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Anti-serum with anti-autoantibody activity decreases autoantibody-positive B lymphocytes and type 1 diabetes of female NOD mice
Autoimmunity
Abstract
Type 1 diabetes mellitus (T1DM) is an autoimmune disease characterized by an autoimmune-mediated loss of insulin secreting β-cells. Each B lymphocyte clone that escapes immune tolerance produces a specific antibody. No specific treatment against autoantibodies is available for autoimmune diseases. We have developed a strategy to produce an antiserum against autoantibodies for the treatment of T1DM. Non-obese diabetic (NOD) but not Balb/c mouse serum contains autoantibodies. Antisera were produced by immunizing Balb/c mice with affinity-purified IgG from NOD or BALB/c mice along with the immune adjuvant (hereafter, NIgG or BIgG, respectively). A bolus administration of NIgG significantly reduced serum autoantibodies, autoantibody-positive B lymphocytes in the spleens of NOD mice, mortality and morbidity of diabetes, blood glucose and islet immune infiltration, whereas it increased islet mass in NOD mice for at least 26 weeks. NIgG antiserum treatment has no significant effect on CD3(+), CD4(+) or CD8(+) T cells and B220(+) or CD19(+) B cells. BIgG also imparted a moderate therapeutic effect, although it was considerably lower than that of NIgG. NIgG did not cross-react with allogeneic serum. NIgG showed no effect on Balb/c mice. The results show the feasibility of producing antiserum against autoantibodies to prevent and treat autoimmune-induced T1DM with a single bolus administration.
The underlying biology of schizophrenia remains metaphorically an undiscovered black box and still requires a concentrated and rigorous extent of investigation. Consciousness is an enigma and an enigma cannot be defined, but it can be described. Consciousness itself requires better explanation in order to understand the symptoms of schizophrenia. Consciousness may have a neurological origin, and the Penrose-Hameroff Orch OR theory may be helpful in elucidating only the mechanical quantum consciousness. The concept of quantum decoherence has been linked with psychopathology. A neuro-quantological approach has great potential for understanding the symptoms of schizophrenia as essentially disorders of consciousness. Auditory hallucinations may be acoustic holograms of parallel thinking. Non-clinical auditory hallucinations are not uncommon and pose an interpretational challenge. The symptoms of schizophrenia may encompass disorders of consciousness. Consciousness based studies of schizophrenic symptoms would necessitate formulations of new models of brain-mind-consciousness complex. A quantum leap is overdue in schizophrenia research itself both in the theoretical and experimental fields and the present paper is focussed on the former.
Data presented here demonstrate multifunctional vaccination strategies that harness vaccinia virus mediated delivery of a gene encoding an immunoenhanced diabetes autoantigen in combination with complete Freund's adjuvant (CFA) that can maintain safe and durable immunologic homeostasis in NOD mice. Systemic coinoculation of prediabetic mice with recombinant vaccinia virus rVV-CTB::GAD and undiluted or 10-fold diluted CFA demonstrated a significant decrease in hyperglycemia and pancreatic islet inflammation in comparison with control animals during 17-61 and 17-105 weeks of age, respectively. Synergy in these beneficial effects was observed during 43-61 and 61-105 wks of age, respectively. Inflammatory cytokine and chemokine levels in GAD-stimulated splenocytes isolated from vaccinated mice were generally lower than those detected in unvaccinated mice. The overall health and humoral immune responses of the vaccinated animals remained normal throughout the duration of the experiments.
Type 1 diabetes (T1D) is a T cell-mediated autoimmune disease, although B cells also play an important role in T1D development. Both T cell- and B cell-directed immunotherapies have shown efficacy in the prevention and reversal of T1D. However, whether the combined strategy of targeting both T and B cells could further improve the therapeutic efficacy remains to be explored. Herein we show that the combined treatment with intravenous anti-human CD20 (hCD20) and oral anti-CD3 significantly delayed diabetes development in pre-diabetic hCD20 transgenic NOD mice. More importantly, the combined treatment reversed diabetes in more than 60% of mice newly diagnosed with diabetes. Further mechanistic studies demonstrated that the addition of oral anti-CD3 to the B cell depletion therapy synergistically enhanced the suppressive function of Treg. Interestingly, the oral anti-CD3 treatment induced a fraction of IL-10-producing CD4 T cells in the small intestine through IL-10 and IL-27-producing dendritic cells. Thus, our findings demonstrated that combining anti-CD20 and oral anti-CD3 is superior to anti-CD20 monotherapy for restoring normoglycemia in diabetic NOD mice, providing important preclinical evidence for the optimization of B cell-directed therapy for type 1 diabetes.
Type 1 diabetes results from the destruction of β-cells by an autoimmune T-cell response assisted by antigen-presenting B cells producing autoantibodies. CD8(+) T-cell responses against islet cell antigens, thought to play a central role in diabetes pathogenesis, can be monitored using enzyme-linked immunosorbent spot (ELISpot) assays. However, such assays have been applied to monitoring of adult patients only, leaving aside the large and increasing pediatric patient population. The objective of this study was twofold: 1) to develop a CD8(+) T-cell interferon-γ ELISpot assay for pediatric patients and 2) to determine whether zinc transporter 8 (ZnT8), a recently described target of autoantibodies in a majority of patients, is also recognized by autoreactive CD8(+) T cells. Using DNA immunization of humanized mice, we identified nine HLA-A2-restricted ZnT8 epitopes. Among 36 HLA-A2(+) children with diabetes, 29 responded to ZnT8 epitopes, whereas only 3 of 16 HLA-A2(+) control patients and 0 of 17 HLA-A2(-) control patients responded. Some single ZnT8 epitopes performed as well as the group of epitopes in discriminating between patients and control individuals. Thus, ZnT8 is a major CD8(+) T-cell autoantigen, and ELISpot assays display similar performance in adult and pediatric type 1 diabetes.
Consistent with studies in NOD mice, early clinical trials addressing whether depletion of B cells by the Rituximab CD20-specific antibody provides an effective means for type 1 diabetes reversal have produced promising results. However, to improve therapeutic efficacy, additional B-cell-depleting agents, as well as attempts seeking diabetes prevention, are being considered.
Autoantibodies, including those against insulin (IAAs), are used to identify at-risk subjects for inclusion in diabetes prevention trials. Therefore, we tested the ability of anti-CD20 to prevent diabetes in NOD mice when administered either before or after IAA onset.
