Study of procainamide hapten-specific antibodies in rabbits and humans

Drug-induced Glomerulonephritis: The Spectre of Biotherapeutic and Antisense Oligonucleotide Immune Activation in the Kidney

Prevalence of immune-mediated glomerulonephritis has increased in preclinical toxicity studies, with more frequent use of biotherapeutic agents (especially antigenic humanized molecules) and antisense oligonucleotide (ASO) therapies. Immune complex disease affects a small number of study monkeys, often correlates with antidrug antibody (ADA) titers, and occurs at a dose that favors immune complex formation or impedes clearance. While preclinical glomerulonephritis often fails to correlate with evidence of glomerular or vascular injury in human clinical trials and is not considered predictive, additional animal investigative immunohistochemical work may be performed to substantiate evidence for immune complex pathogenesis. While ADA is most commonly encountered as a predisposing factor with biotherapeutic agents, complement activation may occur without circulating complexes, and other mechanisms of non-ADA immune-mediated glomerulonephritis have been observed including nonendogenous immune aggregates and immunoregulatory pharmacology. Although glomerulonephritis associated with oligonucleotide therapies has been noted occasionally in preclinical studies and more rarely with human patients, pathophysiologic mechanisms involved appear to be different between species and preclinical cases are not considered predictive for humans. ADA is not involved in oligonucleotide-associated cases, and complement fixation plays a more important role in monkeys. Recent screening of ASOs for proinflammatory activity appears to have decreased glomerulonephritis incidence preclinically.

Drug-induced lupus

INTRODUCTION

Drug-induced lupus (DIL) refers to an idiosyncratic side effect of numerous, apparently unrelated, medications, in which symptoms overlap with those of systemic lupus erythematosus. DIL is reversible by discontinuation of the medication. The etiological mechanism underlying DIL is linked to the inherent susceptibility of the adaptive immune system to lapse into auto-reactivity.

AREAS COVERED

Clinical and laboratory features of DIL will be compared with those of idiopathic systemic lupus and with other types of drug reactions with overlapping features. Formerly commonly-used drugs conferred very high risk of developing DIL, although the probability of developing DIL has not been established with most lupus-inducing drugs. Pharmacological or physiochemical properties of the parent compounds are uninformative, but the importance of reactive drug metabolites in initiating autoimmunity will be discussed. As with most systemic autoimmune diseases, the pathogenesis of DIL is complex and obscure. The role of complement and human leukocyte allotypes as well as drug acetylator phenotype inform the underlying mechanism, and several of these non-mutually exclusive concepts will be described.

EXPERT OPINION

The pros and cons of proposed mechanisms for DIL will be discussed in the context of current understanding of autoimmunity and immune tolerance to self.

Autoantibodies to posttranslational modifications in rheumatoid arthritis

Autoantibodies have been associated with human pathologies for a long time, particularly with autoimmune diseases (AIDs). Rheumatoid factor (RF) is known since the late 1930s to be associated with rheumatoid arthritis (RA). The discovery of anticitrullinated protein antibodies in the last century has changed this and other posttranslational modifications (PTM) relevant to RA have since been described. Such PTM introduce neoepitopes in proteins that can generate novel autoantibody specificities. The recent recognition of these novel specificities in RA provides a unique opportunity to understand human B-cell development in vivo. In this paper, we will review the three of the main classes of PTMs already associated with RA: citrullination, carbamylation, and oxidation. With the advancement of research methodologies it should be expected that other autoantibodies against PTM proteins could be discovered in patients with autoimmune diseases. Many of such autoantibodies may provide significant biomarker potential.

A comparison of the covalent binding of clozapine, procainamide, and vesnarinone to human neutrophils in vitro and rat tissues in vitro and in vivo

