Glycosphingolipids of Human Peripheral Nervous System Myelins Isolated from Cauda Equina

Abstract: Compositions of neutral and sulfated glucuronyl glycosphingolipids purified from human motor and sensory nerves and myelins were studied. Higher neutral glycosphingolipids (fraction B), which were separated from GazlCer (fraction A), were analyzed by TLC and TLC-immunostaining. Both nerve myelins contained paragloboside (nLc₄Cer) and nLc₆Cer dominantly as major higher glycosphingolipids and very little globoside (Gb₄Cer), whereas both nerves contained Gb₄Cer and nLc₄Cer. Besides these major glycosphingolipids, a neutral glycolipid containing asialoGMI (Gg₄Cer) epitope and other minor components such as ceramide trihexoside and ceramide dihexoside were detected in both nerves and their myelins. Furthermore, sulfated glucuronyl nLc₄Cer and n Lc₆Cer, which were monoclonal antibody HNK-1 reactive glycolipids, were detected in both nerves and myelins.     

Myelin Gangliosides: An Unusual Pattern in the Avian Central Nervous System

Abstract: Gangliosides were isolated from purified myelin obtained from brain and spinal cord of mature chickens and pigeons. Total concentrations were approximately two- to fivefold greater than for previously reported mammalian species, and their patterns also differed in containing significantly more sialosylgalactosylceramide (G_M4). The latter comprised one-third to one-fourth of total myelin ganglioside, approximately equivalent to G_M1 (II³NeuNAc-GgOse₄Cer). As in mammals, G_M4 of avian CNS appeared to be localized in myelin. Fatty acids of this ganglioside included both the hydroxy- and unsubstituted types. and, long-chain bases were almost entirely C₁₈. Ganglioside G_M1 split into two closely migrating bands on TLC, the slower of which resembled mammalian G_M1 in having stearate as the main fatty acid with a measurable amount (10%) of C₂₀-sphingosine; the faster band had predominantly longer-chain fatty acids and very little C₂₀-sphingosine.     

Subcellular Fractionation of Rat Sciatic Nerve and Specific Localization of Ganglioside LM1 in Rat Nerve Myelin

Subcellular fractionation of rat sciatic nerve was developed to determine the specific localization of gangliosides in the nerve membrane fractions. Myelin, microsomal, and a plasma membrane-like fraction were isolated and purified by sucrose density gradient centrifugation. These subfractions were characterized by electron microscopy, marker enzyme assays, and their protein and lipid profile. In rat sciatic nerve myelin, 90 mol% of the total gangliosides were monosialogangliosides. LM1 (sialosyl-lactoneotetraosylceramide) (61 mol%) and GM3 (21%) were the major gangliosides of the rat nerve myelin. Two other neolacto series of gangliosides, viz., sialosyl-lactoneonorhexaosylceramide and sialosyl-lactoneooctaosylceramide, were also localized mostly in the myelin fraction. GM1 was only a minor (less than 2%) ganglioside in myelin. The ganglioside patterns of the microsomal and plasma membrane-like fractions were similar with minor quantitative differences and were entirely different from that of myelin. Monosialogangliosides were approximately 70-75 mol% of the total in these fractions. The major gangliosides of the microsomal and plasma membrane-like fractions were GM3 (approximately 40%) and GM1 (approximately 20%). LM1 in these fractions was minimal (less than approximately 5%). Significant amounts of GM3 with N-glycolylneuraminic acid (approximately 10%) and GM1b (4-14%) were also identified in the microsomal and plasma membrane-like fractions but not in myelin. These and the higher lactoneo series of gangliosides have not been previously reported to be present in the rat nervous system. Almost exclusive localization of LM1 in myelin in rat peripheral nervous system is consistent with our previous observation that deposition of LM1 in the nerve with age was very similar to that of myelin marker lipids cerebrosides and sulfatides.     

Myelin Gangliosides in Vertebrates

Abstract: A phylogenetic survey of brain myelin ganglioside patterns and concentrations has been carried out on 16 vertebrate species. Gangliosides were isolated from purified myelin and found to vary in concentration from 25 μg of sialic acid per 100 mg of myeh for goldfish to a value of 395 for turkey. The latter species had approximately equivalent amounts of G_M1 and G_M4 as the two major gangliosides. The 11 mammals studied all had G_M1 as the major ganglioside, with variable amounts of G_M4; rhesus monkey and human had 20-25% G_M4, whereas the others had less than 10%. Amphibia and fish myelin contained the least total ganglioside, with patterns that showed relatively little G_M1 and no detectable G_M4. Alligator myelin was unique in having a total concentration as high as the avian species, but a pattern with predominantly diand trisialo gangliosides.     

