Myelin proteolipid protein is not esterified at the site of synthesis

Brain slices prepared from 20-day old rats were incubated with [³H]palmitic acid to study its incorporation into myelin proteins. After separation by SDS-PAGE, most of the label was found to be associated with the major proteolipid protein (PLP) and with the intermediate protein (I). The radioactivity measured in PLP at short incubation times was shown to be due to palmitic acid bound to the protein by ester linkages. Time-course incorporation of [³H]palmitic acid into PLP of fraction SN₄ (a myelin like membrane) and of purified myelin showed that the former was poorly labeled and no relationship of the type ‘precursor-product’ between these fractions could be detected. Incorporation of the fatty acid into PLP was not affected by inhibition of the synthesis or transport of myelin PLP with cycloheximide or colchicine, indicating that the pool of PLP that can be acylated must be larger than the extramyelin pool. Addition of unlabeled palmitic acid to the incubation medium, 30 min after the addition of [³H]palmitate, stopped the appearance of label in myelin PLP almost immediately, indicating that there is no significant extramyelin pool of PLP destined for transport into myelin. The results presented in this paper strongly suggest that esterification of PLP takes place in the myelin membrane or at a site very close to it.     

Proteolipid protein and DM-20 are synthesized by Schwann cells,present in myelin membrane,but they are not fatty acylated

Proteolipid protein (PLP) and DM-20 were intensely labeled after immunoprecipitation of total cellular proteins and myelin proteins labeled with [³⁵S]methionine in nerve slices. These results provided evidence that PLP and DM-20 are incorporated into the myelin membrane following their synthesis in Schwann cells. In contrast, PLP and DM-20 were not fatty acylated after incubation of the nerve slices with [³H]palmitic acid, however, PO glycoprotein and 24kDa protein were heavily fatty acylated. The lack of fatty acylation of PLP and DM-20 in the peripheral nervous system suggests that fatty acyltransferase responsible for their acylation is absent or non-functional in the peripheral nervous system.     

Suppressive Effect of Triethyllead on Entry of Proteins into the CNS Myelin Sheath In Vitro

Incorporation of [¹⁴C]leucine into the myelin sheath was studied in brain stem slices prepared from 22-day-old rats. Individual major myelin proteins were separated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate. There was a time lag before incorporation of the label into proteolipid protein (PLP) and intermediate protein (IP) reached maximal rates. Labelling of basic proteins (BP) and Wolfgram proteins (WP) revealed a much shorter lag in entry. Appearance of radioactive proteins in the myelin sheath was significantly hampered by triethyllead (PbEt₃) added to the incubation medium at micromolar concentrations. Inhibition values were highest in the case of PLP and were closely followed by the values for IP. BP and WP were less inhibited, although incorporation of these proteins into myelin was still suppressed more than was synthesis of total homogenate protein. Thus, myelin-forming cells seem to be unduly vulnerable to the toxin relative to the rest of the tissue. Furthermore, the results indicate an interference of PbEt₃ with certain posttranslational processes involved in furnishing of integral myelin proteins.     

Differential effect of colchicine upon the entry of proteins into myelin and myelin related membranes

Brain slices from 20 day old rats were incubated with radioactive aminoacids in the presence and absence of 500 M colchicine and the appearance of labeled proteins in myelin and in a myelin-like fraction (SN₄ fraction) was measured. In the presence of the inhibitor, the entry of proteolipid proteins was decreased to 55% in myelin and to 45% in SN₄ fraction with reference to control values while the entry of basic proteins and other minor protein components was unaffected in both fractions. The synthesis of proteolipid proteins was not affected by the presence of colchicine; moreover, a slight accumulation of these proteins was observed in microsomes. The results suggest that the microtubular system is involved in the transport of proteolipid proteins from their site of synthesis to their site of deposition and that the various types of myelin proteins follow different transport routes to enter into this special type of membrane.     

