Christine Stadelmann

The development of inflammatory T(H)-17 cells requires interferon-regulatory factor 4

Interferon-regulatory factor 4 (IRF4) is essential for the development of T helper type 2 cells. Here we show that IRF4 is also critical for the generation of interleukin 17–producing T helper cells (TH-17 cells), which are associated with experimental autoimmune encephalomyelitis. IRF4-deficient (Irf4−/−) mice did not develop experimental autoimmune encephalomyelitis, and T helper cells from such mice failed to differentiate into TH-17 cells. Transfer of wild-type T helper cells into Irf4−/− mice rendered the mice susceptible to experimental autoimmune encephalomyelitis. Irf4−/− T helper cells had less expression of RORγt and more expression of Foxp3, transcription factors important for the differentiation of TH-17 and regulatory T cells, respectively. Altered regulation of both transcription factors contributed to the phenotype of Irf4−/− T helper cells. Our data position IRF4 at the center of T helper cell development, influencing not only T helper type 2 but also TH-17 differentiation.

Intrathecal pathogenic anti–aquaporin-4 antibodies in early neuromyelitis optica†

The serum of most neuromyelitis optica (NMO) patients contains autoantibodies (NMO‐IgGs) directed against the aquaporin‐4 (AQP4) water channel located on astrocyte foot processes in the perivessel and subpial areas of the brain. Our objectives were to determine the source of central nervous system (CNS) NMO‐IgGs and their role in disease pathogenesis.

Activation of Caspase-3 in Single Neurons and Autophagic Granules of Granulovacuolar Degeneration in Alzheimer's Disease: Evidence for Apoptotic Cell Death

Neuronal loss is prominent in Alzheimers disease (AD), and its mechanisms remain unresolved. Apoptotic cell death has been implicated on the basis of studies demonstrating DNA fragmentation and an up-regulation of proapoptotic proteins in the AD brain. However, DNA fragmentation in neurons is too frequent to account for the continuous neuronal loss in a degenerative disease extending over many years. Furthermore, the typical apoptotic morphology has not been convincingly documented in AD neurons with fragmented DNA. We report the detection of the activated form of caspase-3, the central effector enzyme of the apoptotic cascade, in AD and Downs syndrome (DS) brain using an affinity-purified antiserum. In AD and DS, single neurons with apoptotic morphology showed cytoplasmic immunoreactivity for activated caspase-3, whereas no neurons were labeled in age-matched controls. Apoptotic neurons were identified at an approximate frequency of 1 in 1100 to 5000 neurons in the cases examined. Furthermore, caspase-3 immunoreactivity was detected in granules of granulovacuolar degeneration. Our results provide direct evidence for apoptotic neuronal death in AD with a frequency compatible with the progression of neuronal degeneration in this chronic disease and identify autophagic vacuoles of granulovacuolar degeneration as possible means for the protective segregation of early apoptotic alterations in the neuronal cytoplasm.

The neuroprotective effect of inflammation: implications for the therapy of multiple sclerosis

Autoreactive T cells are a component of the normal immune system. It has been proposed that some of these autoreactive T cells even have a protective function. Recent studies support this notion by demonstrating that (a) myelin basic-protein (MBP-) specific T cells show neuroprotective effects in vivo, and (b) activated antigen-specific human T cells and other immune cells produce bioactive brain-derived neurotrophic factor (BDNF) in vitro. Furthermore, BDNF is expressed in different types of inflammatory cells in brain lesions of patients with acute disseminated leukoencephalopathy or multiple sclerosis. We postulate that the neuroprotective effect of T cells and other immune cells observed in vivo is at least partially mediated by BDNF and other neurotrophic factors. The concept of neuroprotective autoimmunity has obvious implications for the therapy of multiple sclerosis and other neuroimmunological diseases.

Detection of apoptosis in tissue sections.

Abstract During the last few years, detection of apoptosis has evolved from a predominantly morphological basis to the use of ever more specific techniques. The methods widely used to visualize DNA fragmentation in tissue sections are now supplemented by a variety of specific antisera against components of the cell death pathways. Essential requirements for apoptosis detection techniques include high sensitivity for apoptotic cells, the ability to differentiate between apoptotic and necrotic cell death and other forms of DNA damage, and the distinction between different stages of the cell death process. In this overview, we will focus on recent technical advances in apoptosis detection covering improvements of in situ DNA fragmentation techniques, as well as pointing out some of the new tools available for the detection of apoptotic cells in tissue.

Neurotrophic cross-talk between the nervous and immune systems: implications for neurological diseases.

Inflammatory reactions in the central nervous system usually are considered detrimental, but recent evidence suggests that they also can be beneficial and even have neuroprotective effects. Intriguingly, immune cells can produce various neurotrophic factors of various molecular families. The concept of “neuroprotective immunity” will have profound consequences for the pathogenesis and treatment of neuroinflammatory diseases such as multiple sclerosis. It also will prove important for neurodegenerative disorders, in which inflammatory reactions often occur. This review focuses on recent findings that immune cells produce brain‐derived neurotrophic factor in multiple sclerosis lesions, whereas neurons and astrocytes express the appropriate tyrosine kinase receptor TrkB. Together with functional evidence for the neuroprotective effects of immune cells, these observations support the concept of “neuroprotective immunity.” We next examine current and future therapeutic strategies for multiple sclerosis and experimental autoimmune encephalomyelitis in light of neuroprotective immunity and finally address the broader implications of this new concept for other neuroinflammatory and neurodegenerative diseases. Ann Neurol 2003