Composition and Metabolism of Gangliosides in Rat Peripheral Nervous System During Development

Abstract: Ganglioside composition of rat trigeminal nerve was studied during development in order to understand the changes that occur as a result of cellular differentiation in the nerve. The ganglioside composition of the trigeminal nerve was entirely different from that of brain. The major gangliosides in adult trigeminal nerve were GM₃, GD₃, and LM₁ (sialosyl-lactoneotetraosylceramide or sialosylparagloboside). The structure of LM₁ and other gangliosides was established by enzymatic degradation and by analysis of the products of acid hydrolysis. At 2 days after birth, when the Schwann cells were immature, GM₃ and GD₃ were the major gangliosides in the nerve, 50 and 18 mol %, respectively. As the nerve developed and Schwann cells proliferated and myelinated the axons, the mol % of GM₃ and GD₃ reduced and that of LM₁ steadily increased. Polysialogangliosides did not change drastically with nerve development. The rate of deposition of LM₁ in the nerve with age was very similar to that of myelin marker lipids, cerebrosides, and sulfatides; thus, deposition appears to be localized mainly in the rat nerve myelin. LM₁ also had long-chain fatty acids 22:0 and 24:0, which are not usually found in CNS gangliosides. The ganglioside pattern of the rat trigeminal nerve was very similar to that of rat sciatic nerve, but was different from that of rabbit and chicken sciatic nerve. The activity of the two key enzymes involved in the metabolism of GM₃, viz., CMP-N-acetylneuraminic acid:lactosylceramide sialyltransferase and UDP-N-acetylgalactosamine:GM₃-N-acetylgalactosaminyltransferase, was also studied during development of the nerve and brain. The developmental profiles of both enzymes were consistent with the amounts of GM₃ present in the nerve.     

Enzymatic Regulation of Glycoprotein Synthesis in Peripheral Nervous System Myelin

The enzyme UDP-N-acetylglucosamine: dolichyl phosphate, N-acetylglucosamine-1-phosphate transferase initiates the synthesis of the oligosaccharide chain of complex-type glycoproteins. In view of the high content of glycoprotein in peripheral nerve myelin, the properties of this enzyme, its changes with age, and the effect of the specific inhibitor tunicamycin were investigated. The enzyme activity in rat peripheral nerve homogenate was completely dependent on the presence of exogenous dolichyl phosphate as well as Mg2+ and a detergent (Triton X-100) and was also greatly stimulated by a high salt concentration (0.4 M KCl) and AMP. The highest specific activity was present in the postmitochondrial membranes. The specific activity in postmitochondrial membranes in the presence of exogenous dolichyl phosphate reached a maximum at 17 days and remained relatively high throughout development, up to 2 years of age, but the activity was much lower when dolichyl phosphate was not added. This indicates that the enzyme level does not decrease with age, but that the content of the lipid cofactor may limit glycoprotein synthesis in vivo. Tunicamycin (5 micrograms) was injected intraneurally into 24-day-old rat sciatic nerve, and the enzyme was assayed from 1 to 24 days after injection. The specific activity of the transferase remained at low levels (5-40% of the level in control nerve) in most injected nerves assayed throughout this postinjection period. A protein previously identified as the unglycosylated P0 protein was synthesized in vitro by the tunicamycin-injected nerve and could be demonstrated to be incorporated into myelin in large amounts at 2 days and in small amounts at 6 days after injection.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunochemical Characterization of Peripheral Nervous System Myelin 170,000-Mr Glycoprotein

A recently described 170,000-Mr glycoprotein, specific to peripheral nervous system (PNS) myelin, was purified from rat PNS myelin by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis and used to immunize guinea pigs and rabbits. The resultant antisera proved specific for 170,000-Mr glycoprotein by enzyme-linked immunosorbent assay, by immunoprecipitation of the appropriate peptide from solubilized PNS myelin, and by immunoblot analysis of rat PNS myelin. The anti-rat 170,000-Mr glycoprotein antisera cross-reacted with proteins of similar molecular weight in human and bovine PNS myelin, but such proteins were not detected in human or rat CNS myelin or other rat tissues. The 170,000-Mr glycoprotein was also detected by this immunoblot procedure in recently isolated rat Schwann cells but not in those kept in culture for greater than or equal to 3 days. By indirect immunofluorescent microscopy, anti-rat 170,000-Mr glycoprotein antibody bound to rat PNS myelin sheaths but not to other rat tissues. Together, these studies indicate the 170,000-Mr glycoprotein is specific to PNS myelin of several species and that a neuronal influence may be required for its expression by Schwann cells.     

