Expression of myelin basic protein genes in several dysmyelinating mouse mutants during early postnatal brain development

RNA-binding Protein Quaking Stabilizes Sirt2 mRNA during Oligodendroglial Differentiation

Myelination is controlled by timely expression of genes involved in the differentiation of oligodendrocyte precursor cells (OPCs) into myelinating oligodendrocytes (OLs). Sirtuin 2 (SIRT2), a NAD⁺-dependent deacetylase, plays a critical role in OL differentiation by promoting both arborization and downstream expression of myelin-specific genes. However, the mechanisms involved in regulating SIRT2 expression during OL development are largely unknown. The RNA-binding protein quaking (QKI) plays an important role in myelination by post-transcriptionally regulating the expression of several myelin specific genes. In quaking viable (qk^v/qk^v ) mutant mice, SIRT2 protein is severely reduced; however, it is not known whether these genes interact to regulate OL differentiation. Here, we report for the first time that QKI directly binds to Sirt2 mRNA via a common quaking response element (QRE) located in the 3' untranslated region (UTR) to control SIRT2 expression in OL lineage cells. This interaction is associated with increased stability and longer half-lives of Sirt2.1 and Sirt2.2 transcripts leading to increased accumulation of Sirt2 transcripts. Consistent with this, overexpression of qkI promoted the expression of Sirt2 mRNA and protein. However, overexpression of the nuclear isoform qkI-5 promoted the expression of Sirt2 mRNA, but not SIRT2 protein, and delayed OL differentiation. These results suggest that the balance in the subcellular distribution and temporal expression of QKI isoforms control the availability of Sirt2 mRNA for translation. Collectively, our study demonstrates that QKI directly plays a crucial role in the post-transcriptional regulation and expression of Sirt2 to facilitate OL differentiation.

Rescuing qkV dysmyelination by a single isoform of the selective RNA-binding protein QKI

Alternative splicing of the qkI transcript generates multiple isoforms of the selective RNA-binding protein QKI, which play key roles in controlling the homeostasis of their mRNA targets. QKI deficiency in oligodendrocytes of homozygous quakingviable (qkV/qkV) mutant mice results in severe hypomyelination, indicating the essential function of QKI in myelinogenesis. However, the molecular mechanisms by which QKI controls myelination remain elusive. We report here that QKI-6 is the most abundant isoform in brain and is preferentially reduced in the qkV/qkV mutant during normal myelinogenesis. To test whether QKI-6 is the predominant isoform responsible for advancing CNS myelination, we developed transgenic mice that express Flag-QKI-6 specifically in the oligodendroglia lineage, driven by the proteolipid protein (PLP) promoter. When introduced into the qkV/qkV mutant, the QKI-6 transgene rescues the severe tremor and hypomyelination phenotype. Electron microscopic studies further revealed that the Flag-QKI-6 transgene is sufficient for restoring compact myelin formation with normal lamellar periodicity and thickness. Interestingly, Flag-QKI-6 preferentially associates with the mRNA encoding the myelin basic protein (MBP) and rescues MBP expression from the beginning of myelinogenesis. In contrast, Flag-QKI-6 binds the PLP mRNA with lower efficiency and has a minimal impact on PLP expression until much later, when the expression level of QKI-6 in the transgenic animal significantly exceeds what is needed for normal myelination. Together, our results demonstrate that QKI-6 is the major isoform responsible for CNS myelination, which preferentially promotes MBP expression in oligodendrocytes.

A new ENU-induced allele of mouse quaking causes severe CNS dysmyelination

The mutant allelic series of the mouse quaking gene consists of the spontaneous quaking(viable) (qk(v)) allele, which is homozygous viable with a dysmyelination phenotype, and four ENU-induced alleles (qk(kt 1), qk(k2), qk(kt3/4), and qk(l-1)), which are homozygous embryonic lethal. Here we report the isolation of qk(e5), the first ENU-induced viable allele of quaking. Unlike qk(v)/qk(v), qk(e5)/qk(e5) animals have early-onset seizures, severe ataxia, and a dramatically reduced lifespan. Ultrastructural analysis of qk(e5)/qk(e5) brains reveals severe dysmyelination when compared with both wild-type and qk(v)/qk(v) brains. In addition, Calbindin detection in young adult qk(e5)/qk(e5) mice reveals Purkinje cell axonal swellings indicative of neurodegeneration , which is not seen in young adult qk(v)/qk(v) mice. Although the molecular defect in the qk(e5) allele is not evident by sequencing, protein expression studies show that qk(e5)/qk(e5) postnatal oligodendrocytes lack the QKI-6 and QKI-7 isoforms and have reduced QKI-5 levels. The oligodendrocyte developmental markers PDGF alpha R, NG 2, O4, CNP, and MBP are also present in the qk(e5)/qk(e5) postnatal brain although CNP and MBP levels are considerably reduced. Because the qk(v) allele is a large deletion that affects the expression of three genes, the new neurologic qk(e5) allele is an important addition to this allelic series.

