Neuroimmunopathology in a murine model of neuropsychiatric lupus

Animal models are extremely useful tools in defining pathogenesis and treatment of human disease. For many years researchers believed that structural damage to the brain of neuropsychiatric (NP) patients lead to abnormal mental function, but this possibility was not extensively explored until recently. Imaging studies of NP-systemic lupus erythematosus (SLE) support the notion that brain cell death accounts for the emergence of neurologic and psychiatric symptoms, and evidence suggests that it is an autoimmunity-induced brain disorder characterized by profound metabolic alterations and progressive neuronal loss. While there are a number of murine models of SLE, this article reviews recent literature on the immunological connections to neurodegeneration and behavioral dysfunction in the Fas-deficient MRL model of NP-SLE. Probable links between spontaneous peripheral immune activation, the subsequent central autoimmune/inflammatory responses in MRL/MpJ-Tnfrsf6(lpr) (MRL-lpr) mice and the sequential mode of events leading to Fas-independent neurodegenerative autoimmune-induced encephalitis will be reviewed. The role of hormones, alternative mechanisms of cell death, the impact of central dopaminergic degeneration on behavior, and germinal layer lesions on developmental/regenerative capacity of MRL-lpr brains will also be explored. This model can provide direction for future therapeutic interventions in patients with this complex neuroimmunological syndrome.

Autoimmune-induced damage of the midbrain dopaminergic system in lupus-prone mice

Spontaneous development of lupus-like disease is accompanied by impaired dopamine catabolism and degenerating axon terminals in the mesencephalon of MRL-lpr mice. We presently examine the hypothesis that systemic autoimmunity affects the central dopaminergic system in behaviorally impaired animals. The functional damage of the nigrostriatal pathway was assessed from rotational behavior after a single injection of the D1/D2-receptor agonist apomorphine. Neurodegeneration in the midbrain was estimated by Fluoro Jade B (FJB) staining. The causal role of autoimmunity was tested by comparing asymptomatic and diseased MRL-lpr mice, and by employing the immunosuppressive drug cyclophosphamide. Damage of dopaminergic neurons was assessed by tyrosine-hydroxylase (TH) staining of the midbrain. Apomorphine induced significant asymmetry in limb use, which lead to increased circling in the diseased MRL-lpr group. While FJB-positive somas were not seen in the striatum, increased staining in the substantia nigra (SN) and ventral tegmental area (VTA) were detected in behaviorally impaired MRL-lpr mice, but not in age-matched controls. Reduced brain mass and increased levels of TNF-alpha in their cerebrospinal fluid (CSF) suggested cerebral atrophy and inflammation. In addition, CSF was neurotoxic to a dopaminergic progenitor cell line. Immunosuppression attenuated CSF cytotoxicity, TNF-alpha levels, and midbrain neurodegeneration. Supportive of the notion that dying neurons were dopaminergic, the SN of autoimmune mice showed approximately a 35% reduction in the number of TH-positive cells. A three-fold increase in serum brain-reactive antibodies accompanied this loss. Although the source of toxic mediator(s) remains unknown, present results are consistent with the hypothesis that autoimmunity-induced destruction of mesonigral and mesolimbic dopaminergic pathways contributes to the etiology of aberrant behavior in an animal model of neuropsychiatric lupus.

Increased ICAM-1 and VCAM-1 expression in the brains of autoimmune mice

Pathogenic mechanisms of central nervous system (CNS) involvement in systemic lupus erythematosus (SLE) remain unknown. We recently reported the presence of autoantibodies in the brain tissue ex vivo of autoimmune MRL/lpr mice. We postulated that at least some of these autoantibodies are produced in situ because of B-cell entry into the brain. The blood-brain barrier (BBB) blocks the entry of most large molecules and cells into the brain. In certain CNS pathologies, however, immune cells gain entry due to elevated expression of adhesion molecules. This study looked at adhesion molecule expression, ICAM-1 and VCAM-1, in the brains of MRL/lpr mice. Using immunofluorescent antibody binding assays and confocal laser imaging, we show that expression of ICAM-1 and VCAM-1 is elevated in MRL/lpr mice brains at 4 months of age as compared to age-matched controls. These results suggest a possible mechanism for leukocyte entry into the brains of autoimmune mice that in turn suggest immune-mediated pathology in CNS-lupus.

Immunoglobulin binding to brain in autoimmune mice

Brain-reactive autoantibodies (BRAA) are thought to play an important role in central nervous system (CNS) manifestations of systemic lupus erythematosus (SLE). Previous studies have shown the existence of BRAA in human and murine SLE. This study was undertaken to establish and characterize the presence of autoantibody binding to brain of autoimmune mice. Laser confocal microscopy was performed on frozen brain sections to detect the presence of immunoglobulin (Ig) in the brain of MRL/lpr and BXSB mice and compare that to control strains of MRL/mp and C57BL/6 mice. There was a dramatic increase in fluorescence in the brains of MRL/lpr and BXSB at 4 months of age. There was little or no Ig detected in the brains of control mice. This increase in presence of Ig in the autoimmune mouse brain was paralleled by an increase in the serum titers of BRAA and anti-DNA autoantibodies as determined by ELISA. These studies provide another link between the existence of brain-reactive autoantibodies and altered CNS functioning.

