Deregulation of signalling in genetic conditions affecting the lysosomal metabolism of cholesterol and galactosyl-sphingolipids.

The role of lipids in neuroglial function is gaining momentum in part due to a better understanding of how many lipid species contribute to key cellular signalling pathways at the membrane level. The description of lipid rafts as membrane domains composed by defined classes of lipids such as cholesterol and sphingolipids has greatly helped in our understanding of how cellular signalling can be regulated and compartmentalized in neurons and glial cells. Genetic conditions affecting the metabolism of these lipids greatly impact on how some of these signalling pathways work, providing a context to understand the biological function of the lipid. Expectedly, abnormal metabolism of several lipids such as cholesterol and galactosyl-sphingolipids observed in several metabolic conditions involving lysosomal dysfunction are often accompanied by neuronal and myelin dysfunction. This review will discuss the role of lysosomal biology in the context of deficiencies in the metabolism of cholesterol and galactosyl-sphingolipids and their impact on neural function in three genetic disorders: Niemann-Pick type C, Metachromatic leukodystrophy and Krabbe's disease.

Persistence of psychosine in brain lipid rafts is a limiting factor in the therapeutic recovery of a mouse model for Krabbe disease.

Sphingolipids are intrinsic components of membrane lipid rafts. The abnormal accumulation of these molecules may introduce architectural and functional changes in these domains, leading to cellular dysfunction. Galactosylsphingosine (psychosine) is a pathogenic lipid raft-associated molecule whose accumulation leads to brain deterioration and irreversible neurological handicap in the incurable leukodystrophy Krabbe disease (KD). The relevance of clearing excessive levels of pathogenic psychosine from lipid rafts in therapy for KD has not been investigated. The work presented here demonstrates that psychosine inhibits raft-mediated endocytosis in neural cells. In addition, although in vitro enzyme reconstitution is sufficient for the reversal of related endocytic defects in affected neural cells, traditional in vivo enzyme therapies in the mouse model of KD appear to be insufficient for complete removal of pathogenic levels of raft-associated psychosine. This work describes a mechanism that may contribute to limiting the in vivo efficacy of traditional therapies for KD.

Combined hematopoietic and lentiviral gene-transfer therapies in newborn Twitcher mice reveal contemporaneous neurodegeneration and demyelination in Krabbe disease.

This study characterized the therapeutic benefits of combining hematogenous cell replacement with lentiviral-mediated gene transfer of galactosylceramidase (GALC) in Twitcher mice, a bona fide model for Krabbe disease. Bone marrow cells and GALC-lentiviral vectors were administered intravenously without any preconditioning to newborn Twitcher pups before postnatal day 2. Treated Twitchers survived up to 4 months of age. GALC activity remained less than 5% of normal values in the nervous system for the first 2 months after treatment and reached approximately 30% in long-term-surviving mice. Long-term reconstitution of GALC activity in the nervous system was provided primarily by infiltrating macrophages and to a lesser extent by direct lentiviral transduction of neural cells. Treated Twitchers had significant preservation of myelin, with a G-ratio (ratio of the axon diameter to the diameter of the myelinated fiber) in sciatic nerve myelin of 0.75 +/- 0.08 compared with 0.85 +/- 0.10 in untreated mutants. Although treated mutants had improved locomotor activities during their long-term survival, they died with symptoms of progressive neurological degeneration, indistinguishable from those seen in untreated Twitchers. Examination of long-lived Twitchers showed that treated mutants were not protected from developing degeneration of axons throughout the neuroaxis. These results suggest that GALC deficiency not only affects myelinating glia but also leads to neuronal dysfunction. The contemporaneous neuropathology might help to explain the limited efficacy of current gene and cell therapies.

Cerebellar neurons and glial cells are transducible by lentiviral vectors without decrease of cerebellar functions.

Due to the profuse connections of the cerebellum to the rest of the central nervous system, cerebellar dysfunction impacts tremendously on movement coordination, maintenance of equilibrium, muscle tone and motor memory. Efficient gene transfer of therapeutic genes to this central nervous system structure would constitute a relevant step ahead the design of treatments to ameliorate cerebellar dysfunction. Lentiviral vectors (LVs) have been used as efficient vehicles to integrate transgenes into dividing and non-dividing cells, such as postmitotic adult neurons, with minimal toxicity and immune response. This study aimed to use LVs carrying green fluorescent protein (GFP) cDNA for transduction of cerebellar cells in vivo without compromising neurological cerebellar functions. Our results indicate that LVs, injected in the lobulus simplex, transduced different cerebellar neurons including stellate, Purkinje cells, granular neurons and glial cells such as astrocytes, oligodendrocytes, and that this gene transfer approach was not accompanied by cerebellar deficits.