The murine CD20-specific 18B12 antibody that like Rituximab, depletes the follicular (FO) but not marginal zone subset of B cells, efficiently inhibited diabetes development in NOD mice in a likely regulatory T-cell-dependent manner only when treatment was initiated before IAA detection. One implication of these results is that the FO subset of B cells preferentially contributes to early diabetes initiation events. However, most important, the inefficient ability of anti-CD20 treatment to exert late-stage diabetes prevention was found to be attributable to downregulation of CD20 expression upon B cell entry into pancreatic islets.
These findings provide important guidance for designing strategies targeting B cells as a potential means of diabetes intervention.
Autoantibodies to zinc transporter 8 (ZnT8A) constitute an additional marker of autoimmune diabetes, complementing those already used in diagnosis support. ZnT8A could also be found in latent autoimmune diabetes of adults (LADA). The aim of this study was to evaluate the prevalence of ZnT8A in adult-onset diabetic patients in Argentinian population. A total of 271 patients diagnosed for diabetes at mean age 53.4 ± 10.9, body mass index ≤ 30, without insulin treatment for the first year of disease, and initially classified as type 2 diabetic patients were tested for ZnT8A using cDNA plasmids encoding the C-terminal domains (aa 268-369) carrying 325Arg, 325Trp, and a dimeric cDNA construct carrying both 325Arg and 325Trp (ZnT8 Arg-Trp325). We also analyzed proinsulin autoantibodies (PAA), glutamic acid decarboxylase autoantibodies (GADA), and protein tyrosine phosphatase IA-2 autoantibodies (IA-2A). A subset of 101 patients was followed during 6 years in order to analyze insulin requirement. Out of the 271 patients, 22.1% presented at least one humoral marker, 2.6% were PAA+, 12.5% were GADA+, 3.3% were IA-2A+, and 10.7% were ZnT8A+. Among the latter, 7.0% were ZnT8A-Arg325, 51.7% were ZnT8A-Trp325, and 62.1% were ZnT8A-Arg-Trp325. Furthermore, the prevalence of autoantibodies in the group of patients treated with insulin (n = 18) was 55.6%. These results demonstrated that a significant proportion of autoimmune adult-onset diabetic patients presented ZnT8A as the only humoral marker. Between them, the higher prevalence was for ZnT8A-Trp325. We suggest that screening for LADA patients, best performed with a minimal set of marker determination, must include at least the screening of GADA and ZnT8A-Arg-Trp325.
The ideal drug of modern medicine is the one that achieves its therapeutic target with minimal adverse effects. Immune therapy of Type 1 diabetes (T1D) is no exception, and knowledge of the antigens targeted by pathogenic T cells offers a unique opportunity towards this goal. Different antigen formulations are being considered, such as proteins or peptides, either in their native form or modified ad hoc, DNA plasmids, and cell-based agents. Translation from mouse to human should take into account important differences, particularly in the time scale of autoimmune progression, and intervention. Critical parameters such as administration route, dosing and interval remain largely empirical and need to be further dissected. T1D staging through immune surrogate markers before and after treatment will be key in understanding therapeutic actions and to finally turn ordinary blanks into magic bullets.
Insulin-dependent diabetes mellitus (IDDM) is thought to result from the autoimmune destruction of the insulin-producing beta cells of the pancreas. Years before IDDM symptoms appear, we can detect autoantibodies to one or both forms of glutamate decarboxylase (GAD65 and GAD67), synthesized from their respective cDNAs in a bacterial expression system. Individual IDDM sera show distinctive profiles of epitope recognition, suggesting different humoral immune responses. Although the level of GAD autoantibodies generally decline after IDDM onset, patients with IDDM-associated neuropathies have high levels of antibodies to GAD, years after the appearance of clinical IDDM. We note a striking sequence similarity between the two GADs and Coxsackievirus, a virus that has been associated with IDDM both in humans and in experimental animals. This similarity suggests that molecular mimicry may play a role in the pathogenesis of IDDM.
A novel cDNA, IA-2beta, was isolated from a mouse neonatal brain library. The predicted protein sequence revealed an extracellular domain, a transmembrane region, and an intracellular domain. The intracellular domain is 376 amino acids long and 74% identical to the intracellular domain of IA-2, a major autoantigen in insulin-dependent diabetes mellitus (IDDM). A partial sequence of the extracellular domain of IA-2beta indicates that it differs substantially (only 26% identical) from that of IA-2. Both molecules are expressed in islets and brain tissue. Forty-six percent (23 of 50) of the IDDM sera but none of the sera from normal controls (0 of 50) immunoprecipitated the intracellular domain of IA-2beta. Competitive inhibition experiments showed that IDDM sera have autoantibodies that recognize both common and distinct determinants on IA-2 and IA-2beta. Many IDDM sera are known to immunoprecipitate 37-kDa and 40-kDa tryptic fragments from islet cells, but the identity of the precursor protein(s) has remained elusive. The current study shows that treatment of recombinant IA-2beta and IA-2 with trypsin yields a 37-kDa fragment and a 40-kDa fragment, respectively, and that these fragments can be immunoprecipitated with diabetic sera. Absorption of diabetic sera with unlabeled recombinant IA-2 or IA-2beta, prior to incubation with radiolabeled 37-kDa and 40-kDa tryptic fragments derived from insulinoma or glucagonoma cells, blocks the immunoprecipitation of both of these radiolabeled tryptic fragments. We conclude that IA-2beta and IA-2 are the precursors of the 37-kDa and 40-kDa islet cell autoantigens, respectively, and that both IA-2 and IA-2beta are major autoantigens in IDDM.
We report here our prospective study of 15,224 non-diabetic, first-degree relatives of probands with immune-mediated (type 1) diabetes (IMD), of which 135 were found to eventually develop diabetes. We determined islet cell, insulin, GAD65, insulinoma-associated antigen-2 and 2beta autoantibodies (ICA, IAA, GAD65A, IA-2A and IA-2betaA), on the first available serum samples. The latter three autoantibodies were however assayed on subsets of the relatives with and without ICA, IAA and/or GAD65A, plus most of the relatives who developed diabetes. Of the relatives who progressed to diabetes, 94% had at least one of these autoantibodies on the first screening, while ICA proved to be the most sensitive single marker (sensitivity 74%). Risk of diabetes was however negligible when ICA was found in the absence of the others (5-year risk=5.3%), but increased dramatically whenever two or more autoantibodies were present (5-year risk=28.2% and 66.2%, respectively). The most predictive combination of markers was ICA plus IA-2A and/or IA-2beta A. Loss of first phase insulin release to IVGTT also occurred only in those ICA-positive relatives who had one or more of the other autoantibodies. The data suggests that significant beta-cell damage is seen only when the underlying autoimmunity has spread to multiple antigenic islet cell determinants. Combinations of the autoantibodies occurred most often in relatives with the highest risk HLA-DR/DQ phenotypes. These data document that only relatives positive for at least two or more of these five autoantibodies are at significant risk of diabetes themselves. Intervention trials for the prevention of type 1 diabetes could be designed based on testing for these autoantibodies alone, without the need for HLA typing and IVGTT testing.
