Faculty Bibliography

This study explores subtle defects in the myelin of proteolipid protein (PLP)-null mice that could potentially underlie the functional losses and axon damage known to occur in this mutant and in myelin diseases including multiple sclerosis. We have compared PLP-null central nervous system (CNS) myelin with normal myelin using ultrastructural methods designed to emphasize fine differences. In the PLP-null CNS, axons large enough to be myelinated often lack myelin entirely or are surrounded by abnormally thin sheaths. Short stretches of cytoplasm persist in many myelin lamellae. Most strikingly, compaction is incomplete in this mutant as shown by the widespread presence of patent interlamellar spaces of variable width that can be labeled with ferricyanide, acting as an aqueous extracellular tracer. In thinly myelinated fibers, interlamellar spaces are filled across the full width of the sheaths. In thick myelin sheaths, they appear filled irregularly but diffusely. These patent spaces constitute a spiral pathway through which ions and other extracellular agents may penetrate gradually, possibly contributing to the axon damage known to occur in this mutant, especially in thinly myelinated fibers, where the spiral path length is shortest and most consistently labeled. We show also that the 'radial component' of myelin is distorted in the mutant ('diagonal component'), extending across the sheaths at 45 degrees instead of 90 degrees. These observations indicate a direct or indirect role for PLP in maintaining myelin compaction along the external surfaces of the lamellae and to a limited extent, along the cytoplasmic surfaces as well and also in maintaining the normal alignment of the radial component

Galactocerebroside (GalC) and sulfatide are abundant myelin lipids. In mice incapable of synthesizing these lipids, myelin is thin and regionally unstable and exhibits several subtle structural abnormalities. Although galactolipid-null mice have been beneficial in the analysis of galactolipid function, it has not been possible to differentiate between the functions of GalC and sulfatide with these mice alone. In the present work, we have analyzed a murine model that forms normal levels of GalC but is incapable of synthesizing sulfatide. By comparing a plethora of morphological features between the galactolipid-null and the sulfatide-null mice, we have begun to differentiate between the specific functions of these closely related lipids. The most striking difference between these two mutants is the reduction of myelin developmental abnormalities (e.g., redundant and uncompacted myelin sheaths) in young adult sulfatide-null mice as compared with the galactolipid-null animals. Although sulfatide appears to play a limited role in myelin development, this lipid is essential for myelin maintenance, as the prevalence of redundant, uncompacted, and degenerating myelin sheaths as well as deteriorating nodal/paranodal structure is increased significantly in aged sulfatide-null mice as compared with littermate wildtype mice. Finally, we show that the role played by sulfatide in CNS maintenance is not limited to the myelin sheath, as axonal caliber and circularity are normal in young adult mutant mice but are significantly altered in aged sulfatide-null animals.

The signals that determine whether axons are ensheathed or myelinated by Schwann cells have long been elusive. We now report that threshold levels of neuregulin-1 (NRG1) type III on axons determine their ensheathment fate. Ensheathed axons express low levels whereas myelinated fibers express high levels of NRG1 type III. Sensory neurons from NRG1 type III deficient mice are poorly ensheathed and fail to myelinate; lentiviral-mediated expression of NRG1 type III rescues these defects. Expression also converts the normally unmyelinated axons of sympathetic neurons to myelination. Nerve fibers of mice haploinsufficient for NRG1 type III are disproportionately unmyelinated, aberrantly ensheathed, and hypomyelinated, with reduced conduction velocities. Type III is the sole NRG1 isoform retained at the axon surface and activates PI 3-kinase, which is required for Schwann cell myelination. These results indicate that levels of NRG1 type III, independent of axon diameter, provide a key instructive signal that determines the ensheathment fate of axons

Neuropathy target esterase (NTE) is a neuronal membrane protein originally identified for its property to be modified by organo-phosphates (OPs), which in humans cause neuropathy characterized by axonal degeneration. Drosophila mutants for the homolog gene of NTE, swisscheese (sws), indicated a possible involvement of sws in the regulation of axon-glial cell interaction during glial wrapping. However, the role of NTE/sws in mammalian brain pathophysiology remains unknown. To investigate NTE function in vivo, we used the cre/loxP site-specific recombination strategy to generate mice with a specific deletion of NTE in neuronal tissues. Here we show that loss of NTE leads to prominent neuronal pathology in the hippocampus and thalamus and also defects in the cerebellum. Absence of NTE resulted in disruption of the endoplasmic reticulum, vacuolation of nerve cell bodies, and abnormal reticular aggregates. Thus, these results identify a physiological role for NTE in the nervous system and indicate that a loss-of-function mechanism may contribute to neurodegenerative diseases characterized by vacuolation and neuronal loss