Calcium-Stimulated Proteolysis in Myelin: Evidence for a Ca2+-Activated Neutral Proteinase Associated with Purified Myelin of Rat CNS

Incubation of myelin purified from rat spinal cord with CaCl2 (1-5 mM) in 10-50 mM Tris-HCl buffer at pH 7.6 containing 2 mM dithiothreitol resulted in the loss of both the large and small myelin basic proteins (MBPs), whereas incubation of myelin with Triton X-100 (0.25-0.5%) and 5 mM EGTA in the absence of calcium produced preferential extensive loss of proteolipid protein (PLP) relative to MBP. Inclusion of CaCl2 but not EGTA in the medium containing Triton X-100 enhanced degradation of both PLP and MBPs. The Ca2+-activated neutral proteinase (CANP) activity is inhibited by EGTA (5 mM) and partially inhibited by leupeptin and/or E-64c. CANP is active at pH 5.5-9.0, with the optimum at 7-8. The threshold of Ca2+ activation is approximately 100 microM. The 150K neurofilament protein (NFP) was progressively degraded when incubated with purified myelin in the presence of Ca2+. These results indicate that purified myelin is associated with and/or contains a CANP whose substrates include MBP, PLP, and 150K NFP. The degradation of PLP (trypsin-resistant) in the presence of detergent suggests either release of enzyme from membrane and/or structural alteration in the protein molecule rendering it accessible to proteolysis. The myelin-associated CANP may be important not only in the turnover of myelin proteins but also in myelin breakdown in brain diseases.     

Zinc Ions Stabilise the Association of Basic Protein with Brain Myelin Membranes

Myelin basic protein (MBP) dissociated from brain myelin membranes when they were incubated (37 degrees C; pH 7.4) at physiological ionic strength. Zinc ions inhibited, and calcium promoted, this process. Protease activity in the membrane preparations cleaved the dissociated MBP into both small (less than 4 kilodaltons) and large (greater than 8 kilodaltons) fragments. The latter were detected, together with intact MBP, by gel electrophoresis of incubation media. Zinc ions appeared to act in two distinct processes. In the presence or absence of added CaCl2, zinc ions in the range 0.1-1 mM inhibited MBP-membrane dissociation. This process was relatively insensitive to heat and Zn2+ could be substituted by either copper (II) or cobalt (II) ions. A second effect was evident only in the presence of added calcium ions, when lower concentrations of Zn2+ (less than 0.1 mM) inhibited MBP-membrane dissociation and the accumulation of intact MBP in incubation media. This process was heat sensitive and only copper (II), but not cobalt (II), ions could replace Zn2+. To determine whether endogenous zinc in myelin membranes is bound to MBP, preparations were solubilised in buffers containing Triton X-100/2 mM CaCl2 and subjected to gel filtration. Endogenous zinc, as indicated by a dithizone-binding method, eluted with fractions containing both MBP and proteolipid protein (PLP). Thus, one means whereby zinc stabilises association of MBP with brain myelin membranes may be by promoting its binding to PLP.     

CONDENSING VACUOLE CONVERSION AND ZYMOGEN GRANULE DISCHARGE IN PANCREATIC EXOCRINE CELLS: METABOLIC STUDIES

We have examined, in the pancreatic exocrine cell, the metabolic requirements for the conversion of condensing vacuoles into zymogen granules and for the discharge of the contents of zymogen granules. To study condensing vacuole conversion, we pulse labeled guinea pig pancreatic slices for 4 min with leucine-³H and incubated them in chase medium for 20 min to allow labeled proteins to reach condensing vacuoles. Glycolytic and respiratory inhibitors were then added and incubation continued for 60 min to enable labeled proteins to reach granules in control slices. Electron microscope radioautography of cells or of zymogen granule pellets from treated slices showed that a large proportion of prelabeled condensing vacuoles underwent conversion in the presence of the combined inhibitors. Osmotic fragility studies on zymogen granule suspensions suggest that condensation may result from the aggregation of secretory proteins in an osmotically inactive form. Discharge was studied using an in vitro radioassay based on the finding that prelabeled zymogen granules can be induced to release their labeled contents to the incubation medium by carbamylcholine or pancreozymin. Induced discharge is not affected if protein synthesis is blocked by cycloheximide for up to 2 hr, but is strictly dependent on respiration. The data indicate that transport and discharge do not require the pari passu synthesis of secretory or nonsecretory proteins (e.g. membrane proteins), suggesting that the cell may reutilize its membranes during the secretory process. The energy requirements for zymogen discharge may be related to the fusion-fission of the granule membrane with the apical plasmalemma.     

Simultaneously entry of palmitic acid into proteolipid protein in different myelin subfractions of rat brain

Rats of 20-days of age were injected intracranially with radioactive palmitic acid to study its incorporation into proteolipid protein (PLP) of myelin and myelin subfractions. At short times (120 min), the radioactivity present in PLP was shown to be due to palmitic acid bound to the protein by ester linkages. The specific radioactivity of palmitic acid labeled PLP was identical in all the myelin subfractions except the myelin-like fraction, in which it was lower, suggesting that the entry of the fatty acid into PLP of the different subfractions occurs simultaneously.Experiments using time staggered injections of ¹⁴C- and ³H-labeled palmitic acid also showed that entry of the fatty acid into PLP of the various subfractions was simultaneous. These results seem to indicate that the acylation of PLP occurs in the myelin membrane and that synthesis and transport of this protein are events unrelated to the acylation process.     

