There has been significant progress in our understanding of the pathology and pathogenesis of central nervous system inflammatory demyelinating diseases. Neuropathological studies have provided fundamental new insights into the pathogenesis of these disorders and have led to major advances in our understanding of multiple sclerosis (MS) heterogeneity, the substrate of irreversible progressive disability in MS, the relationship between inflammation and neurodegeneration in MS, the neuroimaging correlates of MS lesions, and the pathogenesis of other central nervous system inflammatory disorders, including neuromyelitis optica, acute disseminated encephalomyelitis, and Balo's concentric sclerosis. Herein, we review the pathological features of these central nervous system inflammatory demyelinating disorders and discuss neuropathological studies that have yielded novel insights into potential mechanisms involved in the formation of the demyelinated lesion.
The Pathology of an Autoimmune Astrocytopathy: Lessons Learned from Neuromyelitis Optica
Neuromyelitis optica (NMO) is a disabling autoimmune astrocytopathy characterized by typically severe and recurrent attacks of optic neuritis and longitudinally-extensive myelitis. Until recently, NMO was considered an acute aggressive variant of multiple sclerosis (MS), despite the fact that early studies postulated that NMO and MS may be two distinct diseases with a common clinical picture. With the discovery of a highly specific serum autoantibody (NMO-IgG), Lennon and colleagues provided the first unequivocal evidence distinguishing NMO from MS and other CNS inflammatory demyelinating disorders. The target antigen of NMO-IgG was confirmed to be aquaporin-4 (AQP4), the most abundant water channel protein in the central nervous system (CNS), mainly expressed on astrocytic foot processes at the blood brain barrier, subpial and subependymal regions. Pathological studies demonstrated that astrocytes were selectively targeted in NMO as evidenced by the extensive loss of immunoreactivities for the astrocytic proteins, AQP4 and glial fibrillary acidic protein (GFAP), as well as perivascular deposition of immunoglobulins and activation of complement even within lesions with a relative preservation of myelin. In support of these pathological findings, GFAP levels in the cerebrospinal fluid (CSF) during acute NMO exacerbations were found to be remarkably elevated in contrast to MS where CSF-GFAP levels did not substantially differ from controls. Additionally, recent experimental studies showed that AQP4 antibody is pathogenic, resulting in selective astrocyte destruction and dysfunction in vitro, ex vivo, and in vivo. These findings strongly suggest that NMO is an autoimmune astrocytopathy where damage to astrocytes exceeds both myelin and neuronal damage. This chapter will review recent neuropathological studies that have provided novel insights into the pathogenic mechanisms, cellular targets, as well as the spectrum of tissue damage in NMO.
Molecular outcomes of neuromyelitis optica (NMO)-IgG binding to aquaporin-4 in astrocytes
The astrocytic aquaporin-4 (AQP4) water channel is the target of pathogenic antibodies in a spectrum of relapsing autoimmune inflammatory central nervous system disorders of varying severity that is unified by detection of the serum biomarker neuromyelitis optica (NMO)-IgG. Neuromyelitis optica is the most severe of these disorders. The two major AQP4 isoforms, M1 and M23, have identical extracellular residues. This report identifies two novel properties of NMO-IgG as determinants of pathogenicity. First, the binding of NMO-IgG to the ectodomain of astrocytic AQP4 has isoform-specific outcomes. M1 is completely internalized, but M23 resists internalization and is aggregated into larger-order orthogonal arrays of particles that activate complement more effectively than M1 when bound by NMO-IgG. Second, NMO-IgG binding to either isoform impairs water flux directly, independently of antigen down-regulation. We identified, in nondestructive central nervous system lesions of two NMO patients, two previously unappreciated histopathological correlates supporting the clinical relevance of our in vitro findings: (i) reactive astrocytes with persistent foci of surface AQP4 and (ii) vacuolation in adjacent myelin consistent with edema. The multiple molecular outcomes identified as a consequence of NMO-IgG interaction with AQP4 plausibly account for the diverse pathological features of NMO: edema, inflammation, demyelination, and