based genotyping. Cd25 fingerprinting analysis of these isolates revealed two distinct populations, the first of which consisted of 10 closely related genotype 1 isolates (average similarity coefficient [S(AB)] value, 0.86). The second population of 20 isolates was much more heterogeneous (average S(AB) value, 0.35) and consisted of two distinct subpopulations, one of which consisted of genotype 3 isolates (n = 13) and the other of genotype 4 isolates (n = 7). A mixed dendrogram generated from the fingerprint data from the 30 Saudi Arabian and Egyptian isolates, 5 Israeli isolates, and 51 previously characterized international isolates (32 of Cd25 group I and 19 of Cd25 group II) revealed the presence of three distinct main clades. The first corresponded to the previously described Cd25 group I and contained all the Saudi Arabian, Egyptian, and Israeli genotype 1 isolates mixed with international isolates. The second clade corresponded to the previously described Cd25 group II and contained three Israeli isolates, one genotype 2 isolate, one genotype 3 isolate, and a genotype 4 variant isolate, which were mixed with international isolates. The third clade has not been described before and consisted solely of the 20 Saudi Arabian and Egyptian genotype 3 and 4 isolates identified in this study and a previously described genotype 4 Israeli isolate. All 20 Cd25 group III isolates exhibited high-level resistance to 5-flucytosine (MIC > or = 128 microg/ml), whereas all Cd25 group I and Cd25 group II isolates tested (10 Saudi Arabian and Egyptian, 16 Israeli, and 24 international) were susceptible to 5-flucytosine (MIC < or = 0.125 microg/ml). The results of this study show for the first time the presence of a novel 5-flucytosine-resistant clade of C. dubliniensis (Cd25 group III) that is predominant among isolates from Saudi Arabia and Egypt and absent from a previously characterized international collection of 98 isolates from 15 countries.     

Conservation of a protective surface antigen of Tritrichomonas foetus.

Bovine trichomoniasis is a sexually transmitted disease caused by the flagellated protozoan Tritrichomonas foetus. A protective surface antigen was previously identified and immunoaffinity purified from T. foetus isolate D1 with cross-reactive monoclonal antibodies (MAbs) TF1.15 and TF1.17 (BonDurant, R. H., R. R. Corbeil, and L. B. Corbeil, Infect. Immun. 61:1385-1394, 1993). This antigen elicited antibody responses in the serum and cervicovaginal mucus of heifers. Thus, it may be useful as an immunodiagnostic reagent as well as a subunit vaccine. Conservation of the antigen in all strains would be crucial for either application. We investigated the conservation of this antigen among 36 isolates of T. foetus from Argentina, Costa Rica, and the United States using MAbs TF1.15 and TF1.17 in an enzyme-linked immunosorbent assay. MAb TF1.17 reacted with 32 of the 36 isolates, whereas MAb TF1.15 reacted with all of the isolates tested. One of the isolates which did not react with MAb TF1.17 (i.e., D1#3) was investigated further by Western blotting (immunoblotting) to determine the reason for the lack of reactivity with one of the two cross-reactive MAbs. The antigenic band that was reactive with MAb TF1.15 had a molecular mass slightly lower than that of the corresponding band from isolate D1, which reacted with both MAbs TF1.15 and TF1.17. Thus, at least a major portion of the antigen appeared to be conserved. This was confirmed in a study of heifers infected with isolate D1#3. The vaginal immunoglobulin A antibodies of these infected heifers reacted with the antigen of isolate D1 that was immunoaffinity purified with MAb TF1.17. Therefore, even though the epitope recognized by MAb TF1.17 was missing in the challenge isolate (D1#3), the heifers developed an immune response to the rest of the molecule. These results indicate that the major portion of the previously described protective antigen is conserved in different isolates of T. foetus. This portion contains the epitope that reacts with MAb TF1.15. Most isolates express the whole antigen, which possesses both TFl.15 and TF1.17 epitopes, but the few isolates that are missing the portion containing the TF1.17 epitope may still elicit an immune reponse to the conserved portion. Thus, the protective surface antigen is promising for use in immunodiagnosis or vaccination against bovine trichomoniasis.     