Regulation of mRNA stability in the nervous system and beyond

The ability to control gene expression is central to normal development and function. For a growing number of genes in the central nervous system and peripheral tissues, expression is determined by changes in the rate of mRNA decay. At a molecular level, regulated interactions between the mRNA target and sequence-specific binding proteins either inhibit or accelerate decay, affording tight control over gene expression. This review discusses several examples of such posttranscriptional gene regulation.

Endocytic depletion of L-MAG from CNS myelin in quaking mice

Quaking is an autosomal recessive hypo/dysmyelinating mutant mouse which has a 1-Mbp deletion on chromosome 17. The mutation exhibits pleiotrophy and does not include genes encoding characterized myelin proteins. The levels of the 67-kD isoform of the myelin-associated glycoprotein (S-MAG) relative to those of the 72-kD isoform (L-MAG) are increased in the quaking CNS, but not in other dysmyelinating mutants. Abnormal expression of MAG isoforms in quaking may result from altered transcription of the MAG gene or from abnormal sorting, transport, or targeting of L-MAG or S-MAG. To test these hypotheses, we have determined the distribution of L-MAG and S-MAG in cervical spinal cord of 7-, 14-, 21-, 28-, and 35-d-old quaking mice. In 7-d-old quaking and control spinal cord, L- and S-MAG was detectable in periaxonal regions of myelinated fibers and in the perinuclear cytoplasm of oligodendrocytes. Between 7 and 35 d, L-MAG was removed from the periaxonal membrane of quaking but not control mice. Compared to control mice, a significant increase in MAG labeling of endosomes occurred within oligodendrocyte cytoplasm of 35-d-old quaking mice. S-MAG remained in periaxonal membranes of both quaking and control mice. Analysis of the cytoplasmic domain of L-MAG identifies amino acid motifs at tyrosine 35 and tyrosine 65 which meet the criteria for "tyrosine internalization signals" that direct transmembrane glycoproteins into the endocytic pathway. These results establish that L-MAG is selectively removed from the periaxonal membrane of CNS-myelinated fibers by receptor-mediated endocytosis. The loss of L-MAG from quaking periaxonal membranes results from increased endocytosis of L-MAG and possibly a decrease in L-MAG production.

Structural features of myelin basic protein mRNAs influence their translational efficiencies

The myelin basic protein (MBP) gene expresses several alternatively spliced products with the same 5' and 3' untranslated regions (UTRs). It has been reported that its expression may be regulated not only at the transcriptional level but also at the translational level during development. We engineered several MBP mRNA deletion mutants with 5' (-48, -37, -27, -22, and -10) and 3' UTRs of differing lengths and examined the translational efficiencies of these constructs in cell-free systems. The translational efficiencies of the constructs differed significantly over a range of almost 10-fold. A deletion of 11 nucleotides from the 5' end of the natural (i.e., -48) MBP mRNA resulted in an approximate fourfold reduction in translational efficiency. Further truncation of the 5' UTR increased the translational efficiencies of the constructs as has been observed with many RNAs. These results suggest that there may be a positive control element between -48 and -37 nucleotides in the 5' UTR of MBP mRNA. The effects of modifying the lengths of the 5' UTR on the translational efficiency of mRNAs encoding the 21.5-kDa and 14-kDa MBPs were the same, suggesting that the effect observed was not unique to the 21.5-kDa MBP mRNA. Truncating the 3' UTR of four different alternatively spliced MBP mRNAs also altered their translational efficiencies. Thus, the 5' and 3' UTRs of MBP mRNAs appear to influence the translation of these mRNAs, and such factors may be involved in the translational regulation of MBP gene expression.