To determine whether loss of beta-cell mass and function in the NOD mouse occurs gradually, beginning after the onset of insulitis, or abruptly, just before the onset of overt diabetes, beta-cell mass and rates of beta-cell proliferation and insulin secretory responses from the perfused pancreas were measured in NOD and control NOD/Scid mice at 8-9, 13, and 18 weeks of age. Of the NOD mice, 11 and 70% had diabetes (fasting blood glucose >8.3 mmol/l) at 13 and 18 weeks of age, respectively. Beta-cell mass in 8-week-old NOD mice was 69% of control mice (P>0.05), but the rate of 5-bromo-2-deoxyuridine uptake was greater, suggesting a compensatory proliferative response to ongoing autoimmune beta-cell destruction. Despite an increase in the rate of beta-cell proliferation, beta-cell mass was significantly reduced by 42% in 13-week-old nondiabetic NOD mice and by 73% in 18-week-old diabetic NOD mice. Insulin secretory responses to glucose and arginine demonstrated reductions of similar magnitude. In 18-week-old diabetic NOD mice, insulin secretion was reduced to a greater degree than beta-cell mass, suggesting the presence of beta-cell dysfunction in addition to reduced mass. These results suggest that in the NOD mouse, beta-cell destruction begins soon after the onset of insulitis. Despite a compensatory beta-cell proliferative response, beta-cell mass progressively falls and is significantly reduced by 13 weeks despite normal blood glucose concentrations. Diabetes may be present when residual beta-cell mass represents 30% of control levels.
Several self-antigens have been reported as targets of the autoimmune response in nonobese diabetic (NOD) mice. The aim of this workshop was to identify autoantibody assays that could provide useful markers of autoimmunity in this animal model for type 1 diabetes. More than 400 serum samples from NOD (4, 8, and 12 weeks of age and at diabetes onset), BALB/c, and B6 mice were collected from six separate animal facilities, coded, and distributed to five laboratories for autoantibody measurement. Insulin autoantibodies (IAA) were measured by radiobinding assay (RBA) by four laboratories and by enzyme-linked immunosorbent assay (ELISA) in one laboratory. Using the 99th percentile of BALB/c and B6 control mice as the threshold definition of positivity, IAA by RBA were detected in NOD mice at frequencies ranging from 10 to 30% at age 4 weeks, from 26 to 56% at 8 weeks, from 42 to 56% at 12 weeks, and from 15 to 75% at diabetes onset. With ELISA, IAA signals differed significantly between control mouse strains and increased with age in both control and NOD mice, with frequencies in NOD animals being 0% at 4 weeks, 14% at 8 weeks, 19% at 12 weeks, and 42% at diabetes onset. For IAA, the ELISA results were relatively discordant with those of RBA. GAD autoantibody (GADA) and IA-2 autoantibody (IA-2A) signals obtained by RBA were low (maximum 2.5% of total) but were increased in NOD mice compared with control mice at diabetes onset (GADA 29-50%; IA-2A 36-47%). ELISA also detected GADA (42%) and IA-2A (50%) at diabetes onset, with results concordant with those of RBA. Remarkably, GADA and IA-2A frequencies varied significantly with respect to the source colony of NOD mice. Furthermore, whereas neither GADA nor IA-2A correlated with IAA, there was strong concordance between GADA and IA-2A in individual mice. Sera with increased binding to GAD and IA-2 also had increased binding to the unrelated antigen myelin oligodendrocyte glycoprotein, and binding to GAD could not be inhibited with excess unlabeled antigen, suggesting nonspecific interactions. In sum, this workshop demonstrated that IAA measured by sensitive RBA are a marker of autoimmunity in NOD mice and draw into question the true nature of GADA and IA-2A in this animal model.
According to the traditional immunization procedure, after the first injection of the sample A (emulsion of aimed antigen and Freund's complete adjuvant) to immunize rabbit, successive injections of the sample B (emulsion of aimed antigen and Freund's incomplete adjuvant) were followed every 2-4 weeks. In general, high titer of the corresponding polyclonal antisera will be observed after 4-5 injections of sample B in 3-4 months. This report presents a simply modified procedure that was able to stimulate the antisera formation in one month and achieve enough avidity to satisfy either Western blot or immunohistochemistry analysis. It just applied an additional injection of the sample A to the rabbit at the 3rd day after the primary immunization injection. You could gain the high titer of the antisera right after the first sample B injection in one month. This method has produced the desired results in three different recombinant antigens with different molecular weight (5.9 KD-55 KD) expressed from prokaryotic or eukaryotic cells.
Type 1 diabetes mellitus (T1D) in humans is an organ-specific autoimmune disease in which pancreatic islet beta cells are ruptured by autoreactive T cells. NOD mice, the most commonly used animal model of T1D, show early infiltration of leukocytes in the islets (insulitis), resulting in islet destruction and diabetes later. NOD mice produce various islet beta cell-specific autoantibodies, although it remains a subject of debate regarding whether these autoantibodies contribute to the development of T1D. Fc gammaRs are multipotent molecules that play important roles in Ab-mediated regulatory as well as effector functions in autoimmune diseases. To investigate the possible role of Fc gammaRs in NOD mice, we generated several Fc gammaR-less NOD lines, namely FcR common gamma-chain (Fc Rgamma)-deficient (NOD.gamma(-/-)), Fc gammaRIII-deficient (NOD.III(-/-)), Fc gammaRIIB-deficient (NOD.IIB(-/-)), and both Fc Rgamma and Fc gammaRIIB-deficient NOD (NOD.null) mice. In this study, we show significant protection from diabetes in NOD.gamma(-/-), NOD.III(-/-), and NOD.null, but not in NOD.IIB(-/-) mice even with grossly comparable production of autoantibodies among them. Insulitis in NOD.gamma(-/-) mice was also alleviated. Adoptive transfer of bone marrow-derived dendritic cells or NK cells from NOD mice rendered NOD.gamma(-/-) animals more susceptible to diabetes, suggesting a possible scenario in which activating Fc gammaRs on dendritic cells enhance autoantigen presentation leading to the activation of autoreactive T cells, and Fc gammaRIII on NK cells trigger Ab-dependent effector functions and inflammation. These findings highlight the critical roles of activating Fc gammaRs in the development of T1D, and indicate that Fc gammaRs are novel targets for therapies for T1D.