Decreased Fatty Acylation of Myelin Proteolipid Protein in the Twitcher Mouse

We examined chronological changes of myelin proteins of the brainstem and spinal cord of the twitcher mouse (15, 20, and 30 days old), a murine model of human globoid cell leukodystrophy caused by a genetic deficiency of galactosylceramidase I activity. The yield of myelin was normal until postnatal day 20, whereas galactosylsphingosine (psychosine) accumulated with age in myelin. The protein profiles of myelin and the activity of 2',3'-cyclic nucleotide 3'-phosphodiesterase in the myelin remained normal throughout the experimental period. Fatty acylation of proteolipid protein (PLP) was examined in a cell-free system by incubation of myelin with [3H]palmitic acid, CoA, and ATP, and was normal at postnatal day 15, but decreased after postnatal day 20. Decreased fatty acylation of PLP was also observed in the twitcher mouse at postnatal day 20 when the isolated myelin was incubated with [14C]palmitoyl-CoA in the absence of ATP and CoA, or the slices of brainstem and spinal cord were incubated with [3H]palmitic acid. The activity of fatty acid:CoA ligase was reduced in myelin. These data suggest that decreased acylation of PLP in twitcher mouse myelin is probably due to reduced activities for both activation and transfer of fatty acid into PLP and that metabolic disturbance is present in myelin because acylation of PLP has been shown to occur in myelin membrane. Although psychosine (200 microM) inhibited only 17% of the acylation in vitro, it may be responsible for the reduced acylation of PLP in vivo.     

Role of anions in low pH-induced translocation of diphtheria toxin

Previous work has shown that when Vero cells with surface-bound diphtheria toxin are exposed to low pH, toxin entry across the plasma membrane is induced and that this entry involves two steps, insertion of the B-fragment of the toxin into the membrane and translocation of the enzymatically active A-fragment to the cytosol. Here we have studied the role of permeant anions in this process. It was found that when the B-fragment was inserted into the membrane, part of it, a 25-kDa polypeptide, was shielded from externally added Pronase. This insertion did not require permeant anions. The translocation of the A-fragment was monitored by measuring either its ability to inhibit protein synthesis in the cells or the appearance of radioactively labeled 21-kDa fragment after treatment of the cells with externally applied Pronase. The translocation of the A-fragment was dependent on the presence of permeant anions in the medium. However, when the cells were depleted of Cl- by incubation in Cl- free buffer at high pH, translocation of the A-fragment did not require permeant anions in the medium. The possibility that translocation of the A-fragment is inhibited by an outward directed chloride gradient rather than by the absence of chloride is discussed.     

Exposure of Rat Optic Nerves to Nitric Oxide Causes Protein S-Nitrosation and Myelin Decompaction

This study investigates the effect of nitric oxide (NO) on both the chemical modifications of CNS proteins and the architecture of the myelinated internode. Incubation of rat optic nerves for 2 h with 1 mM concentration of the NO-donors S-nitroso-N-acetyl-penicillamine (SNAP), ethyl-2-[hydroxyimino]-5-nitro-3-hexeneamide (NOR-3), and 4-phenyl-3-furoxan carbonitrile (PFC) led to decompaction of myelin at the level of the intraperiod line (IPL). In contrast, incubation with 1 mM sodium nitroprusside, which slowly releases NO, sodium nitrite, and N-nitrosopyrrolidine failed to cause myelin disassembly. This suggests that free NO and/or some of its direct oxidation products (e.g., N2O3) are the active molecular species. NO-induced alterations in myelin architecture could not be assigned to protein or lipid degradation, lipid peroxidation, ATP depletion, calcium uptake, protein nitration, protein carbonylation, and nerve depolarization. NO-treatment, however, resulted in the S-nitrosation of a number of proteins. In myelin, one of the major S-nitrosated substrates was identified as proteolipid protein (PLP), an abundant cysteine-rich protein that is responsible for IPL stabilization. Peripheral nervous system myelin, whose stability depends on proteins other than PLP, was not decompacted upon incubation of sciatic nerves with SNAP. It is proposed that NO-mediated nitrosation of sulfhydryl groups is likely to interfere with the normal function of PLP and other important CNS myelin proteins leading to the structural demise of this membrane. These findings are relevant to multiple sclerosis and other inflammatory demyelinating disorders where both excessive NO production and myelin instability are known to occur.     