Regional and developmental variations of GFAP and actin mRNA levels in the CNS of jimpy and shiverer mutant mice

Gliosis is a common reaction to brain damage. Glial fibrillary acidic protein (GFAP) is a classical astrocytic marker. We have undertaken to measure the level of GFAP-mRNA as an index of gliosis in the brain of jimpy (jp) and shiverer (shi) murine mutants, in which hypomyelination is either severe or moderate, respectively. This study was conducted in five different CNS regions and at different ages. In young jp mutant, the amount of GFAP-mRNA was either normal or lower than in control animals; but after 3 wk of age, the level of GFAP-transcript increased dramatically in all regions examined. A parallel increase in actin-mRNA was also observed, mostly in the diencephalon and to a lesser extent in cortex and spinal cord, but not in the cerebellum and brainstem. In the shi mutant, variations in the amount of GFAP-mRNA were less important than in the jp with two exceptions: In brainstem of 3-wk-old animals, a 2.5-fold increase was observed, and in all the regions but the spinal cord of 12-d-old shi, the levels of GFAP-transcript were 2-5 times lower than in controls. In this mutant, the levels of actin message were usually close to normal, or slightly lower than in controls.

Quaking phenotype influences brain lipid-related mRNA levels

Although lipids compose almost 80% of myelin, the influence of quaking on mRNAs encoding lipid biosynthetic enzymes and transport proteins has not been previously reported. Understanding the influence of quaking on myelin-specific and lipid-related mRNAs will be useful in determining the mechanism of the quaking defect. Stearoyl CoA desaturase (SCD) catalyzes a key step in the biosynthesis of oleic acid (C18:1, n-9), a major fatty acid in myelin. SCD, LDL receptor (LDLR) and apolipoprotein E (Apo E) mRNA levels are all reduced in neonatal quaking brains. In contrast to brain, quaking hepatic LDLR and Apo E mRNA levels are normal. These results indicate that lipid-related mRNAs are reduced in neonatal quaking brain, but the quaking liver is unaffected. The quaking defect influences gene expression in multiple cell types of glial lineage in the developing CNS.

Spatial distribution of myelin basic protein mRNA and polypeptide in quaking oligodendrocytes in culture

In the CNS, myelin is formed from the expansion of oligodendrocyte processes. In order to study myelin assembly in the hypomyelinating mutant mouse quaking (qk), cultures of oligodendrocytes were established from affected and control animals. The cytoarchitecture of the oligodendrocytes was analyzed by performing morphometric measurements after immunostaining with antitubulin. The results indicate that the gross morphology of the processes is similar in control and mutant cells. The localization of the message for the myelin structural component, myelin basic protein (MBP), was examined by in situ hybridization. In control oligodendrocytes, 80% of MBP mRNA is found in the processes. In contrast, only 23% of MBP mRNA is localized to these structures in the mutant; the majority of MBP mRNA remains in the cell body. The mutant cells are capable of distributing mRNAs to the periphery as shown by the presence of tubulin mRNA in their processes. MBP polypeptide was visualized by immunofluorescence and found in the perikaryon, processes and membranous expansions of the control cells. In the mutant, it is largely confined to the perikaryon, reflecting the distribution of the mRNA. These results suggest that the localization of MBP polypeptide is achieved by restricting the distribution of its mRNA, and that MBP assembly into the myelin membrane occurs in the processes. This step appears to be blocked in qk oligodendrocytes in culture.

Developmental expression of myelin protein genes in dysmyelinating mutant mice: analysis by nuclear run-off transcription assay, in situ hybridization, and immunohistochemistry

Gene expression for myelin proteolipid protein (PLP) and myelin basic protein (MBP) in the dysmyelinating mutant mice shiverer and jimpy was analyzed by nuclear run-off transcription assay, in situ hybridization, and immunohistochemistry. The level of PLP transcription in shiverer brains was lower than that in controls at postnatal day 18 but relatively higher at later stages. In spite of the considerable amount of hybridization with PLP cDNA, immunoreaction for PLP was greatly reduced in shiverer mice throughout their lives, probably owing to a defect in the assembly of PLP into myelin. Abnormal deposition of PLP in oligodendroglial cell bodies suggested that transport of PLP to myelin is delayed in shiverer brains. The number of oligodendrocytes expressing PLP mRNA was drastically reduced in jimpy mice. MBP mRNA in jimpy mice is localized preferentially in oligodendroglial cell bodies, a result suggesting that oligodendrocytes in jimpy are mostly the immature type. Although transcriptional activity of the MBP gene in jimpy was greatly reduced, a finding reflecting the decrease in the number of mature oligodendrocytes, that of the PLP gene remained high at early stages. The discrepancy of the two gene expressions is discussed relative to the role of PLP transcripts at early stages of myelination.

