Anti-B-Cell Therapies in Autoimmune Neurological Diseases: Rationale and Efficacy Trials

B cells have an ever-increasing role in the etiopathology of a number of autoimmune neurological disorders, acting as antibody-producing cells and, most importantly, as sensors, coordinators, and regulators of the immune response. B cells, among other functions, regulate the T-cell activation process through their participation in antigen presentation and production of cytokines. The availability of monoclonal antibodies or fusion proteins against B-cell surface molecules or B-cell trophic factors bestows a rational approach for treating autoimmune neurological disorders, even when T cells are the main effector cells. This review summarizes basic aspects of B-cell biology, discusses the role(s) of B cells in neurological autoimmunity, and presents anti-B-cell drugs that are either currently on the market or are expected to be available in the near future for treating neurological autoimmune disorders.     

Invited article: inhibition of B cell functions: implications for neurology

B cells are involved in the pathophysiology of many neurologic diseases, either in a causative or contributory role, via production of autoantibodies, cytokine secretion, or by acting as antigen-presenting cells leading to T cell activation. B cells are clonally expanded in various CNS disorders, such as multiple sclerosis (MS), paraneoplastic CNS disorders, or stiff-person syndrome, and are activated to produce pathogenic autoantibodies in demyelinating neuropathies and myasthenia. B cell activating factor (BAFF) and a proliferating inducing ligand (APRIL), key cytokines for B cell survival, are strongly unregulated in MS brain and in muscles of inflammatory myopathies. Modulation of B cell functions using a series of monoclonal antibodies against CD20+ B cells or the molecules that increase B cell survival, such as BAFF/APRIL and their receptors BAFF-R, TACI, and BCMA, provide a rational approach to the treatment of the aforementioned neurologic disorders. In controlled studies, rituximab, a B cell-depleting monoclonal antibody, has been encouraging in MS and paraproteinemic anti-MAG demyelinating neuropathy, exerting long-lasting remissions. In uncontrolled series, benefit has been reported in several disorders. B cell depletion is a well-tolerated therapeutic option currently explored in the treatment of several autoimmune neurologic disorders.     

Effect of rituximab on the peripheral blood and cerebrospinal fluid B cells in patients with primary progressive multiple sclerosis

BACKGROUND: Rituximab, an anti-CD20 monoclonal antibody that depletes CD20(+) B cells, has demonstrated efficacy in peripheral neurological diseases. Whether this efficacy can be translated to neurological diseases of the central nervous system with possible autoimmune B-cell involvement remains unknown. OBJECTIVE: To determine the effect of rituximab on cerebrospinal fluid B cells in patients with multiple sclerosis. DESIGN: Four patients with primary progressive multiple sclerosis were treated with rituximab. Cerebrospinal fluid and peripheral blood B-cell subsets were identified by flow cytometry from each patient before and after rituximab treatment. RESULTS: The B cells in cerebrospinal fluid were not as effectively depleted as their peripheral blood counterparts. Rituximab treatment temporarily suppressed the activation state of B cells in cerebrospinal fluid. The residual B cells underwent expansion after rituximab treatment. CONCLUSION: The effect(s) of rituximab on the cerebrospinal fluid B-cell compartment is limited in comparison with the effect(s) on the B cells in the periphery, but this finding will need to be confirmed in a larger group of MS patients.     

B-cell depletion abrogates T cell-mediated demyelination in an antibody-nondependent common marmoset experimental autoimmune encephalomyelitis model

