Plp gene regulation in the developing murine optic nerve: correlation with oligodendroglial process alignment along the axons.

The factors regulating the expression and splicing of the major myelin gene, proteolipid protein (Plp), are unclear. The gene encodes two splice variants, Plp and Dm20. During active myelination, transcription of the Plp gene is markedly upregulated and the splice variant ratio becomes Plp-mRNA dominant. We hypothesised that these aspects of Plp gene regulation are linked to overt axonal contact. Using the developing optic nerve of mice, we demonstrate that alignment of oligodendroglial processes with the axon correlates with both the expression of Plp-mRNA and the transcriptional upregulation of the gene. We test the above hypothesis more extensively in a subsequent study.

Myelin proteolipid proteins promote the interaction of oligodendrocytes and axons.

Although proteolipid protein (PLP) and its DM20 isoform are the major membrane proteins of CNS myelin, their absence causes surprisingly few developmental defects. In comparison, missense mutations of the X-linked Plp gene cause severe dysmyelination. Previous studies have established roles for PLP/DM20 in the formation of the intraperiod line and in maintaining axonal integrity. We now show that a normal number of oligodendrocytes are present in mice lacking PLP/DM20. However, in heterozygous females, which are natural chimeras for X-linked genes, oligodendrocytes lacking PLP/DM20 are in direct competition with wild-type oligodendrocytes that have a distinct advantage. PLP+ oligodendrocytes and PLP+ myelin sheaths make up the greater majority, and this feature is generalised in the CNS throughout life. Moreover, in the absence of PLP/DM20, a proportion of small-diameter axons fails to myelinate, remaining ensheathed but lacking a compact sheath, or show delayed myelination. These findings suggest that PLP/DM20 is also involved in the early stages of axon-oligodendrocyte interaction and wrapping of the axon.

A proteolipid protein-specific pre-mRNA (Ppm-1) contains intron 3 and is up-regulated during myelination in the CNS.

Alternative splicing of the precursor for messenger RNA (pre-mRNA) is a common process utilised by higher eukaryotes to modulate gene expression. A single primary transcript may generate several proteins with distinct functions, expressed in tissue-specific, developmental patterns. This article describes an oligodendrocyte-specific pre-mRNA product of proteolipid protein gene (P/p) transcription, which is the precursor for P/p but not Dm20 mRNA in the CNS. This P/p-specific pre-mRNA (Ppm-1) includes the intact intron 3 of the P/p gene. It is first expressed during active myelination, and it localises to the nucleus of oligodendrocytes, in both normal and jimpy (jp) murine CNS. In addition to mouse, Ppm-1 is found also in rat and dog, but not toad or trout. Our work suggests that alternative splicing of the P/p gene primary transcript follows a branching pattern, resulting in the presence of at least one P/p isoform-specific pre-mRNA molecule, Ppm-1. Therefore, Dm20 mRNA may be the product of a divergent set of pre-mRNA splicing events.

The early phenotype associated with the jimpy mutation of the proteolipid protein gene.

The jimpy mutation of the X-linked proteolipid protein (Plp) gene causes dysmyelination and premature death of the mice. The established phenotype is characterised by severe hypomyelination, increased numbers of dead oligodendrocytes and astrocytosis. The purpose of this study was to define the earliest cellular abnormalities in the cervical spinal cord. We find that on the first and third postnatal days the amount of myelin in jimpy spinal cord is approximately 20% of wild-type. However, the total glial cell density, the number of dead glial cells and the number and distribution of Plp-positive cells, as assessed by in situ hybridization, are similar to wild-type during the first week of life. Immunostaining of cryosections has identified that jimpy spinal cords express on schedule, a variety of antigens associated with mature oligodendrocytes. Dissociated oligodendrocytes, cultured for 18 hours to reflect their in vivo differentiation, express MBP and surface myelin-associated glycoprotein at the same frequency as wild-type. By comparison, the proportion of jimpy oligodendrocytes expressing surface myelin/oligodendrocyte glycoprotein is reduced by approximately 34%. In vivo, however, only a small minority of axons is surrounded by a collar of myelin-associated glycoprotein, suggesting that the majority of jimpy oligodendrocytes fail to make appropriate ensheathment of axons. Although the DM20 isoform is expressed in the embryonic CNS prior to myelin formation, the cellular abnormalities appear to correspond to the time at which the Plp isoform becomes predominant. The results suggest that the primary abnormality in jimpy is the inability of oligodendrocytes to properly associate with, and then ensheath, axons and that oligodendrocyte death compounds, rather than initiates, the established phenotype.