Posttranscriptional events in the expression of myelin protein genes

A number of posttranscriptional events may be involved in regulating the expression of the myelin protein genes. One such event in the expression of the myelin basic protein (MBP) gene is the translocation of MBP mRNAs from oligodendrocyte cell bodies to their processes. This translocation can be observed in vivo and in primary mixed glial cell cultures. In jimpy brains the translocation of MBP mRNA appears to be disrupted, so that most of the mRNA remains associated with cell bodies. This apparent failure of translocation may account for the lack of incorporation of newly synthesized MBP into jimpy myelin. In quaking myelin, where MBP assembly is also defective, translocation appears to be normal, suggesting that incorporation of MBP into the membrane also is regulated posttranslationally. We have identified a number of the structural features of MBP mRNAs that influence the efficiencies with which they are translated and may be involved in regulating the levels of individual MBP produced. We also found that glucocorticoids stimulate the translation of MBP and PLP mRNAs and inhibit the translation of CNP mRNA in cell-free systems. Our results suggest that this pattern of translational regulation may be physiologically meaningful, especially during maturation of myelin. The mechanism by which the steroids modulate translation of these messages appears to be novel. Analysis of the effect of steroids on cRNAs produced from engineered MBP cDNA constructs has permitted the identification of a nine nucleotide element involved in this steroid modulation within the 5' untranslated region of the MBP mRNA.

Nuclear proteins in mouse brain cells bind specifically to the myelin basic protein regulatory region

Expression of myelin basic protein (MBP) in mice is regulated in a cell- and stage-specific manner during brain development. The MBP control region contains multiple cis-acting elements, shown by in vivo and in vitro assays, which are responsible for its unique pattern of transcription. Using synthetic DNA fragments spanning the MBP control region, we have analyzed nuclear proteins obtained from newborn (2-3 d), young adult (18-30 d), and adult (60 d) animals; these nuclear proteins form DNA-protein complexes with the MBP regulatory region. Brain extracts from young adult and adult mice showed enhanced binding activities with the sequences supporting transcriptional activation in glial cells. Deletion analysis of the proximal activating sequence located at position -14 to -50 with respect to the RNA initiation site resulted in identification of a small region, located between nucleotides -14 to -37, which is required for formation of the complexes. Southwestern assay revealed a major 39-kD protein from young adult brain extract that recognizes the sequences between nucleotides -14 to -37. An additional minor 37-kD protein, derived from young adult brain extract, was also found to be associated with this proximal activating region. Of particular interest is the observation that the minor 37-kD protein became more abundant in the extract derived from adult brain, whereas the major 39-kD protein became less abundant. The possible role of these proteins in cell/stage-specific transcription of MBP is discussed.

Quaking*jimpy double mutant mice: additional evidence for independence of primary deficits in jimpy

Mice which have the genotype qk/qk*Tajp/Y, and therefore simultaneously express both the quaking (qk) and jimpy (jp) mutations, have CNS white matter morphology intermediate between qk and jp with respect to amount of myelin, myelin structure, and oligodendrocyte number. The level of myelin basic protein in the CNS is also intermediate; however, myelin proteolipid protein (PLP) is virtually absent. Thus in the qk/qk*Tajp/Y double mutant mouse the PLP deficit is as severe as in jp alone but the oligodendrocyte survival deficit (reflected in number and myelin production) of jp alone is rendered less severe. The observation that these two cardinal deficits of the jp mutation can be independently altered in double mutant combinations is consistent with our previous suggestion that the PLP genetic locus may encode at least two independently regulated primary gene functions: a structural protein and signal influencing oligodendrocyte behavior.

Restoration of myelin formation by a single type of myelin basic protein in transgenic shiverer mice

A minigene containing mouse cDNA coding for the smallest type of myelin basic protein and including the native promoter was constructed and used to produce transgenic shiverer mice. The hypomyelinating mouse, the shiverer, has a deletion in its myelin basic protein gene, lacks all four types of myelin basic protein in its myelin, and shows abnormal behavior such as violent tremors. Five of twenty-one transgenic shiverer mice showed recovered protein synthesis, compact myelin formation, and normal behavior. These results suggest that a single type of myelin basic protein restores myelin formation and returns the shivering phenotype to normal in the transgenic shiverer mouse.