CD20-positive B-cell depletion is a highly promising treatment for multiple sclerosis (MS), but the mechanisms underlying therapeutic effects are poorly understood. B cells are thought to contribute to MS pathogenesis by producing autoantibodies that amplify demyelination via opsonization of myelin. To analyze autoantibody-nondependent functions of B cells in an animal model of MS, we used a novel T cell-driven experimental autoimmune encephalomyelitis (EAE) model in marmoset monkeys (Callithrix jacchus). In this model, demyelination of brain and spinal cord white and gray matter and the ensuing neurological deficits are induced by immunization with peptide 34 to 56 of myelin/oligodendrocyte glycoprotein (MOG34-56) in incomplete Freund's adjuvant. Although autoantibodies do not have a detectable pathogeniccontribution in the model, depletion of B cells with monoclonal antibody 7D8, a human IgG1κ monoclonal antibody against human CD20, suppressed clinical and pathological EAE. In B cell-depleted monkeys, the activation of peptide-specific Th17-producing and cytotoxic T cells, which in previous studies were found to play an essential role in disease induction, was impaired. Thus, we demonstrate a critical antibody-nondependent role for B cells in EAE, that is, the activation of pathogenic T cells.     

Autoantibodies against heterogeneous nuclear ribonucleoprotein B1 in CSF of MS patients

Heterogeneous nuclear ribonucleoproteins (hnRNPs) play an important role as the autoantigens in certain autoimmune disorders including neurological diseases such as HTLV-1-associated myelopathy/tropical spastic paraparesis and paraneoplastic neurological syndromes. To clarify their implication in multiple sclerosis (MS), we assayed antibodies (Abs) against hnRNP A and B proteins in sera and cerebrospinal fluid (CSF) of MS patients and compared the results with 25 patients with other neurological diseases (ONDs). Using recombinant hnRNP A1, A2, and B1 proteins and Western blotting for the assay, we found Abs against hnRNP B1 in CSF from 32 of 35 MS patients (91.4%) but not in any sera or CSF of the 25 OND patients. Most notably, no Abs against hnRNP B1 were found in sera of all 22 MS patients examined. Although Abs against hnRNP A1 and A2 were concomitantly found in CSF reacting with B1, their incidence and immunoreactivity were lower or weaker than those of anti-hnRNP B1 Abs. There was no correlation between the reactivity of CSF with hnRNP B1 and CSF parameters-such as the number of the cells and the IgG level-or clinical parameters-such as duration of illness and disease activity. The selective generation of Abs against hnRNP B1 in CSF was shown to be highly specific for MS, which makes them a disease marker.     

The natural history of B cells

Multiple sclerosis is a common neurological disorder that represents a significant source of disability. B cells have recently emerged as a novel therapeutic target for multiple sclerosis. The natural development of B cells is characterized by an antigen-independent phase that occurs in the bone marrow and an antigen-dependent phase that takes place in the peripheral lymphoid tissue. The stage of B-cell development can be identified by the presence of specific cell surface markers. Checkpoints are in place to prevent self-reactive B cells from further development and activation. Some self-reactive B cells are able to escape these checkpoints, resulting in a loss of tolerance. B cells may contribute to systemic autoimmunity and the development of autoimmune disease via cytokine production, antigen presentation, and complement activation. In addition, B cells may trigger autoimmune disease via molecular mimicry, which occurs when a single B-cell receptor recognizes both a non-self antigen molecule and a self-molecule. Accumulating data suggest that ectopic proliferation of B cells in the central nervous system may also play a role. Further research is needed to elucidate the pathology of B cells and their role in central nervous system autoimmune diseases, including multiple sclerosis.     

Strategies for the modulation of neuroimmunological disease at the level of autoreactive T-lymphocytes

Cell lines of autoimmune T-lymphocytes have been established in several neuroimmunological model diseases and also in a human neurological autoimmune disease, myasthenia gravis. These cell lines generally have the T helper/inducer phenotype and recognize autoantigen in the context of class II histocompatibility antigens. Autoreactive helper T cell lines may become useful tools for the evaluation of new immunotherapeutic strategies. (1) Treatment with anti-Ia monoclonal antibodies presumably interferes with the interaction between Ia on the surface of antigen-presenting cells and the autoreactive T cell receptor; (2) Therapy with unmodified or modified autoantigen may be used to tolerize or delete the autoimmune T cells; (3) Monoclonal antibodies against the 'T cell domains' of autoantigen may prevent its recognition by the autoreactive T cells; (4) Treatment with monoclonal antibodies against T cell clonotypic or differentiation antigens may effectively delete or inactivate the autoreactive T cells. Furthermore, autoreactive helper T cells may be used to induce and establish anti-idiotypic suppressor T cell lines, or the autoimmune helper T cells may themselves display suppressive effects in an allogeneic system.     

