Denise L. Faustman

TNF receptor 2 pathway: drug target for autoimmune diseases

Although drug development has advanced for autoimmune diseases, many current therapies are hampered by adverse effects and the frequent destruction or inactivation of healthy cells in addition to pathological cells. Targeted autoimmune therapies capable of eradicating the rare autoreactive immune cells that are responsible for the attack on the bodys own cells are yet to be identified. This Review presents a new emerging approach aimed at selectively destroying autoreactive immune cells by specific activation of tumour necrosis factor receptor 2 (TNFR2), which is found on autoreactive and normal T lymphocytes, with the potential of avoiding or reducing the toxicity observed with existing therapies.

Reversal of established autoimmune diabetes by restoration of endogenous β cell function

In NOD (nonobese diabetic) mice, a model of autoimmune diabetes, various immunomodulatory interventions prevent progression to diabetes. However, after hyperglycemia is established, such interventions rarely alter the course of disease or allow sustained engraftment of islet transplants. A proteasome defect in lymphoid cells of NOD mice impairs the presentation of self antigens and increases the susceptibility of these cells to TNF-alpha-induced apoptosis. Here, we examine the hypothesis that induction of TNF-alpha expression combined with reeducation of newly emerging T cells with self antigens can interrupt autoimmunity. Hyperglycemic NOD mice were treated with CFA to induce TNF-alpha expression and were exposed to functional complexes of MHC class I molecules and antigenic peptides either by repeated injection of MHC class I matched splenocytes or by transplantation of islets from nonautoimmune donors. Hyperglycemia was controlled in animals injected with splenocytes by administration of insulin or, more effectively, by implantation of encapsulated islets. These interventions reversed the established beta cell-directed autoimmunity and restored endogenous pancreatic islet function to such an extent that normoglycemia was maintained in up to 75% of animals after discontinuation of treatment and removal of islet transplants. A therapy aimed at the selective elimination of autoreactive cells and the reeducation of T cells, when combined with control of glycemia, is thus able to effect an apparent cure of established type 1 diabetes in the NOD mouse.

NOD Mice Are Defective in Proteasome Production and Activation of NF-κB

ABSTRACT The nonobese diabetic (NOD) mouse is an animal model of human type I diabetes with a strong genetic component that maps to the major histocompatibility complex (MHC) of the genome. We have identified in NOD lymphocytes a specific proteasome defect that results from the lack of the LMP2 subunit. The pronounced proteasome defect results in defective production and activation of the transcription factor NF-κB, which plays an important role in immune and inflammatory responses as well as in preventing apoptosis induced by tumor necrosis factor alpha. The defect in proteasome function in NOD mouse splenocytes was evident from impaired NF-κB subunit p50 and p52 generation by proteolytic processing and impaired degradation of the NF-κB-inhibitory protein IκBα. An obligatory role of MHC-linked proteasome subunits in transcription factor processing and activation has been established in a spontaneous-disease model and mutant cells similarly lacking the MHC-encoded subunit. These data suggest that NOD proteasome dysfunction is due to a tissue- and developmental-stage-specific defect in expression of the MHC-linkedLmp2 gene, resulting in altered transcription factor NF-κB activity, and that this defect contributes to pathogenesis in NOD mice. These observations are consistent with the diverse symptomatology of type I diabetes and demonstrate clear sex-, tissue-, and age-specific differences in the expression of this error which parallel the initiation and disease course of insulin-dependent (type I) diabetes mellitus.

Persistence of Prolonged C-peptide Production in Type 1 Diabetes as Measured With an Ultrasensitive C-peptide Assay

OBJECTIVE To examine persistence of C-peptide production by ultrasensitive assay years after onset of type 1 diabetes and factors associated with preserving β-cell function. RESEARCH DESIGN AND METHODS Serum C-peptide levels, a marker of insulin production and surviving β-cells, were measured in human subjects (n = 182) by ultrasensitive assay, as was β-cell functioning. Twenty-two times more sensitive than standard assays, this assay’s lower detection limit is 1.5 pmol/L. Disease duration, age at onset, age, sex, and autoantibody titers were analyzed by regression analysis to determine their relationship to C-peptide production. Another group of four patients was serially studied for up to 20 weeks to examine C-peptide levels and functioning. RESULTS The ultrasensitive assay detected C-peptide in 10% of individuals 31–40 years after disease onset and with percentages higher at shorter duration. Levels as low as 2.8 ± 1.1 pmol/L responded to hyperglycemia with increased C-peptide production, indicating residual β-cell functioning. Several other analyses showed that β-cells, whose C-peptide production was formerly undetectable, were capable of functioning. Multivariate analysis found disease duration (β = −2.721; P = 0.005) and level of zinc transporter 8 autoantibodies (β = 0.127; P = 0.015) significantly associated with C-peptide production. Unexpectedly, onset at >40 years of age was associated with low C-peptide production, despite short disease duration. CONCLUSIONS The ultrasensitive assay revealed that C-peptide production persists for decades after disease onset and remains functionally responsive. These findings suggest that patients with advanced disease, whose β-cell function was thought to have long ceased, may benefit from interventions to preserve β-cell function or to prevent complications.