Expression and regulation of golli products of myelin basic protein gene during in vitro development of oligodendrocytes.

The myelin basic protein (MBP) gene produces two families of proteins, the classic MBPs, important for myelination of the CNS, and the golli proteins, whose biological role in oligodendrocytes (OLs) is still unknown. The goals of this work were to study the in vitro pattern of expression of the golli products during OL differentiation and to compare it with that of the classic MBP products of the gene. Mouse primary glial cultures were analyzed at the mRNA and protein levels with an array of techniques. We found that OLs express golli mRNA primarily during intermediate stages of differentiation, which was confirmed by immunocytochemical analysis. Golli expression was low in proliferating OL progenitors as well as in terminally mature OLs. Golli proteins were found associated with the OL cell soma and nuclei and, to a lesser extent, with the cellular processes. We also found that golli proteins are not targeted to myelin in vitro and in vivo, in contrast to the classic MBPs. Finally, we found that golli expression is regulated during OL development and can be manipulated by growth factors such as basic fibroblast growth factor, neurotrophin-3, and retinoic acid.

Classic and soma-restricted proteolipids are targeted to different subcellular compartments in oligodendrocytes.

The myelin proteolipid (PLP) gene is very active in oligodendrocytes (OLs) and generates at least four proteins: the classic PLP and DM20 proteolipids, which are associated with compact myelin and the srPLP and srDM20, which are associated with the cell soma. These proteins are extremely hydrophobic and appear to follow the biosynthetic route used by secretory proteins. In this study, we have analyzed the subcellular distribution of the newly described sr-proteolipids and compared it to that of the classic proteolipids. Immunocytochemical analysis indicates that the sr-proteolipids and classic proteolipids are found in association with the endoplasmic reticulum (ER) and Golgi apparatus of mature OLs in vitro. Whereas the classic proteolipids become associated with the myelin-like sheets elaborated by OLs, the sr-proteolipids are not targeted to the myelin leaflets. The sr-proteolipids were associated with endosomes and with recycling vesicles as determined by double immunocytochemistry with markers such as syntaxin 6 and clathrin. In vivo, immunohistochemical analysis showed a distribution of the sr-proteolipids that was similar to that obtained in vitro, with a total absence of incorporation of sr-proteolipids into compact myelin. This differential subcellular localization is further evidence for a biological role for these products of the PLP/DM20 gene, which is different from that of the classic proteolipids.

Differential sensitivity in the survival of oligodendrocyte cell lines to overexpression of myelin proteolipid protein gene products.

The proteolipid (PLP) gene encodes at least four proteins, including the classic PLP and DM20, which are important components of the myelin sheath, and the recently identified soma-restricted (sr) isoforms, srPLP and srDM20. The classic PLP and DM20 gene products have been implicated in oligodendrocyte survival by overexpression studies in vitro and in vivo. The classic and sr proteolipids are targeted to different cellular compartments in the oligodendrocyte, suggesting different cellular functions. Accordingly, we examined the effects of in vitro overexpression of the sr-PLP/DM20 isoforms on the survival of stably transfected, conditionally immortalized, oligodendroglial cell lines and compared this to overexpression of the classic and the jimpy-mutated proteolipids. The results indicate that overexpression of either normal or jimpy classic PLP/DM20 resulted in a dramatic reduction in the survival of the oligodendrocyte cell lines at the nonpermissive temperature, but not the COS-7 cell line, a cell line expressing the same oncogene constitutively. Survival of the oligodendrocyte cell lines was significantly less affected when either the sr-PLP/DM20 or the dopamine D-2 receptor, another cell membrane protein, was overexpressed in the cell lines. These results suggest that overexpression of the "classic" PLP or DM20 can compromise the survival of oligodendrocytes whether or not they are mutated. Furthermore, they suggest that the internal mechanisms for normal targeting of the PLP/DM20 isoforms of either the "classic" or the "sr" types influence the oligodendrocyte's ability to survive when these proteolipids are overexpressed.