Active Aβ vaccination fails to enhance amyloid clearance in a mouse model of Alzheimer's disease with Aβ42-driven pathology

S100B is a Ca(2+)-binding protein expressed in the nervous system. Increased levels of S100B in the extracellular space have been detected in several neurological disorders. We investigated the response of human astrocytes to micromolar chronic concentrations of this protein measuring the expression of some costimulatory molecules, such as CD137, CD137-L, CD40, CD40-L, the chemokine RANTES and two growth factors FGF-2 and TGF-β2. Our findings suggest that high levels of S100B in the brain parenchyma may modulate the activation status of astrocytes decreasing their neuroprotective role and modifying their interaction with microglia and other inflammatory cells. This effect may contribute to evolution of some neurological disorders.     

The evidence for a role of B cells in multiple sclerosis

Understanding the pathogenesis of complex immunologic disorders such as multiple sclerosis (MS) is challenging. Abnormalities in many different cell types are observed in the immune system and CNS of patients with MS and the identification of the primary and secondary events is difficult. Recent studies suggest that the model of MS as a disorder mediated only by T cells is overly simplistic and propose an important role for B cells in the propagation of the disease. B-cell activation in the form of oligoclonal bands (OCB) production is the most consistent immunologic finding in patients with MS. Notably, markers of B-cell activation within the CSF of patients with MS predict conversion from clinically isolated syndrome to clinically definite MS and correlate with MRI activity, onset of relapses, and disability progression. In addition, the main genetic risk factor in MS is associated with OCB production, and environmental agents associated with MS susceptibility (vitamin D and the Epstein-Barr virus) influence B-cell proliferation and function. Finally, the only cell-specific treatments that are effective in patients with MS are monoclonal antibodies targeting the B-cell antigen CD20, suggesting a potentially causative role for B cells. Based on current evidence there is no longer doubt that B cells are relevant to the etiology and pathogenesis of MS. Elucidating the role of B cells in MS will be a fruitful strategy for disease prevention and treatment.     

An uncontrolled trial of rituximab for antibody associated paraneoplastic neurological syndromes

Abstract Anti-CD20 monoclonal antibody (rituximab) is effectively used in the treatment of B-cell lymphomas. Recent reports in the literature suggest that antibody associated autoimmune disorders may respond to rituximab. We therefore treated nine patients with anti-Hu or anti-Yo associated paraneoplastic neurological syndromes (PNS) with a maximum of four monthly IV infusions of rituximab (375mg/m²). In this uncontrolled, unblinded trial of rituximab, three patients improved ≥1 point on the Rankin Scale (RS). One patient with limbic encephalitis improved dramatically (RS from 5 to 1). Further studies of rituximab in autoantibody associated PNS are warranted.     

Cerebrospinal fluid CD19+ B‐cell expansion in N‐methyl‐D‐aspartate receptor encephalitis

There is increasing interest in the role of autoantibodies in acquired autoimmune central nervous system disorders. N‐methyl‐d ‐aspartate receptor (NMDAR) encephalitis is an autoimmune encephalitis defined by the presence of autoantibodies that bind to the NMDAR. Although there is evidence of NMDAR antibody pathogenicity, it is unclear which treatment results in the best outcome. We measured the proportion of B‐cells in the cerebrospinal fluid of two children with NMDAR encephalitis (a 6‐year‐old male and a 4‐year‐old female), one in the acute phase and one in the relapsing phase. The proportion of CD19⁺ B‐cells in both children was greater than 10%, significantly higher than seen in non‐inflammatory neurological disorders (<1%). This finding supports the use of drugs, such as rituximab, that deplete B‐cells in severe or refractory cases of NMDAR encephalitis, and lends further support to the humoral autoimmune hypothesis in NMDAR encephalitis.     