Staging of Neurofibrillary Pathology in Alzheimer's Disease: A Study of the BrainNet Europe Consortium

It has been recognized that molecular classifications will form the basis for neuropathological diagnostic work in the future. Consequently, in order to reach a diagnosis of Alzheimers disease (AD), the presence of hyperphosphorylated tau (HP‐tau) and β‐amyloid protein in brain tissue must be unequivocal. In addition, the stepwise progression of pathology needs to be assessed. This paper deals exclusively with the regional assessment of AD‐related HP‐tau pathology. The objective was to provide straightforward instructions to aid in the assessment of AD‐related immunohistochemically (IHC) detected HP‐tau pathology and to test the concordance of assessments made by 25 independent evaluators. The assessment of progression in 7‐µm‐thick sections was based on assessment of IHC labeled HP‐tau immunoreactive neuropil threads (NTs). Our results indicate that good agreement can be reached when the lesions are substantial, i.e., the lesions have reached isocortical structures (stage V–VI absolute agreement 91%), whereas when only mild subtle lesions were present the agreement was poorer (I–II absolute agreement 50%). Thus, in a research setting when the extent of lesions is mild, it is strongly recommended that the assessment of lesions should be carried out by at least two independent observers.

Widespread Demyelination in the Cerebellar Cortex in Multiple Sclerosis

Neocortical demyelination in the forebrain has recently been identified as an important pathological feature of multiple sclerosis (MS). Here we describe that the cerebellar cortex is a major predilection site for demyelination, in particular in patients with primary and secondary progressive MS. In these patients, on average, 38.7% of cerebellar cortical area is affected, reaching in extreme examples up to 92%. Cerebellar cortical demyelination occurs mainly in a band‐like manner, affecting multiple folia. The lesions are characterized by primary demyelination with relative axonal and neuronal preservation, although some axonal spheroids and a moderate reduction of Purkinje cells are present. Although cortical demyelination sometimes occurs together with demyelination in the adjacent white matter (leukocortical lesions), in most instances, the cortex was affected independently from white matter lesions. We found no correlation between demyelination in the cortex and the white matter, and in some cases, extensive cortical demyelination was present in the near absence of white matter lesions. Our data identify cortical demyelination as a potential substrate of cerebellar dysfunction in MS.

Alzheimer disease : DNA fragmentation indicates increased neuronal vulnerability, but not apoptosis

Although nerve cell loss is prominent in certain brain regions in Alzheimer disease (AD), it is currently unresolved how these cells die. Recent studies unanimously agree that there are more neurons displaying DNA fragmentation in AD compared with normal controls. However, controversy remains as to whether cell death is mediated by apoptosis or necrosis. We addressed this question by comparing AD lesions with those from cases with pontosubicular neuron necrosis (PSNN), a human pathological condition with unequivocal neuronal apoptosis, with regard to cell and nuclear morphology, immunohistochemistry, and in situ tailing. Immunohistochemistry was performed for an array of proteins with presumptive roles in the apoptotic process or the protection thereof, i.e. a recently described apoptosis-specific protein (ASP), the transcription factor c-Jun, Bcl-2, and various stress proteins: alpha B-Crystallin, heat shock protein (HSP) 27, HSP 65, HSP 70, HSP 90, and ubiquitin. Apoptotic neurons in PSNN displayed chromatin condensation, nuclear fragmentation, and cytoplasmic condensation. They were labeled with the in situ tailing technique and stained for the ASP. Despite the large numbers of cells with DNA fragmentation identified in the hippocampus of AD brains, only exceptional cells displayed the morphological characteristics of apoptosis or labeled for the ASP. We suggest that the increased rate of neuronal DNA fragmentation in AD patients indicates a higher susceptibility of the cells to metabolic disturbances compared with normal controls. The large number of cells with DNA fragmentation most likely reflects metabolic disturbances in the premortem period, and cell destruction is mediated through necrosis rather than apoptosis.

Identification of a pathogenic antibody response to native myelin oligodendrocyte glycoprotein in multiple sclerosis

Multiple sclerosis (MS) is a chronic inflammatory disease of the central nervous system. Although the cause of MS is still uncertain, many findings point toward an ongoing autoimmune response to myelin antigens. Because of its location on the outer surface of the myelin sheath and its pathogenicity in the experimental autoimmune encephalomyelitis model, myelin oligodendrocyte glycoprotein (MOG) is one of the potential disease-causing self antigens in MS. However, the role of MOG in the pathogenesis of MS has remained controversial. In this study we addressed the occurrence of autoantibodies to native MOG and its implication for demyelination and axonal loss in MS. We applied a high-sensitivity bioassay, which allowed detecting autoantibodies that bind to the extracellular part of native MOG. Antibodies, mostly IgG, were found in sera that bound with high affinity to strictly conformational epitopes of the extracellular domain of MOG. IgG but not IgM antibody titers to native MOG were significantly higher in MS patients compared with different control groups with the highest prevalence in primary progressive MS patients. Serum autoantibodies to native MOG induced death of MOG-expressing target cells in vitro. Serum from MS patients with high anti-MOG antibody titers stained white matter myelin in rat brain and enhanced demyelination and axonal damage when transferred to autoimmune encephalomyelitis animals. Overall these findings suggest a pathogenic antibody response to native MOG in a subgroup of MS patients.