Covalent binding of drug reactive metabolites to neutrophils or their precursors is thought to play a role in the development of drug-induced agranulocytosis. In this study, we used immunochemical techniques to compare the covalent binding of clozapine, vesnarinone, and procainamide (three drugs associated with agranulocytosis) to phorbol-12,13-myristate acetate (PMA)-activated human neutrophils in vitro and rat tissues in vivo. In PMA-activated human neutrophils in vitro, clozapine and procainamide modified neutrophil proteins with molecular masses ranging from 30 to 200 kDa, while vesnarinone predominately formed adducts with molecular masses greater than 70 kDa. All three drugs formed adducts at 126, 98, and 58 kDa, and they all covalently bound to human myeloperoxidase when incubated with this enzyme and H2O2 in vitro. Covalent binding to PMA-activated neutrophils was inhibited by nucleophiles, such as glutathione and N-acetylcysteine, but not by N-acetyllysine. In the presence of the PMA, all three drugs covalently bound to activated rat bone marrow cells in vitro, while in its absence only clozapine did. Covalently modified liver proteins were observed in rats treated for 6 weeks with clozapine (25 or 50 mg/kg/day), vesnarinone (300 mg/kg/day), or procainamide (50 mg/kg/day). Clozapine extensively modified proteins in all subcellular fractions; procainamide formed a 99 kDa adduct in a membrane-containing fraction and 57, 47, and 36 kDa adducts in a cytosolic fraction, while vesnarinone formed liver-protein adducts with molecular masses of 82, 62, 49, and 40 kDa in membrane, cytosolic, and S9 fractions. In addition, clozapine and procainamide, but not vesnarinone, formed a 49 kDa drug-protein adduct in the bone marrow of treated rats. Furthermore, procainamide covalently bound to a 58 kDa protein in neutrophils of a patient treated with the drug. We suspect that covalent modification of common targets in the neutrophils by these three drugs plays a role in the development of drug-induced agranulocytosis.

Thymus function in drug-induced lupus

Autoimmunity develops when a lupus-inducing drug is introduced into the thymus of normal mice, but the relevance of this model to the human disorder is unclear in part because it is widely assumed that the thymus is non-functional in the adult. We compared thymus function in 10 patients with symptomatic procainamide-induced lupus to that in 13 asymptomatic patients who only developed drug-induced autoantibodies. T cell output from the thymus was quantified using a competitive polymerase chain reaction that detects T cell receptor DNA excision circles in peripheral blood lymphocytes. Despite the advanced age of the patient population under study, newly generated T cells were detected in all subjects. Although there was no overall quantitative difference between the symptomatic and asymptomatic patients, we found a positive correlation between the level of T cell receptor excision circles in peripheral lymphocytes and serum IgG anti-chromatin antibody activity in patients with drug-induced lupus. The association between autoantibodies and nascent peripheral T cells supports the requirement for T cells in autoantibody production. Our observations are consistent with findings in mice in which autoreactive T cells derived from drug-induced abnormalities in T cell development in the thymus.

Genetic and immunologic studies of patients on procainamide

Forty (40) patients with cardiac arrhythmias receiving procainamide (PA) therapy and 24 patients who were receiving other drugs for their cardiac disorders were investigated for class II HLA phenotypes and their DRB1*04 and DQB1*03 subtypes. Other genetic marker evaluations in the PA patients included: 1) class III MHC C4A and C4B null alleles of complement; and, 2) acetylation phenotype. Twenty (20) of the PA patients were also tested for the ability of their stimulated cells to secrete Interleukin-1 (IL-1 beta) and tumor necrosis factor (TNF alpha). We also examined the spontaneous production of these cytokines by peripheral blood leukocytes (PBL) from patients who were receiving chronic PA treatment. The results revealed no association of acetylation phenotypes with the class II HLA phenotypes nor class III MHC C4 allotypes in these patients. The results did show a significant increase in class III C4 complement allotypes in the PA patients when compared to the controls. The results also showed a significant increase in autoantibodies and DQw3 phenotypes in the PA patient group when compared to control populations. Results of spontaneous IL-1 and TNF production suggested there may be an association of select class II HLA phenotypes in some patients and this may be relevant to host responsiveness to PA treatment.

Persistence of autoantibodies against recombinant mitochondrial and nuclear pore proteins after orthotopic liver transplantation for primary biliary cirrhosis