Decreased suppressor-inducer T lymphocytes in multiple sclerosis and other neurological diseases

Decreased numbers of CD4+CD45R+ suppressor-inducer T cells have been reported in patients with a variety of autoimmune diseases including systemic lupus erythematosus, rheumatoid arthritis and multiple sclerosis but not in patients with other neurological diseases. We now report our findings using murine monoclonal antibodies and two-color flow cytometric analysis on CD4+CD45R+ T cells in 22 patients with chronic progressive multiple sclerosis, 23 patients with other neurological diseases and 42 normal, healthy controls. Suppressor-inducer T cells were significantly reduced (p less than 0.001) in both patients with multiple sclerosis and other neurological diseases as compared to controls. Both patient populations had elevated helper T cell subset ratios. Thus, our data suggests that decreases in suppressor-inducer T cells may represent a common immunological defect among autoimmune and presumably non-autoimmune neurological disorders.     

The autoimmune vulnerability of the node of Ranvier

The nodes of Ranvier (NoR) are essential domains for nerve conduction and their disruption plays a key role in the pathophysiology of immune-mediated neuropathies. Our understanding of the specialized nodal regions and the immune mechanisms that affect them is growing and has led to the update of peripheral neuropathy classification to include the autoimmune nodopathies, defined by the site of the autoimmune attack. Autoantibodies directed against molecules of the nodal region (as neurofascin-140/186, neurofascin-155, contactin-1, contactin-associated protein 1, contactin-associated protein 2, gangliosides, LGI4, or myelin-associated glycoprotein), macrophage-induced paranodal demyelination, and phenotypic changes of the nodal domains of Schwann cells have been identified as key mechanisms in the pathogenesis of the autoimmune neuropathies. This review explores the current knowledge of the autoimmune vulnerability of the NoR, including the underlying mechanisms leading to dysfunction in the diverse autoimmune disorders.     

Synthesis of anti-acetylcholine receptor antibodies by CD5- B cells from peripheral blood of myasthenia gravis patients

An increased frequency of CD5⁺ B cells (or, according to a new nomenclature, B 1 cells) has been detected in the peripheral blood of a proportion of patients with myasthenia gravis (MG), as in some other autoimmune diseases. To elucidate the pathogenic significance of this B-cell subset in myasthenia gravis, mononuclear cells from the peripheral blood of six MG patients were separated into T and B lymphocytes by a magnetic cell separation procedure employing superparamagnetic microbeads (MACS). Subsequently, the B-cell fraction was depleted of CD5⁺ B cells in a second separation. The resulting purified CD5^– B-cell fraction was cultured alone or with the addition of autologous T cells. Anti-acetylcholine receptor (AChR) synthesis by CD5^– B cells in cultures with T cells was significantly increased by pokeweed mitogen (176 ±130 fmol/ml per week/2 × 10⁵ B cells) compared with unfractionated cells (75 ± 101) or CD5^– B cells alone (19 ± 4). These results demonstrate that in MG anti-AChR are synthesized, at least in part, by CD5^– B cells which are dependent on T cells. Although this does not exclude the existence of AChR-specific CD5⁺ B cells, it provides evidence against a pivotal role of this B-cell subset in anti-AChR synthesis.     

Pathogenetic role of autoantibodies in neurological diseases

Autoreactive B cells and antibodies can be detected in a variety of neurological diseases. Their causative role has been established in some disorders and they are obviously involved in the pathogenesis of others. Some mechanisms engendering B-cell autoimmunity in animal models have been shown to operate in humans. Factors that determine B-cell immune-response patterns and the effector pathways have been identified. B-cell responses to CNS-restricted autoantigens are governed by distinctive immune reactions. Evidence has accumulated that the CNS is a permissive and, under inflammatory conditions, even a B-cell-supporting micro-environment. Data from human and animal experiments have enhanced our understanding of B-cell physiology in health and neurological disease, which has relevant diagnostic and therapeutic implications.     