Intracellular Translocation of Myelin Proteolipid Protein

Brainstem slices prepared from 22-day-old rats were employed to study the intracellular translocation of radioactively labeled myelin proteolipid protein (PLP). Double-isotope and short pulse-chase procedures allowed us to demonstrate the flux of PLP through nine different subcellular membrane fractions that were isolated on the basis of their particle size and buoyant density. Tagged PLP was rapidly depleted from microsomes, showed transient passage through a number of presumably intermediate membranous pools, and accumulated in myelin. On the basis of the kinetics of PLP labeling and isotope ratios, the membranes can be arranged as they participate in the intracellular translocation of PLP and consistently show a pattern indicating possible precursor-product relationships.     

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)     

Effects of monensin on posttranslational processing of myelin proteins

Rat brain slices were incubated with [3H]palmitic acid and [14C]glycine to label the lipid and protein moieties, respectively, of myelin proteolipid protein (PLP). The effects of monensin on posttranslational processing of proteins were examined by measuring the appearance of [14C]glycine- and [3H]palmitate-labeled proteins in myelin and myelin-like fractions. At 0.01 and 0.10 microM, monensin did not appreciably affect total lipid or protein synthesis; higher concentrations caused increased inhibition. Monensin at 0.10 microM markedly decreased the appearance of [14C]glycine-labeled PLP in myelin, but had little effect on the 14C basic proteins or the incorporation of [3H]palmitic acid into total or myelin PLP. The same relative effect was apparent at higher monensin concentrations. In the myelin-like fraction, monensin at 0.10 microM also depressed entry of [14C]glycine into protein comigrating with PLP, and again had no effect on incorporation of [3H]palmitic acid. In addition, monensin increased the [3H]palmitate label associated with two high-molecular-weight proteins in the myelin-like fraction with no concomitant increase in [14C]glycine label.     

In vitro insertion of the myelin proteolipid apoprotein into oligodendrocyte plasma membranes

Uncoated vesicles (UCV) loaded with the myelin proteolipid apoprotein covalently tagged with fluorescein (PLP_F) were found to interact with isolated oligodendrocytes from bovine brain at 4°C as well as at 37°C. After 1.5 hours of incubation, the labeled protein was localized in the cell membranes. After 2.5 hours the fluorescence intensity associated with the oligodendrocytes decreased and completely disappeared at t=3.5 hours. Addition of KCl or EDTA in the incubation medium significantly hindered the interaction with cells. In contrast, the elimination of membrane proteins from UCV did not perturb cell labeling. A specific role of PLP was suggested since UCV loaded with a soluble protein (BSA_F) led to a weak cell labeling.Abbreviations IAF 5-iodacetamidofluorescein - BSA bovine serum albumin - BSA BSA labelled with IAF - PLP proteolipid apoprotein - PLP_F aqueous form of PLP tagged with IAF - CV coated vesicles - UCV uncoated vesicles - UCV^*PLP_F UCV loaded with PLP_F - MV model vesicles This work was suported by Cnrs and INSERM.     

Myelin changes induced by incubation of brain slices with serum

Forebrain and brain stem slices prepared from adult rats were incubated with pooled normal human serum. Following the incubation, the tissue was homogenized and the fraction floating on 0.32 M sucrose as well as two myelin subfractions (light and heavy) were isolated. Addition of serum into the incubation medium increased generation of the floating fraction by the cerebral slices. Changes in the myelin membrane were also observed. Thus, myelin isolated from forebrain slices revealed pronounced increase in the buoyant density of its particles and loss of basic protein. Furthermore, in spite of the intensive washing employed during the isolation procedure, some serum proteins were found firmly attached to the membraneous fractions. The demonstration of the myelin alterations in the living cerebral tissue exposed to serum during incubation may contribute to understanding the pathogenesis of multiple sclerosis.     

