Rabbits produce SLE-like anti-RNA polymerase I and anti-DNA autoantibodies in responses to immunization with either human or murine SLE anti-DNA antibodies.

Anti-DNA and anti-DNA polymerase I (RPI) autoantibody responses are symptoms of systemic lupus erythematosus (SLE). To investigate the relationship between these antibodies (Ab), rabbits were immunized with one of the following preparations: human SLE anti-DNA Ab; human SLE anti-DNA IgG; normal human anti-DNA Ab; human Grave's disease anti-DNA Ab; murine SLE anti-DNA Ab or anti-DNA IgG Fab; various normal human, murine, or rabbit IgG preparations; or complete Freund's adjuvant (CFA), alone. All of the animals immunized with anti-DNA Ab (n = 14) generated Ab reactive in radioimmunoassay with: ssDNA, dsDNA, RPI, the soluble fraction of rabbit liver crude nuclear extract, and the immunogen. Induced rabbit anti-DNA Ab in turn induced these responses in a different rabbit: a rabbit immunized with rabbit anti-DNA IgG Ab which had been previously induced by immunization with human anti-DNA Ab, produced Ab reactive with ssDNA, dsDNA, RPI, and the soluble fraction of rabbit liver nuclear extract. Although an individual animal's antisera reacted consistently over the course of immunization with the same individual RPI subunit(s), antisera from different animals reacted with different subunits of the 9-subunit RPI complex in Western blot analyses: 190 kD (n = 6); 120 kD (n = 1); 62 kD (n = 4); 45 kD (n = 2); and, no reactivity (n = 2). In contrast, animals immunized with normal IgG or CFA produced responses only against the immunogen. Together, these data suggest that anti-DNA and anti-RPI responses are connected through an autoimmune network in SLE.

Detection of benzoquinone adducts to rat liver protein sulfhydryl groups using specific antibodies.

Benzoquinone is an electrophilic metabolite of bromobenzene and other simple aromatic compounds of toxicological interest including benzene, phenol, hydroquinone, and acetaminophen. In reacting with proteins benzoquinone shows great selectivity for Michael addition to sulfhydryl groups and formation of S-(2,5-dihydroxyphenyl) protein adducts. To facilitate the specific detection and eventual isolation and identification of such adducted proteins, we prepared an antiserum capable of recognizing hydroquinone moieties by immunizing rabbits with keyhole limpet hemocyanin modified with 3-[2,5-dihydroxyphenyl)thio]propanoyl groups as haptens. The antiserum had a high titer and showed high specificity for hapten in competitive ELISA with hapten analogues. In Western blot experiments the antiserum detected not only synthetically haptenized control proteins but also several proteins from rat liver microsomes that had been incubated in vitro with [14C]bromobenzene. This binding was completely blocked by free hapten, showing that it was hapten-specific. Each of the microsomal protein bands detected in the Western blots also contained radioactivity, but not all radioactive protein bands reacted with antibody. This antiserum should prove useful in exploring the role of protein arylation by benzoquinone in cytotoxic responses to its metabolic precursors.

Identification of a rat liver microsomal esterase as a target protein for bromobenzene metabolites.

The hepatotoxicity of bromobenzene and many other simple organic molecules has been associated with their biotransformation to chemically reactive metabolites and the subsequent covalent binding of those metabolites to cellular macromolecules. To identify proteins targeted by bromobenzene metabolites, we incubated [14C]bromobenzene in vitro with liver microsomes from phenobarbital-induced rats under conditions which typically led to covalent binding of 2-4 nmol equiv of bromobenzene/mg of protein. Microsomal proteins were solubilized with detergent, separated by chromatography and electrophoresis, and analyzed for 14C by phosphorimaging of stained blots. Much of the radioactivity was associated with several bands of proteins of ca. 50-60 kDa, plus another prominent band around 70 kDa, but labeling density appeared to vary considerably overall. A major radiolabeled protein was purified by preparative electrophoresis and submitted to automated Edman microsequencing. Its N-terminal sequence was found to correspond to that of a known rat liver microsomal carboxylesterase (E.C. 3.1.1.1) previously identified as a target for reactive metabolites of halothane. The extent to which covalent modification of this protein by reactive metabolites contributes to the production of hepatotoxic effects remains to be determined.

Detection of adducts of bromobenzene 3,4-oxide with rat liver microsomal protein sulfhydryl groups using specific antibodies.

The hepatotoxicity of bromobenzene (BB) has been attributed to covalent modification of cellular proteins by reactive metabolites generated during its oxidative biotransformation. Much of the net covalent binding which occurs originates via quinone metabolites, but bromobenzene 3,4-oxide (BBO), which is the reactive metabolite thought to be most significant toxicologically, also arylates protein side chains, although to a lesser extent. To facilitate the detection, isolation, and identification of rat liver proteins specifically adducted by BBO, we raised polyclonal antibodies capable of recognizing S-(p-bromophenyl)cysteine moieties (anti-BP) by immunizing rabbits with p-bromophenylmercapturic acid conjugated to keyhole limpet hemocyanin. The antiserum had a high titer, showed a high specificity for hapten in competitive ELISA with hapten analogues, and performed well in Western blot experiments using synthetically haptenized control proteins. When used for Western analysis of protein fractions from in vitro incubations of rat liver microsomes with [14C]BB, affinity-purified anti-BP recognized a limited number of bands, each of which also contained 14C. One of these bands corresponds to hydrolase B, a nonspecific esterase known to contain one free sulfhydryl group and previously shown to be a target protein for [14C]BB metabolites.

Induction of an anti-Fab, anti-DNA and anti-RNA polymerase I autoantibody response network in rabbits immunized with SLE anti-DNA antibody.

Systemic lupus erythematosus (SLE)-like anti-IgG Fab autoantibodies (autoAb) were induced in rabbits by immunization with either human, mouse or rabbit anti-DNA Ab. In direct-binding radioimmunoassay (RIA), affinity-purified anti-normal rabbit (NR) Fab autoAb cross-reacted with normal mouse (NM) Fab, ssDNA (but not dsDNA), poly(dA,dT), and RNA polymerase I (RPI). Affinity-purified anti-NM IgG Ab isolated from the same antisera cross-reacted with NR Fab, ssDNA and RPI. In inhibition RIA, soluble NR Fab inhibited anti-NR Fab binding to NR Fab and ssDNA, but enhanced binding to RPI. In contrast, ssDNA or RPI inhibitors had no effect upon autoAb binding to NR Fab. Anti-DNA, anti-RPI and anti-RPI 190 kD subunit autoAb, induced by immunization with lupus mouse anti-DNA Ab, also reacted with NM Fab, but were idiotypically specific for lupus mouse anti-DNA Fab. Further, rabbit anti-DNA and anti-RPI IgG autoAb, induced by immunization with rabbit anti-DNA IgG, were each idiotypically specific for homologous and autologous rabbit anti-ssDNA Fab. Together, these data provide evidence that anti-DNA, anti-RPI and anti-Fab autoAb are linked in a complex, multiple-specific and perhaps regulatory, immune response idiotype network in SLE.