Identification of genes in the oligodendrocyte lineage through the analysis of conditionally immortalized cell lines.

The mouse oligodendrocyte cell lines, N19 and N20.1, were used as sources of potential stage-specific RNA in order to construct a subtraction library enriched in cDNAs expressed early in the oligodendrocyte (OL) lineage. From this library, 23 clones were examined and three were examined in most detail. The mRNAs of the three library clones were preferentially expressed in the N19 (progenitor) compared to the N20.1 (immature) OL line. One of these corresponded to the intermediate filament protein cytokeratin K19, which has not been reported to be expressed in OLs previously. Another was identified as the mouse homolog of T-cadherin, previously reported not to be present in OLs. Antisera raised against a T-cadherin peptide indicated the protein colocalized with the OL lineage markers A(2)B(5), A007, and 01 in mouse primary glial cultures. However, small round cells resembling OL precursors labeled intensely with T-cadherin, but were negative for the other markers, suggesting that this gene might be expressed earlier in the lineage. In early postnatal brain, in addition to the expected neuronal tracts, the T-cadherin antibody labeled small bipolar cells, approximately 8-10 microm in diameter, in white matter tracts. These cells had the morphology of OLs or their precursors and were identified within the cerebellar white matter and the corpus callosum, regions rich in OLs. The third clone, 3g5, was homologous to the P8 clone isolated from rat pancreas. It encoded an 80-amino-acid polypeptide with a protein kinase C domain suggesting a possible role in signal transduction. Antisera to this peptide also colocalized 3g5 with cells expressing A(2)B(5), A007, and 01 in culture and in cells within white matter tracts which had the same morphology as those labeled by T-cadherin in these regions. In addition to these, beta(10) thymosin and mevalonate kinase clones were also isolated from the screen.

Thymocytes express the golli products of the myelin basic protein gene and levels of expression are stage dependent.

The golli products of the myelin basic protein gene have been shown to be expressed in mouse thymus and brain. The full repertoire of thymic cell types expressing golli products has not yet been determined, although immunoreactivity has been found in some macrophages. We have analyzed the cellular expression of golli mRNAs and proteins in the thymus. The results showed that MTS5(+) cortical/MTS10(+) medullary epithelial cells and NLDC145(+) dendritic cells did not express golli, while some macrophages did exhibit strong immunoreactivity. GOLLI: mRNAs were not detected in macrophages by in situ hybridization. Thymocytes expressed significant levels of golli mRNAs and proteins by in situ hybridization and immunohistochemistry. Interestingly, golli immunoreactivity varied with thymocyte stage of differentiation. For example, CD4(-)CD8(-) (double-negative) thymocytes expressed relatively high levels of golli. Upon further differentiation into CD4(-)CD8(-) (double-positive) thymocytes, golli protein expression declined dramatically. When thymocytes developed into CD8(-) or CD4(+) (single-positive) thymocytes, golli protein expression increased again, but it never achieved the levels found in double-negative thymocytes. Thus, the altered levels of expression of golli proteins in developing thymocytes correlated with the transitions from double-negative to double-positive and double-positive to single-positive stages. The lack of significant golli expression in thymic stromal cells may offer an alternative explanation for the mechanism of inefficient negative selection of those autoreactive thymocytes with specificity for myelin basic proteins.

Platelet-derived growth factor and basic fibroblast growth factor regulate cell proliferation and the expression of notch-1 receptor in a new oligodendrocyte cell line.

We generated a new cell line, N38, by conditionally immortalizing mouse oligodendrocytes (OLs) at early stages of maturation. The morphology and marker expression pattern suggest N38 cells are similar to immature OLs. N38 cells were sensitive to changes in serum concentrations, and forcing the cells to differentiate in low serum at 39 degrees C significantly decreased the survival of the cells. Importantly, addition of PDGFaa, bFGF or astrocyte-conditioned medium had protective effects on the cells, by increasing cell proliferation but not cell differentiation. This effect was receptor-mediated. Exposure of N38 cells to differentiating signals such as retinoic acid did not cause further differentiation of the cells. The N38 cell line expresses the vertebrate homolog of the Drosophila notch-1 receptor, a molecule that appears to regulate OL differentiation. Notch-1 receptor was homogeneously distributed in the somas of N38 cells. Incubation of N38 cells with either PDGFaa or bFGF, however, induced a polarized distribution of the receptor in the majority of the cells as well as an upregulation of receptor protein levels. The upregulation of molecules, such the notch-1 receptor, in pathways that control differentiation might be an important mechanism for keeping OL precursors in an undifferentiated state during their exit of the germinal layer and migration in the developing central nervous system. This OL cell line might constitute a suitable model for studies of regulatory mechanisms at this stage of OL differentiation.