A total of 305 ambulatory patients recruited at the Division of Endocrinology, Hospital de Clínicas, University of Buenos Aires, with autoimmune thyroid disease (AITD) were studied to search for associations between autoimmune thyroid disease and presence of serum markers of autoimmune diabetes mellitus. Screening for markers of pancreatic beta-cell autoimmunity was performed by radioligand binding assays (RBA) as follows: autoantibodies to glutamic acid decarboxylase (GADA) and proinsulin (PAA) were determined in all sera, whereas autoantibodies to protein tyrosine phosphatase (IA-2A) and insulin (IAA) were additionally measured in 200 sera randomly selected from the total collection. In addition, every GADA positive serum among the remaining 105 sera was systematically tested for the presence of IA-2A and IAA. In the cohort of 305 AITD patients 22 (7.2%) were previously diagnosed as type 1, type 2 or insulin-requiring type 2 diabetics. Ten of these patients presented serum marker positivity specific for beta-cell autoantigens and 12 were marker negative. On the other hand, considering the majority of non-diabetic AITD patients (n = 283), beta3-cell marker positivity was detected in 17 individuals (6.0%). The prevalence of autoimmune diabetes markers was much higher in the studied population than in the general population utilized as a control group, and GADA was the most frequent marker.
Aim:
Glutamic acid decarboxylase (GAD) and/or islet antigen-2 (IA-2) autoantibodies (ab) are present in 90% of patients at the onset of type 1 diabetes (T1D). Few studies have shown that they may persist in the long-term. We analysed the frequency of GADab and IA-2ab and the factors associated with their persistency in patients with long-lasting T1D.
Methods:
This cross-sectional study included 430 adult patients with T1D of at least 10-year duration, consecutively seen over one year. GADab and IA-2ab were determined by radio-binding assays. Autoantibodies to thyroperoxydase, gastric parietal cells and transglutaminase were assessed in 418 patients, and HLA DRB1 genotyping in 359. Parameters associated with the persistency of antibodies were studied by multivariate analysis.
Results:
Median age at diagnosis of T1D was 12 years, and median diabetes duration was 19 years. Extrapancreatic autoimmunity was present in 38% of the patients, and associated autoimmune diseases in 21%. GADab and/or IA-2ab were found in 56% of the patients, and in 32% in those with more than 25-year diabetes duration. GADab were more frequent than IA-2ab. Female sex, an older age at diagnosis, and a shorter duration of diabetes were independently associated with the presence of ab. The same factors and the DR3 allele were associated with GADab, while only diabetes duration and the DR4 allele were associated with IA-2ab.
Conclusion:
In a large proportion of the patients with T1D, the long-term persistency of diabetes-associated antibodies allows aetiological diagnosis, even far from the onset of hyperglycaemia.
Unlabelled:
Type 1 diabetes (T1D) is an autoimmune disease characterized by the presence of circulating autoantibodies directed against proteins of islet beta-cell. Autoantibody testing is used for diagnostic purposes; however, up to 2-5% of patients who are clinically diagnosed with T1D are found negative for known antibodies, suggesting that the T1D autoantigen panel is incomplete. With the aim of identifying new T1D autoantigen(s), we used sera from subjects clinically diagnosed with T1D, but who tested negative for the four T1D autoantibodies currently used in clinical practice and for genes responsible for sporadic cases of diabetes. Sera from these patients were challenged by Western blot against the proteome from human pancreatic beta-cells resolved by 2DE. Eleven proteins were identified by MS. A radiobinding assay (RBA) was developed to test the reactivity to Rab GDP dissociation inhibitor beta (GDIβ) of T1D sera using an independent method. Depending on the construct used (open reading frame or COOH-terminus) 22% to 32% of fifty T1D sera showed increased binding to GDIβ by RBA. In addition, 15% of patients with celiac disease had raised binding to the COOH-terminus GDIβ. These results indicate that immunoproteomics is a feasible strategy for the identification of candidate T1D autoantigens.
Biological significance:
Several approaches have been previously used to look for new type 1 diabetes autoantigens. With the present work we show that carefully selected sera from rare patients with diabetes both negative for the 5 autoantibodies currently used in clinical practice and for genes responsible for sporadic cases of diabetes, may be exploited in experiments utilizing human pancreatic islets extracts as a target for SERPA to identify novel candidate T1D autoantigens.
Background and aims:
Patients with type 1 diabetes have antibodies to ZnT8 protein is encoded by SLC30A8. The C-allele of the R325 W variant in SLC30A8 is associated with type 2 diabetes and reduced beta-cell function in non-diabetic subjects. Our aim was to assess the prevalence of ZnT8 autoantibodies (ZnT8A) in patients with adult-onset diabetes, and to characterize associations between ZnT8A and phenotype, as well as SLC30A8 and HLA-DQB1 genotypes.
Methods:
ZnT8A were analyzed in patients diagnosed with diabetes >35 years (type 1 diabetes: n = 274; Latent autoimmune diabetes in adults (LADA): n = 294). SLC30A8 R325 W (rs13266634) and HLA-DQB1 alleles were genotyped in all patients and 537 non-diabetic control subjects.
Results:
ZnT8A were significantly more prevalent in LADA (34.3%) compared to adult-onset type 1 diabetes (18.7%, p < 0.0001). Among the patients with adult-onset type 1 diabetes, ZnT8A were associated with shorter disease duration [4.4 (6.0) vs. 10.8 (11.2) years, p < 0.0001], whereas no such association was observed among patients with LADA. The SLC30A8 R325 W variant was associated with LADA with low GADA levels [SLC30A8 CC: OR (95% CI): 1.46 (1.00 - 2.13), p = 0.049], and reduced insulin secretion among the non-diabetic subjects and the patients with LADA.
Conclusion:
ZnT8A were more common and more persistent in patients with LADA compared to adult-onset type 1 diabetes, but their presence was not associated with specific phenotypic characteristics. The SLC30A8 CC genotype adds to the genetic heterogeneity of LADA linked to GADA reactivity.
