Recovery of Proteolipid Protein in Mice Heterozygous for the Jimpy Gene

We have measured levels and synthesis of proteolipid protein (PLP) and its transport into myelin in female mice heterozygous for the jimpy gene and in their normal female littermates. In both cord and cerebrum, jimpy carriers show deficits in PLP during development followed by compensation in adulthood. Recovery of PLP occurs earlier in cord than in brain. At 13 days levels of PLP in carriers compared to controls are reduced to 0.60 and 0.44, respectively, in cord and cerebrum. By 100 days, normal levels of PLP are attained in cord (1.13) whereas levels of PLP in cerebrum are only 0.78 of control. By 200 days full recovery occurs in cerebrum, with a ratio of 1.21, suggesting a possible over-compensation. The yield of myelin from cerebrum was reduced to 0.78 in carriers compared to controls at 17 days. In brain slices, incorporation of [3H]leucine into homogenate PLP from carriers is the same as in controls, whereas [3H]leucine incorporation into myelin PLP is reduced to 0.68 of control. These results indicate that synthesis of PLP in the carriers is normal at 17 days, but transport of PLP into myelin is reduced. Similarly, acylation of homogenate PLP is normal, whereas acylation of myelin PLP is reduced, as measured by incorporation of [3H]palmitic acid. Transport of PLP into myelin was compared to transport of MBP; transport of both proteins was equally decreased as indicated by the similar ratio of labeled PLP to MBP in myelin from carriers compared to noncarriers.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on myelin basic protein-specific protein methylase I in various dysmyelinating mutant mice

Jimpy mice are dysmyelinating mutants characterized by producing near normal levels of myelin basic protein (MBP) in the brain but failing to incorporate these proteins into the myelin sheath. In this study, the activity of MBP-specific protein-arginine N-methyltransferase (protein methylase I) was studied in the brains of normal and jimpy mice of different ages. The enzyme activity varied little with age in normal mice but in 18 and 21 days-old homozygous jimpy mice the activity was reduced by 50% and 75% respectively from the level of their normal littermates. Interestingly, however, heterozygous jimpy mice who are phenotypically normal and quaking mice (a similar dysmyelinating mutant) showed unaltered enzyme levels.     

Biochemical Expression of Mosaicism in Female Mice Heterozygous for the Jimpy Gene

Abstract: Expression of the jimpy gene in heterozygous females was analyzed by measuring galactolipid synthesis in brain during early myelination. Sulfatide labeling in brains of heterozygous females at 13–14 days is decreased to 40–80% that of female littermates who do not carry the jimpy gene. The activities of ceramide galactosyl transferase and cerebroside sulfotransferase and levels of myelin basic protein were similarly depressed. Since the jimpy gene was maintained with the Tabby gene in these studies, the effect of the Tabby gene on these parameters was examined and found to have no effect. These biochemical findings indicate that myelination is retarded in the brains of heterozygous jimpy females during the second week of development. However, at 18 days and thereafter, sulfatide labeling is less reduced, suggesting that the oligodendrocytes in brain attempt to compensate, in agreement with morphologic studies which show that myelin is decreased in brain during early development, but appears normal in adult animals.     

Effect of the Jimpy Mutation on Expression of Myelin Proteins in Heterozygous and Hemizygous Mouse Brain

The levels of myelin basic protein, proteolipid protein, and 2',3'-cyclic nucleotide 3'-phosphohydrolase (EC 3.1.4.37) in cerebral hemispheres of wild-type, heterozygous jp/+, and hemizygous jp/Y mice of different ages were determined by radioimmunoassay and immunoblotting. In jp/Y brain the level of myelin basic protein was 8% that of wild-type at all ages. All forms of the protein were reduced although the 21.5K Mr form was relatively spared at early ages compared to the 18.5K, 17K, and 14K Mr forms. The level of 2',3'-cyclic nucleotide 3'-phosphohydrolase was 8% that of wild-type at all ages, and proteolipid protein was undetectable at any age. These results are consistent with the hypothesis that the jimpy mutation blocks myelin morphogenesis subsequent to incorporation of 21.5K Mr myelin basic protein but prior to incorporation of proteolipid protein. In jp/+ brain the levels of the three proteins were reduced commensurately to 60-70% those of wild-type. The deficit was apparent as early as 10 days after birth and remained proportionately constant throughout development. These results suggest that in jp/+ mice, X-chromosome inactivation produces a mosaic population of functionally wild-type and functionally jimpy oligodendrocytes. The former elaborate normal amounts of myelin but do not completely compensate for the myelin deficit due to the latter.     