Developmental study of myelin basic protein variants in various regions of pig nervous system

A developmental study of myelin basic protein (MBP) variants in eight regions of pig nervous system (NS) was performed using a quantitative electroimmunoblotting procedure. Four major MBP forms with apparent molecular weights of 21.5K, 20.2K, 18.5K, and 17.3K were identified in both the CNS and the PNS and were detected as early as 22 days before birth. Quantification of the most abundant forms, the 21.5K and 18.5K MBPs, revealed characteristic profiles of accumulation of these two variants in different regions of the NS. The ratio of 21.5K:18.5K MBP varied with developmental time as well as with the various NS regions, peaking 20 days postnatally. The 17.3K MBP was observed from embryonic stages to adulthood, as were the 21.5K and 18.5K forms. In contrast, the 20.2K variant appeared most abundant from 10 days before to 22 days after birth and thereafter decreased in intensity so as to be no longer detectable in the brain of a 5-year-old pig. A similar pattern was also observed with an anti-MBP-reacting protein with an apparent molecular weight of 23K. Taken together, these results suggest that in the pig NS, the expression of MBP variants may be regulated both regionally and developmentally.

Translational regulation of myelin protein synthesis by steroids

Various steroids, including glucocorticoids, were observed to exert a direct effect on the rates of translation of several myelin-protein specific transcripts in a cell-free, reticulocyte lysate system. Hydrocortisone caused a twofold stimulation in the translation of mRNAs of myelin basic protein and proteolipid protein. It inhibited the translation of 2',3'-cyclic nucleotide 3'-phosphodiesterase mRNA by 50%, and had no effect on the translation of a number of other mRNAs. The data suggest that steroid-mediated translational regulation may serve as a novel mechanism to modulate the expression of myelin protein genes at the translational level.

Molecular biology of myelin proteins from the central nervous system

Within the past several years, several of the genes coding for the major myelin proteins have been isolated, characterized, and mapped to specific chromosomes. In all cases, it has been clearly established that these proteins exist as multiple isoforms, and their structures have been established through an analysis of the cDNA clones encoding them. In each case, the isoforms appear to arise through the translation of individual mRNAs produced by alternative splicing of the primary transcript of a single gene. In several cases, the expression of the individual isoforms appears to be developmentally and/or regionally regulated, probably at the level of the splicing of the primary transcript. In the case of the dysmyelinating mutants shiverer and jimpy, the molecular defects involve the MBP gene and PLP gene, respectively; most of the dysmyelinating mutants, including those in which the genetic defect is established, appear to exhibit pleiotropy with respect to the expression of other myelin protein genes.

Expression of myelin protein genes in quaking mouse brain

The expression of myelin proteins in actively myelinating quaking and control brains was studied. RNA was extracted from the brains of 18- and 27-day-old mice and analyzed by northern blot using cDNA probes for proteolipid protein (PLP), basic protein (BP), and myelin-associated glycoprotein (MAG). Two PLP transcripts of 3.2 and 2.4 kb (kilobase) were found, whereas PB and MAG probes hybridized to single regions of 2.2 and 2.5 kb, respectively. No abnormality in the transcript pattern was detectable in the quaking brain at either 18 or 27 days of age. Over this 9-day period the level of PLP and BP message in the control brain decreased by approximately 10%, whereas the level of MAG message decreased by approximately 50%. In the 18-day-old quaking brain the expression of PLP and BP was severely reduced amounting to one-third and one-half of the control values, respectively. The reduction at the age of 27 days was less. On the other hand, the quaking brain produced more MAG mRNA amounting to 1.6- and 3.2-fold control on the 18th and 27th day. The results indicate a reduced expression of the PLP and BP genes and a developmental delay in the mutant, whereas the genetic expression of MAG is enhanced and appears to be progressively dysregulated.