The SNP rs13266634 encodes either an Arginine (R) or a Tryptophan (W) (R325W) at the amino acid position 325 in the Zinc Transporter 8 (ZnT8) protein. Autoantibodies (Ab) that recognize ZnT8R, ZnT8W or both at the polymorphic site are common in newly diagnosed type 1 diabetes (T1D) patients. The epitope specificity and affinity of ZnT8Ab are poorly understood, but may be of importance for the prediction and clinical classification of T1D. Therefore, the aims were to 1) determine the immunogenicity of short (318-331) ZnT8 peptides in mice, and 2) test the affinity of short and long (268-369) ZnT8 proteins in T1D patients positive for either ZnT8WAb or ZnT8RAb. Sera from BALB/cByJ mice immunized with short R, W or Q (Glutamine) ZnT8 peptides were tested for ZnT8-peptide antibodies in ELISA and radiobinding assay (RBA). Using reciprocal permutation experiment, short synthetic ZnT8R and ZnT8W (318-331) and long in vitro transcription translation ZnT8R and ZnT8W (268-369) proteins, were tested in competitive RBA with R- and W- monospecific T1D sera samples. All mouse sera developed non-epitope specific peptide-antibodies in ELISA and only 6/12 mice had ZnT8-RWQ antibodies in RBA. Both long ZnT8R and ZnT8W (268-369) but not any short, proteins displaced labeled ZnT8 (268-369) proteins in binding to T1D ZnT8Ab-specific sera. The reciprocal cross-over tests showed that half maximal displacement varied 2-11-fold indicating variable affinity of patient ZnT8Ab, signifying crucial autoantibody epitope spreading. The present approach should make it possible to dissect the importance of the R325W ZnT8 autoantigen epitope in the T1D pathogenesis.
Circulating autoantibodies to beta cell antigens are present in the majority of patients with Type 1 diabetes. These autoantibodies can be detected before and at time of clinical diagnosis of disease. Although the role of autoantibodies in the pathogenesis of the disease is debated, their presence indicates a dysregulation of the humoral immune response. Mechanisms regulating autoantibodies in Type 1 diabetes are not well understood. In contrast, in other autoimmune diseases there is acceptance that autoantibodies are regulated not only by antigen but also by other antibodies that bind to the antigen-binding site of these autoantibodies (anti-idiotypic antibodies). The proposed purpose of this network is to maintain an equilibrium between autoantibodies and their anti-idiotypic antibodies, preventing autoimmunity, while allowing a robust response to exogenous antigen. Anti-idiotypic antibodies regulate both autoantibody binding and their levels by a) neutralizing autoantibodies, and b) inhibiting the secretion of autoantibodies. Because it has been proposed that the B lymphocytes that produce autoantibodies function as autoantigen presenting cells, inhibiting their binding to autoantigen by anti-idiotypic antibodies may prevent development of autoimmune disease. This hypothesis is supported by the presence of anti-idiotypic antibodies in healthy individuals and in patients in remission from autoimmune diseases, and by the lack of anti-idiotypic antibodies during active disease. We recently reported the presence of autoantibodies to glutamate decarboxylase in the majority of healthy individuals, where their binding to autoantigen is prevented by anti-idiotypic antibodies. These anti-idiotypic antibodies are absent at clinical diagnosis of Type 1 diabetes, revealing the presence of autoantibodies. Type 1 diabetes (T1D) is an autoimmune disease characterized by the dysfunction and destruction of insulin-producing beta cells by autoreactive T cells. Although much progress has been made towards understanding the respective roles of effector and regulatory T cells in this beta cell destruction, the development of autoantibodies to beta cell proteins is widely considered simply a by-product of the autoimmune destruction of the beta cells, rather than having an active role in the pathogenesis. This view is starting to change based on increasing recognition that autoantibodies can have defined roles in other autoimmune diseases, and the emergence of new data on their role in T1D. This exploration of the role of autoantibodies in autoimmune disease has been spurred, in part, by increasing recognition that development of autoimmune diseases is influenced by regulatory antibodies (anti-idiotypic antibodies) directed against the unique binding site of autoantibodies. This review provides an overview of the development and function of these anti-idiotypic antibodies, and present evidence supporting their role in the development of autoimmune diseases. Finally, we conclude this review with a model of the events that may cause loss of anti-idiotypic antibodies and the implications for the development of T1D.
Introduction:
Type 1 diabetes mellitus is a chronic, progressive autoimmune disorder linked to numerous genetic and environmental factors. Insulin is the only treatment and preventative strategies do not currently exist. An obvious need exists to develop a safe regimen that suppresses the progression of the disease.
Areas covered:
A MEDLINE search (1966-June 2011) was conducted for English-language articles using the terms 'otelixizumab', 'anti-CD3 antibody' and 'prevention of type 1 diabetes mellitus'. Relevant literature on otelixizumab, an anti-CD3 monoclonal antibody, currently in Phase III clinical trials for prevention of T1DM is discussed.
Expert opinion:
Studies suggest that a monoclonal antibody directed against CD3 mitigates the deterioration in insulin production and decreases the rise in insulin requirement in recent onset T1DM for up to five years. The benefit was most pronounced in younger patients and in those with higher initial β-cell function. Adverse effects were significant but transient. Otelixizumab shows great promise but leaves room for improvement. Results of ongoing trials will help define its role in the prevention of T1DM.
B cells play a pathogenic role as antigen-presenting cells and autoantibody secretors in the lead up to T cell-mediated autoimmune destruction of insulin-producing β cells in type 1 diabetes (T1D). This has led to significant interest in the use of B cell depletion therapies as a treatment for T1D. In this review, we compare results from five recent studies that used distinct B cell-depleting agents and protocols to successfully prevent and even reverse T1D in the non-obese diabetic (NOD) mouse model. We discuss how information gained from animal studies could be used to improve on the positive outcomes of a completed phase II clinical trial of the B cell-depleting drug rituximab in humans with recent-onset T1D.
We hypothesised that the correlation between autoantibody specificity for the ZnT8 Arg325Trp isoforms and the type 2 diabetes-associated rs13266634 may affect β-cell function at type 1 diabetes (T1D) onset. To study this, we tested 482 newly diagnosed diabetic probands and 478 healthy siblings from the Danish population-based T1D registry for autoantibodies to ZnT8 (ZnT8A) in addition to GAD65 and IA-2. The prevalence and titres of autoantibodies were correlated with genotypes for rs13266634 and HLA-DQB1, age at diagnosis (AAD) and insulin dose-adjusted HbA1c (IDAA1c), as a proxy for residual β-cell function. We replicated the correlation between rs13266634 genotypes and specificity for the ZnT8-Argenine (ZnT8R) and ZnT8-Tryptophan (ZnT8W) isoforms previously reported. ZnT8A overlapped substantially with autoantibodies to glutamate decarboxylase 65 (GADA) and IA-2 (IA-2A) and correlated significantly with IA-2A prevalence (p < 2e-16). No effect on IDAA1c was demonstrated for ZnT8A or rs13266634. We found a correlation between ZnT8R positivity and HLA-DQB1*0302 genotypes (p = 0.016), which has not been shown previously. Furthermore, significantly lower ZnT8R and GADA prevalence and titres was found among probands with AAD < 5 years (prevalence: p = 0.004 and p = 0.0001; titres: p = 0.002 and p = 0.001, respectively). The same trend was observed for IA-2A and ZnT8W; however, the difference was non-significant. Our study confirms ZnT8 as a major target for autoantibodies at disease onset in our Danish T1D cohort of children and adolescents, and we have further characterised the relationship between autoantibody specificity for the ZnT8 Arg325Trp epitopes and rs13266634 in relation to established autoantibodies, AAD, measures of β-cell function and HLA-DQB1 genotypes in T1D.