The therapeutic potential of tumor necrosis factor for autoimmune disease: a mechanistically based hypothesis

Abstract.Excess levels of tumor necrosis factor-α (TNF-α) have been associated with certain autoimmune diseases. Under the rationale that elevated TNF-α levels are deleterious, several anti-TNF-α therapies are now available to block the action of TNF-α in patients with autoimmune diseases with a chronic inflammatory component to the destructive process. TNF-α antagonists have provided clinical benefit to many patients, but their use also is accompanied by new or aggravated forms of autoimmunity. Here we propose a mechanistically based hypothesis for the adverse events observed with TNF-α antagonists, and argue for the opposite therapeutic strategy: to boost or restore TNF-α activity as a treatment for some forms of autoimmunity. Activation defects in the transcription factor nuclear factor κB leave autoreactive T cells sensitive to TNF-α-induced apoptosis. Treatment with TNF-α, by destroying autoreactive T cells, appears to be a highly targeted strategy to interrupt the pathogenesis of type 1 diabetes, lupus and certain forms of autoimmunity.

Proof-of-Concept, Randomized, Controlled Clinical Trial of Bacillus-Calmette-Guerin for Treatment of Long-Term Type 1 Diabetes

Background No targeted immunotherapies reverse type 1 diabetes in humans. However, in a rodent model of type 1 diabetes, Bacillus Calmette-Guerin (BCG) reverses disease by restoring insulin secretion. Specifically, it stimulates innate immunity by inducing the host to produce tumor necrosis factor (TNF), which, in turn, kills disease-causing autoimmune cells and restores pancreatic beta-cell function through regeneration. Methodology/Principal Findings Translating these findings to humans, we administered BCG, a generic vaccine, in a proof-of-principle, double-blind, placebo-controlled trial of adults with long-term type 1 diabetes (mean: 15.3 years) at one clinical center in North America. Six subjects were randomly assigned to BCG or placebo and compared to self, healthy paired controls (n = 6) or reference subjects with (n = 57) or without (n = 16) type 1 diabetes, depending upon the outcome measure. We monitored weekly blood samples for 20 weeks for insulin-autoreactive T cells, regulatory T cells (Tregs), glutamic acid decarboxylase (GAD) and other autoantibodies, and C-peptide, a marker of insulin secretion. BCG-treated patients and one placebo-treated patient who, after enrollment, unexpectedly developed acute Epstein-Barr virus infection, a known TNF inducer, exclusively showed increases in dead insulin-autoreactive T cells and induction of Tregs. C-peptide levels (pmol/L) significantly rose transiently in two BCG-treated subjects (means: 3.49 pmol/L [95% CI 2.95–3.8], 2.57 [95% CI 1.65–3.49]) and the EBV-infected subject (3.16 [95% CI 2.54–3.69]) vs.1.65 [95% CI 1.55–3.2] in reference diabetic subjects. BCG-treated subjects each had more than 50% of their C-peptide values above the 95th percentile of the reference subjects. The EBV-infected subject had 18% of C-peptide values above this level. Conclusions/Significance We conclude that BCG treatment or EBV infection transiently modified the autoimmunity that underlies type 1 diabetes by stimulating the host innate immune response. This suggests that BCG or other stimulators of host innate immunity may have value in the treatment of long-term diabetes. Trial Registration ClinicalTrials.gov NCT00607230

Lymphocyte transfusions prevent diabetes in the Bio-Breeding/Worcester rat.

The Bio-Breeding/Worcester (BB/W) rat develops spontaneous autoimmune diabetes similar to human insulin-dependent diabetes mellitus. Transfusions of whole blood from the nondiabetic W-line of BB/W rats prevent the syndrome in diabetes-prone recipients. We report three experiments designed to determine which blood component is protective. In all experiments, diabetes-prone BB/W rats 23 to 35 d of age were given four or six weekly intravenous injections. In the first experiment, animals received either saline or transfusions of erythrocytes, white blood cells, or plasma from W-line donors. Diabetes occurred in 7/22 (32%) erythrocyte, 2/27 (7%) white cell, 14/24 (58%) plasma, and 15/27 (56%) saline recipients (P less than 0.001). At 120 d of age, peripheral blood was obtained from nondiabetic rats. Fluorescence-activated cell sorter analysis of OX 19 tagged leucocytes revealed 35% T lymphocytes in white cell recipients (n = 13), compared with 9% in saline recipients (n = 7; P less than 0.001). Responsiveness to concanavalin A was also increased in the white cell group, whereas the frequency of both insulitis and thyroiditis was decreased. In the second experiment, 1/19 (5%) rats transfused with W-line spleen cells developed diabetes, as contrasted with 12/18 (67%) recipients of diabetes-prone spleen cells and 19/31 (61%) noninjected controls (P less than 0.001). In the third experiment, diabetes-prone rats received either W-line blood treated with a cytotoxic anti-T lymphocyte antibody plus complement, untreated blood, or saline. Diabetes occurred in 8/20 (40%), 1/20 (5%), and 13/19 (68%) rats in each group, respectively (P less than 0.001). We conclude that transfusions of W-line T lymphocytes prevent diabetes in the BB/W rat.