Primary biliary cirrhosis is an autoimmune disease characterized by high titer autoantibodies predominantly against mitochondrial antigens PDC-E2, BCOADC-E2 and OGDC-E2. Currently orthotopic liver transplant (OLT) is the major form of treatment for end-stage primary biliary cirrhosis (PBC), but it is still unclear whether the autoimmune response continues post-transplantation. In this study we took advantage of a well-defined collection of sera collected serially before and after liver transplantation. We assayed these sera for quantitative and isotype-specific titers of antibodies against a set of recombinant mitochondrial autoantigens. We also studied reactivity to gp210. Serum samples were taken before transplantation and at intervals of 6 months, 1, 2, and 3 years after OLT. Before OLT 24/35 patients were AMA-positive, including seven out of the 35 to PDC-E2 alone, eight to both PDC-E2 and OGDC-E2, six to both PDC-E2 and BCOADC-E2, two to BCOADC-E2 alone and one to OGDC-E2. Following OLT, the frequency of sera that responded to PDC-E2 alone increased from seven to 12/35. Similarly, reactivity to BCOADC-E2 slightly increased from two to four out of 35. However, there was an overall decrease in sera that responded to more than one antigen. Neither Ig isotype nor subclass of the autoimmune response changed following OLT. Findings with gp210 were similar, in that reactivity to gp210 was found in nine out of 35 patients pre-OLT; following OLT the frequency decreased to seven out of 35 patients. Overall, the titers of AMAs decline slightly during the first year post-OLT, but are equivalent to pre-OLT values by 6 months. Moreover, the antibody subclass/ isotype remained unchanged. These data suggest that the removal of a diseased PBC liver has little, if any, impact on the serological characteristics of PBC. Moreover, it provides information regarding the natural history of PBC, particularly on the long latency time for disease development.

Autoimmunity caused by disruption of central T cell tolerance. A murine model of drug-induced lupus

A side effect of therapy with procainamide and numerous other medications is a lupus-like syndrome characterized by autoantibodies directed against denatured DNA and the (H2A-H2B)-DNA subunit of chromatin. We tested the possibility that an effect of lupus-inducing drugs on central T cell tolerance underlies these phenomena. Two intrathymic injections of procainamide-hydroxylamine (PAHA), a reactive metabolite of procainamide, resulted in prompt production of IgM antidenatured DNA antibodies in C57BL/6xDBA/2 F1 mice. Subsequently, IgG antichromatin antibodies began to appear in the serum 3 wk after the second injection and were sustained for several months. Specificity, inhibition and blocking studies demonstrated that the PAHA-induced antibodies showed remarkable specificity to the (H2A-H2B)-DNA complex. No evidence for polyclonal B cell activation could be detected based on enumeration of Ig-secreting B cells and serum Ig levels, suggesting that a clonally restricted autoimmune response was induced by intrathymic PAHA. The IgG isotype of the antichromatin antibodies indicated involvement of T cell help, and proliferative responses of splenocytes to oligonucleosomes increased up to 100-fold. As little as 5 microM PAHA led to a 10-fold T cell proliferative response to chromatin in short term organ culture of neonatal thymi. We suggest that PAHA interferes with self-tolerance mechanisms accompanying T cell maturation in the thymus, resulting in the emergence of chromatin-reactive T cells followed by humoral autoimmunity.

The role of the lymphocyte in an immune response

The immune system has evolved in the human being as an elaborate mechanism to distinguish itself from all else that is not self. This process serves in the defence against invaders. The cells of the immune system learn to tolerate all tissues, cells and proteins of the body. Failure to control the state of tolerance results in autoimmunity. The understanding of the role of T-cell receptors (TCR), the Major Histocompatibility Complex (MHC), adhesion molecules and growth factors in antigen recognition has lead to the exploration of various means to modulate the immune response. Safety measures exist to prevent the immune system from attacking its host. The antigen has to be recognized by the T-cell. This involves the TCR and the MHC. In addition it must receive a second signal to become activated. The second signal involves a protein such as B7 binding with CD28. Certain specialized cells, macrophages, dendritic cells and activated B-cells can deliver this second signal for activation; receipt of only one signal can prevent activation. The elucidation of the role of cell-to-cell interactions, the adhesion molecules involved and the accessory growth factors provides modalities for selectively modifying the immune response. This would be of great relevance in autoimmunity and transplantation.

Role of genetic factors in drug-related autoimmunity

Although there is evidence to suggest that genetic factors play a major role in the pathogenesis of many of the rheumatic diseases, far less is known of their role in the induction and expression of human autoimmunity resulting from long-term exposure to drugs, chemicals and environmental agents. Pharmacogenetic factors represent an important source of interindividual variation in response to drugs; most research to date has focused on genetic polymorphism of drug metabolism via N-acetylation, S-methylation or cytochrome P-450-catalyzed oxidation. In drug-related autoimmunity, there is limited evidence that the host's genetic background plays a major role beyond the expression of autoantibodies. More recent prospective studies have concentrated on the association of MHC-genes in the expression of autoimmunity and the susceptibility of patients to develop drug-related clinical syndromes.