Serological analysis of serogroup icterohaemorrhagiae using monoclonal antibodies

Eighteen serovars (19 strains) of serogroup Icterohaemorrhagiae were serologically analyzed using 18 monoclonal antibodies against serovar copenhageni Shiromizu, M20 and serovar icterohaemorrhagiae RGA strains. The reaction patterns of the serovars against these monoclonal antibodies were different. According to these results, we divided the serovars, except for serovar tonkini, into the following three subgroups: Subgroup 1 reacted to many monoclonal antibodies including serovars icterohaemorrhagiae, copenhageni, hualien, monymusk, mankarso, and budapest. Subgroup 2 fell between subgroups 1 and 3 including serovars dakota, naam, bogvere, birkini, smithi, ndambari, gem, ndahambukuje and mwogolo. Subgroup 3 reacted to only a few monoclonal antibodies: serovars weaveri and sarmin. Serovar tonkini did not react to any of the monoclonal antibodies used. There is a possibility that serovar tonkini does not belong to serogroup Icterohaemorrhagiae. Further studies on the serological reactions of each strain revealed that it was impossible to distinguish the RGA strain from the serovar hualien LT11-31 strain, indicating that they may be identical. It was also observed that serovar copenhageni and monymusk seemed to be closely related. Serovars birkini and smithi, and serovars ndambari and gem were alike in their serological reactivities. Among the 18 monoclonal antibodies, RGAMA-1 was a unique antibody which reacted only to serovar icterohaemorrhagiae and serovar hualien, indicating that it must be the serovar icterohaemorrhagiae specific antibody. On the other hand, SHIRMA-2, 5, 6 reacted to all the serovars except for serovars weaveri, sarmin, and tonkini. These antibodies exhibited a broad reaction spectrum.     

Restriction endonuclease DNA analysis of Leptospira interrogans serovars Icterohaemorrhagiae and Copenhageni

Leptospira interrogans serovar icterohaemorrhagiae strains Ictero No. I and RGA and serovar copenhageni strains M20, Shiromizu and Shibaura were examined by restriction endonuclease DNA analysis. Fifteen endonucleases (AluI, BamHI, BglII, EcoRI, HaeIII, HhaI, HindIII, KpnI, PstI, SacI, SalI, SmaI, StyI, XbaI and XhoI) were used as the digesting enzymes. Strain Ictero No. I showed endonuclease cleavage patterns which differed from those of the other four strains only when it was digested with enzymes KpnI and HindIII. When digested with KpnI, an extra band of about 5.4 kb was clearly produced, and when digested with HindIII, an extra band of about 25 kb was produced. When the other 13 enzymes were used, no differences were found between the endonuclease cleavage patterns among the five strains. Moreover, strains RGA, M20, Shiromizu and Shibaura could not be distinguished by the restriction endonuclease DNA analysis using all 15 endonucleases. In addition, six newly isolated leptospires from patients with leptospirosis and from Rattus norvegicus were compared with the Ictero No. I and M20 strains, by restriction endonuclease DNA analysis using enzymes KpnI and HindIII. Three leptospires belonging to serovar icterohaemorrhagiae showed the same endonuclease cleavage patterns as the M20 strain. The other three strains, which belong to serovar copenhageni, showed almost the same endonuclease cleavage patterns as the M20 strain; only the Kai ima 702 strain produced an extra band which was not identical to the Ictero No. I-specific extra band when digested with HindIII. The leptospiral restriction endonuclease DNA analysis has revealed taxonomic structures that are unrecognized by serology alone.     

An immunoprotective monoclonal antibody directed against Leptospira interrogans serovar copenhageni

A monoclonal antibody (mAb) was prepared by hybridoma technology in BALB/c mice immunized to Leptospira interrogans serovar copenhageni. This mAb agglutinated serovars copenhageni and icterohaemorrhagiae to high titres and protected hamsters, dogs and monkeys against challenge with a virulent strain of serovar copenhageni. The mAb gave protection to hamsters at dilutions up to 1 in 1000; at a 1 in 10 dilution the protective effect lasted for at least two weeks. Biochemical analysis by SDS-PAGE and Western blotting indicated that this mAb reacted with an epitope of a carbohydrate nature.     