Current concepts of PLP and its role in the nervous system.

Proteolipid protein (PLP) and its smaller isoform DM20 constitute the major myelin proteins of the CNS. Mutations of the X-linked Plp gene cause the heterogeneous syndromes of Pelizaeus-Merzbacher disease (PMD) and spastic paraplegia (SPG) in man and similar dysmyelinating disorders in a range of animal species. A variety of mutations including missense mutations, deletions, and duplications are responsible. Missense mutations cause a predicted alteration in primary structure of the encoded protein(s) and are generally associated with early onset of signs and generalised dysmyelination. The severity of the phenotype varies according to the particular codon involved and the influence of uncharacterised modifying genes. There is some evidence that the dysmyelination results from the altered protein acquiring a novel function deleterious to the oligodendrocyte's function. Transgenic mice carrying extra copies of the Plp gene provide a valid model of PMD/SPG due to gene duplication. Depending on the gene dosage, the phenotype can vary from early onset of severe and lethal dysmyelination through to a very late onset of a tract-specific demyelination and axonal degeneration. Mice with a null mutation of the Plp gene assemble and maintain normal amounts of myelin but develop a progressive axonopathy, again demonstrating tract specificity. The results indicate that the functions of PLP are far from clear. There is good evidence that it is involved in the formation of the intraperiod line of myelin, and the results from the knockout and transgenic mice suggest a role in the interaction of oligodendrocyte and axon.

Molecular cloning and transfection studies of M6b-2, a novel splice variant of a member of the PLP-DM20/M6 gene family.

The present study documents the nucleic acid and deduced amino acid sequence of M6b-2, a novel splice variant of the M6b gene, which belongs to the PLP-DM20/M6 gene family. M6b-2 differs from the previously published M6b by a novel 40-amino acid insertion which is characterised by a high proline content, two casein kinase, and one tyrosine kinase consensus sequences. M6b-2 mRNA is enriched in perinatal central nervous system (CNS), and although it declines during development, it does persist into adulthood. Transient transfection studies coupled to secondary structure and hydrophobicity analysis suggest that the novel polypeptide in M6b-2 lies at the cytoplasmic face of the plasma membrane. It is therefore possible that the function(s) of M6b-2 may be regulated intracellularly by phosphorylation during CNS development.

A novel gelsolin isoform expressed by oligodendrocytes in the central nervous system.

Two isoforms of the Ca2+-sensitive, actin-binding protein gelsolin have been identified thus far; one is an intracellular protein, cytoplasmic gelsolin, and the other is a secretory protein called plasma gelsolin. Gelsolin expression in the mammalian CNS appears to be localized mainly to oligodendrocytes where it is presumed that the cytoplasmic isoform predominates. Here, we show that oligodendrocytes not only contain cytoplasmic gelsolin, but they also express a novel gelsolin isoform that we have named gelsolin-3. Cytoplasmic gelsolin, plasma gelsolin, and gelsolin-3 arise by alternative splicing from the same gene. The N-terminal amino acid sequence unique to gelsolin-3 is shown to be encoded by a single exon in a region previously thought to be an intron in the human gelsolin gene. In situ hybridization analysis confirmed that gelsolin-3 mRNA is localized primarily to oligodendrocytes in rat brain. In other tissues, gelsolin-3 shows a more restricted pattern of expression than cytoplasmic gelsolin. These data support the view that the gelsolin isoforms have differential roles in the regulation of the actin cytoskeleton.

Effects of rumpshaker mutation on CNS myelin composition and structure.

