Myelin deficient mice: expression of myelin basic protein and generation of mice with varying levels of myelin

Mice homozygous for the mutation myelin deficient (mld), an allele of shiverer, exhibit decreased CNS myelination, tremors, and convulsions of progressively increasing severity leading to an early death. In this report we demonstrate in mld mice that the gene encoding myelin basic protein (MBP) is expressed at decreased levels and on an abnormal temporal schedule relative to the wild-type gene. Southern blot analyses, field-inversion gel electrophoresis studies, and analyses of mld MBP cosmid clones indicate that there are multiple linked copies of the MBP gene in mld mice. We have introduced an MBP transgene into mld mice and found that myelination increases and tremors and convulsions decrease. Mld and shiverer mice with zero, one, or two copies of the MBP transgene express distinct levels of MBP mRNA and myelin. The availability of a range of mice expressing graded levels of myelin should facilitate quantitative analysis of the roles of MBP in the myelination process and of myelin in nerve function.     

Molecular biology of myelin basic protein: gene rearrangement and expression of anti-sense RNA in myelin-deficient mutants.

1. Myelin is an important structure for facilitating the conduction of impulses along the axons both in the central nervous system (CNS) and peripheral nervous system (PNS). 2. Myelin basic protein (MBP) is a major protein in CNS myelin. 3. MBP is expressed specifically in the nervous system. 4. The MBP gene has been cloned and characterized. 5. Two mutant mice, Shiverer (shi) and myelin-deficient (mld. shimid), are autosomal recessive mutants that show severe symptoms such as intentional tremor. They have been found to have a mutation in the MBP gene that results in poor myelination in the central nervous system. 6. It was found that rearrangement within the MBP gene results in low expression of the gene. 7. In Shiverer, the MBP gene is partially deleted (from exons 3 to 7), and in mld, the gene is duplicated tandemly and a large portion of the duplication is inverted upstream of the intact copy. 8. In mld, anti-sense RNA complementary to exons 3-7, which correspond to the inverted segment, was detected by RNase protection studies, and presumed to be responsible for the reduced expressions of MBP. 9. The mechanism of gene rearrangement in MBP was also characterized. 10. This article reviews the recent progress in the study of the MBP gene, especially the rearrangement of the gene and its expression in mutant mice.     

Gene organization and transcription of duplicated MBP genes of myelin deficient (shi(mld)) mutant mouse

A hereditary dysmyelinating mutation, named myelin deficient (shi(mld)), is characterized by reduced expression of myelin basic protein (MBP). In shi(mld), the MBP gene is duplicated and its reduced expression is mainly determined by the level of mRNA. We have characterized the structure and function of the promoter regions of the duplicated MBP genes in shi(mld). Among the lambda clones containing promoter regions of the duplicated MBP genes in shi(mld), one (gene 1) had the same restriction enzyme pattern as that in control mice, but another (gene 2) had a rearrangement on a distal part of the promoter. A 712-bp nucleotide sequence upstream of the first exons of both of the duplicated MBP genes of shi(mld) was completely consistent with that of the control. Promoter activities of 1.3-kb 5'-flanking regions from respective genes of shi(mld) measured by in vitro run-off assay using HeLa whole-cell extracts were indistinguishable from that of the control MPB gene. Chromosomal mapping by in situ hybridization suggested that the duplicated MBP genes were located closely to each other at the distal part of chromosome 18. A recombinational event including the inversion seemed to have occurred within gene 1 and its possible relationship to the reduced expression of MBP is discussed.     