Cellular and molecular aspects of myelin protein gene expression

The cellular and molecular aspects of myelin protein metabolism have recently been among the most intensively studied in neurobiology. Myelination is a developmentally regulated process involving the coordination of expression of genes encoding both myelin proteins and the enzymes involved in myelin lipid metabolism. In the central nervous system, the oligodendrocyte plasma membrane elaborates prodigious amounts of myelin over a relatively short developmental period. During development, myelin undergoes characteristic biochemical changes, presumably correlated with the morphological changes during its maturation from loosely-whorled bilayers to the thick multilamellar structure typical of the adult membrane. Genes encoding four myelin proteins have been isolated, and each of these specifies families of polypeptide isoforms synthesized from mRNAs derived through alternative splicing of the primary gene transcripts. In most cases, the production of the alternatively spliced transcripts is developmentally regulated, leading to the observed protein compositional changes in myelin. The chromosomal localizations of several of the myelin protein genes have been mapped in mice and humans, and abnormalities in two separate genes appear to be the genetic defects in the murine dysmyelinating mutants, shiverer and jimpy. Insertion of a normal myelin basic protein gene into the shiverer genome appears to correct many of the clinical and cell biological abnormalities associated with the defect. Most of the dysmyelinating mutants, including those in which the genetic defect is established, appear to exhibit pleiotropy with respect to the expression of other myelin genes. Post-translational events also appear to be important in myelin assembly and metabolism. The major myelin proteins are synthesized at different subcellular locations and follow different routes of assembly into the membrane. Prevention of certain post-translational modifications of some myelin proteins can result in the disruption of myelin structure, reminiscent of naturally occurring myelin disorders. Studies on the expression of myelin genes in tissue culture have shown the importance of epigenetic factors (e.g., hormones, growth factors, and cell-cell interactions) in modulating myelin protein gene expression. Thus, myelinogenesis has proven to be very useful system in which to examine cellular and molecular mechanisms regulating the activity of a nervous system-specific process.

Developmental expression of the myelin proteolipid protein and basic protein mRNAs in normal and dysmyelinating mutant mice

Expression of the myelin proteolipid protein (PLP) was examined in the nuclei and polysomes of 12-27-day-old quaking, jimpy, and shiverer mouse brains and in 2-27-day-old normal brains and compared with expression of the myelin basic proteins (MBPs). Northern blots showed the presence of multiple mouse PLP RNAs, the developmental expression of which coincided with myelination. Two major mouse PLP RNAs, 3.5 and 2.6 kilobases in length, were observed in both cytoplasmic polyribosomes and nuclei, and, in addition, a larger 4.6-kilobase PLP RNA was observed in nuclei. Quantitative measurements with slot blot analyses showed that the levels of PLP and MBP RNAs peaked simultaneously at 18 days in nuclei but that maximal levels of PLP RNA lagged behind MBP RNA by several days in the polysomes. The developmental expression of both major classes of myelin protein mRNAs was affected in all three mutants. In shiverer brains, the levels of PLP mRNA in polysomes and nuclei were only 30-55% of control levels after 15 days. Thus, the deletion of a portion of the MBP gene appeared to have a major effect on the expression of the PLP gene in this mutant. In jimpy mice, where the mutation has been shown to involve the PLP gene, expression of MBP mRNA was also severely reduced, to less than 25% of control values. In quaking brains, the expression of each gene followed its own developmental course, different from each other and different from the normal mouse. The extent to which the expression of PLP and MBP was affected by the quaking mutation depended on the age at which it was examined.

Characterization of myelin proteolipid mRNAs in normal and jimpy mice

A clone specific for the rat myelin proteolipid protein (PLP) was isolated from a cDNA library made in pUC18 from 17-day-old rat brain stem mRNA. This clone corresponded to the carboxyl-terminal third of the PLP-coding region. The clone was used to identify PLP-specific mRNAs in mouse brain and to establish the time course of PLP mRNA expression during mouse brain development. Three PLP-specific mRNAs were seen, approximately 1,500, 2,400, and 3,200 bases in length, of which the largest was the most abundant. During brain development, the maximal period of PLP mRNA expression was from 14 to 25 days of age, and this was a similar time course to that for myelin basic protein mRNA expression. When the jimpy mouse, an X-linked dysmyelination mutant, was studied for PLP mRNA expression, low levels of PLP mRNA were seen which were approximately 5% of wild-type levels at 20 days of age. When jimpy brain RNA was analyzed by Northern blotting, the PLP-specific mRNA was shown to be 100 to 200 bases shorter than the wild-type PLP-specific mRNA. This size difference was seen in the two major PLP mRNAs, and it did not result from a loss of polyadenylation of these mRNAs.

Identification of a cDNA coding for a fifth form of myelin basic protein in mouse

