Axon–Myelin Interactions During a Viral Infection of the Central Nervous System

Axon–Myelin Interactions During a Viral Infection of the Central Nervous System

Opinion Axon–Myelin Interactions during a Viral Infection of the Central Nervous System Michel Brahic1*, Jean-Pierre Roussarie2 1 Department of Microbiology-Immunology, Stanford University School of Medicine, Stanford, California, United States of America, 2 Molecular and Cellular Neuroscience, The Rockefeller University, New York, New York, United States of America Theiler’s virus offers a remarkable tions in the Mbp and Plp1 genes, which oligodendrocytes is normal in these mu- example of a pathogen that navigates the encode two major myelin components, tants, supporting our hypothesis [7]. various cells of the organism to evade myelin basic protein (MBP) and proteolipid Importantly, by performing these experi- immune responses and establish a persis- protein (PLP), respectively. Shiverer mice ments with Wlds mice, a mutant whose tent infection. Here, we discuss the make very little myelin, whereas in rump- axons are strikingly resistant to degenera- transition from neuron to myelin and shaker mice, the amount of myelin is tion, we showed that the virus was able to oligodendrocyte infection, a step that is reduced and the periodicity of myelin traffic from axon to myelin in the absence crucial for the persistence of this virus in leaflets is slightly altered [5,6]. Theiler’s of axonal degeneration [8]. the central nervous system (CNS). virus infects neurons and is transported in Enveloped viruses with their lipid bilay- CNS myelin is an extension of the axons in these mutant mice just as in wild- er and glycoproteins can exit the cyto- cytoplasmic membrane of oligodendro- type mice. However, it disappears from the plasm by budding from the plasma cytes wrapped numerous times around CNS of the mutants after 2–3 weeks. membrane and entering a new host cell axons. An oligodendrocyte sends many Various experiments showed that this by fusion. Classically non-enveloped virus- such extensions and can myelinate up to clearance was not immune mediated and es such as picornaviruses exit by causing 50 different axons. Myelinated axon that shiverer oligodendrocytes grown in cell lysis. How can Theiler’s virus cross segments are separated by short unmy- culture were permissive to viral replication from intact axons into the surrounding elinated regions called nodes of Ranvier. [7]. These results suggested that myelin myelin? Before presenting hypotheses it is Cytoplasm is totally extruded from myelin might play a crucial role in viral persis- necessary to review briefly the salient except in areas where it forms channels tence. What could that role be? aspects of axon–myelin interactions. that are in continuity with the oligoden- We postulated that viruses transported drocyte cell body. These channels form in axons infect the surrounding myelin and Axon–Myelin Interactions the so-called ad-axonal inner loop and the spread to oligodendrocyte cell bodies, then paranodal loops at the level of the nodes of to macrophages, where infection persists. Mice and humans with myelin muta- Ranvier. Inner and paranodal loops are in Accordingly, myelin would be an obliga- tions have provided most of our under- close contact with the axon membrane tory passage that would be prevented by standing of axon–myelin interactions. PLP (Figure 1). (For a review of myelin and the shiverer and rumpshaker mutations. We is a major myelin protein. Plp1nul mice node organization, see [1].) tested this hypothesis by introducing virus have myelinated axons, surprisingly, and in the vitreous chamber of the eye. The mice are normal at birth [9]. However, in Theiler’s Virus virus infected retinal ganglion cells and late life, organelles accumulate in the axons at the level of the nodes of Ranvier Theiler’s virus, a mouse picornavirus, is was transported anterogradely in the and there is axonal swelling and degener- responsible for a peculiar neurological axons of the optic nerve. Infected oligo- ation [10]. The Plp1 gene is on the X disease. It infects neurons and spreads by dendrocytes were observed in the nerve of chromosome. Because in females one of fast axonal transport for approximately 2 wild-type mice as early as 3 days post- the X chromosomes is inactivated, the weeks following intracerebral inoculation. inoculation. The only possible source of oligodendrocytes of a female heterozygous Depending on their genetic background, infection for these oligodendrocytes is the for a Plp1 mutation form a mosaic of wild- mice may clear this infection or remain axons of retinal ganglion cells. In contrast, type and mutant cells. In these mice, the persistently infected. The virus is no longer the infection of oligodendrocyte cell bodies same axon can be myelinated alternatively in neurons