New insights on the biology of myelin basic protein gene: the neural-immune connection.

In the past 6 years, our conception of the major myelin protein genes has begun to change significantly because of recent findings documenting the existence of new exons encoding other products of these genes. A decade ago the myelin basic protein (MBP) and proteolipid protein (PLP) genes were thought to be expressed solely in myelin-forming cells, and their products were thought to be structural components of myelin. Since then, abundant evidence has been gathered identifying the presence of products of these genes in nonmyelinating cell types including both the immune and the nervous systems. Furthermore, within the nervous system, products of these genes have been identified in neurons and embryonic cells, clearly indicating that these myelin protein genes have additional functions in a number of cell types that are unrelated to myelination. In this brief communication, we review the recent literature that has resulted in this revision of our understanding of the MBP gene structure, products and expression.

Identification of a new exon in the myelin proteolipid protein gene encoding novel protein isoforms that are restricted to the somata of oligodendrocytes and neurons.

The myelin proteolipid protein (PLP) gene (i.e., the PLP/DM20 gene) has been of some interest because of its role in certain human demyelinating diseases, such as Pelizaeus-Merzbacher disease. A substantial amount of evidence, including neuronal pathology in knock-out and transgenic animals, suggests the gene also has functions unrelated to myelin structure, but the products of the gene responsible for these putative functions have not yet been identified. Here we report the identification of a new exon of the PLP/DM20 gene and at least two new products of the gene that contain this exon. The new exon, located between exons 1 and 2, is spliced into PLP and DM20 mRNAs creating a new translation initiation site that generates PLP and DM20 proteins with a 12 amino acid leader sequence. This leader sequence appears to target these proteins to a different cellular compartment within the cell bodies of oligodendrocytes and away from the myelin membranes. Furthermore, these new products are also expressed in a number of neuronal populations within the postnatal mouse brain, including the cerebellum, hippocampus, and olfactory system. We term these products somal-restricted PLP and DM20 proteins to distinguish them from the classic PLP and DM20 proteolipids. They represent putative candidates for some of the nonmyelin-related functions of the PLP/DM20 gene.

Two neuronal cell lines expressing the myelin basic protein gene display differences in their in vitro survival and in their response to glia.

We have generated two conditionally immortalized neuronal cell lines from primary cultures of embryonic day 13 (E13) and postmitotic (postnatal day 0; P0) cortical neurons transformed with the temperature-sensitive SV-40 large-T antigen. Two clonal cell lines (CN1.4 from E13 cultures and SJ3.6 from P0 cultures) were isolated and stable maintained in vitro. Both cell lines expressed a number of neuronal markers such as the neurofilaments, glutamic acid decarboxylase 67, neuron-specific enolase, and the BG21 isoform of the myelin basic protein gene. At 34 degrees C, the CN1.4 cell line had elaborated short processes, whereas the SJ3.6 cell line produced long processes that formed a delicate network. When these cell lines were cultured at 39 degrees C, some of the cellular processes grew longer, adopting a more mature neuronal morphology. Interestingly, at 39 degrees C, the in vitro survival of these cell lines differed significantly. Whereas the survival of CN1.4 cell line was greatly unaffected, SJ3.6 cells died soon after they were cultured at 39 degrees C. The cell death of SJ3.6 cells was accompanied by fragmentation and condensation of DNA in their nuclei, indicative of an apoptotic event. Under these conditions, SJ3.6 showed an upregulation of the p75 receptor. When this cell line was cocultured with oligodendrocytes, astrocytes, or glial conditioned media (GCM), there was a marked increase in survival. In contrast, little effect of glial cells or GCM was observed on the CN1.4 cell line. These lines appear to be useful models to study neuronal-glial interactions in addition to neuronal cell death and the effects of glial factors that promote the survival of neurons.