Homogeneous Expansion of Human T-Regulatory Cells Via Tumor Necrosis Factor Receptor 2

T-regulatory cells (Tregs) are a rare lymphocyte subtype that shows promise for treating infectious disease, allergy, graft-versus-host disease, autoimmunity, and asthma. Clinical applications of Tregs have not been fully realized because standard methods of expansion ex vivo produce heterogeneous progeny consisting of mixed populations of CD4 + T cells. Heterogeneous progeny are risky for human clinical trials and face significant regulatory hurdles. With the goal of producing homogeneous Tregs, we developed a novel expansion protocol targeting tumor necrosis factor receptors (TNFR) on Tregs. In in vitro studies, a TNFR2 agonist was found superior to standard methods in proliferating human Tregs into a phenotypically homogeneous population consisting of 14 cell surface markers. The TNFR2 agonist-expanded Tregs also were functionally superior in suppressing a key Treg target cell, cytotoxic T-lymphocytes. Targeting the TNFR2 receptor during ex vivo expansion is a new means for producing homogeneous and potent human Tregs for clinical opportunities.

Human Pancreatic Islet-Derived Progenitor Cell Engraftment in Immunocompetent Mice

The potential for the use of stem/progenitor cells for the restoration of injured or diseased tissues has garnered much interest recently, establishing a new field of research called regenerative medicine. Attention has been focused on embryonic stem cells derived from human fetal tissues. However, the use of human fetal tissue for research and transplantation is controversial. An alternative is the isolation and utilization of multipotent stem/progenitor cells derived from adult donor tissues. We have previously reported on the isolation, propagation, and partial characterization of a population of stem/progenitor cells isolated from the pancreatic islets of Langerhans of adult human donor pancreata. Here we show that these human adult tissue-derived cells, nestin-positive islet-derived stem/progenitor cells, prepared from human adult pancreata survive engraftment and produce tissue chimerism when transplanted into immunocompetent mice either under the kidney capsule or by systemic injection. These xenografts seem to induce immune tolerance by establishing a mixed chimerism in the mice. We propose that a population of stem/progenitor cells isolated from the islets of the pancreas can cross xenogeneic transplantation immune barriers, induce tissue tolerance, and grow.

Abnormal T-Lymphocyte Subsets in Type I Diabetes

Type I (insulin-dependent) diabetes mellitus is a slow autoimmune disease associated with the selective destruction of β-cells in the islets of Langerhans. Recent studies in humans indicate that autoantibodies to insulin and islets of Langerhans appear years before overt diabetes and identify a normoglycemic prediabetic state. To determine whether type I diabetes mellitus represents a generalized immunologic disorder, we studied the phenotypic characteristics of peripheral blood lymphocytes from all stages, i.e., prediabetic, new-onset diabetic, and long-term diabetic patients, with the anti-2H4 monoclonal antibody CD45R, which defines a human suppressor-inducer subset, and the anti-4B4 monoclonal antibody CDw29, which defines a human helper-inducer subset of peripheral blood lymphocytes. All 22 prediabetic patients had elevated T4+2H4+ (suppressor-inducer) cells and reciprocal depressed T4+4B4+ (helper-inducer) cells compared with healthy age-matched control subjects. In addition, the T4/T8 ratio in prediabetic patients was decreased compared with the age-matched control subjects. The abnormal T4+2H4+ and T4+4B4+ subsets were resolved in 20 new-onset and 15 long-term diabetic patients. Family studies showed that the changes in the 2H4 and 4B4 antigens were not part of an inherited polymorphic determinant, because these markers were normal in unaffected siblings and parents. Ten prediabetic patients were restudied >1 yr after the original analysis and showed the persistence of the observed changes. This abnormal increase in suppressor-inducer cells and decrease in helper-inducer cells among islet and insulin antibody-positive prediabetic patients may be of help in understanding diabetes pathogenesis and may also be an early noninvasive screening tool for the detection of the prediabetic state.