Structure and Expression of Myelin Basic Protein Gene Sequences in the mld Mutant Mouse: Reiteration and Rearrangement of the Mbp Gene

The mld mutation on chromosome 18 in the mouse is a putative allele of the shiverer (shi) mutation. We have analyzed the structure of myelin basic protein (MBP) gene sequences in mld DNA by restriction mapping of genomic DNA. The results indicate that the mld chromosome carries two copies of the MBP structural gene, one of which is intact and one of which is interrupted. Genetic analysis indicates that the interrupted gene is close to the intact MBP structural gene and cosegregates with the mld mutation. We have also analyzed the levels of MBP polypeptides and MBP-specific mRNA in wild-type, homozygous and heterozygous shiverer and mld mice and in mice carrying both mutations. The results indicate that both shi and mld are cis-acting codominant mutations that cause severely reduced steady state levels of MBP-specific mRNA and MBP polypeptides in the brain. We have analyzed the total number of oligodendrocytes and the number of MBP-positive oligodendrocytes in mld and shi brain primary cultures. In shi cultures, none of the oligodendrocytes expresses MBP. However, in mld cultures, approximately 5% of the oligodendrocytes express MBP. The nature of the "revertant" mld oligodendrocytes is not known.     

Expression of a myelin basic protein gene in transgenic shiverer mice: correction of the dysmyelinating phenotype

Mice homozygous for the autosomal recessive mutation shiverer (shi) lack myelin basic protein (MBP) and exhibit a distinct behavioral pattern including tremors (shivering), convulsions, and early death. We have previously demonstrated that shiverer mice have a partial deletion in the gene encoding MBP. We now have introduced the wild-type MBP gene into the germ line of shiverer mice by microinjection into fertilized eggs. Transgenic shiverer mice homozygous for the introduced gene have MBP mRNA and protein levels that are approximately 25% of normal, and produce compacted myelin with major dense lines. Correct temporal and spatial expression of the MBP gene is achieved with a genomic MBP cosmid clone containing 4 kb of 5' flanking sequence and 1 kb of 3' flanking sequence. Moreover, the four different forms of MBP produced by alternative patterns of RNA splicing are present. These homozygous transgenic shiverer mice no longer shiver nor die prematurely.     

Myelin instability and oligodendrocyte metabolism in myelin-deficient mutant mice

During the active phase of myelination in myelin-deficient mutant mice (mld), myelin basic protein (MBP) synthesis is defective and the myelin lamellae are uncompacted. In these mutants, we found a fast metabolism of the myelin-associated glycoprotein (MAG) and of sulfatides, and the presence of cholesterol esters and a degradation product of MAG, dMAG, indicating that mld myelin was unstable. The increased synthesis of MAG and Wolfgram protein, two proteins present in uncompacted myelin sheath and paranodal loops, was demonstrated by high levels of messengers. Simultaneously, we found an accumulation of inclusion bodies, vacuoles, and rough endoplasmic reticulum in mld oligodendrocytes. This material was heavily immunostained for MAG. Furthermore, the developmental change between the two molecular forms of MAG (p72MAG/p67MAG) was delayed in mld mice. In 85-d-old mld mice, the MBP content increased and myelin lamellae became better compacted. In these mutants, dMAG was absent and MAG mRNAs were found in normal amounts. Furthermore, the fine structure of mld oligodendrocytes was normal and the MAG immunostaining was similar to age-matched controls. These results support a functional role for MBP in maintaining the metabolic stability and the compact structure of myelin. Furthermore, in the absence of MBP and myelin compaction, the regulation of the synthesis of at least two membrane proteins related to myelin cannot proceed.     

Expression of myelin protein genes in the developing brain

The major myelin proteins fall into two classes, the basic proteins and the proteolipid proteins. In mice, five forms of the myelin basic protein (MBP) have been identified with apparent molecular masses of 21.5 kD, 18.5 kD, 17 kD and 14 kD. The 17 kD MBP variant consists of two molecular forms with similar molecular masses but different amino acid sequences. Cell-free translation studies and analyses of MBP cDNAs have shown that each of the MBP variants is encoded by a separate mRNA of approximately 2 000 bp. The five mouse MBP mRNAs appear to be derived by alternative splicing of exons 2, 5, and 6 of the MBP gene. cDNAs encoding four forms of MBP have been isolated from a human fetal spinal cord library. The mRNAs corresponding to these cDNAs are probably derived by alternative splicing of exons 2 and 5 of the human MBP gene. Proteolipid protein (PLP) cDNAs have been isolated from several species and used to establish that the size of the major PLP mRNA is approximately 3 kb. Multiple size classes of the PLP mRNAs exist in mice and rats whereas the 3 kb mRNA is the predominant form in the developing human spinal cord. In normal mice, maximal expression of the PLP gene lags behind that of the MBP gene by several days. Studies on dysmyelinating mutants have determined some of the molecular defects with respect to these two classes of myelin proteins. For example, there is a deletion of a portion of the MBP gene in the shiverer mutant. In the quaking mutant, the expression of both classes of myelin proteins is significantly reduced prior to 3 weeks. However, after 3 weeks, MBP expression approaches normal levels but the newly synthesized protein fails to be incorporated into myelin. In the jimpy mutant, although the expression of both classes of proteins is reduced, PLP expression is most severely affected.     