Type 1 diabetes is an autoimmune disorder afflicting millions of people worldwide. Once diagnosed, patients require lifelong insulin treatment and can experience numerous disease-associated complications. The last decade has seen tremendous advances in elucidating the causes and treatment of the disease based on extensive research both in rodent models of spontaneous diabetes and in humans. Integrating these advances has led to the recognition that the balance between regulatory and effector T cells determines disease risk, timing of disease activation, and disease tempo. Here we describe current progress, the challenges ahead and the new interventions that are being tested to address the unmet need for preventative or curative therapies.
Autoantibodies to the islet-specific zinc transporter isoform 8 (ZnT8) are detected in the majority of type 1 diabetes patients prior to and at clinical diagnosis. The presence of ZnT8Ab after diagnosis has not been investigated. This study analyzed the autoantibody response to ZnT8 in regard to age at onset and disease duration. Two new onset type 1 diabetes patient cohorts with different age distributions at onset (2-17 and 15-34 years of age at onset), a longitudinal subset of the younger type 1 diabetes patient cohort (n = 32), and a cohort of GAD65Ab-positive LADA patients (n = 47) was analyzed for the presence of autoantibodies directed to the two major isoforms, ZnT8-Arginine (ZnT8R) and ZnT8-Tryptophan (ZnT8W). The majority of type 1 diabetes patients tested positive for ZnT8Ab to both isoforms. ZnT8Ab titers were significantly higher in the younger type 1 diabetes patients as compared with the older cohort (ZnT8RAb at a median of 148 and 29 U/ml, respectively, p < 0.001) (ZnT8WAb at a median of 145 and 58 U/ml, respectively, p < 0.01). ZnT8RAb and ZnT8WAb titers were significantly lower in the LADA patients (ZnT8RAb at a median of 14 U/ml, ZnT8WAb at a median of 25 U/ml) as compared with either type 1 diabetes cohorts. In our longitudinal analysis of type 1 diabetes patients after clinical diagnosis, ZnT8Ab levels to both isoforms declined significantly during the initial year of disease (ZnT8RAb from a median of 320-162 U/ml, p = 0.0001; ZnT8WAb from a median of 128-46 U/ml, p = 0.0011). The antibody titers further declined during the following 4 years (p < 0.0001). We conclude that ZnT8Ab presents a useful marker for type 1 diabetes, especially in younger patients at disease diagnosis.
Type 1A diabetes is strongly associated with the presence of islet autoantibodies. Large scale population screening of islet autoantibodies is essential for many different national and international studies related to defining subtypes of diabetes, the natural history of the disease, and for trials of prevention. Testing for relevant autoantibodies has become more difficult as the number of important autoantibodies/epitopes increases. In the present study, we created a chimeric protein, IA2-ZnT8WR, with two major islet autoantigens, IA-2 and the recent Zinc transporter 8 (ZnT8). The chimeric molecule included both common polymorphisms of the ZnT8 molecule, arginine or tryptophan at position 325. Serum samples from 284 patients with newly diagnosed diabetes, 10 prediabetics, and 110 age-matched normal controls were analyzed for islet autoantibodies reacting with the IA2-ZnT8WR molecule. Autoantibodies to the chimeric molecule were compared to reactivity with individual assays detecting autoantibodies reacting with the separate molecules (IA-2, ZnT8-R and ZnT8-W). With this chimeric protein antigen, IA2-ZnT8WR, one radioassay is able to detect autoantibodies to IA-2 and to both major forms of ZnT8 (100% sensitivity, 100% unchanged specificity, relative to individual molecules). The chimeric assay provides an efficient and economical technique to screen for islet autoantibodies reacting with IA-2 and ZnT8.
The nonobese diabetic mouse (NOD) is widely used as a model to study human type 1 diabetes (T1D). In the NOD mouse T1D is a T cell-mediated autoimmune disease of complex etiology in which B cells play an essential role. One of the major unresolved issues in T1D is the genetic and/or environmental factors that trigger the autoimmune reaction. In the NOD mouse, as in humans, auto-antibodies to pancreatic islets are present at early ages and are highly correlated to diabetes progression, but their etiological role has long been disputed. NOD auto-antibodies have the characteristics of a natural repertoire, and B1 cells, the main natural antibody producers, exhibit functional differences in this strain that could have consequences for disease determination. Using a genetic approach, we propose to test if the NOD natural auto-antibody repertoire includes innate reactivities that participate in diabetes pathogenesis by promoting insulitis initiation.
Therapeutic approaches for autoimmune diseases are primarily based on suppressive measures that down regulate an over productive immune system. The increasing availability of modern biological therapies has advanced the ability to target and to neutralize essential components of the immune response without experiencing the hazardous adverse effects caused by the traditional immunosuppressants. One of the noticeable examples of this approach is the increasing use of high-dose intravenous immunoglobulin (IVIg). IVIg mechanisms include modulating function of Fc receptors, interference with complement activation and cytokine network, provision of anti-idiotypic antibodies, regulation of cell growth, and effects on of T and B cells. In this review we gather existing information regarding IVIg mechanisms of action, clinical applications and its effects on various conditions.
Our previous reports showed that a single injection of live BCG, one of the biological response modifiers, prevents insulitis and overt diabetes in NOD mice and that the suppression could be due to the generation of some type of suppressor cells in the BCG-treated mice. Furthermore, a more recent study has revealed that macrophages suppressive against a variety of lymphocyte functions can be induced by BCG, which suggests that these macrophages are involved in the suppression of the pathogenesis. To obtain valid evidence for this speculation, the effects of transfer of macrophage and T-cell fractions on the pathogenesis were examined in the present study. Transfer of macrophage-enriched spleen cell fraction harvested from the BCG-treated females to young females abolished the occurrence of spontaneous diabetes up to the age of 25 to 30 weeks. Also, macrophage transfer prevented the progress of insulitis. In contrast, transfer of a T-cell-enriched fraction did not suppress insulitis and overt diabetes. From these results, it could be concluded that the suppression of the autoimmune pathogenesis of diabetes by BCG is due to the generation of suppressor macrophages.