Acylation of myelin proteolipid protein in subcellular fractions of rat brainstem

The acylation of myelin proteolipid protein (PLP) and intermediate protein (IP) was investigated in an in vitro system of tissue slices prepared from actively myelinating rat brainstem. The incorporation of [³H]palmitate into the proteins in nine subcellular fractions including myelin and other cellular membranes which are actively involved in the synthesis and intracellular transport of the proteins was measured. More than 80% of [³H]palmitate-labeled proteins were recovered in myelin. The incorporation was highest in the heavy myelin and lowest in the light myelin subfraction. Appreciable acylation was also detected in the myelin-like fraction. On the other hand, the remaining fractions comprising a variety of endo- and ectomembranes, which harbored over 90% of newly synthesized PLP and IP as seen from [³H]leucine labeling showed practically no [³H]palmitate incorporation. The results indicate that the acylation of PLP and IP is a late event in their posttranslational processing and occurs only at their entry into the myelin sheath.     

In vitro acylation of myelin PLP and DM-20 in the quaking mouse brain

Both proteolipid proteins (PLP) and DM-20 were found to be present by the immunoblot technique in myelin isolated from quaking mouse brain; however, the relative concentration of these proteins in myelin from quaking brain was substantially reduced when compared to the control. Brain slices from littermate control and quaking mice were incubated with [³H]palmitic acid to determine the incorporation of fatty acid into myelin proteolipid proteins. Fluorography of gels containing myelin proteins from control and quaking mice brain revealed that both PLP and DM-20 were acylated. The incorporation of [³H]palmitic acid into quaking myelin PLP and DM-20 was reduced by 75% and 20% respectively of those in control brain. The significance of differential acylation of quaking myelin PLP and DM-20 is discussed with respect to availability of non-acylated pools of proteolipid proteins and the activities of acylating enzymes.     

Proteolipid/DM-20 proteins bearing the paralytic tremor mutation in peripheral nerves and transfected Cos-7 cells

Paralytic tremor (Plp-pt) is a missense mutation of the myelin proteolipid gene (Plp) in rabbits. The myelin yield in the Plp-pt brain is reduced and the protein and lipid composition of central nervous system (CNS) myelin is abnormal. We studied the intracellular transport of the normal and Plp-pt mutant PLP and DM-20 in transiently transfected Cos-7 cells. While the mutant PLP accumulates in the rough endoplasmic reticulum and does not reach the plasma membrane, the spliced isoform of PLP, mutant DM-20, is normally transported to the cell surface and integrated into the membrane. Analysis of rabbit sciatic nerves revealed that concentration of peripheral nervous system (PNS) myelin proteins is normal in Plp-pt myelin. In the PNS like in the CNS, the level of Plp gene products is subnormal. But this does not affect myelination, in the PNS where PLP, present in low concentration, is not a structural component of compact myelin. The normal level of Plp gene expression in Schwann cells is low and these results suggest that, in the Plp-pt PNS, Schwann cell function is not affected by the deficiency in PLP and/or the impairment of intracellular PLP transport. Special issue dedicated to Dr Marion E. Smith.     

Autoacylation of myelin proteolipid protein with acyl coenzyme A

Rat brain myelin proteolipid protein (PLP) is known to contain long chain, covalently bound fatty acids. In the course of characterizing the mechanism of acylation, we found that the isolated PLP, in the absence of any membrane fraction, was esterified after incubation with [3H]palmitoyl coenzyme A (CoA). This observation demonstrated that the protein acts as both an acylating enzyme and an acceptor. Thus, acylation occurs by an autocatalytic process. The possibility of a separate acyltransferase that copurifies with PLP was essentially excluded by adding brain subcellular fractions to the reaction mixtures and by changing the isolation procedure. After deacylation, the protein was acylated at a 4-fold greater rate, suggesting that the original sites were reacylated. The palmitoyl-CoA concentration followed Michaelis kinetics, confirming that spontaneous acylation was not occurring. Pulse-chase experiments indicated that the reaction entails net addition of acyl groups. Although fatty acids are bound via an O-ester linkage, free SH groups are required in the reaction. Denaturation of the protein by sodium dodecyl sulfate or heat inhibits the reaction, whereas cerulenin has little or no effect. PO, the major protein in peripheral nerve myelin, is also an acylated protein, but it was not labeled upon incubation of either peripheral myelin or the isolated protein with [3H]palmitoyl-CoA, demonstrating that it is acylated by a different route. Several synthetic peptides derived from PLP sequences with sites known to be acylated in vivo as well as a series of deacylated PLP tryptic peptides were not labeled, indicating that integrity of the protein is required for acylation. Limited proteolysis and peptide mapping showed that the same sites are acylated in vitro or in vivo, suggesting that the autocatalytic acylation reaction is physiological.