Identification of the dopamine D3 receptor in oligodendrocyte precursors: potential role in regulating differentiation and myelin formation.

Expression of the dopamine D3 receptor (D3r) was found in primary mixed glial cultures from newborn brain and in the corpus callosum in vivo during the peak of myelination. Expression of the D3r mRNA, but not D2r mRNA, was detected as early as 5 d in vitro (DIV) by RT-PCR. Immunoblot studies revealed D3r protein was also expressed in the cultures. Double immunofluorescence analysis for the D3r and for surface markers of specific stages of oligodendrocyte development indicated that D3r expression occurred in precursors and in immature oligodendrocytes but not in mature oligodendrocytes (i.e. , A2B5(+) 007(-) 01(-) and A2B5(+) 007(+) 01(-) cells but not A2B5(-) 007(+) 01(+) cells). Confocal microscopic analysis indicated that D3r was associated with cell bodies and cell membranes but not with the processes emanating from cell somas. Immunohistochemistry of brain sections revealed the presence of D3r in some oligodendrocytes located mainly within the genu and radiato of the corpus callosum during the active period of myelination. Treatment of cultures with 20 microM quinpirole led to decreased numbers of O1(+) oligodendrocytes possessing myelin-like membranes as well as an increase in the number of precursors in 14 DIV cultures. This effect was prevented by the dopamine antagonist haloperidol. These results show that the D3r expression is not restricted to neurons but it is also expressed in differentiating oligodendrocytes before terminal maturation. It also suggests that dopamine or some other D3r ligand may play a role in oligodendrocyte differentiation and/or the formation of myelin by mature oligodendrocytes.

Temperature-dependent regulation of PLP/DM20 and CNP gene expression in two conditionally-immortalized jimpy oligodendrocyte cell lines.

We conditionally immortalized jimpy primary oligodendrocytes (ODCs) with the temperature-sensitive SV40 large T antigen. Two cell lines (clones JP1.1 and JP1.2) were generated that expressed a number of ODC markers. Both jimpy cell lines expressed DM20 mRNAs at the proliferative temperature of 34 degrees C, but not at the "differentiation" temperature of 39 degrees C. Interestingly, at 39 degrees C neither cell line appeared to differentiate further, and neither survived longer than 7 days, in contrast to other ODC cell lines from normal animals that survive many weeks at 39 degrees C. These findings are not consistent with the notion that a PLP/DM20 gene product is the cause of oligodendrocyte cell death in jimpy, since neither jimpy cell line survived at 39 degrees C, and neither line expressed PLP or DM20 proteins. Analysis of the expression of the CNP (2'3' cyclic nucleotide-3'-phosphodiesterase) gene indicated that in both cell lines only one of the two CNP isoforms was expressed at 34 degrees C. Raising the temperature to 39 degrees C caused a greater reduction in the levels of CNP protein than CNP mRNA. Taken together, the DM20 and CNP data suggest that at least some of the decline in myelin/oligodendrocyte components observed in jimpy brains may not be due simply to fewer mature oligodendrocytes, but also to a down regulation of expression of these genes at several levels including transcriptional and post-transcriptional events. Our results provide two cell models for in vitro investigations into the nature of the jimpy mutation at several cellular and molecular levels.

Oxidative damage to proteins and lipids of CNS myelin produced by in vitro generated reactive oxygen species.

Purified myelin isolated from 70-day-old rats was submitted to nonenzymatic peroxidative systems containing 100 microM FeCl3.6H2O, 100 microM ascorbic acid, and 100 microM CuSO4.6H2O 10 mM H2O2 in order to investigate the extent of damage produced by reactive oxygen species (ROS). Iron and copper catalyzing systems were selected because of the known importance of these metals in producing free radical chain reactions in biological membranes (Halliwell and Gutteridge: "Free Radicals in Biology and Medicine," Oxford: Clarendon Press, 1989). Our findings show that: (1) although after 1 hour of peroxidation, an important level of thiobarbituric acid-reactive substances (TBARS) was detected, polyunsaturated fatty acids (20:2; 20:4; 22:4 and 22:6) were markedly affected only after 14 hours of incubation; (2) protein thiol groups were very sensitive to the attack of ROS generated by copper but resistant to iron-generated ROS; (3) aggregation of myelin proteins produced by peroxidation could be prevented by sulfhydryl (SH)-reducing agents, and (4) as a consequence of these modifications, compact myelin suffered disruption of its intraperiodic line. In conclusion, our results demonstrate that this unique membrane of the central nervous system (CNS) is highly vulnerable to oxidative stress and that this susceptibility to oxidative damage could be prevented, at least partially, by the use of SH-protective molecules.