Antigenic differentiation of avian pneumovirus isolates using polyclonal antisera and mouse monoclonal antibodies

Avian pneumovirus (AVP) isolates F83, CC220 and 1260 from Great Britain and 1556, 657/4, 2119 and 872/S from France, Hungary, Italy and Spain, respectively, were compared in ELISA and virus neutralization (VN) tests for reactions with chicken polyclonal sera against each of the viruses and monoclonal antibodies (MAbs) against two British isolates. ELISA test results using the polyclonal antisera indicated that all seven viruses were antigenically related, but some variation between strains could be detected, especially when antigens were prepared from infected cells using Nonidet P40 (NP40) rather than freezing and thawing. In VN tests results also showed that all viruses tested were related but there was evidence that the three British isolates showed closer relationships with each other than with the viruses from Italy, Hungary and Spain. In ELJSA tests, isolates F83 and 1556 bound all 11 MAbs and 1260 reacted with 10/11 MAbs. Isolate CC220 showed reaction with all the MAbs but for 8/11 MAbs the optical density differences were low. Isolates 2119 and 872/S both reacted only with MAb 4 and none of the MAbs reacted with 657/4.     

Serotyping Isolates of Anaplasma phagocytophilum by Using Monoclonal Antibodies

Ten mouse monoclonal antibodies (MAbs) that react with Anaplasma phagocytophilum (the human granulocytic ehrlichiosis agent) Webster isolates were developed. Seven different isolates of A. phagocytophilum were subtyped with these MAbs. Western blot analysis revealed that these MAbs reacted mainly with 41- to 46-kDa Msp2 proteins. Six MAbs reacted with all isolates. Four other MAbs reacted with human isolates from Wisconsin, but not with human isolates from New York or with animal isolates. Three different serotypes were identified. These features may lead to the development of other specific MAbs in order to provide tools for antigenic characterization of human isolates of A. phagocytophilum.     

Novel monoclonal antibodies that bind to wild and fixed rabies virus strains

Ten monoclonal antibodies (MAbs) against rabies virus, including IgG3κ, IgG2aκ, IgMκ, and an IgG2bκ isotype, were produced and characterized using neutralization, ELISA, immunodot-blot, and immunofluorescence assays. MAb 8D11, which recognized rabies virus glycoprotein, was found to neutralize rabies virus in vitro. When submitted to an immunofluorescence assay, seven MAbs showed different reactivity against 35 Brazilian rabies virus isolates. Three MAbs (LIA 02, 3E6, and 9C7) only failed to recognize one or two virus isolates, whereas MAb 6H8 was found to be reactive against all virus isolates tested. MAbs were also evaluated for their immunoreactivity against fixed rabies virus strains present in human and veterinary commercial vaccines. MAbs LIA 02, 6H8, and 9C7 reacted against all vaccine strains, while the remaining MAbs recognized at least 76% of vaccine strains tested. This research provides a set of MAbs with potential application for improving existing or developing new diagnostic tests and immunoassays.     

Characterisation and epitope analysis of monoclonal antibodies to virions of clover yellow vein and Johnsongrass mosaic potyviruses

