Monoclonal antibody to native P39 protein from Borrelia burgdorferi.

We have produced, by using a sonicate of Borrelia burgdorferi, a monoclonal antibody (MAb), NYSP39H, that is specific for the P39 protein band. This MAb reacted with 13 isolates of B. burgdorferi but not with eight different spirochetes (four borrelias, two leptospiras, and two treponemas). Surface labeling of B. burgdorferi with biotin and subsequent treatment with Nonidet P-40 showed that P39 was not biotinylated but was extracted with Nonidet P-40, indicating that it is present within the outer membrane, but not on the surface of the spirochete. Immunoelectron microscopy revealed the immunogold probe primarily at the cytoplasmic membrane region of the spirochete. The MAb detected B. burgdorferi in the indirect fluorescent-antibody test only when the spirochetes from a culture or in a tick homogenate were fixed with polylysine and not with acetone. NYSP39H appears to be an appropriate probe for use in the specific detection of B. burgdorferi.

Differences in expression of lupus nephritis in New Zealand mixed H-2z homozygous inbred strains of mice derived from New Zealand black and New Zealand white mice. Origins and initial characterization.

BACKGROUND: F1 hybrids of New Zealand Black (NZB) and New Zealand White (NZW) mice develop autoimmune glomerulonephritis resembling human lupus nephritis. Susceptibility to this complex autoimmune syndrome in humans and mice has been linked to genes mapping in or near the major histocompatibility complex that govern immune responses and levels of certain complement components. Previous studies showed that both parental strains contribute major histocompatibility complex-linked genes that are important for disease of the F1 hybrid. EXPERIMENTAL DESIGN: New inbred strains of New Zealand Mixed (NZM) mice were derived by selective inbreeding of progeny of a cross between NZB and NZW mice. Twelve of the 27 new NZM strains were selected for analysis. Mice were observed for up to 10 months of age to document the occurrence of nephritis and strain-specific differences in disease expression. H-2, Hc, and coat color loci were determined for each strain to establish homozygosity of NZB and NZW polymorphic markers. Strains were screened for the presence of anti-dsDNA autoantibodies. RESULTS: In some NZM strains early onset of lupus nephritis in females resembled the (NZB x NZW)F1 model, whereas in other strains early disease also occurred in males. Age at death and severity of nephritis vary among the lines; a few strains remain relatively free of glomerular lesions. Histocompatibility (H-2) typing showed that all strains are homozygous for the NZW haplotype (Ku, Au, Sz, Dz). Coat color analysis for four loci on chromosomes 2, 4, and 7 was consistent with specific reassortments and recombinations to explain the grey, tan, and white mice with red/pink eyes and the presence or absence of the fifth component of serum complement (C5) (Hc, chromosome 2). Anti-dsDNA autoantibodies were found in all but one of the NZM strains reported here. CONCLUSIONS: The NZM strains of mice are a unique set of inbred strains that have inherited various genomic segments of the two parental strains that lead to phenotypic differences in disease expression. These results indicate that the previously proposed strict requirement for H-2 heterozygosity for the development of nephritis in the (NZB x NZW)F1 hybrid mice may not be valid. It is assumed that both the Lpn-1 locus of NZB and the Lpn-2 locus of NZW and a sufficient number of other disease-associated genes of both ancestral strains have been recombined in these new strains to produce the various patterns of renal disease.

Lack of passive transfer of renal tubulointerstitial disease by serum or monoclonal antibody specific for renal tubular antigens in the mouse.

Mice immunized with rabbit renal basement membranes form autoantibodies to their kidney glomerular and tubular basement membranes (GBM/TBM). Development of renal tubular disease (RTD) consists of deposition of autoantibodies along the GBM/TBM with the inter- and intratubular accumulation of lymphocytes and macrophages and destruction of the TBM. Transfer of this disease in mice with either serum or monoclonal antibodies, however, has been difficult to demonstrate and, therefore, attempts were made to confirm a report that RTD is passively transferred by anti-TBM autoantibodies. Using the revised protocol in this later report, we found that 12 weeks after transfer autoantibodies were deposited along the GBM and/or TBM of the recipients, yet RTD was not observed. Although qualitative and quantitative characteristics of the antibody may play a role in the pathogenesis in the murine model of RTD, we could not obtain evidence to support and confirm this study.