Serological studies on Leptospira strain Ictero No. I using monoclonal antibodies.

In order to elucidate the full serological characteristics of strain Ictero No. I, the first strain of Leptospira isolated by Inada and Ido in 1914, 17 monoclonal antibodies against the strain were produced by cell fusion technology. The antibody-producing hybridomas were designated IMAs 1 to 17. The reactivities of the monoclonal antibodies produced by the hybridomas were determined by the microscopic agglutination test. One of the 17 monoclonal antibodies, IMA 1, reacted with strains Ictero No. I, LT 1131 and Naam, but not with other strains of the serogroup Icterohaemorrhagiae including strain RGA used in the present study. Moreover, the reactivity of the antigenic determinant of IMA 1 was inactivated by treatment at 56 C for 30 min. The 16 other monoclonal antibodies, IMAs 2 to 17, showed different reaction patterns against Leptospira strains of the serogroup Icterohaemorrhagiae. All of the 16 antibodies reacted with both Ictero No. I and RGA strains. The antigens against antibodies IMAs 2 to 17 were thermostable. The present study thus clarified the presence of a thermolabile antigen in strain Ictero No. I, and allowed correct distinction between the serotype of strain Ictero No. I and that of strain RGA using IMA 1. Therefore, we propose that strain Ictero No. I represents serovar icterohaemorrhagiae, as originally designated by Inada and Ido. Moreover, strain Ictero No. I should be designated as the type strain of Leptospira interrogans.     

Monoclonal antibodies for a comparative serological study of strains of Vibrio anguillarum

Murine monoclonal antibodies against characteristic determinants of heat stable somatic antigens of typical serovar I (820/15/8 Kop) and serovar II (134/82/1 Kiel) of European Vibrio anguillarum strains were produced. Three stable hybridoma cell lines, called aVaI/1F4, aVaI/6F4 and aVaI/2H5, produced monoclonal antibodies each against a typical serovar I determinant of strain 820/15/8 Kop. One hybridoma cell line (aVaII/5A4) producing monoclonal antibodies against Vibrio anguillarum strain 134/82/1 Kiel (serovar. II) was established. Fourteen Vibrio strains and Aeromonas salmoniáda strains were serologically compared by Enzyme-Linked Immunosorbent Assay (Elisa ).     

An application of monoclonal antibodies to identification of leptospires of serogroup icterohaemorrhagiae found in China

For the purpose of improving the procedures of identification of leptospires, a set of 5 monoclonal antibodies with different serological reactivity against serovars of Leptospira interrogans Icterohaemorrhagiae serogroup isolated in China was developed. One hundred and eight strains isolated from epidemic fields in 5 provinces in southern China were distinctly identified into 4 serovars of Icterohaemorrhagiae serogroup by the monoclonal antibody procedure, i.e., 98 isolates were identified as serovar lai, 7 as icterohaemorrhagiae, 2 as copenhageni, and 1 as H2. Factor antiserum procedure was used at the same time as control for typing these strains and an identical result was obtained.     

Spherical Parasporal Inclusions of the Lepidoptera-Specific and Coleoptera-Specific Bacillus thuringiensis Strains: A Comparative Electron Microscopic Study

Four Lepidoptera-specific Bacillus thuringiensis strains that belong to the four H serogroups (serovars sumiyoshiensis, fukuokaensis, darmstadiensis, and japonensis) and a Coleoptera (Scarabaeidae)-specific strain belonging to serovar japonensis were examined for comparative ultrastructure of spherical parasporal inclusions. The prominent feature of the inclusions of the Lepidoptera-specific strains was the existence of thick, highly electron-dense envelopes surrounding a homogeneous protein matrix. The envelopes were 15.0–66.7 nm thick and consisted of 5–12 layers of membrane. This is also the case with inclusions of a Coleoptera-specific strain. The ultrastructure of inclusions from the five strains was in marked contrast to that of the bipyramidal parasporal inclusions produced by a Lepidoptera-specific serovar sotto strain. Received: 26 July 1999 / Accepted: 30 August 1999     

Incidence of leptospiral antibodies in different game species over a 10-year period (1996–2005) in Croatia