Expression of Myelin Basic Protein Genes in Several Dysmyelinating Mouse Mutants During Early Postnatal Brain Development

Northern blot and "dot" blot analyses using a myelin basic protein (MBP) specific cDNA probe and in vitro translation techniques were utilized to estimate the relative levels of myelin basic protein messenger RNA (mRNA) in the brains of C57BL/6J control mice, three dysmyelinating mutants (qk/qk, jp/Y, and shi/shi), and three heterozygote controls (qk/+, jp/+, and shi+) during early postnatal development. In general, the MBP mRNA levels measured directly by Northern blot and "dot" blot analyses correlated well with the indirect in vitro translation measurements. The Northern blots indicated that the size of MBP mRNAs in quaking and jimpy brain polysomes appeared to be similar to controls. Very low levels of MBP mRNAs were observed in shi/shi brain polyribosomes throughout early postnatal development. Compared to C57BL/6J controls, accumulation of MBP mRNAs in qk/qk and qk/+ brain polyribosomes was delayed by several days. That is, whereas MBP mRNA levels were below normal between 12 and 18 days, normal levels of message had accumulated in both qk/qk and qk/+ brain polyribosomes by 21 days. Furthermore, normal levels of MBP mRNAs were observed to be maintained until at least 27 days. MBP mRNA levels remained well below control levels in jp/Y brain polyribosomes throughout early postnatal development. The levels did, however, fluctuate slightly and peaked at 15 days in both jp/Y and jp/+ brains, 3 days earlier than in normal mice. Thus, it appears that jimpy and quaking mice exhibit developmental patterns of MBP expression different from each other and from C57BL/6J control mice.     

Myelin basic protein is affected by reduced synthesis of myelin proteolipid protein in the jimpy mouse.

Myelin basic proteins (MBPs) from 6-day-old, 10-day-old, 20-day-old and adult normal mouse brain were compared with those from 20-day-old jimpy (dysmyelinating mutant) mouse brain to determine the effect of reduced levels of proteolipid protein (PLP) on MBPs. Alkaline-urea-gel electrophoresis showed that 6-day-old and 10-day-old normal and jimpy MBPs lacked charge microheterogeneity, since C8 (the least cationic of the components; not be confused with complement component C8) was the only charge isomer present. In contrast, MBPs from 20-day-old and adult normal mouse brain displayed extensive charge microheterogeneity, having at least eight components. A 32 kDa MBP was the major isoform observed on immunoblots of acid-soluble protein from 6-day-old and 10-day-old normal and 20-day-old jimpy mouse brain. There were eight bands present in 20-day-old and adult normal mouse brain. Purified human MBP charge heteromers C1, C2, C3 and C4 reacted strongly with rat 14 kDa MBP antiserum, whereas the reaction with human C8 was weak. This suggested that MBPs from early-myelinating and jimpy mice did not react to MBP antisera because C8 was the major charge isomer in these animals. Purification of MBPs from normal and jimpy brain by alkaline-gel electrophoresis showed that both normal and jimpy MBPs have size heterogeneity when subjected to SDS/PAGE. However, the size isoforms in normal mouse brain (32, 21, 18.5, 17 and 14 kDa) differed from those in jimpy brain (32, 21, 20, 17, 15 and 14 kDa) in both size and relative amounts. Amino acid analyses of MBPs from jimpy brain showed an increase in glutamic acid, alanine and ornithine, and a decrease in histidine, arginine and proline. The changes in glutamic acid, ornithine and arginine are characteristic of the differences observed in human C8 when compared with C1.     

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.     

Proteolipids in the developing brains of normal mice and myelin deficient mutants

Abstract— A developmental study of proteolipids from brains of normal mice and two myelin deficient mutants, jimpy and quaking, was performed. The proteolipids were obtained by diethyl ether precipitation of washed total lipid extracts from whole brains and were analysed on polyacrylamide gels containing sodium dodecyl sulphate. The amount of ether precipitable material extractable from normal brains increased almost six-fold between 12 and 21 days posr partum. This increase was not observed with the mutant mice. Polyacrylamide gel electrophoretic analysis of the proteolipid fraction showed it to be heterogeneous, with eight major protein bands. Two of these proteins increased rapidly in quantity in normal mice between 13 and 21 days. These two proteins were present, in severely reduced quantities in the brains of jimpy and quaking mice at all ages examined. One of these proteolipids was the major species present in proteolipid extracts from the brains of normal mature mice. This protein coelectrophoresed with proteolipid isolated from purified myelin and has been tentatively identified as the myelin proteolipid. The other proteolipid which was deficient in jimpy and quaking brains was not characterized, but it appeared to be of extra-myelin origin, and suggests that parts of the brain other than the myelin sheath may be involved in the jimpy and quaking disorders.     