Increased susceptibility to degradation by trypsin and subtilisin of in vitro peroxidized myelin proteins.

We examined the possibility that the peroxidative damage to central nervous system myelin produced by reactive oxygen species (ROS), could modify the susceptibility of its proteins to the proteolytic action of proteases such as trypsin and subtilisin. Purified myelin membranes obtained from adult rat brains were "in vitro" peroxidized by two non-enzymatic systems: Fe3+ plus ascorbic acid and Cu2+ plus hydrogen peroxide. Myelin proteins were severely affected by peroxidation. There was an increase in the amount of carbonyl groups (CO), accompanied by an enhanced susceptibility to degradation by trypsin and subtilisin of myelin basic proteins (MBP) and of the major proteolipid protein (PLP). The effect upon the degradation of myelin protein is a possible consequence of the appearance in the structure of myelin proteins of peroxidative modifications that contribute to the recognition by proteolytic enzymes. This hypothesis is supported by the fact that if peroxidation of myelin membranes is done in the presence of EDTA, both CO formation and increased sensitivity to enzymatic breakdown disappear. These results suggest that the appearance of abnormal post-translational modifications in the myelin membrane produced by peroxidation could constitute a putative mechanism of modulating the capacity of myelin proteins to be metabolized by proteases.

Single intracerebral injection of apotransferrin in young rats induces increased myelination.

Three-day-old rats were injected intracranially with 210 or 350 ng of apotransferrin (aTf) to study the possible neurotrophic effects of this iron transport protein. Treated animals and appropriate controls were injected with saline, denatured aTf or ovalbumin. Myelin was isolated from the brains and used to study its chemical composition and the protein electrophoretic pattern. Total myelin galactolipids and especially total phospholipids were significantly increased with reference to controls at both ages studied. A slight increase in total cholesterol was also observed. Total myelin proteins were markedly increased both at 10 and 17 days in comparison to controls. Chloroform:methanol-soluble proteins (proteolipids) were only slightly increased. The electrophoretic profile showed that the two main bands corresponding to myelin basic protein (MBP) were relatively increased in the treated animals. The enzymatic activity of 2'3'-cyclic nucleotide 3'-phosphohydrolase (CNPase) was significantly increased. The changes observed were dose- and age-dependent. The injection of aTf was effective only within a short developmental period since animals treated at 20 days of age showed no apparent changes in myelin composition. The actions of aTf injection persisted at least up to 60 days, since at this age the myelin obtained from injected animals still contained higher amounts of total proteins phospholipids and galactolipids in comparison to control animals. The action of aTf appears to be specific for myelin, since no significant effects were observed in membranes of a total brain homogenate. The effects are specific for the apoprotein injected since other proteins (ovalbumin) or heat-denatured aTf were ineffective.

Vesicular transport of myelin proteolipid and cerebroside sulfates to the myelin membrane.

The possibility that cerebroside sulfates and myelin proteolipid (PLP) could be simultaneously located in transport vesicles destined to be assembled in myelin was investigated in the brain of 20 day old rats. The brain was homogenized and fractionated according to Burkart et al. (J Biol Chem 257:3151-3156, 1982) to obtain a microsomal fraction that was further subfractionated in a linear sucrose density gradient following the procedure of Siegrist et al. (J Neurochem 33:497-504, 1979) to obtain a vesicular fraction which has been shown to transport cerebroside sulfates (Burkart et al., as above). This fraction was associated with acid hydrolase activity and had a lipid composition different from that of myelin and microsomal fractions. Studied by slab gel electrophoresis, dot blot, and Western blot analysis, using a highly specific anti-PLP antibody, it was found to contain myelin PLP. In view of previous findings of several laboratories including our own, the presence of myelin proteolipid in a vesicular fraction which is related to the transport of cerebroside sulfates gives further support to the hypothesis that the delivery of both constituents to the myelin membrane could be associated.