Autoimmune and paraneoplastic channelopathies

Thirty years ago, antibodies against the muscle acetylcholine receptor (AChR) were recognized as the cause of myasthenia gravis. Since then, there has been great interest in identifying other neurological disorders associated with auto-antibodies. Several other antibody-mediated neuromuscular disorders have been identified, each associated with an antibody against a ligand- or voltage-gated ion channel. The Lambert-Eaton syndrome is caused by antibodies against voltage-gated calcium channels and often occurs in patients with small cell lung cancer. Acquired neuromyotonia is caused by voltage-gated potassium channel antibodies, and autoimmune autonomic ganglionopathy is caused by antibodies against the neuronal AChR in autonomic ganglia. There is good evidence that antibodies in these disorders cause changes in synaptic function r neuronal excitability by directly inhibiting ion channel function. More recently, studies have identified ion channel antibodies in patients with certain CNS disorders, such as steroid-responsive encephalitis and paraneoplastic cerebellar ataxia. It remains unclear if antibodies can gain access to the CNS and directly cause ion channel dysfunction. Treatment of autoimmune channelopathies includes drugs that help restore normal neuronal function and treatments to remove pathogenic antibodies (plasma exchange) or modulate the immune response (steroids or immunosuppressants). These disabling neurological disorders may be dramatically responsive to immunomodulatory therapy. Future studies will likely lead to identification of other ion channel antibodies and other autoimmune channelopathies.     

Inhibition of rat autoimmune T cell activation by monoclonal antibodies

The essential requirement for adoptive transfer of autoimmune diseases such as experimental allergic encephalomyelitis (EAE) by T lymphoblasts from established T cell lines, is a prior activation of these cells by autoantigen or mitogen. We have investigated the possibility of modulating this activation process by using monoclonal antibodies directed against rat leukocyte differentiation antigens. We report here that antigen-driven activation of autoimmune, encephalitogenic T cells from established myelin basic protein (MBP)-specific rat T cell lines can be inhibited by some, but not all, antibodies against RT1.B Class II restriction elements. In addition, monoclonal antibodies with specificity for rat leukocyte common antigen (OX-1) and T cell differentiation antigens W3/13 and W3/25 are inhibitory, while monoclonal antibody OX-8 with specificity for T cytotoxic/suppressor cells has no effect. We also observed that concanavalin A-induced activation of the T cells is more resistant to the inhibitory effect of monoclonal antibodies, and can be blocked effectively only by antibody OX-1. This demonstration that autoimmune T cell function can be inhibited by monoclonal antibodies points the way in suggesting cellular targets for immunotherapeutic purposes.     

Chemokines and chemokine receptors in the pathogenesis of multiple sclerosis

In recent years we have seen growing evidence for the role of chemokines in the pathogenesis of several infectious and non-infectious inflammatory CNS disease states, including Multiple Sclerosis (MS) and its animal model, experimental allergic encephalomyelitis (EAE). An increase in proinflammatory chemokines has been associated with demyelinating lesions and clinical neurological dysfunction in patients with MS; these chemokines could be potential targets for MS therapy. Besides a clearly defined role in mediating leukocyte migration, these and other chemokines may act as immunoregulatory molecules in the driving to Th1/Th2 responses, switch of cytokine profiles, and the induction of tolerance. Since chemokine receptors have now been identified on macrophages, microglia, astrocytes, and endothelial cells as well as neurons in the CNS, chemokine/receptor interactions may mediate functional responses in a variety of CNS cell types during the course of inflammatory disease states. Therefore, clarification of the roles of chemokines and their receptors in the pathogenesis of EAE and MS will be useful in establishing immunotherapeutic strategies for these neurological autoimmune disorders.