Peripheral Nervous System Myelin and Schwann Cell Glycoproteins: Identification by Lectin Binding and Partial Purification of a Peripheral Nervous System Myelin-Specific 170,000 Molecular Weight Glycoprotein

Radioiodinated lectins were used to detect glycoproteins of peripheral nervous system (PNS) myelin (rat, human, bovine) and cultured rat Schwann cells. Proteins were resolved by sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis and transferred to nitrocellulose filters. The filters were overlaid with radioiodinated lectins of known saccharide affinities. These included concanavalin A, Helix pomatia, Limulus polyphemus, Maclura pomifera, peanut, soybean, Ulex europaeus, and wheat germ agglutinins. Inclusion of the appropriate monosaccharide in the overlay solution (0.2 M) inhibited lectin binding to the nitrocellulose-fixed proteins. Fluorography permitted identification of 26 myelin glycoproteins and many more in Schwann cells. All lectins labeled a band present in myelin, but not Schwann cells, corresponding to the major PNS myelin protein, P0. Our attention focused on a high-molecular-weight myelin glycoprotein [apparent molecular weight (Mr) 170,000], which appeared abundant by Coomassie Blue staining and which was heavily labeled by all lectins except concanavalin A. A protein with approximately this Mr and lectin-binding pattern was present in human and bovine PNS myelin as well, but not detected in rat Schwann cells, CNS myelin, liver and fibroblast homogenates, or cultured bovine oligodendroglia. Hence this 170,000 Mr glycoprotein is apparently unique to PNS myelin.     

Regulation of Oleoyl-CoA Synthesis in the Peripheral Nervous System: Demonstration of a Link with Myelin Synthesis

Abstract: We studied the regulation of oleic acid synthesis in the PNS. During mouse postnatal development, the proportion of 18:1 rises in the sciatic nerve from 17% at 5 days of age to 33% at 25 days. However, this rise does not occur in the dysmyelinating mutant mouse trembler. In normal mouse development, the total stearoyl-CoA desaturase (SCD) activity measured in sciatic nerve homogenates is high during the first 3 weeks. Yet in trembler nerves, this SCD activity represents only 15% of normal values. Using the RT-PCR technique, we demonstrate that the SCD2 isoform is predominantly expressed in the PNS. Northern blot analysis showed that the mRNA levels for SCD2 parallel those of other specific myelin proteins in both normal mouse and trembler mutant development. Similar experiments in a rat demyelination-remyelination model confirmed that SCD2 mRNA levels are regulated in the PNS in a similar manner to myelin-specific proteins.     

Characterization and Regional Distribution of Individual Gangliosides in Goldfish Central Nervous System

Gangliosides were partially purified from goldfish brain and fractionated by DEAE Fractogel column chromatography. Each fraction was then analyzed by HPTLC and also by HPLC after conversion of the gangliosides to 2,4-dinitrophenylhydrazides. The tetrasialoganglioside GQ1c was found to constitute more than 50% of the total gangliosides. Gangliosides in smaller quantities were also tentatively identified. These included GT1b, GT1c, GT2, GT3, GD1a, and several others. By using this information, the amounts of individual gangliosides in various regions of goldfish central nervous system were compared. Although all areas of brain examined contained similar concentrations of gangliosides, with GQ1c as the predominant component, retina and optic nerve contained significantly lower concentrations of GQ1c, and GM3 was the major component.     