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.     

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.     

Protein-catalyzed exchange of phosphatidylinositol between rat brain microsomes and myelin.

Exchange of phosphatidylinositol and phosphatidylcholine between microsomal and myelin membranes has been demonstrated. This exchange is reversible and catalyzed by soluble proteins from the brain homogenate precipitated at pH 5.1. The extent of exchange of phosphatidylinositol from microsomal membrane to myelin is dependent upon pH and temperature, with an optimum around pH 7 and at 50 degrees C. Maximum exchange was observed at approximately equal amounts of microsomal, myelin, and supernatant proteins. The extent of the catalyzed exchange increases 4- to 8-fold upon using sonicated or heat-treated myelin as an acceptor membrane. Heating of microsomal membranes results in no change. The extent of catalyzed exchange of phosphatidylcholine is less than that of the phosphatidylinositol. The exchange of other phospholipids and glycolipids between microsomal and myelin membranes cannot be demonstrated. The catalytic activity of the pH 5.1 supernatant proteins in rat brain for the exchange of phosphatidylinositol increases with age after birth and reaches a maximum around 21 days of age analogous to the process of myelination. The pH 5.1 supernatant proteins from quaking and jimpy mutant mice has normal catalytic activity.     

Alpha hydroxylation of lignoceric acid to cerebronic acid during brain development. Diminished hydroxylase activity in myelin-deficient mouse mutants.

Alpha Hydroxylation of lignoceric acid (n-tetracosanoic acid) to cerebronic acid (2-hydroxylignoceric acid) by postnuclear preparations of brains from developing rat, mouse, and several neurological mouse mutants was studied. The preparations of brains from jimpy and myelin synthesis deficiency (msd) mice were found to synthesize cerebronic acid at less than 10 percent of their control rates, and those from quaking and dilute-lethal approximately 30 and 50 percent, respectively. The apparent low rate of in vitro hydroxylation by brains of the mutant mice appeared to be due to decreased synthesis rather than increased oxidation of cerebronic acid. Mixing experiments eliminated the possibility of an inhibitor in the mutant or an activator in normal animals. The preparations of brains from wabbler-lethal, ducky, and weaver mice showed normal activity. The developmental pattern of the hydroxylase activity was examined in quaking, jimpy, and their control mice. In normal brains the hydroxylase activity was low in the immediate postnatal period, increased sharply between 10 and 20 days after birth, and fell to a low level following maturation of the brain. The hydroxylase activity in quaking mice changed similarly during brain development but at a much reduced level. The brains of jimpy mice had barely detectable hydroxylase activity which changed little with age and reached a peak at about 15 days postpartum. The subnormal hydroxylase activity in brains of quaking mice and the near absence in brains of jimpy and msd mice correlate with the observations that myelin deficiency is more severe in jimpy and msd than in quaking. These results suggest a close association of the synthesis of cerebronic acid with the synthesis of the characteristic myelin lipid that is cerebroside (N-acyl sphingosine beta-D-galactoside).     

The distribution of myelin basic protein in subcellular fractions of developing Jimpy mouse brain.

Abstract— The amount of myelin basic protein in jimpy mutants and unaffected littermates was measured by radioimmunoassay during the period of most active myelination (11-21 days). This protein was examined in whole brain homogenates and in four subcellular fractions (nuclear, 900 g pellet; heavy membrane, 11,500 g pellet; microsomal, 100,000 g pellet; and cytosol, 100,000g supernatant solution). At all ages examined, the mutants, which have very little myelin in the CNS, had only about 2% the amount of basic protein found in controls. As expected, the amount of myelin basic protein increased 4-fold in the control animals during the developmental period studied. This was not the case in the jimpy mutants, where little increase in the whole brain basic protein was observed. In the jimpy mutants, all of the fractions had significantly less basic protein than control fractions, except the cytosol, where the amounts of basic protein were similar in controls and mutants. These results are discussed with respect to possible mechanisms of myelination and the site of the genetic lesion.     

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.     