The immune system can affect learning: chronic immune complex disease in a rat model

Evidence is presented that the immune system can affect central nervous system functioning, leading to changes in learning. Immune complex disease is induced in rats and their behavior tested using a Lashley maze. Significant differences in behavior were found between the animals with high disease activity and those with low disease activity and the non-disease controls. These changes were not due to uremia and are most likely due to the immune response. There is some evidence immune complex deposits in the choroid plexus may play some role, but not the sole or major role in the behavioral changes. This provides a model by which immunologic processes can cause neuropsychiatric manifestations in autoimmune diseases like lupus, as well as showing that immune processes can affect behavioral functioning.

Learning in year-old female autoimmune BXSB mice

BXSB/ MpJ-Yaa and NZB/BINJ mice have been used as animal models for both developmental learning disability and systemic autoimmune disease. Approximately 40-60% of these animals show ectopic clusters of neurons in Layer I of cortex similar to those found in postmortem analyses of human dyslexics, and all exhibit an autoimmune condition similar to systemic lupus erythematosus (SLE) in humans. The expression of immune disease in the BXSB strain, unlike in humans, is more severe in males than females. Most previous studies have examined the behavioral sequelae of neocortical ectopias at a relatively young age, when the BXSB females (unlike the male BXSB and female and male NZBs) are not yet showing high titers of autoantibodies associated with their lupus-like form of autoimmune disease. This study examined the behavior of BXSB females at an age subsequent to autoimmune disease onset. When contrasted with younger animals, year-old BXSB females showed good learning behavior, with no differences in Lashley maze learning and remarkably good performance in a visual discrimination learning task. These results are consistent with other data which indicate that many types of learning behavior are apparently unperturbed by systemic autoimmune disease. Results also showed significant interactions between a measure of lateral paw preference and the presence or absence of ectopias in Lashley maze learning. Animals without ectopias that exhibited a right lateral paw preference showed the greatest number of errors on a number of test measures. These findings support previous results indicating that behavioral effects associated with ectopias may vary based upon the behavioral laterality of affected animals.

Brain-reactive antibodies and behavior of autoimmune MRL-lpr mice

The hypothesis that brain-reactive autoantibodies (BRA) impair behavior was examined in MRL-lpr mice, which develop spontaneous autoimmune disease. Circulating BRA were measured as in vitro serum reactivity to Neuro-2A neuroblastoma cell line, and behavioral competence was assessed in activity monitors, open field, beam walking, and Morris water maze task. Mice with BRA in serum (BRA positive) exhibited slower spontaneous locomotion in a novel environment, shorter grooming episodes, and less exploration of the open field centre when compared to age-matched 7-11-week-old BRA-negative cagemates. Moreover, when initially exposed to the large swimming pool, BRA-positive mice showed increased swimming along the wall, but had no difficulty in learning the water maze task or in traversing a narrow beam. Brain-reactive autoantibodies titre and behavioral measures were not correlated, suggesting that the concentration of serum BRA is not reflective of the magnitude of behavioral impairment. Nevertheless, the present study suggests that the presence of circulating BRA is associated with impaired exploration and/or enhanced emotional reactivity in MRL-lpr mice. It also supports the hypothesis of a pathogenic role of BRA in various mental disorders.

A monoclonal thymocytotoxic autoantibody from autoimmune-disease-prone New Zealand black mouse recognizes beta-tubulin in neural tissue

On the basis of our previous report that a thymocytotoxic monoclonal autoantibody (NTA260) derived from a New Zealand Black mouse reacts with brain tissues as well as lymphoid cells, the neuronal antigen reacting with this antithymocyte antibody was characterized in the present experiment. Double staining of cultured brain cells with NTA260 and anti-tubulin antibody revealed that both staining patterns closely resembled each other. NTA260 reacted with purified tubulin molecules on Western blotting. Two-dimensional gel electrophoresis of the whole lysate of embryonic mouse brain revealed that NTA260 stained the spot corresponding to that of beta-tubulin but not that of alpha-tubulin. These results suggest that beta-tubulin is a prominent neuronal antigen recognized by NTA260.

Spatial learning during the course of autoimmune disease in MRL mice

The present study examines whether autoimmune MRL-lpr mice develop impairments in learning and memory that correlate with changing severity of lupus-like disease. MRL-lpr mice (n = 20) were tested in the Morris water-maze at 12, 14, 16 and 18 weeks of age. Age-matched controls were congenic MRL +/+ mice (n = 20) that develop the disease much later. Immune status was assessed by the presence of anti-nuclear antibodies (ANA), brain-reactive antibodies, proteinuria, and haematocrit. Learning rates and memory retention did not differ between the substrains, and did not correlate or deteriorate with advancing age and autoimmunity. However, the baseline performance level in autoimmune MRL-lpr mice was shifted, as evidenced by a consistently longer task-solving latencies. Thigmotaxic swimming (along the pool wall) was pronounced in the MRL-lpr group, and was associated with the observed difference in performance. The present study does not support the notion that learning/memory abilities of autoimmune MRL-lpr mice are impaired per se, but may support the hypothesis that the rapid progress of humoral autoimmunity affects the emotionality of lupus-prone mice.