During the 10-year survey (1996–2005), a total of 868 blood samples from different game species in Croatia were analyzed for the presence of leptospiral antibodies. The specific antibodies (AB) were detected in 242 samples (27.88%). According to the species in red deer (Cervus elaphus), the antibodies against six different leptospiral serovars were found in 43 of 226 analyzed sera (19.02%). The most frequent antigen serovars in the deer population were Pomona and Ballum (with the same frequency of 23.6%), whereas the highest titer was recorded for serovar Sejroe (1:800). In the analyzed roe deer (Capreolus capreolus) serum samples, a low level of leptospiral antibodies (6.07%) was determined, with just two AB for antigen serovars—Australis and Sejroe. In wild boar (Sus scrofa), leptospiral antibodies were detected in 151 of 431 samples analyzed (35.03%), with AB for nine antigen serovars. The serovars most frequently found were Australis (48.70%) and Pomona (22.70%), and these serovars also recorded the highest titer (1:3,200). Among brown bear (Ursus arctos) samples, leptospiral antibodies were detected in 25.00% of the samples, with four AB for antigen serovars, of which the most frequent was Icterohaemorrhagiae (>40%). This serovar had the highest recorded titer (1:400). From 112 analyzed red fox (Vulpes vulpes) samples, leptospiral antibodies were found in 35 samples (31.25%). The determined antibodies were specific for four antigen serovars, of which the most frequent (46.2%) and with highest titer (1:1600) was serovar Australis. No antibodies (28/0) were recorded in mouflon (Ovis musimon). The most important game species from an epizootiological point of view in the studied area were certainly wild boar and red foxes. With strong serological reactions, these two species could be emphasized as important hosts for Leptospira interrogans sv. Australis in Croatia, but for their declaration as ‘maintaining hosts,’ isolation of sv. Australis is needed. According to aerial distribution, the highest number of positive samples from different game species was recorded in the central and eastern parts of Croatia, known as the ‘historical natural foci’ of leptospirosis—the regions of Posavina, Podravina, Slavonija, and Baranja. In contrast, the areas of Kordun and Gorski Kotar are declared as leptospira low-risk regions for the game species studied.     

AN INDIRECT ENZYME-LINKED IMMUNOSORBENT ASSAY FOR THE DETECTION OF LEPTOSPIRA INTERROGANS SEROVAR POMONA ANTIBODIES IN BOVINE SERA

An indirect ELISA was developed and initially evaluated for the detection of bovine antibodies to Leptospira interrogans serovar pomona. The antigen used in this ELISA was extracted from a serovar pomona culture supernatant by a combination of centrifugation, digestion with proteinase K and ultra-centrifugation. The antigen showed little cross-reaction with immune rabbit sera to L. interrogans serovars copenhageni, grippotyphosa, hardjo and sejroe and, Leptospira biflexa serovar patoc. Some cross-reaction was observed with immune rabbit serum to L. interrogans serovar canicola. The relative sensitivity of the ELISA was 94.76% confidence interval =± 3.32%) when estimated with bovine sera (n=172) with serovar pomona microscopic agglutination test (MAT) titers of 100. The relative specificity of the ELISA was 99.28% (95% confidence interval = 1.40%) when estimated with bovine sera (n=139) with MAT titers of <100 to L. interrogans serovars canicola, copenhageni, grippotyphosa, hardjo, pomona and sejroe. Thirty six of 258 field sera (13.95%) with serovar pomona MAT titers of <100, gave positive reactions in the ELISA.     

Production and specificity of monoclonal antibodies and polyclonal antibodies to Escherichia coli

Monoclonal antibodies were produced to whole cells of heat-treated Escherichia coli. Balb/c mice were immunized with a pool of five strains of heat-treated E. coli, and the resulting hybridomas were screened by indirect immunoassay. E. coli strains other than those used for immunization were used for screening to detect hybridomas producing antibody that reacted with a large number of E. coli strains. Of 864 hybridomas, 32 reacted strongly with either two or all three of the strains used for screening; 15 were successfully cloned. Antibody from hybridoma 6H2 reacted with 35 of 68 (51%) E. coli; of 13 non-E. coli tested, only Enterobacter agglomerans was weakly positive. Hybridoma 9B12 antibody reacted with all six E. coli tested. Hybridoma 9B12, however, stopped producing antibody. Five hybridomas produced antibody which reacted with a majority of the bacteria tested whereas antibodies from two other hybridomas reacted with several E. coli and non-E. coli. Polyclonal antibodies produced to two strains of E. coli varied in the numbers of E. coli with which they reacted; both antisera cross-reacted with several non-E. coli.     