Rearrangement and Reactivation of the Myelin Basic Protein Locus in Myelin-Deficient (mld) Mouse Brain

Abstract: Myelin-deficient ( mld ) is a complex mutation affecting the myelin basic protein (MBP) locus of the mouse. It consists of duplication and partial inversion of the MBP gene and results in a dysfunctional MBP locus. The mutant phenotype is reversed, both in vivo and in vitro, in ∼5% of mld oligodendrocytes. One possible mechanism for the somatic reversion is recombination between homologous sequences of the duplicated gene copies to reconstitute a functional MBP locus. There are several possible recombination events that could reconstitute a functional MBP locus by DNA rearrangement. Two of these would result in reinversion and circularization of specific MBP gene sequences, respectively. In this work polymerase chain reaction analysis was used to detect both reinverted and circularized MBP gene sequences in mld mouse tissues, indicating that DNA rearrangement at the MBP locus does occur. Analysis of individually harvested cells showed that in revertant MBP-positive mld oligodendrocytes DNA rearrangement at the MBP locus was correlated with reactivation of the MBP gene. Fluctuation analysis showed that reactivation of the MBP locus is a stochastic event occurring with a frequency of ∼1.4 × 10⁻⁶ per cell per cell cycle during oligodendrocyte development. The frequency of rearrangement and reactivation of the MBP locus was comparable in double mutant ( mld/mld , scid/scid ) and single mutant ( mld/mld , + ^scid /+ ^scid ) mice, indicating that the scid factor is not required for MBP gene reactivation in mld . The significance of DNA rearrangement in mammalian development is discussed.     

The Endogenous Lectin Cerebellar Soluble Lectin and Its Ligands in Central Nervous System Myelin of Myelin-Deficient (mld) Mutant Mice

The myelin-deficient (mld) mutation is autosomal recessive mutation in the murine CNS exhibiting severe hypomyelination. The primary defect results in a drastic reduction of myelin basic protein synthesis caused by a duplication of the myelin basic protein gene with partial inversion of the upstream gene copy. The severe deficit of myelin basic protein is responsible for the absence of the major dense line but cannot explain the heterogeneity of myelin compaction found in mld. We have tested the hypothesis that the endogenous cerebellar soluble lectin (CSL) and/or its endogenous glycoprotein ligands could be involved in myelin abnormalities in the dysmyelinating mutant, mld. Immunocytochemical and immunoblotting techniques showed that the CSL level was not reduced significantly in the mld mutant. Furthermore, two ligands of CSL, the myelin-associated glycoprotein and an axonal glycoprotein, with a relative molecular mass of 31 kDa, were not decreased in level in the purified myelin fraction isolated from mld mice. In contrast, three minor glycoprotein ligands of CSL of relative molecular mass of 23, 18, and 16 kDa were greatly reduced in content. The reduced concentration of these low-molecular-mass glycoproteins in mld myelin suggests that they are constituents of compact myelin. Furthermore, the observation that CSL is specifically localized in vivo in regions where mld myelin is more compact and absent from regions devoid of myelin compaction may suggest that the endogenous CSL lectin, as well as its minor glycoprotein ligands, plays a role in the stabilization of the myelin sheath.