Bovine Peripheral Nervous System Myelin P2 Protein: Chemical and Immunological Characterization of the Cyanogen Bromide Peptides

Cleavage of bovine P2 protein by cyanogen bromide (CNBr) produced peptide fractions CN1, CN2, and CN3 which were isolated by gel filtration chromatography. CN2 was found to contain two NH2-terminals (lysine and valine) and accounted for both of the cysteine residues of P2. When reduced carboxymethylated P2 (RCM-P2) was digested with CNBr, peptides CN1 and CN3 were obtained as were (1) a peptide with NH2-terminal lysine (Lys) that contained no homoserine and only one cysteine residue and (2) a peptide with NH2-terminal valine (Val) that was co-eluted with CN3. These data and the chemical characterization of all the CNBr peptides obtained from P2 and RCM-P2 suggest that isolated P2 protein has a structure composed of the CNBr peptides in the order CN3-CN1-CN2(Val)-CN2(Lys) with an intrachain disulfide bond between the cysteine residues located in the two constituent peptides of CN2, CN2(Lys) and CN2(Val). To locate the neuritogenic region(s) within the P2 protein structure, CN1, CN2, and CN3 were tested for the ability to induced experimental allergic neuritis (EAN) in Lewis rats. The disease-inducing sites of P2 protein were found only in CN1; neither CN2 nor CN3 produced disease. EAN induced by CN1 was comparable to that induced with P2 protein as determined by disease onset, clinical symptoms, and histologic lesions.     

Metabolism of Phosphate and Sulfate Groups Modifying the P0 Protein of Peripheral Nervous System Myelin

We have examined the metabolism of phosphate and sulfate groups modifying the P0 protein, the major protein of peripheral nervous system myelin, using an in vitro incubation system. Incorporation of [3H]leucine into the P0 peptide backbone decreased approximately 25-fold between 10 and 90 days of age, a finding reflecting a decreased rate of myelin synthesis in the older animals. In contrast, incorporation of [32P]phosphate into P0 decreased only four- to fivefold, a result indicating that phosphate groups are metabolized independently of the peptide backbone. Developmental decreases in the incorporation of sulfate groups into P0 were similar to those seen for leucine, an observation suggesting that this modifying group is metabolized together with the peptide backbone as a single metabolic entity. The time course of labeling of P0 isolated from the starting homogenate and from myelin was also compared. Results are consistent with sulfation of P0 protein taking place before insertion of newly synthesized P0 into myelin. In contrast, incorporation of phosphate into P0 appears to involve both the newly synthesized pool and the preexisting pool of P0 in myelin. Presumably, entry of phosphate into P0 in myelin involves turnover of preexisting phosphate groups and rephosphorylation by myelin protein kinases. Developmental decreases in the specific activity of P0 phosphate groups in myelin are consistent with the presence of a small, rapidly turning-over pool of phosphorylated P0 (perhaps associated with the axon-myelin interface), which does not increase to the same extent as the marked increase in bulk myelin that occurs during development.     

Age-Related Changes of Myelin Proteins in the Rat Peripheral Nervous System

Age-related changes in amounts of myelin proteins from rat sciatic nerve or spinal root were analyzed by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE). In the aged peripheral nerve myelin, the relative amounts of band 105K and proteins X and Y increased, whereas those of proteins P0 and P1 and band 190K decreased. Band 105K purified by preparative SDS-PAGE exhibited three bands of 105K, 28K, and 21K at the second electrophoresis. A repeated SDS-PAGE did not improve the purity of bank 105K, but increased the ratio of 21K to 28K. Compared with P0 protein, band 105K has a very similar peptide map pattern and amino acid composition, as well as the identical NH2 terminal residue, isoleucine. These findings suggest that band 105K is an aggregate form of P0 protein and its fragment, 21K. The 21K protein is a distinct entity from X protein. The quantitative and qualitative alterations in myelin proteins, as we report here, may reflect continuing demyelination and remyelination in aged peripheral nerves.     

Spontaneous and Experimental Neuritis and the Distribution of the Myelin Protein P2 in the Nervous System

The P2 contents of nervous tissues from the human, rabbit, guinea pig, and Lewis rat were measured by radioimmunoassay. The ventral spinal roots contained more P2 than any other tissue. Human dorsal roots and peripheral nerves contained 41-65% of the amount in human ventral roots. Human olfactory and optic nerves and brain contained 1.1-2.7%, spinal cord, 2.8%, cranial nerve VIII, 11%, and cerebral grey matter, 0%. The relative amounts in the rabbit nervous system were similar except that the spinal cord contained 20% of the amount in the ventral roots. Qualitative estimates in the guinea pig showed that the spinal roots and peripheral nerves contained more P2 than the spinal cord, and that none was present in the brain. In the Lewis rat, P2 could be detected in the spinal roots and peripheral nerves but not in the CNS. The distribution of P2 in the human nervous system parallels the incidence and severity of lesions in acute polyradiculoneuritis. It also explains the absence of any lesions in the CNS when experimental allergic neuritis is induced in the Lewis rat.     