necrosis. Differences in the nature and anatomical distribution of NMO lesions, and in the clinical and imaging manifestations of disease documented in pediatric and adult patients, may be influenced by regional and maturational differences in the ratio of M1 to M23 proteins in astrocytic membranes.T he most abundant water channel in the central nervous system (CNS) is aquaporin-4 (AQP4), which is confined to astrocytes and ependyma; is enriched at glial-pial and glialendothelial interfaces; and surrounds nodes of Ranvier and paranodes, adjacent oligodendroglial loops, and synapses (1). In 2005, we identified AQP4 as the target of pathogenic autoantibodies in a spectrum of inflammatory CNS disorders of varying severity that is unified by detection of the serum biomarker neuromyelitis optica (NMO)-IgG (2, 3). These disorders are now recognized collectively as IgG-mediated autoimmune astrocytopathies. Before discovery of this antibody, NMO spectrum disorders were misclassified as multiple sclerosis variants. NMOIgG is centrally involved in the pathogenesis of NMO spectrum disorders. Its detection predicts frequent relapses that cause cumulative neurological impairment. Lesions characteristically affect the spinal cord and optic nerve, but do not spare the brain. Independent laboratories have demonstrated that NMO-IgG binding initiates AQP4 down-regulation with accompanying endocytosis of its physically associated glutamate transporter, EAAT2, complement activation, impairment of blood-brain barrier integrity, inflammation, and astrocyte injury (4-8). Demyelination is a proposed consequence of both pa...
Objective: To characterize the neuropathologic features of neuromyelitis optica (NMO) at the medullary floor of the fourth ventricle and area postrema. Aquaporin-4 (AQP4) autoimmunity targets this region, resulting in intractable nausea associated with vomiting or hiccups in NMO.Methods: This neuropathologic study was performed on archival brainstem tissue from 15 patients with NMO, 5 patients with multiple sclerosis (MS), and 8 neurologically normal subjects. Logistic regression was used to evaluate whether the presence of lesions at this level increased the odds of a patient with NMO having an episode of nausea/vomiting.Results: Six patients with NMO (40%), but no patients with MS or normal controls, exhibited unilateral or bilateral lesions involving the area postrema and the medullary floor of the fourth ventricle. These lesions were characterized by tissue rarefaction, blood vessel thickening, no obvious neuronal or axonal pathology, and preservation of myelin in the subependymal medullary tegmentum. AQP4 immunoreactivity was lost or markedly reduced in all 6 cases, with moderate to marked perivascular and parenchymal lymphocytic inflammatory infiltrates, prominent microglial activation, and in 3 cases, eosinophils. Complement deposition in astrocytes, macrophages, and/or perivascularly, and a prominent astroglial reaction were also present. The odds of nausea/ vomiting being documented clinically was 16-fold greater in NMO cases with area postrema lesions (95% confidence interval 1.43-437, p ϭ 0.02).
MS is heterogeneous with respect to clinical, genetic, radiographic, and pathologic features; surrogate MRI, clinical, genetic, serologic, and/or CSF markers for each of the four immunopatterns need to be developed in order to recognize them in the general nonbiopsied MS population. Inflammatory cortical demyelination is an important early event in the pathogenesis of MS and may be driven by meningeal inflammation. These observations stress the importance of developing imaging techniques able to capture early inflammatory cortical demyelination in order to better understand the disease pathogenesis and to determine the impact of potential disease-modifying therapies on the cortex.
We report 12 aquaporin-4 antibody-positive patients (12% of seropositive Mayo Clinic patients identified since 2005) whose initial presenting symptom of neuromyelitis optica was intractable vomiting. The initial evaluation in 75% was gastroenterologic. Vomiting lasted a median of 4 weeks (range, 2 days-80 weeks). Optic neuritis or transverse myelitis developed after vomiting onset in 11 patients (median interval, 11 weeks; range, 1-156). At last evaluation (median, 48 months after vomiting onset), 7 patients fulfilled neuromyelitis optica diagnostic criteria. Our clinical, pathologic and neuroimaging observations suggest the aquaporin-4-rich area postrema may be a first point of attack in neuromyelitis optica.