Myelinated CNS tissues from homozygous/hemizygous and heterozygous jimpy rumpshaker jprsh mutant mice were examined to determine the consequences on myelin structure of this mutation in the proteolipid protein (PLP) gene. Polyacrylamide gel electrophoresis and immunoblotting of brain homogenates confirmed that there was a decrease in PLP levels on the B6C3 genetic background onto which this gene was bred. We also observed an increase in level of a protein band that could correspond to the uncharacterized 10-kDa PLP previously reported in jprsh mice on an Rb(1.3) 1Bnr background. High-performance TLC and densitometry of lipids from brain homogenate and isolated myelin revealed a decrease in content of cerebrosides and sulfatides. Electron microscopy on optic nerves revealed that normal radial component is retained in jprsh myelin, further substantiating that PLP is not a component of this junctional complex. X-ray diffraction measurements on unfixed optic nerves showed that the jprsh period is 5-10 A larger than normal. Moreover, jprsh optic nerve myelin was unstable, as evidenced by a continual increase in the period postdissection. jprsh myelin that was equilibrated at varying pH and ionic strength typically had a larger than normal period under all conditions (both swelling and compacting). Our findings thus demonstrate that the biochemical abnormalities in the jprsh mutant correlate with a wider periodicity and less stable packing of the myelin.

Microtubule-associated proteins in developing oligodendrocytes: transient expression of a MAP2c isoform in oligodendrocyte precursors.

The morphological differentiation of oligodendrocytes is characterized by the formation of multiple, microtubule-rich processes which endow these cells with the ability to myelinate many axons simultaneously. Since microtubule-associated proteins (MAPs) strongly influence the structure and function of microtubules, we have investigated their expression in cultured differentiating oligodendrocytes in order to gain insights into MAP function during process formation and stabilization. MAP1B has been compared with two other structural MAPs: MAP4, which is an ubiquitously expressed protein, and MAP2, which hitherto was thought to be confined to neurons and reactive astrocytes. Immunofluorescence microscopy showed that the colocalization of MAP4 with microtubules in oligodendrocyte processes is not as extensive as found previously for MAP1B (Vouyiouklis and Brophy: J Neurosci Res 35:257-267, 1993). Nevertheless, like MAP1B, the expression of MAP4 increases during oligodendrocyte differentiation. In contrast, the expression of MAP2 is transiently elevated in preoligodendrocytes but declines precipitously at the onset of terminal differentiation. Cells of the oligodendrocyte lineage exclusively express a novel isoform of MAP2c which is primarily localized in the cell bodies of preoligodendrocytes. This suggests that MAP2c assists in the initiation of process extension rather than in the stabilization of microtubules in the cytoplasm-filled membranous extensions of mature cells. MAP-tau was not expressed at any developmental stage by oligodendrocytes. The distinct subcellular localizations and patterns of developmental expression of MAP1B, MAP4, and MAP2c suggest that these MAPs have different roles in the regulation of the microtubule network during the differentiation of myelin-forming oligodendrocytes.

Microtubule-associated protein MAP1B expression precedes the morphological differentiation of oligodendrocytes.

The microtubule-associated protein MAP1B is believed to play an important role in the outgrowth of neurites from neurons (Tucker and Matus, Dev Biol 130: 423-434, 1988). We have investigated the possibility that MAP1B might participate in the formation of processes in cultured oligodendrocytes by an analysis of the expression of MAP1B during oligodendrocyte progenitor development. The appearance of the antigens recognized by the monoclonal antibodies A2B5, O4, and O1 which define distinct stages in the maturation of progenitors, was compared with the developmental expression of MAP1B. MAP1B is first detectable in O4+ preoligodendrocytes prior to the acquisition of galactocerebroside and immediately before they develop the complex process-bearing morphology characteristic of terminally differentiated myelin-forming oligodendrocytes in the CNS. In contrast, astrocytes have negligible amounts of MAP1B. These results demonstrate that the expression of MAP1B precedes the development of the mature oligodendrocyte phenotype and suggest that interactions between microtubules and MAP1B might have a role in the formation and stabilization of myelin-forming processes.