Biochemical Demonstration of the Myelin-Associated Glycoprotein in the Peripheral Nervous System

Abstract: Recent immunocytochemical studies indicated that the myelin-associated glycoprotein (MAG) is localized in the periaxonal region of central nervous system (CNS) and peripheral nervous system (PNS) myelin sheaths but previous biochemical studies had not demonstrated the presence of MAG in peripheral nerve. The glycoproteins in rat sciatic nerves were heavily labeled by injection of [³H]fucose in order to re-examine whether MAG could be detected chemically in peripheral nerve. Myelin and a myelin-related fraction, WI, were isolated from the nerves. Labeled glycoproteins in the PNS fractions were extracted by the lithium diiodosalicylate (LIS)-phenol procedure, and the extracts were treated with antiserum prepared to CNS MAG in a double antibody precipitation. This resulted in the immune precipitation of a single [³H]fucose-labeled glycoprotein with electrophoretic mobility very similar to that of [¹⁴C]fucose-labeled MAG from rat brain. A sensitive peptide mapping procedure involving iodination with Bolton-Hunter reagent and autoradiography was used to compare the peptide maps generated by limited proteolysis from this PNS component and CNS MAG. The peptide maps produced by three distinct proteases were virtually identical for the two glycoproteins, showing that the PNS glycoprotein is MAG. The MAG in the PNS myelin and Wl fractions was also demonstrated by Coomassie blue and periodic acid-Schiff staining of gels on which the whole US-phenol extracts were electrophoresed, and densitometric scanning of the gels indicated that both fractions contained substantially less MAG than purified rat brain myelin. The presence of MAG in the periaxonal region of both peripheral and central myelin sheaths is consistent with a similar involvement of this glycoprotein in axon-sheath cell interactions in the PNS and CNS.     

Bony Fish Myelin: Evidence for Common Major Structural Glycoproteins in Central and Peripheral Myelin of Trout

Peripheral nervous system (PNS) myelin from the rainbow trout (Salmo gairdneri) banded at a density of 0.38 M sucrose. The main myelin proteins consisted of (1) two basic proteins, BPa and BPb (11,500 and 13,000 MW, similar to those of trout central nervous system (CNS) myelin proteins BP1 and BP2), and (2) two glycosylated components, IPb (24,400 MW) and IPc (26,200 MW). IPc comigrated with trout CNS myelin protein IP2 in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, whereas trout CNS myelin protein IP1 had a lower molecular weight (23,000). Following two-dimensional separation, however, both IPb and IPc from PNS showed two components; the more acidic component of IPc comigrated with IP2 from CNS. PNS tissue autolysis led to the formation of IPa (20,000 MW), consisting of two components in isoelectric focusing of which again the more acidic one comigrated with the CNS autolysis product IP0. Limited enzymatic digestion of isolated IP proteins from PNS and CNS led to closely similar degradation patterns, being most pronounced in the case of IP2 and IPc. Immunoblotting revealed that all IP components from trout PNS and CNS myelins reacted with antibodies to trout IP1 (CNS) and bovine P0 protein (PNS) whereas antibodies to rat PLP (CNS) were entirely unreactive. All BP components from trout PNS and CNS myelins bound to antibodies against human myelin basic protein. On the basis of these studies trout PNS and CNS myelins contain at least one common IP glycoprotein, whereas other members of the IP myelin protein family appear closely related. In the CNS myelin of trout the IP components appear to replace PLP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Connexin43 Is Another Gap Junction Protein in the Peripheral Nervous System