Monoclonal antibodies againstAgrobacterium tumefaciens strain C58

Hybridoma cell lines were derived from the fusion of mouse myeloma cells with spleen cells from a mouse that had been immunized withAgrobacterium tumefaciens strain A759, a flagella-less mutant of strain C58 containing the Ti plasmid of strain B6. All of the 20 antibodies produced by the cloned hybridomas reacted with strain C58 and with other strains derived from C58. The antibodies did not react with 34 other strains ofA. tumefaciens, representing the three biovars, or with strains ofA. radiobacter, A. rubi, Rhizobium leguminosarum, R. meliloti, or other plant-associated bacteria such asErwinia herbicola andPseudomonas syringae. In addition to reacting with whole cells of strain A759, the antibodies reacted with phenol-water extracts of A759, indicating that they may recognize the lipopolysaccharide. These antibodies may be useful for ecological and epidemiological studies ofA. tumefaciens strain C58 in the agroecosystem.     

Molecular cloning and characterization of <Emphasis Type="Italic">clyA</Emphasis> genes in various serotypes of <Emphasis Type="Italic">Salmonella enterica</Emphasis>

Cytolysin A (ClyA) is a pore-forming hemolytic protein encoded by the clyA gene. It has been identified in Salmonella enterica serovars Typhi and Paratyphi A. To identify and characterize the clyA genes in various Salmonella enterica strains, 21 different serotypes of strains isolated from clinical specimens were presently examined. Full-length clyA genes were found in S. enterica serovar Brandenburg, Indiana, Panama, and Schwarzengrund strains by polymerase chain reaction amplification. The ClyA proteins from these four strains showed >97% amino acid identity to that of S. enterica serovar Typhi. Although all four serovars expressed detectable levels of ClyA as determined by Western blot analysis, they did not show a strong hemolytic effect on blood agar, indicating that ClyA may not be efficiently expressed or secreted. Escherichia coli transformed with clyA genes from the four serovars enhanced production of ClyA proteins and hemolytic activities to a level similar to S. enterica serovar Typhi ClyA. The present results suggest that ClyA may play a role in the pathogenesis of S. enterica serovar Brandenburg, Indiana, Panama and Schwarzengrund.     

Production and specificity of monoclonal antibodies and polyclonal antibodies to Escherichia coli

Monoclonal antibodies were produced to whole cells of heat-treated Escherichia coli. Balb/c mice were immunized with a pool of five strains of heat-treated E. coli , and the resulting hybridomas were screened by indirect immunoassay. E. coli strains other than those used for immunization were used for screening to detect hybridomas producing antibody that reacted with a large number of E. coli strains. Of 864 hybridomas, 32 reacted strongly with either two or all three of the strains used for screening; 15 were successfully cloned. Antibody from hybridoma 6H2 reacted with 35 of 68 (51%) E. coli ; of 13 non- E. coli tested, only Enterobacter agglomerans was weakly positive. Hybridoma 9B12 antibody reacted with all six E. coli tested. Hybridoma 9B12, however, stopped producing antibody. Five hybridomas produced antibody which reacted with a majority of the bacteria tested whereas antibodies from two other hybridomas reacted with several E. coli and non- E. coli. Polyclonal antibodies produced to two strains of E. coli varied in the numbers of E. coli with which they reacted; both antisera cross-reacted with several non- E. coli.     

