Differential expression of tumor necrosis factor in primary glial cell cultures infected with demyelinating and non-demyelinating MHVs

Magnetic cell sorting: a fast and effective method of concurrent isolation of high purity viable astrocytes and microglia from neonatal mouse brain tissue

Pathologically altered functions of astrocytes and microglia play a pivotal role in diseases of the central nervous system (CNS). The complexity of the CNS makes it difficult to determine the function of individual glial cells in vivo. Insight into the role of individual glial cell function lies in their successful isolation and purification to maintain phenotype and realistically mimic in vivo conditions. To facilitate such experiments we have designed a single-step glial cell isolation procedure based on antigen antibody-mediated magnetic cell sorting whereby individual glial cell populations are enriched by positive selection or by depletion from the same mixed glial culture. We removed oligodendroglial contamination from mixed glial culture by antibody-mediated cytolysis, and applied the remaining cells to CD11b MicroBeads in a magnetic field. From the CD11b column we isolated microglia by positive selection and astrocytes by depleting microglia. Microglia isolated by positive selection were >99% pure and free from astrocytes, while astrocytes collected by negative selection were 95-97% pure and completely free from microglia. This modified technique is simple, fast, versatile, convenient and reliable for the isolation of individual glial cell populations from single mixed glial cultures based on cell-specific antigen-antibody interaction. Subsequently, these cultures can be applied to study the function of individual glial cells at the morphological and molecular level during normal and pathological condition.

Coronavirus neurovirulence correlates with the ability of the virus to induce proinflammatory cytokine signals from astrocytes and microglia

The molecular and cellular basis of coronavirus neurovirulence is poorly understood. Since neurovirulence may be determined at the early stages of infection of the central nervous system (CNS), we hypothesize that it may depend on the ability of the virus to induce proinflammatory signals from brain cells for the recruitment of blood-derived inflammatory cells. To test this hypothesis, we studied the interaction between coronaviruses (mouse hepatitis virus) of different neurovirulences with primary cell cultures of brain immune cells (astrocytes and microglia) and mouse tissues. We found that the level of neurovirulence of the virus correlates with its differential ability to induce proinflammatory cytokines (interleukin 12 [IL-12] p40, tumor necrosis factor alpha, IL-6, IL-15, and IL-1beta) in astrocytes and microglia and in mouse brains and spinal cords. These findings suggest that coronavirus neurovirulence may depend on a novel discriminatory ability of astrocytes and microglia to induce a proinflammatory response in the CNS.