Summary Mouse monoclonal antibodies (MAbs) against the Australian B strain of clover yellow vein (C1YVV-B) and the JG strain of Johnsongrass mosaic (JGMV) potyviruses were produced, characterised and the epitopes with which they reacted were deduced. Using intact particles of C1YVV a total of ten MAbs were obtained which reacted strongly with C1YVV-B in an enzyme-linked immunosorbent assay and Western blots. Four of these MAbs (1, 2, 4, and 13) were found to be ClYVV-specific, as they reacted with all five C1YVV strains from Australia and the U.S.A. but not with 11 strains of bean yellow mosaic (BYMV), pea mosaic (PMV), and white lupin mosaic (WLMV) viruses which, together with C1YVV, form the BYMV subgroup of potyviruses. These MAbs failed to react with eight other potyvirus species, including six which infect legumes like the viruses in the BYMV subgroup. The C1YVV MAb 10 was found to be BYMV subgroup-specific. It reacted strongly with 15 of the 16 strains of viruses in the subgroup and gave no reaction with eight other potyviruses. The other five C1YVV MAbs reacted with varying degrees of specificity with the BYMV subgroup viruses and also with other potyviruses. Eight of the C1YVV MAbs (1, 2, 4, 5, 13, 17, 21, and 22) reacted with the intact coat proteins only and not with the truncated (minus amino terminus) coat protein of C1YVV suggesting that the epitopes for these MAbs are located in the surface-exposed, amino-terminal region of the C1YVV coat protein. Comparison of published coat protein sequences of BYMV and C1YVV isolates indicated that the epitopes for the four ClYVV-specific MAbs may be in the amino-terminal region spanning amino acid residues 18 to 30, whereas those for the other four MAbs may be located in the first 17 amino-terminal amino acid residue region. The epitopes that reacted with BYMV subgroup-specific MAb 10 and MAb 30 which reacted with 20 of the 24 potyvirus isolates, are probably located in the core region of C1YVV coat protein as these MAbs reacted with the intact as well as truncated coat protein of C1YVV. Analysis, in Western blot immunoassay, of 17 MAbs raised against virions of JGMV revealed that only two MAbs (1–25 and 4–30) were JGMV-specific, whereas others displayed varying degrees of specificity to different potyviruses. When these MAbs were screened against the intact and truncated (minus 67 amino-terminal amino acid residues) coat proteins of JGMV, the two JGMV-specific MAbs reacted only with the intact coat protein, whereas the other MAbs reacted with the intact as well as with truncated coat proteins, in Western blots. These results suggest that the epitopes for the two JGMV-specific MAbs are located in the surface-exposed amino-terminal 67 amino acid residue region and those for the cross-reactive MAbs are contained in the conserved core region of the JGMV coat protein. Screening of potyvirus MAbs against intact and truncated coat proteins thus appears to be a simple procedure to select virus-specific MAbs to potyviruses.     

Serological specificities of murine hybridoma monoclonal antibodies against Neisseria meningitidis serogroups B, C, Y, and W135 and evaluation of their usefulness as serogrouping reagents by indirect whole-cell enzyme-linked immunosorbent assay

Murine hybridoma monoclonal antibodies (MAbs) were produced against the capsular antigens of serogroups B, C, Y, and W135 meningococci. Each serogroup-specific MAb reacted with the extracted capsular polysaccharide from its homologous serogroup only and did not react with capsules from the other three serogroups. The application of these MAbs for serogroup identification of meningococci was demonstrated by their abilities to correctly identify 183 clinical isolates of 185 meningococci recovered from individual invasive meningococcal disease (IMD) patients during routine surveillance in 2002. The remaining two meningococci were identified by PCR grouping as C in one case and Y in another, but neither isolate was positive by bacterial agglutination using rabbit antisera or by enzyme-linked immunosorbent assay using MAbs. The specificities of the anti-Y and anti-W135 MAbs were further assessed by tests with 37 serogroup W135 and 106 serogroup Y meningococci recovered from IMD cases during 1999 to 2001 and 2003. All 143 meningococci except one serogroup Y isolate were correctly identified by positive reactions with the corresponding MAbs that identified their homologous serogroups. The single serogroup Y isolate was received as nonagglutinable and tested as negative with both rabbit anti-Y antiserum and anti-Y MAb but was positive for the serogroup Y-specific siaD gene. The advantage of using MAbs for serogrouping of meningococci is discussed.     

A panel of monoclonal antibodies targeting the rabies virus phosphoprotein identifies a highly variable epitope of value for sensitive strain discrimination

A recombinant rabies virus phosphoprotein fusion product (GST-P) was used to generate a series of monoclonal antibodies (MAbs) with anti-P reactivity. Competitive binding assays classified 27 of these MAbs into four groups (I to IV), and 24 of them were deemed to recognize linear epitopes, as judged by their reaction in immunoblots. The linear epitope recognized in each case was mapped by using two series of N- and C-terminally deleted recombinant phosphoproteins. Assessment of the reactivities of representative MAbs to a variety of lyssavirus isolates by an indirect fluorescent antibody test indicated that group I MAbs, which recognized a highly conserved N-terminal epitope, were broadly cross-reactive with all lyssaviruses assayed, while group III MAbs, which reacted with a site overlapping that of group I MAbs, exhibited variable reactivities and group IV MAbs reacted with most isolates of genotypes 1, 6, and 7 only. In contrast, group II MAbs, which recognized an epitope located within a highly divergent central portion of the protein, were exquisitely strain specific. These anti-P MAbs are potentially useful tools for lyssavirus identification and discrimination.