THE PATHOGENESIS OF HERPES VIRUS ENCEPHALITIS: I. VIRUS PATHWAYS TO THE NERVOUS SYSTEM OF SUCKLING MICE DEMONSTRATED BY FLUORESCENT ANTIBODY STAINING

doi:10.1084/jem.119.2.343

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THE PATHOGENESIS OF HERPES VIRUS ENCEPHALITIS : I. VIRUS PATHWAYS TO THE NERVOUS SYSTEM OF SUCKLING MICE DEMONSTRATED BY FLUORESCENT ANTIBODY STAINING

Richard T. Johnson M.D.¹

¹ From the Department of Microbiology, John Curtin School of Medical Research, Australian National University, Canberra, Australia

The pathogenesis of herpes simplex virus encephalitis and myelitiswas studied in suckling mice using routine titration proceduresand fluorescent antibody staining for the identification ofinfected cells. After intracerebral inoculation virus was shownto disperse rapidly in the cerebrospinal fluid (CSF), multiplyin meninges and ependyma, and then invade the underlying parenchymainfecting both neurons and glia.

Following extraneural inoculationvirus gained access to the central nervous system (CNS) by bothhematogenous and neural pathways. After intraperitoneal andintranasal inoculation virus was found to multiply in visceraand produce viremia; foci of CNS infection then developed aroundsmall cerebral vessels.

After subcutaneous and intranasal inoculationneural spread of virus was demonstrated along correspondingperipheral and cranial nerves. This spread resulted from thecentripetal infection of endoneural cells (Schwann cells andfibroblasts). Antigen was not found in axons even after infectionof the corresponding ganglion cell perikaryon. Subsequent spreadwithin the CNS was unrelated to neural tracts, and there wasno evidence of axonal spread of virus in the host-virus systemstudied.

These findings are discussed in relation to previousand current theories of the viral "blood-brain barrier" andneural pathways of infection.

Submitted on October 31, 1963

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