Monoclonal antibodies with specificity for three different serotypes of Marek's disease viruses in chickens

A total of 50 antibody-secreting hybridoma cells against Marek's disease virus (MDV) and turkey herpesvirus (HVT) have been produced. Eleven hybridomas were used for serotyping a panel of 15 pathogenic and nonpathogenic strains of MDV and HVT, representing three serotypes. The antibodies from the culture medium have fluorescence antibody (FA) titers of up to 100 and those from mouse ascitic fluid have titers ranging from 10(4) to 10(6). Monoclonal antibody T81 is type-common, i.e., it reacts at equal titer with all MDV and HVT tested. Of the remaining 10 antibodies, eight react only with pathogenic and attenuated strains of MDV (presumably serotype 1), one reacts only with nonpathogenic MDV (presumably) serotype 2), and one reacts only with strains of HVT (presumably serotype 3). Two hybridomas belong to IgG2a and IgG2b subclasses, respectively, and the remaining nine belong to IgG1 subclass. None of the antibodies specific for MDV strains reacted with homologous viruses in serum neutralization (SN), agar gel precipitin (AGP), or membrane immunofluorescence tests. Antibody L78, which is specific for HVT, was reactive with its homologous virus in the SN test; antibody from the culture medium showed an SN titer of 10 and that from mouse ascites a titer of 10,000. None of the antibodies specific for MDV or HVT reacted with other avian or mammalian herpesviruses, avian leukosis viruses (ALV), reticuloendotheliosis viruses (REV), or Marek's disease tumor-associated surface antigen (MATSA) expressed in a lymphoblastoid cell line, MDCC-MSB-1.     

Discrimination among <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> H serotypes,serovars and strains based on 16S rRNA, <Emphasis Type="Italic">gyrB</Emphasis> and <Emphasis Type="Italic">aroE</Emphasis> gene sequence analyses

Our aim was to investigate the capability of each of three genes, 16S rRNA, gyrB and aroE, to discriminate, first, among Bacillus thuringiensis H serotypes; second, among B. thuringiensis serovars from the same H serotype; and third, among B. thuringiensis strains from the same serovar. The 16S rRNA, gyrB and aroE genes were amplified from 21 B. thuringiensis H serotypes and their nucleotide sequences determined. Additional strains from four B. cereus sensu lato species were included for comparison purposes. These sequences were pair-wise compared and phylogenetic relationships were revealed. Each of the three genes under study could discriminate among B. thuringiensis H serotypes. The gyrB and aroE genes showed a discriminatory power among B. thuringiensis H serotypes up to nine fold greater than that of the 16S rRNA gene. The gyrB gene was retained for subsequent analyses to discriminate B. thuringiensis serovars from the same H serotype and to discriminate strains from same serovar. A total of 42 B. thuringiensis strains, which encompassed 25 serovars from 12 H serotypes, were analyzed. The gyrB gene nucleotide sequences were different enough as to be sufficient to discriminate among B. thuringiensis serovars from the same H serotype and among B. thuringiensis strains from the same serovar. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Comparative studies of strains Ictero No. I and RGA as the type strain of Leptospira interrogans: agglutinin absorption test, protein and antigen profiles, and enzyme activities

Strain Ictero No. I, the first isolate of Leptospira, isolated by Inada and Ido in 1914, was found to be sufficiently qualified to be the type strain of Leptospira interrogans rather than strain RGA. In an agglutinin absorption test, anti-Ictero No. I serum was not absorbed completely with strain RGA, and 25% of the homologous titer remained unabsorbed, while anti-RGA serum was completely absorbed with strain Ictero No. I. Thus, strain Ictero No. I was not serologically identical with strain RGA, and the two strains were considered to be different serovars. A protein band with a molecular weight of approximately 33,000 daltons was detected in strain Ictero No. I but not in strain RGA by SDS-PAGE. By Western blotting, this protein band was detectable with anti-Ictero No. I serum but not with anti-RGA serum. The presence of the 33K protein in strain Ictero No. I, but not in strain RGA, was confirmed by radioimmunoprecipitation using [125I]-labeled antigens, indicating that the protein antigen was surface-exposed. Only 8 of the 89 enzymes activities were different between strains Ictero No. I and RGA (line Sapporo). From the above results, we propose that strain Ictero No. I should be designated as the type strain of L. interrogans instead of strain RGA.     

Murine monoklonale Antikörper gegen Vibrio anguillarum vom Serotyp I und II

Murine monoclonal antibodies against Vibrio anguillarum serotype I und II Four stabil hybridoma cell lines against the Vibrio anguillarum strain 820/15/8 Kopenhagen—a typical serotype I strain—were raised. Three hybridoma cell lines producing monoclonal antibodies against the Vibrio anguillarum strain 134/82/1 Kiel (Serotype II) were established. The specifity of the antibodies was screened by ELISA. Monoclonal antibodies reacted with the characteristic determinant of the respective serotype only.     