The primary sequences of four molecular mass variants (14, 17, 18.5, and 21.5 kDa) of the mouse myelin basic protein (MBP) have recently been determined through analysis of cDNA clones of their mRNAs. The mRNAs coding for the four MBP variants are thought to arise by differential splicing of two exons (exons 2 and 6) from a single gene. In contrast, exons 2 and 5 may be spliced out in the posttranscriptional processing of the human MBP gene. To investigate the possibility that a third exon (exon 5) may also be differentially spliced out in the processing of the mouse MBP gene transcript, a mouse cDNA library was screened to search for cDNAs missing exon 5. A MBP cDNA was isolated whose coding region specified a fifth mouse MBP variant with a molecular mass of approximately equal to 17 kDa. The mass of this variant (17,257 Da) is so close to that of the other 17-kDa mouse MBP (17,224 Da) that the two would be indistinguishable on NaDodSO4/polyacrylamide gels. Analysis of the sequence of the cDNA clone indicates that excision of exons 2 and 5 of the mouse MBP gene would produce the mRNA encoding this newly described 17-kDa MBP, whereas excision of exon 6 would produce the mRNA for the other 17-kDa MBP variant. Thus, the "17-kDa" mouse MBP consists of at least two molecular forms with very similar molecular masses but markedly different primary sequences. Of five full-length or near full-length cDNAs representing 17-kDa MBPs, one was missing exons 2 and 5 and four were missing exon 6.

Assignment of the myelin basic protein gene to human chromosome 18q22-qter

The assignment of the human myelin basic protein gene to 18q22-qter has been made using a mouse cDNA probe in the study of human-mouse somatic cell hybrids and by in situ hybridization. These results confirm the earlier assignment using in situ studies alone by Saxe et al. (1985).

Translational regulation of myelin basic protein synthesis

Synthesis of the mouse myelin basic proteins (MBPs) was studied in reticulocyte lysates programmed with brain mRNA in the presence or absence of brain factors. Addition of brain factors to the lysates increased the incorporation of [35S]methionine into total TCA-precipitable protein by a factor of 6-9, and the majority of this stimulation was found to be due to initiation factors. Although brain factors increased total protein synthesis, the percentage of MBP synthesis was reduced from 4.3% of the total counts incorporated (in the absence of brain factors) to 1.4% (in their presence). Increasing the concentration of brain mRNA in the lysates also reduced the relative levels of MBP synthesis. These results suggested the MBP mRNAs, as a group, were less efficiently initiated than most brain mRNAs. An analysis of the nucleotide sequence flanking the initiator codon of the MBP mRNAs indicates the presence of a second AUG codon 5 bases upstream, immediately followed by a termination codon, which may provide a structural explanation for the poorer initiation efficiency of the MBP mRNAs. Further analysis of the synthesis of the individual MBPs in the presence or absence of inhibitors of initiation (7-methylguanosine triphosphate and aurintricarboxylic acid) and elongation (anisomycin and emetine) indicated than the 14-kD MBP mRNA was less efficiently translated than the other MBP mRNAs. Synthesis of the 14-kD MBP was more strongly inhibited by the initiation inhibitors than the other MBP mRNAs, and synthesis of the 14-kD MBP was increased relative to the other MBPs in the presence of elongation inhibitors.(ABSTRACT TRUNCATED AT 250 WORDS)

Biochemical correlates of myelination in brain and spinal cord of mice heterozygous for the jimpy gene

Brain and spinal cord of female mice heterozygous for the jimpy gene were analyzed during development for activity of ceramide galactosyl transferase (CGT) and for levels of myelin basic protein (MBP). CGT activity was low at 13-14 days in brains of heterozygous jimpy females but showed normal levels by 31-36 days, in agreement with our earlier study of this enzyme. In cord, CGT activity was normal or slightly above normal at all ages studied, from 13-14 days into adulthood. In both brain and cord, decreased levels of MBP were observed at 13 days; by 100 days, amounts of MBP approached normal levels. Proven female carriers of the jimpy gene also showed normal levels of CGT activity, MBP, and isolated myelin at 200-250 days of age in both brain and cord. These biochemical findings agree with previous morphologic measurements in cord demonstrating deficits in myelin at early ages but compensation by 100 days. Our results show that compensation occurs earlier in cord than in brain and that levels of MBP show a closer correlation than CGT activity with amounts of myelin, as measured by either morphometric analysis or direct isolation.

Characterization of myelin proteolipid mRNAs in normal and jimpy mice

A clone specific for the rat myelin proteolipid protein (PLP) was isolated from a cDNA library made in pUC18 from 17-day-old rat brain stem mRNA. This clone corresponded to the carboxyl-terminal third of the PLP-coding region. The clone was used to identify PLP-specific mRNAs in mouse brain and to establish the time course of PLP mRNA expression during mouse brain development. Three PLP-specific mRNAs were seen, approximately 1,500, 2,400, and 3,200 bases in length, of which the largest was the most abundant. During brain development, the maximal period of PLP mRNA expression was from 14 to 25 days of age, and this was a similar time course to that for myelin basic protein mRNA expression. When the jimpy mouse, an X-linked dysmyelination mutant, was studied for PLP mRNA expression, low levels of PLP mRNA were seen which were approximately 5% of wild-type levels at 20 days of age. When jimpy brain RNA was analyzed by Northern blotting, the PLP-specific mRNA was shown to be 100 to 200 bases shorter than the wild-type PLP-specific mRNA. This size difference was seen in the two major PLP mRNAs, and it did not result from a loss of polyadenylation of these mRNAs.