In studies of immune cell defects in autoimmune diabetes mellitus, we observed that complete Freund's adjuvant (CFA) prevented the onset of diabetes when injected into 8- to 10-wk-old prediabetic nonobese diabetic (NOD) mice. The prevalence of the onset of diabetes in the CFA-injected versus uninjected NOD mice was 2 of 81 (2.5%) vs. 231 of 379 (61%) among females and 2 of 44 (4.5%) vs. 83 of 336 (25%) among males, respectively. The incidence of histologically identifiable insulitis was significantly reduced in CFA-treated prediabetic female NOD mice (18%) compared with the incidence in female age-matched controls (70%). Splenocytes or Mac-(1+)-enriched splenocytes from CFA-treated NOD mice, when cotransferred with splenocytes from diabetic mice, reduced the incidence of diabetes provoked by diabetic splenocytes in vivo. In the spleen, CFA injection induced sustained increases in cell proliferation and an associated major increase in the numbers of an immature cell type that expressed the Mac-1 surface antigen. In CFA-treated NOD mice, lymphocytes derived from the spleen failed to respond in vitro to stimulation by the mitogen concanavalin A or by anti-CD3. When cocultured, Mac-1+ cells, enriched from the splenocytes of CFA-treated mice, suppressed concanavalin A- or anti-CD3-induced proliferation of T lymphocytes derived from either the spleen or thymus of untreated NOD mice. Therefore, treatment with CFA prevents the development of diabetes, and concomitantly, insulitis while stimulating the generation of splenic suppressor cells that are capable of suppressing diabetogenic T-lymphocyte function in vivo and in vitro.
DURING the past decade a wealth of information concerning the pathogenesis of Type I diabetes has become available. Two spontaneous animal models of the disease have been discovered and characterized (the Biobreeding rat and the non-obese diabetic mouse); the importance of a gene or genes in the major histocompatibility complex in Type I diabetes of human beings, of mice, and of rats has been appreciated; and the prognostic importance of selected assays for islet-cell antibodies has been defined. T-cell abnormalities that precede diabetes have been discovered. Evidence has suggested that progressive loss of first-phase insulin secretion precedes diabetes, and immunologic . . .
A sensitive assay was used to measure the binding of iodine-125-labeled insulin in serum obtained from 112 newly diagnosed insulin-dependent diabetics before insulin treatment was initiated. Two groups of nondiabetics served as controls: children with a variety of diseases other than diabetes and nondiabetic siblings of insulin-dependent diabetics. Eighteen of the diabetics were found to have elevated binding and 36 were above the 95th percentile of control values. The insulin-binding protein is precipitated by antibody to human immunoglobulin G, has a displacement curve that is parallel and over the same concentration range as serum from long-standing insulin-dependent diabetics, and elutes from a Sephacryl S-300 column at the position of gamma globulin. These insulin antibodies are present in a large percentage of newly diagnosed, untreated diabetics and may be an immune marker of B-cell damage.
A quantitative analysis of substance P (SP)-immunoreactive (IR) terminals contacting physiologically characterized dorsal horn neurons was performed. Three types of neuron were studied: nociceptive specific (NS) from lamina I (n = 3), wide dynamic range (WDR) from laminae II-IV (n = 3), and nonnociceptive (NN) from lamina IV (n = 3). The nociceptive response of focus was a slow, prolonged depolarization to noxious stimuli, because this response was previously shown to be blocked by selective neurokinin-1 (NK-1) receptor antagonists.
Ultrastructural immunocytochemistry was used to quantify the relative number of SP-IR boutons apposed to the intracellularly labeled cell per unit of length (density). Densities of the total population (SP immunoreactive + nonimmunoreactive) of apposed boutons were similar in all three regions (cell body, proximal and distal dendrites) for the three functional types of neuron. NS neurons received a significantly higher density of appositions from SP-IR boutons than NN cells in all three regions. However, compared to WDR cells, NS cells possessed a significantly higher density of appositions from SP-IR boutons only in the cell body and proximal dendrites. WDR cells had a higher density of appositions from SP-IR boutons than NN cells, but only in the proximal and distal dendrites. On average, 33.5% of the SP-IR boutons apposed to the cells displayed a synaptic contact. Finally, 30–45% of the SP-IR boutons apposed to the cells colocalized calcitonin gene-related protein (CGRP) immunoreactivity, indicating their primary sensory origin. The data indicate a direct correlation between the amount of SP-IR input and the nociceptive nature of the cells and suggest that SP acts on NK-1 receptors at a short distance from its release site.
Strategies for assessing risk of progression to IDDM, based on single and combined autoantibody measurement, were evaluated in 2,855 schoolchildren (median age 11.4 years) and 256 children with newly diagnosed IDDM (median age 10.2 years), recruited to a population-based study in the Oxford region. In 256 children with IDDM, levels of antibodies > or =97.5th centile of the schoolchild population were found in 225 (88%) for islet cell antibodies (ICAs), in 190 (74%) for antibodies to GAD, in 193 (75%) for antibodies to protein tyrosine phosphatase IA-2 (IA-2), and in 177 (69%) for autoantibodies to insulin (IAAs). Estimates of risk of progression to IDDM within 10 years, derived by comparing the distribution of antibody markers in the two populations (schoolchildren and children with IDDM), were 6.7% (ICAs), 6.6% (GAD antibodies), 5.6% (IA-2 antibodies), and 4.8% (IAAs) for schoolchildren with levels above the 97.5th centile, increasing to 20, 23, 24, and 11%, respectively, for antibody levels >99.5th centile. Most children with IDDM had multiple antibody markers, and 89% of those diagnosed over age 10 years had > or =2 antibodies above the 97.5th centile, as compared against 0.7% of schoolchildren, in whom this combination gave a 27% 10-year estimated risk of IDDM. Risk increased but sensitivity fell as combined antibody thresholds were raised, or the number of antibodies above the threshold was increased. Strategies based on detection of > or =2 antibodies with primary testing for GAD and IA-2 antibodies and second line testing for ICAs and/or IAAs were evaluated. Detection of at least two markers selected from GAD antibodies > or =97.5th centile and/or IA-2 antibodies > or =99.5th centile and/or ICAs > or =97.5th centile identified 0.25% of schoolchildren and 83% of children with newly diagnosed IDDM, with an estimated risk of 71% (95% CI 57-91). Although confirmation from prospective studies is still needed, this analysis suggests that antibody combinations can predict diabetes in the general population.
