Laurence M. Howard

Mechanisms of immunotherapeutic intervention by anti-CD40L (CD154) antibody in an animal model of multiple sclerosis

Relapsing experimental autoimmune encephalomyelitis (R-EAE) in the SJL mouse is a Th1-mediated autoimmune demyelinating disease model for human multiple sclerosis and is characterized by infiltration of the central nervous system (CNS) by Th1 cells and macrophages. Disease relapses are mediated by T cells specific for endogenous myelin epitopes released during acute disease, reflecting a critical role for epitope spreading in the perpetuation of chronic central CNS pathology. We asked whether blockade of the CD40-CD154 (CD40L) costimulatory pathway could suppress relapses in mice with established R-EAE. Anti-CD154 antibody treatment at either the peak of acute disease or during remission effectively blocked clinical disease progression and CNS inflammation. This treatment blocked Th1 differentiation and effector function rather than expansion of myelin-specific T cells. Although T-cell proliferation and production of interleukin (IL)-2, IL-4, IL-5, and IL-10 were normal, antibody treatment severely inhibited interferon-gamma production, myelin peptide-specific delayed-type hypersensitivity responses, and induction of encephalitogenic effector cells. Anti-CD154 antibody treatment also impaired the expression of clinical disease in adoptive recipients of encephalitogenic T cells, suggesting that CD40-CD154 interactions may be involved in directing the CNS migration of these cells and/or in their effector ability to activate CNS macrophages/microglia. Thus, blockade of CD154-CD40 interactions is a promising immunotherapeutic strategy for treatment of ongoing T cell-mediated autoimmune diseases.

Transient anti-CD154-mediated immunotherapy of ongoing relapsing experimental autoimmune encephalomyelitis induces long-term inhibition of disease relapses

Relapsing experimental autoimmune encephalomyelitis (R-EAE) is a Th1-mediated central nervous system (CNS) autoimmune disease with pathology similar to that of relapsing-remitting multiple sclerosis. Among recent therapeutic approaches to prevent or treat relapsing disease is the strategic blockade of the CD154-CD40 ligand pair interactions. We have previously shown that CD154 blockade at the peak of acute disease can, in the short term, inhibit spontaneous disease relapse and this is at least partly associated with the inhibition of T cell effector function and blockade of inflammatory cell recruitment to and/or retention in the CNS. However, little is understood about the long-term effects of CD154 blockade in the inhibition of immune responses to encephalitogenic antigens. Here we demonstrate that transient anti-CD154 blockade of CD154-CD40 interactions at the peak of acute phase of R-EAE resulted in significant long-term inhibition (by >80%) of clinical relapses and that clinical disease in those mice that did relapse was reduced in duration and severity compared to control antibody-treated mice. Additionally, we show that this strategy permanently inhibits DTH responses of T cells specific for relapse-associated encephalitogenic epitopes. Thus, transient CD154 blockade during ongoing disease has a long-term therapeutic efficacy in preventing disease relapses.

Immunotherapy targeting the CD40/CD154 costimulatory pathway for treatment of autoimmune disease.

The CD154–CD40 ligand pair interaction plays a central role in both induction of the immune response and in immune effector functions. Indeed, many animal disease models and human autoimmune diseases have demonstrated a central role for CD154 expression. The expression of CD154 is very tightly regulated by the immune system through a number of non-redundant overlapping mechanisms that ensure its limited initial induction, along with its temporal maintenance and rapid elimination from the cell surface, and its functional neutralization by the release of soluble CD40. In this review, we discuss the current state of understanding of CD154 regulation during the activation of the immune system and describe numerous strategic mechanisms by which modulation of CD154–CD40 interactions may be applied to treat autoimmune disease.

Autoimmune Intervention by CD154 Blockade Prevents T Cell Retention and Effector Function in the Target Organ

The CD40-CD154 interaction is an attractive target for therapeutic intervention in many autoimmune disorders, including multiple sclerosis. Previously, we showed that CD154 blockade both inhibited the onset of experimental autoimmune encephalomyelitis and blocked clinical disease progression (relapses) in mice with established disease. The mechanism of this protection is poorly understood. Because CD154 plays a role in Th1 development, its blockade has been thought to promote anti-inflammatory Th2 responses. However, these conclusions have primarily been based on extrapolated data from in vitro experiments, which may not accurately reflect the more complex events occurring in vivo. In this paper we determine how the immune response develops under the influence of therapeutic CD154 blockade in vivo. We demonstrate that anti-CD154 treatment does not alter the early expansion of Ag-specific T cells in secondary lymphoid organs or result in deviation to a Th2-dominant response. Interestingly, the late expansion and retention of Th1 cells in the lymph nodes were markedly reduced following immunization of Ab-treated mice, and this coincided with a recompartmentalization of these cells to the spleen. Most importantly, anti-CD154 treatment eliminated the retention/expansion of encephalitogenic Th1 cells, but not their entry into the CNS. These data indicate that a major mechanism by which CD154 blockade protects against autoimmune disease is by controlling the amplitude of acute phase Th1 responses in the draining lymph nodes and by preventing the sustained expansion of effector cells within the target organ.