Expression of myelin proteolipid protein and basic protein in normal and dysmyelinating mutant mice

Expression of myelin proteins was studied in the brains of 21-day-old normal mice and three dysmyelinating mutants-jimpy, quaking, and shiverer. Total brain polyribosomes and poly(A)+ mRNA were translated in two cell-free systems and the levels of synthesis of the myelin basic proteins (MBPs) and proteolipid protein (PLP) were determined. Synthesis of the MBPs in quaking homozygotes was at or above normal levels but PLP synthesis was significantly reduced to approximately 15% of control values, indicating independent effects on the expression of these proteins in this mutant. Immunoblot analysis of 21-day-old quaking brain homogenates showed a reduction in the steady-state levels of MBPs and PLP, suggesting a failure of newly synthesized MBPs to be incorporated into a stable membrane structure such as myelin. In the shiverer mutant very little synthesis of MBPs was observed, whereas greater synthesis of PLP occurred (approximately 50% of control). Almost no MBP, and low levels of PLP, were detected in the immunoblots, suggesting the possibility of a partial failure of PLP to be assembled into myelin in shiverer. In the jimpy mutant, low levels of MBP synthesis were observed in vitro (approximately 26% of controls) and very little synthesis of PLP was evident. The immunoblots of 21-day jimpy brain homogenates revealed no appreciable steady-state levels of PLP or MBP, again indicating that most newly synthesized MBPs were not incorporated into a stable membrane structure in this mutant. In sum, the data show that in the three cases examined, the mutation appears to affect the expression of the MBPs and PLP independently. Furthermore, regardless of their absolute levels of synthesis these proteins may or may not be assembled into myelin.

Expression of myelin proteolipid and basic protein mRNAs in cultured cells

Studies were undertaken to investigate the regulation of myelin-specific mRNA expression in cultured cells. Three experimental systems were investigated: primary oligodendrocytes grown as enriched cell populations, primary oligodendrocytes grown in the presence of chick spinal cord neurons, and C6 cells. cDNA probes specific for the myelin proteolipid mRNA and the myelin basic protein mRNA were used to quantitate proteolipid and myelin basic protein mRNA levels in cells under different experimental conditions. C6 cells expressed less than 0.2% of the proteolipid mRNA that was expressed in primary oligodendrocytes. Primary oligodendrocytes expressed the myelin-specific mRNAs for at least 104 days in culture, and the level of these mRNAs in cultures was elevated fourfold by coculturing rat oligodendrocytes with chick spinal cord neurons.

Isolation and characterization of a cDNA coding for a novel human 17.3K myelin basic protein (MBP) variant

Human fetal spinal cord poly A (+) mRNA was found to direct the synthesis of three major myelin basic protein (MBP) variants with molecular weights of 17K, 18.5K, and 21.5K when translated in reticulocyte lysates. In order to investigate the structural relationships between these MBP variants and their corresponding mouse variants, human fetal spinal cord and mouse brain cDNA libraries were constructed and screened for MBP cDNAs. A number of MBP cDNA clones were isolated and characterized. One of these, PP535 contained the entire coding region of the mouse 14K MBP; and another mouse cDNA clone, PP1.85, was almost full-length and coded for either the 21.5K MBP or the 18.5K MBP. A human clone (KK36), 1,173 nucleotides in length, contained the entire coding region of an MBP variant with a molecular weight of 17,342. The structure of this clone within its coding region is significantly different from the corresponding mouse 17K MBP cDNA. It is missing two sequences found in the mouse 17K MBP cDNA (exons 2 and 5); and it contains a sequence (exon 6) that is missing from the mouse 17K MBP cDNA. Thus, this human 17.3K cDNA codes for a "17K" human MBP variant that is quite different from the corresponding mouse variant and is identical to the human 18.5K MBP except for a deletion of a peptide consisting of 11 amino acids that includes the single tryptophan residue of the 18.5K MBP. An analysis of the structure of this 17.3K human MBP cDNA suggests that the major pathway for splicing the primary human MBP gene product may be different from that in the mouse.