Serum autoantibodies in patients with Alzheimer's disease and vascular dementia and in nondemented control subjects

BACKGROUND AND PURPOSE

In this study we sought to evaluate the clinical significance of serum autoantibodies to dementing processes.

METHODS

We assessed 40 age-matched subjects: 10 patients with probable Alzheimer's disease, 10 with possible Alzheimer's disease with cerebrovascular disease, 10 with vascular dementia, and 10 nondemented control subjects. Serum from each subject was tested for the presence of antithyroglobulin antibody, thyroid antimicrosomal antibody, gastric anti-parietal cell antibody, anti-smooth muscle antibody, antinuclear antibody, rheumatoid factor, antineuronal antibody, and anticardiolipin antibody. In addition, we investigated the sera of these patients for the presence of an antivascular antibody directed against the vascular basement membrane proteoglycan antigen and for circulating immune complexes.

RESULTS

Autoantibodies were present in 100% of the patients with possible Alzheimer's disease with cerebrovascular disease, 80% of those with vascular dementia, 40% of those with probable Alzheimer's disease, and 30% of the nondemented control subjects. The highest number of autoantibodies was observed in patients with vascular dementia and possible Alzheimer's disease with cerebrovascular disease. Antinuclear antibody was present in 60% of vascular dementia patients and antineuronal antibody in 50% of these patients. However, no individual autoantibody could differentiate Alzheimer's disease from cerebrovascular disorders. Immune complexes were detected in the serum of 20-30% of each patient group. Neither the patient nor the control sera was found to contain antiendothelial antibody.

CONCLUSIONS

Despite the relatively small number of individuals examined in each category, the elevated number of autoantibodies associated with possible Alzheimer's disease with cerebrovascular disease and vascular dementia indicates a possible link between the presence of autoantibodies and cerebrovascular disorders in dementia.

Brain specific autoantibodies in murine models of systemic lupus erythematosus

Autoantibodies which bind to integral membrane proteins of brain were tested for their ability to bind to cross-reactive antigens on non-neural tissue. Both brain specific autoantibodies and antibodies which bind to cross-reactive antigens were found. There were two types of brain reactive autoantibodies which could not be adsorbed by non-neural tissue. One type was adsorbable by crude cell membrane preparations of brain. The second type was reactive against integral membrane proteins of brain, but not adsorbable by any of the crude membrane preparations tested. Autoantibodies of the first type reacted against integral membrane proteins with apparent molecular weights of 75, 70, 62, 50, 27, 24 and 20 kDa, as determined by gel electrophoresis and immunoblotting. As in previous studies, a diversity of brain reactive autoantibodies were found. The greatest numbers and strongest banding patterns were seen in the autoimmune strains of mice. The non-autoimmune strain displayed these autoantibodies at much lower levels. These results are the first to find brain specific autoantibodies, from autoimmune mice, against integral brain membrane antigens. The data support the idea that there is a sub-population of brain reactive autoantibodies which are involved in the pathogenesis of neuropsychiatric manifestations in immunologic disorders, particularly systemic lupus erythematosus.

Animal models of age-related dementia: neurobehavioral dysfunctions in autoimmune mice

The development of strategies for treatment of Alzheimer's disease and other age-associated dementias is an important goal of research in the neurosciences. It is suggested that advances in understanding of the etiology of those disorders would provide the most obvious avenues to development of preventative treatments. Research findings from both clinical investigations and studies of animal models are presented which suggest a neuroimmunologic component in age-associated dementia. Clinical studies suggest an association between dementia and brain-reactive autoantibodies in subsets of patients with Alzheimer's disease. Studies of mice suggest that: 1) when compared with normal genotypes, mutant mice with accelerated autoimmunity show learning and memory impairments at earlier chronological ages; 2) the learning and memory deficits of autoimmune and normal mice are qualitatively similar; 3) the behavioral deficits of normal aged and autoimmune mice are sensitive to similar pharmacologic interventions. Overall, these findings suggest that intervention strategies targeting the immune system might be useful in the treatment or prevention of aging-associated dementia. Autoimmune mice would be useful as models for the development and testing of such immune-based interventions.

Autoimmunity and age-associated cognitive decline

It is suggested that the immune system may play a role in the etiology of age-associated cognitive decline and/or Alzheimer's disease. The relationship between brain-reactive antibodies (BRA) and age-associated cognitive dysfunction is reviewed and discussed. A parallel relationship between BRA increases with age and decline of avoidance learning capacity is described in mouse models. Transfer of immunity from old to young mice was found to accelerate both age-related formation of brain-reactive antibodies and age-related decline of avoidance learning capacity. Short-lived mouse genotypes with accelerated autoimmunity were found to show accelerated age-related declines in their ability to acquire an avoidance response when compared with nonautoimmune mice. Overall, these findings suggest that the immune system could be an important target for development of intervention strategies aimed at extending the intellectually competent period of life. Mice in which autoimmunity is accelerated may be useful as models for the development of such interventions.