The influence of maternally transmitted immunoglobulins on the development of autoimmune diabetes mellitus in genetically susceptible human progeny remains unknown. Given the presence of islet beta cell-reactive autoantibodies in prediabetic nonobese diabetic (NOD) mice, we abrogated the maternal transmission of such antibodies in order to assess their influence on the susceptibility of progeny to diabetes. First, we used B cell-deficient NOD mothers to eliminate the transmission of maternal immunoglobulins. In a complementary approach, we used immunoglobulin transgenic NOD mothers to exclude autoreactive specificities from the maternal B-cell repertoire. Finally, we implanted NOD embryos in pseudopregnant mothers of a non-autoimmune strain. The NOD progeny in all three groups were protected from spontaneous diabetes. These findings demonstrate that the maternal transmission of antibodies is a critical environmental parameter influencing the ontogeny of T cell-mediated destruction of islet beta cells in NOD mice. It will be important to definitively determine whether the transmission of maternal autoantibodies in humans affects diabetes progression in susceptible offspring.
Aims:
The aim of this study is to demonstrate the incidence of spastic tetraparesis (ST) in meningitis patients in the paediatric ICU, together with the associated variables, and establish comparisons with the existing literature.
Patients and methods:
We reviewed the medical records of patients who presented symptoms of meningitis and required hospital treatment in the Paediatric ICU at the Hospital de Clínicas de Porto Alegre, between January 1985 and June 2001. In addition to the diagnosis of meningitis and the incidence of ST as a complication, we also examined the aetiological agent, sex, age at the moment of hospital admittance, length of time spent in hospital and treatment given in each case. RESULTS AND DISCUSSION. An incidence of 15.1% was found for cerebral palsy in the 112 cases of bacterial meningitis that were followed up clinically. In the patients with ST, the time spent in hospital was longer, and the frequency of seizures, intracranial hypertension and the protein concentration levels in CSF were higher (p<0.05).
Analysis of spontaneous hybridomas generated from nonobese diabetic (NOD) mice indicates that the natural autoantibody repertoire of NOD mice is highly active compared with C57BL/6 and BALB/c mice. This property of increased B cell activity is present early in life (4 wk) and persists in older mice of both sexes. Even when selected for binding to a prototypic beta cell Ag, such as insulin, NOD mAb have characteristics of natural autoantibodies that include low avidity and broad specificity for multiple Ags. Analyses of the variable region of Ig H chain (V(H)) and variable region kappa L chain genes expressed by six insulin binding mAb show that V gene segments are often germline encoded and are identical with those used by autoantibodies, especially anti-dsDNA, from systemic autoimmune disease in MRL, NZB/W, and motheaten mice. V(H) genes used by four mAb are derived from the large J558 family and two mAb use V(H)7183 and V(H)Q52 genes. The third complementarity-determining region of Ig H chain of these mAb have limited N segment diversity, and some mAb contain DNA segments indicative of gene replacement. Genetic abnormalities in the regulation of self-reactive B cells may be a feature that is shared between NOD and conventional systemic autoimmune disorders. In NOD, the large pool of self-reactive B cells may fuel autoimmune beta cell destruction by facilitating T-B cell interactions, as evidenced by the identification of one mAb that has undergone Ag-driven somatic hypermutation.
Diabetes mellitus is a disorder characterized by hyperglycemia in both the fasting and post-prandial states. The two most common forms of diabetes mellitus, type 1 and type 2 (previously called juvenile-onset and adult-onset, respectively), comprise the vast majority of cases. Type 1 diabetes (T1DM) has been shown to be a disease characterized by immune-mediated destruction of the insulin-secreting cells of the pancreas; it comprises the majority of cases of diabetes seen in childhood and approximately, 5-10% of all cases of diabetes mellitus in the USA and perhaps accounts for an even higher percentage in those nations with lower rates of obesity. The process of beta-cell destruction, marked by the production of autoantibodies to the beta-cell, occurs over many years and ultimately results in metabolic abnormalities first manifested as impaired glucose tolerance and then progressing to symptomatic hyperglycemia. It has been reported that approximately 50% of the genetic risk for T1DM can be attributed to the HLA region. The highest risk HLA-DR3/4 DQ8 genotype has been shown to be highly associated with beta-cell autoimmunity. The first antibodies described in association with the development of T1DM were islet cell autoantibodies (ICA). Subsequently, antibodies to insulin (IAA), glutamic acid decarboxylase (GAA or GAD) and protein tyrosine phosphatase (IA2 or ICA512) have all been defined. The number of antibodies, rather than the individual antibody, is thought to be most predictive of progression to overt diabetes.
Autoantibodies (Abs) directed against L-type voltage-gated calcium channels (VGCCs) have been shown to contribute to autonomic dysfunction of the gastrointestinal tract and bladder in patients with Type 1 diabetes mellitus (T1D). We used a passive transfer model to determine whether the functional activity of the Ab requires crosslinking of channels in colon and bladder and can be neutralized by intravenous immunoglobulin (IVIg). Mice were injected with mono- and divalent F(ab) fragments of patient IgG with anti-VGCC activity and tested for gut and bladder function using a colonic migrating motor complex (MMC) assay and bladder-filling cystometry. The ability of IVIg to neutralize anti-VGCC IgG-mediated autonomic dysfunction was investigated by injection of mice with an equimolar concentration of IVIg prior to T1D IgG injection, or by injection with T1D IgG passed over a sepharose 4B column coupled with F(ab')(2) from IVIg. Passive transfer of T1D IgG and its F(ab')(2) or F(ab) fragments reduced the amplitude of spontaneous colonic motility. In contrast, intact IgG and F(ab')(2,) but not F(ab), produced the urodynamics features of an overactive bladder. T1D IgG-mediated colonic and bladder dysfunction was neutralized in vivo by prior injection of animals with equimolar IVIg. Moreover, anti-VGCC activity was depleted by preabsorption of patient IgG on a IVIg F(ab')(2) column. The activity of anti-VGCC IgG is mediated by the antigen-binding site consistent with a true functional Ab. The pathogenic effect on the bladder requires crosslinking of the channel, whereas monovalent binding of Ab is sufficient for disruption of colon motility. The anti-VGCC Abs are neutralized by antiidiotypic antibodies present in IVIg that may prevent the emergence of these Abs in healthy individuals.