Therapeutic blockade of TCR signal transduction and co-stimulation in autoimmune disease.

Autoimmune diseases are initiated and maintained by presentation of self antigen through complex interactions between different cells of the immune system. In most autoimmune disorders, autoantigen-specific responses are induced by the activation of specific T cells with self peptides displayed on activated antigen presenting cells (APCs). These T cells may then activate and drive B cell responses that either initiate or contribute to chronic disease pathogenesis. In order to activate the T cell, two signals are required: T cell receptor (TCR) engagement by autoantigen presented in the context of self MHC class II and costimulation (CD28-CD80/CD86 interactions). Feedback must also be provided to the APC through MHC class II engagement by the TCR and through costimulatory events controlling T cell differentiation and effector function (CD154-CD40 interactions, among others). With this in mind, numerous strategies have been developed to block the engagement and activation of self-reactive cells. We review and discuss recent progress in understanding the efficacy and underlying molecular mechanisms of three separate immunotherapeutic strategies targeting the TCR and costimulatory molecules: i) blocking TCR signaling (using non-mitogenic anti-CD3 monoclonal antibody); ii) blocking CD28 costimulation (anti-B7 monoclonal antibody blockade); and iii) blocking CD40 engagement on APCs (anti-CD154 monoclonal antibody blockade).

CD154 Blockade Results in Transient Reduction in Theiler's Murine Encephalomyelitis Virus-Induced Demyelinating Disease

ABSTRACT Transient CD154 blockade at the onset of Theilers murine encephalomyelitis virus-induced demyelinating disease ameliorated disease progression for 80 days, reduced immune cell infiltration, and transiently increased viral loads in the central nervous system. Peripheral antiviral and autoimmune T-cell responses were normal, and disease severity returned to control levels by day 120.

Mouse Models of Multiple Sclerosis

Experimental autoimmune encephalomyelitis (EAE) and Theilers murine encephalitis virus-induced demyelinating disease (TMEV-IDD) are two clinically relevant murine models of multiple sclerosis (MS). Like MS, both are characterized by mononuclear cell infiltrate into the central nervous system and demyelination. EAE is induced by either the administration of protein or peptide in adjuvant or by the adoptive transfer of encephalitogenic T-cell blasts into naive recipients. The relative merits of each of these protocols are compared. Depending on the type of question asked, different mouse strains and peptides are used. Different disease courses are observed with different strains and different peptides in active EAE. These variations are addressed, and grading of mice in EAE is discussed. In addition to EAE induction, useful references for other disease indicators, such as delayed-type hypersensitivity, in vitro proliferation, and immunohistochemistry, are provided. TMEV-IDD is a useful model for understanding the potential viral etiology of MS. This chapter provides detailed information on the preparation of viral stocks and subsequent intracerebral infection of mice. In addition, virus plaque assay and disease assessment are discussed. Recombinant TMEV strains have been created for the study of molecular mimicry; these strains incorporate 30 various amino acid myelin epitopes within the leader region of TMEV.

Pathogenesis of epitope spreading in relapsing EAE-intrinsic and induced regulation

PLP139-151-induced relapsing EAE (R-EAE) in the SJL/J mouse is characterized by a relapsing-remitting clinical course in which epitope spreading leads to the induction of T cells specific for myelin epitopes (e.g., PLP178-t91 and MBP84-104) distinct from that which initiated disease. Investigation of the mechanisms responsible for intrinsic remissions of active R-EAF have shown that IL-4 mRNA expression in the CNS correlates with disease remissions. In addition, FaslFasL-mediated apoptosis plays a major role in intrinsic regulation of disease as Fas-deficient SJL Ipr/lpr mice fail to remit from the acute paralytic episode. We have also successfully utilized induction of peptide-spocific immune tolerance and antagonists of the B7/CD28:CTLA-4 pathway to down-regulate established R-EAE. These experiments have demonstrated that BT-l-controlled responses to relapse-associated epitopes play the major pathologic role in mediating disease relapses. In addition, these treatments are highly efficacious, long-lasting, and associated with the induction of anergy in T cells specific for relapse-associated epitopes. CD40 and its ligand, CD154 have been shown to play a critical role in the regulation of both humeral and cell-mediated immunity. Blockade of CD154 has been demonstrated to be effective in ameliorating a wide spectrum of autoimmune diseases and thus has become an attractive therapeutic target in auotimmune diseases, like multiple sclerosis. CD154 plays multiple roles in the regulation of cell mediated immunity. First, data presented will show that CD40 acts as an essential maturafional signal for dendritic cells (I:)(2) in vivo and second, it can regulate the quality of the T cell-mediated immune response (Thl vs Th2). Studies show that both the generation of eneeephalogenie T cells and their effector functions earl be blocked by aCD154 treatment. The basis for these actions will be discussed.