Development and Application of Monoclonal Antibodies Against Xylella fastidiosa, the Causal Bacterium of Pear Leaf Scorch

Ten stable hybridoma cell lines, M As l -10, secreting monoclonal antibodies specific to the causal bacterium of pear leaf scorch (PLS), Xylella fastidiosa. were produced. The monoclonal antibodies can detect 3 × 10⁵ PLS-bacterium cells by indirect enzyme-linked immunosorbent assay (ELISA). In the antibody titer determination by indirect ELISA, hybridoma-culture supernatant from clone MA4 had the highest titer of 20480. In the antibody specificity tests, nine of the 10 monoclonal antibodies did not cross-react with 14 other bacterial strains belonging to nine genera. Only the antibody from hybridoma clone MAI cross-reacted with Xanthomonas campestris pv. cam-pestris and X. campestris pv. vesicatoria. In western blot analysis, all the monoclonal antibodies recognized the major 46.9-kDa polypeptide from all 12 X. fastidiosa strains and a distinct 21.5-kDa polypeptide only from PLS bacterium. In tissue-blotting detection, the PLS bacteria were specifically detected in blots of tissue sections from infected pear with the antibodies developed.     

Comparison of invasion of fibroblasts and macrophages by high- and low-virulence Leptospira strains: colonization of the host-cell nucleus and induction of necrosis by the virulent strain

The infection cycle of low- and high-virulence strains of Leptospira interrogans was compared in fibroblasts and macrophages. L. interrogans serovar Lai strain Lai was used as a representative high-virulence strain, while L. interrogans serovars Pomona strain Luo was used as a low-virulence strain. L. biflexa serovar Patoc strain Patoc I, a nonparasitic strain of Leptospira, was used as a control. Both the high- and low-virulence strains could adhere to fibroblasts and macrophages using one or both ends of the spirochete, which was followed by phagocytosis of both strains. Both strains adhered more strongly to macrophages than fibroblasts. However, the high-virulence strain could invade the host-cell nucleus, while the low-virulence strain remained in phagosomes. The L. biflexa strain neither adhered to nor invaded either cell type. Both of the L. interrogans strains also induced cell death (mostly necrosis) of macrophages, whether or not the spirochetes were viable, suggesting that leptospiral virulence is unrelated to macrophage death. However, the high-virulence strain induced mainly necrosis in fibroblasts, while the low-virulence strain induced more apoptosis. Thus, the main feature distinguishing the two L. interrogans strains is the ability of the high-virulence strain to invade the host-cell nucleus and induce pro-inflammatory necrosis in fibroblasts.     

Characterization of newly isolated monoclonal antibodies against MHC of a Japanese wild mouse

We have already developed nine B10.MOL congenic strains carrying H-2 haplotypes derived from Japanese wild mice, Mus musculus molossinus, with the C57BL/10 genetic background. To obtain monoclonal antibodies against the H-2 antigen of the Japanese wild mouse, we carried out cell fusion using spleen cells from the animal immunized with one of the B10.MOL strains, B10.MOL-SGR (H-2 ^wm7). As a result, 19 hybridomas producing monoclonal antibodies were produced. Analysis with the intro-H-2 recombinants derived from B10.MOL-SGR indicated that 8 of them reacted with the class I and II with the class II molecule. The class I antibodies were tested for their cross -reactivities on wild mice and on the panels of standard inbred and B10.MOL strains. Most of the antibodies reacted with both the Japanese wild mice and the other subspecies, including standard inbred, while two antibodies highly specific for the donor H-2K region reacted with only three wild-derived mice, two M. m. molossinus from Anj o and Shizuoka, Japan, and one M. m. domesticus from Pigeon, Canada. In addition, all of the other four antibodies reactive with the K antigen of B10.MOL-SGR also reacted with the same three wild mice. The wild mice belonging to different subspecies might share very similar H-2K antigenic determinants in spite of their genetic and geographical remoteness.