Objective: To describe a patient presenting with a clinically silent, incidentally found, and pathologically confirmed active demyelinating solitary cortical lesion showing MRI gadolinium contrast enhancement, in whom biopsy was performed before the radiographic appearance of disseminated white matter lesions.Methods: Neurologic examination, MRI, CSF and serologic analyses, and brain biopsy were performed. Sections of formalin-fixed paraffin-embedded biopsied brain tissue were stained with histologic and immunohistochemical stains.Results: Biopsy revealed an inflammatory subpial lesion containing lymphocytes and myelin-laden macrophages. Recurrent relapses with dissemination of MRI-typical white matter lesions characterized the subsequent course. Conclusions:Our findings highlight that cortical demyelination occurs on a background of inflammation and suggest that the noninflammatory character of chronic cortical demyelination may relate to long intervals between lesion formation and autopsy. This case provides pathologic evidence of relapsing-remitting MS presenting with inflammatory cortical demyelination and emphasizes the importance of considering demyelinating disease in the differential diagnosis of patients presenting with a solitary cortical enhancing lesion. Neurology Traditionally, multiple sclerosis (MS) has been considered a disease primarily affecting the CNS white matter. Nevertheless, gray matter involvement has been recognized for a long time.1 Recent pathologic studies have revealed that cortical demyelination is more extensive than previously appreciated, 2,3 is characteristic of progressive MS, 4 and is devoid of lymphocytes and macrophages.3 However, these studies have relied on postmortem tissue analysis from patients with longstanding disease. Therefore, the pathology of early cortical demyelinating MS lesions is virtually unknown. Interestingly, pathologic findings in a focal cortical experimental autoimmune encephalomyelitis (EAE) animal model have challenged the concept that cortical lesions are noninflammatory. 5Recent histopathologic studies have shown that cortical demyelination may occur spatially removed from white matter pathology, without obvious anatomic relationships.6 Therefore, it is plausible that cortical demyelination could represent the earliest pathologic event in some patients with MS and, indeed, MRI evidence of MS cortical onset has been previously reported. 7 We describe a patient presenting with a clinically silent, incidentally found, and pathologically confirmed active demyelinating cortical lesion showing MRI gadolinium contrast enhancement, in whom biopsy was performed before the radiographic appearance of disseminated white matter lesions. The patient subsequently fulfilled diagnostic criteria for
Multiple sclerosis (MS) is a chronic inflammatory demyelinating disease of the central nervous system (CNS) in which oligodendrocytes, the CNS cells that stain most robustly for iron and myelin are the targets of injury. Metals are essential for normal CNS functioning, and metal imbalances have been linked to demyelination and neurodegeneration. Using a multidisciplinary approach involving synchrotron techniques, iron histochemistry and immunohistochemistry, we compared the distribution and quantification of iron and zinc in MS lesions to the surrounding normal appearing and periplaque white matter, and assessed the involvement of these metals in MS lesion pathogenesis. We found that the distribution of iron and zinc is heterogeneous in MS plaques, and with few remarkable exceptions they do not accumulate in chronic MS lesions. We show that brain iron tends to decrease with increasing age and disease duration of MS patients; reactive astrocytes organized in large astrogliotic areas in a subset of smoldering and inactive plaques accumulate iron and safely store it in ferritin; a subset of smoldering lesions do not contain a rim of iron-loaded macrophages/microglia; and the iron content of shadow plaques varies with the stage of remyelination. Zinc in MS lesions was generally decreased, paralleling myelin loss. Iron accumulates concentrically in a subset of chronic inactive lesions suggesting that not all iron rims around MS lesions equate with smoldering plaques. Upon degeneration of iron-loaded microglia/macrophages, astrocytes may form an additional protective barrier that may prevent iron-induced oxidative damage.Electronic supplementary materialThe online version of this article (doi:10.1007/s00401-017-1696-8) contains supplementary material, which is available to authorized users.
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