Astrocyte-associated axonal damage in pre-onset stages of experimental autoimmune encephalomyelitis.

Recent studies of axon-glia and glia-glia communication have emphasized interactivity and interdependence between central nervous system (CNS) components. Concurrently, data from imaging, biochemical, and morphological studies have changed the view of multiple sclerosis (MS) from a neuroinflammatory condition with primary demyelination to one in which cumulative axonal damage drives progression. We therefore studied axonal damage in the context of inflammation and glial responses, from the pre-clinical to onset stage of murine experimental autoimmune encephalomyelitis (EAE), an established MS model. We report three major findings: (1) the first evidence of axonal injury before significant T-cell entry into the parenchyma, (3) coincidence of the earliest manifestation of axonal damage and astrocytic responses, and (3) an association between accumulation of axonal and astrocytic changes and specific forms of MS. These data demonstrate the relationship between the initiation of axonal injury and early inflammation. Significantly, we show that, in common with a growing number of neurodegenerative conditions, the pathology of murine EAE is characterized by early active contribution from astrocytes. This marks a change in the understanding of the role of astrocytes in MS pathogenesis and has important implications for the development of neuroprotective strategies.

Early glial responses in murine models of multiple sclerosis.

Investigations of functional interactions among axons and glia over the last decade have revealed the extent and complexity of glial-neuronal and glial-glial communication during development, adult function and recovery from injury. These data have profound implications for the understanding of central nervous system (CNS) disorders, which until recently, have been classified as either neuronal or glial diseases. Re-evaluation of the pathological processes in a number of conditions has clearly shown involvement of both neurons and glia in early pathology. In multiple sclerosis (MS), the myelin sheath has traditionally been regarded as the primary target. However, recent evidence has clearly demonstrated axonal damage in new lesions. We have addressed the question of the role of axonal pathology in early MS by using well-characterized murine models for the relapsing-remitting (RR) or the primary progressive (PP) forms of the disease. We performed a histopathological survey of the CNS, following induction of the disease, to determine the timing of appearance, as well as the development of lesions. Then we analysed the relationship between inflammation, demyelination and axonal damage together with responses from astrocytes and microglia in each model from the earliest evidence of inflammation. We found that axonal damage begins well ahead of the appearance of motor symptoms. Pathology appears to be more closely related to the degree of inflammation than to demyelination. We also show that early astrocyte responses and the degree of axonal loss are markedly different in the two models and relate to the severity of pathology. These data support the now widely accepted hypothesis that axonal damage begins early in the disease process, but also suggest modulation of axonal loss and disease progression by the astrocytic response.