during persistent infection. was considerably impaired in shiverer and Instead, it is found in white matter, in rumpshaker mice, although the number of by wild-type and by mutant oligodendro- oligodendrocytes, in the cytoplasmic chan- nels of myelin, and in macrophages. The Citation: Brahic M, Roussarie J-P (2009) Axon–Myelin Interactions during a Viral Infection of the Central infection is focal and results in inflamma- Nervous System. PLoS Pathog 5(9): e1000519. doi:10.1371/journal.ppat.1000519 tion, primary demyelination, and some Editor: Glenn F. Rall, The Fox Chase Cancer Center, United States of America axonal damage. For more detailed reviews Published September 25, 2009 of Theiler’s virus and its pathogenesis, the Copyright: ß 2009 Brahic, Roussarie. This is an open-access article distributed under the terms of the reader is referred to [2,3]. Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any In the course of studying this persistent medium, provided the original author and source are credited. infection, our laboratory observed that two Funding: We acknowledge the financial support of NIH (grant 5R01AI65972-2) and NMSS (grant RG3924). The myelin mutants, the shiverer and rumpshaker funders had no role in study design, data collection and analysis, decision to publish, or preparation of the mice, were totally resistant to persistent manuscript. infection, whereas the parental strains were Competing Interests: The authors have declared that no competing interests exist. susceptible [4]. These strains bear muta- * E-mail: [email protected] PLoS Pathogens | www.plospathogens.org 1 September 2009 | Volume 5 | Issue 9 | e1000519 Figure 1. Diagrammatic view of CNS myelin. Myelin is an extension of the plasma membrane of the oligodendrocyte. Compact myelin is devoid of cytoplasm. Cytoplasmic channels, which are continuous with the oligodendrocyte cytoplasm, form the so-called inner and outer myelin loops as well as the longitudinal incisures. doi:10.1371/journal.ppat.1000519.g001 cytes. Remarkably, axonal swelling is [12–14]. Cnp12/2 mice have normal In contrast to these mutant pheno- observed only in axon segments myelinat- myelin. However, with age, they develop a types, and others which we did not ed by mutant oligodendrocytes [11]. neurological deficit due to abnormal distri- discuss, there is no axonal degeneration These elegant experiments show that a bution of ion channels in the nodes of in the shiverer mouse even though the myelin protein, PLP, has a direct role in Ranvier [15]. The CNPase mutation nicely amount of myelin is severely restricted, maintaining the integrity of the axon. segregates two functions of the oligodendro- indicating that myelin supports the axon In the CNS, 29,39 cyclic nucleotide 39- cyte: the production of myelin, which is through specific signaling and not just by phosphodiesterase (CNPase) is found only in unaffected, and the support of the axon, the physical presence of an electric oligodendrocyte cell bodies and in myelin which requires the presence of the enzyme. insulator [10]. PLoS Pathogens | www.plospathogens.org 2 September 2009 | Volume 5 | Issue 9 | e1000519 Figure 2. Hypothetical mechanisms for the traffic of Theiler’s virus from the axon into the surrounding myelin, in the absence of axonal degeneration. Viral particles are shown in blue, replication complexes in red. Pathway 1: Viral particles (blue) are engulfed in double- membrane autophagosomes. Following fusion of the autophagosome with a lysosome and digestion of its inner membrane, the particles, which are resistant to low pH and to proteases, are in a single-membrane vesicle that fuses with the axolemma, thereby releasing the virus in the periaxonal space. Entry in the myelin requires the presence of a viral receptor. Pathway 2: The outer membrane of the double-membrane vesicle fuses with the axolemma. The single-membrane vesicle that is released from the axon fuses with the membrane of the myelin inner loop and delivers viral particles into the myelin. This is an unlikely pathway since the viral RNA cannot be released from the virus particle without interaction with a receptor. Pathway 3: A pathway similar to pathway 2, but in this case replication complexes (red), instead of viral particles, are transferred from the axon into the myelin where replication can resume. Pathway 4: Engulfment of replication complexes may take place in the axon, where autophagy is known to be prominent. Pathway 5: Viral particles or replication complexes are transferred from the axon into the myelin by a hypothetical mechanism analogous to the axon clearing mechanism described in peripheral nerves [21]. A double membrane (axolemma plus myelin) engulfs axonal material, including viral products. Two fusion events, (axolemma/axolemma) and (myelin/myelin),

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