The node of Ranvier is a distinct domain of myelinated axons that is highly enriched in sodium channels and is critical for impulse propagation. During development, the channel subtypes expressed at the node undergo a transition from Nav1.2 to Nav1.6. Specialized junctions that form between the paranodal glial membranes and axon flank the nodes and are candidates to regulate their maturation and delineate their boundaries. To investigate these roles, we characterized node development in mice deficient in contactin-associated protein (Caspr), an integral junctional component. Paranodes in these mice lack transverse bands, a hallmark of the mature junction, and exhibit progressive disruption of axon-paranodal loop interactions in the CNS. Caspr mutant mice display significant abnormalities at central nodes; components of the nodes progressively disperse along axons, and many nodes fail to mature properly, persistently expressing Nav1.2 rather than Nav1.6. In contrast, PNS nodes are only modestly longer and, although maturation is delayed, eventually all express Nav1.6. Potassium channels are aberrantly clustered in the paranodes; these clusters are lost over time in the CNS, whereas they persist in the PNS. These findings indicate that interactions of the paranodal loops with the axon promote the transition in sodium channel subtypes at CNS nodes and provide a lateral diffusion barrier that, even in the absence of transverse bands, maintains a high concentration of components at the node and the integrity of voltage-gated channel domains

Purkinje cells generate simultaneous complex spikes as a result of olivocerebellar activity. This synchronization (to within 1 ms) is thought to result from electrotonic coupling of inferior olivary neurons. However, the distance from the inferior olive (IO) varies across the cerebellar cortex. Thus signals generated simultaneously at the IO should arrive asynchronously across the cerebellar cortex, unless the length differences are compensated for. Previously, it was shown that the conduction time from the IO to the cerebellar cortex remains nearly constant at approximately 4 ms in the rat, implying the existence of such compensatory mechanisms. Here, we examined the role of myelination in generating a constant olivocerebellar conduction time by investigating the latency of complex spikes evoked by IO stimulation during development in normal rats and myelin-deficient mutants. In normal rats, myelination not only reduced overall olivocerebellar conduction time, but also disproportionately reduced the conduction time to vermal lobules, which had the longest response latencies prior to myelination. The net result was a nearly uniform conduction time. In contrast, in myelin-deficient rats, conduction time differences to different parts of the cerebellum remained during the same developmental period. Thus myelination is the primary factor in generating a uniform olivocerebellar conduction time. To test the importance of a uniform conduction time for generating synchronous complex spike activity, multiple electrode recordings were obtained from normal and myelin-deficient rats. Average synchrony levels were higher in normal rats than mutants. Thus the uniform conduction time achieved through myelination of olivocerebellar fibers appears to be essential for the normal expression of complex spike synchrony

We showed previously that spinal cord implants of hybridoma cells (O1) that secrete an IgM antigalactocerebroside cause focal multiple-sclerosis-like plaques of demyelination followed by remyelination to form 'shadow plaques' (Rosenbluth et al., 1999). The antibody in that case was directed against a glycolipid present in mature oligodendrocytes and myelin but not in precursor cells. We now report the effects of implanting a different hybridoma (O4) that secretes IgM antibodies directed against sulfatide, a constituent not only of mature myelin and oligodendrocytes but also of late precursor cells, in order to determine whether this hybridoma too would generate focal demyelination and would, in addition, block remyelination. Our results show that focal plaques of demyelination indeed appear after O4 implantation, and that remyelination does occur, but only in cases where the hybridoma cells have degenerated, probably through host rejection. The occurrence of remyelination suggests that oligodendrocyte precursor cells are capable of migrating in rapidly from adjacent areas or that early precursors, not yet expressing sulfatide, remain undamaged within the lesions. In cases where intact hybridoma cells persist at lesion sites, remyelination does not occur. Failure of remyelination in this model thus appears to result from the continuing presence of antimyelin antibodies rather than from depletion of oligodendrocyte precursors

Our understanding of the role that axoglial interactions play in node of Ranvier formation and maintenance remains incomplete. Previous studies of CNS myelinated fibers of CGT-null mice showed abnormalities in the arrangement of paranodal myelin loops and absence of a conspicuous component of the paranodal junction, the ridge-like intercellular transverse bands. Axolemmal sodium channel domains were largely preserved at nodes of Ranvier but displayed some abnormalities in form. Using a combination of freeze-fracture and immunocytochemical methods, we have found additional evidence documenting abnormalities in the size, shape, and location of axolemmal sodium channel clusters in CGT-null mice as well as evidence that these nodal abnormalities are complementary to the organization of paranodal myelin loops, despite the absence of transverse bands. We conclude that the differentiated form of the nodal axolemma and the distribution of axolemmal sodium channels depend on the conformation of paranodal axoglial contacts but not on the presence of transverse bands at the sites of contact