2'',3''-Cyclic Nucleotide 3''-Phosphodiesterase and 5''-Nucleotidase in the Central Nervous System of a Myelin-Deficient Rat Mutant

2',3'-Cyclic nucleotide 3'-phosphodiesterase activity was examined in brains and spinal cords of normal and myelin-deficient Wistar rats. While the activity in normal brains increased from 0.2 mumol/min/mg protein (units) at 6-10 days to 3.5 units at 25 days of postnatal age, the activity in the myelin-deficient rat remained at 0.2-0.3 units over the same period. In spinal cord, the normal activities were 5.7 and 10.9 units at 12 and 20 days, respectively, whereas they declined in the myelin-deficient rat from 1.06 to 0.79 units for the same age points. 5'-Nucleotidase activities in brain and spinal cord were normal in the myelin deficient rat at both ages.     

Myelin Basic Protein Deposition in the Optic and Sciatic Nerves of Dysmyelinating Mutants Quaking, Jimpy, Trembler, MLD, and Shiverer During Development

An ontogenetic survey of the basic protein of myelin, common to both central and peripheral nervous systems, was carried out on normal C57Bl and five dysmyelinating mutant mice. Myelin basic protein (MBP) was quantified by radioimmunoassay in the optic and sciatic nerves of mice from birth to adult stages, giving special attention to the premyelinating and early myelination periods. In the optic nerves of normal mice, MBP was already detectable at birth but the active period of myelin deposition was shown to occur after day 10 postnatal. The timing and rate of accumulation of MBP were normal in Trembler. In contrast, they were abnormal in the other mutants. In the quaking mouse, the active period of MBP deposition was delayed, and its final concentration represented no more than 12% of normal in the adult. No active period of MBP deposition was observed in the other mutants. In the jimpy mouse, a slow accumulation of MBP resulted in a final concentration reaching 2% of the normal value at 25 days. In mild and shiverer mice, the MBP was hardly detectable. In the sciatic nerves of normal mice, the active period of MBP deposition occurred between days 3 and 12 postnatal. No substantial changes occurred in the period of 2 months--2 years.(ABSTRACT TRUNCATED AT 250 WORDS)     

Developmental expression of the myelin gene MOBP in the rat nervous system

The myelin-associated/oligodendrocyte basic proteins (MOBPs) are recently discovered constituents of myelin and are small, cytoplasmic, and highly basic proteins exclusively expressed postnatally by oligodendrocytes. Due to a clustering of positively charged amino acids observed in the most abundant MOBP isoform similar to myelin basic protein (MBP) and P0, it was speculated that MOBP could function in myelin sheath compaction. The present report strongly supports this view. A direct comparison of MBP and proteolipid protein (PLP) gene expression with that of MOBP by in situ hybridization revealed a very similar regional distribution. It was found that MOBP expression was abundant in the rat CNS at postnatal day 15 (P 15) but is restricted to densely myelinated regions. In contrast to MBP and PLP, expression of MOBP was undetectable in the peripheral nervous system during the entire development. Interestingly, MOBP mRNA was localized in oligodendrocyte processes even at early postnatal stages and throughout development. MOBP showed a very specific timing of expression: in spinal cord and brain, MOBP gene expression occurred significantly later (2–3 days) than that of MBP and PLP, but slightly earlier than myelin oligodendrocyte glycoprotein gene expression. MOBP proteins appeared in spinal cord and brain stem also after MBP protein, suggesting that the MOBPs functionally act after the structural myelin proteins MBP and PLP. Our findings imply a function of MOBP during the late steps of myelin formation, presumably at the initiation of sheath compaction.     

SYNTHESIS OF ETHANOLAMINE PHOSPHOGLYCERIDES BY MICROSOMES FROM THE BRAINS OF JIMPY AND QUAKING MICE

Abstract— —Brains of jimpy and quaking mice are known to be deficient in myelin and alkenylacyl-glycero-phosphorylethanolamines (alkenylacyl-GPE, ethanolamine plasmalogens). Ethanolamine plasmalogen synthetic activity appeared to be normal and ethanolamine phosphotransferase (EC 2.7.8.1) activities are higher in the brain microsomes from jimpy and quaking mice than in their littermate controls when the activities are assayed with alkylacylglycerols and CDP[¹⁴C]ethanolamine. When endogenous diradylglycerols were the substrate, the rate of synthesis of diacyl-GPE was normal but the rate of synthesis of the ether lipids, alkenylacyl-GPE and alkylacyl-GPE, was 33% and 8% below control levels for jimpy brain microsomes and quaking brain microsomes respectively. This difference is probably due to a normal content of diacylglycerols and a deficient content of alkylacylglycerols in the mutant brain microsomes. The apparent alkylacylglycerol deficiencies in the microsomes correspond with the ethanolamine plasmalogen deficiencies in the brains of these mutant mice.