Abstract: That many cells express more than one connexin (Cx) led us to examine whether Cxs other than Cx32 are expressed in the PNS. In addition to Cx32 mRNA, Cx43 and Cx26 mRNAs were detected in rat sciatic nerve by northern blot analysis. Cx43 mRNA, but not Cx26 mRNA, was expressed in both the primary Schwann cell culture and immortalized Schwann cell line (T93). The steady-state levels of the Cx43 mRNA in the primary Schwann cell culture increased 2.0-fold with 100 µ M forskolin, whereas that of P₀ increased 7.0-fold. Immunoreactivity to Cx43 was detected on western blots of cultured Schwann cells, T93 cells, and sciatic nerves but not on blots of PNS myelin. Immunohistochemical study using human peripheral nerves revealed that anti-Cx43 antibody stained cytoplasm around nucleus of Schwann cells but not myelin, confirming western blot results. Although P₀ expression was markedly decreased by crush injury of the sciatic nerves, Cx43 expression showed no apparent change. Developmental profiles showed that Cx43 expression in the sciatic nerve increased rapidly after birth, peaked at about postnatal day 6, and then decreased gradually to a low level. In adult rats, the Cx43 mRNA value was much lower than that of Cx32. These findings suggest that Cx43 is localized in Schwann cell bodies and that, compared with P₀, its expression is less influenced by axonal contact and cyclic AMP levels. The high expression on postnatal day 6 indicates that Cx43 may be related to PNS myelination. Cx43 is another gap junction, but its function appears to differ from that of Cx32, as judged by the differences in their localization and developmental profiles.     

Distribution of the 75-kD Low-Affinity Nerve Growth Factor Receptor in the Primate Peripheral Nervous System

Disruption of the 75-kD low-affinity nerve growth factor (NGF) receptor (p75) has been shown to result in sensory and sympathetic nervous system deficits (Lee et al., 1992a,b). In order to establish precisely which subsets of neurons are capable of responding to neurotrophins (NTs) through the low-affinity NGF receptor, p75 was localized in the primate autonomic and somatic sensory nervous systems. In the autonomic system, cell bodies of some parasympathetic and enteric neurons expressed detectable levels of p75, whereas all sympathetic neurons expressed the protein. In the sensory system, some, but not all, cell bodies were labeled in cranial and spinal sensory ganglia and in the mesencephalic nucleus. Some peripheral and central projections of the sensory neurons were also labeled. Centrally, most of the labeled processes were found in regions containing primarily small unmyelinated fibers, including lamina II of Rexed and areas of the solitary tract and nucleus. Peripherally, labeled processes were associated with unmyelinated nerves and specialized structures such as taste buds and Meissner corpuscles, but not with myelinated processes. This study indicates that the subset of neurons in the autonomic nervous system likely to be capable of responding to neurotrophins is broader than generally thought, and that p75-ex-pressing neurons tend to be clustered. Moreover, in the sensory nervous system p75 is expressed by most cell bodies, but expression in their projections is restricted both peripherally and centrally to unmyelinated processes and nerve terminals.     

Mouse Forward Genetics in the Study of the Peripheral Nervous System and Human Peripheral Neuropathy

Forward genetics, the phenotype-driven approach to investigating gene identity and function, has a long history in mouse genetics. Random mutations in the mouse transcend bias about gene function and provide avenues towards unique discoveries. The study of the peripheral nervous system is no exception; from historical strains such as the trembler mouse, which led to the identification of PMP22 as a human disease gene causing multiple forms of peripheral neuropathy, to the more recent identification of the claw paw and sprawling mutations, forward genetics has long been a tool for probing the physiology, pathogenesis, and genetics of the PNS. Even as spontaneous and mutagenized mice continue to enable the identification of novel genes, provide allelic series for detailed functional studies, and generate models useful for clinical research, new methods, such as the piggyBac transposon, are being developed to further harness the power of forward genetics. Special issue article in honor of Dr. George DeVries.     

Activation of Complement by Myelin: Identification of C1-Binding Proteins of Human Myelin from Central Nervous Tissue

Myelin isolated from central nervous tissue activates the classic pathway of complement by directly activating C1. Activation of C1 can proceed to form membrane attack complex, C5b-9, in the myelin. Such an interaction between myelin and complement may be important in diseases involving myelin damage, in view of the role of complement in membrane attack and inflammation. To identify the C1-activating protein, myelin was subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and Western blot. The blots were incubated with C1 or with whole serum complement, followed by immunostaining for C1 or C3, respectively. A duplicate strip was stained with amido black or anti-myelin antibody to visualize the myelin proteins. The results showed that two major protein bands were capable of activating C1. An approximately 56-58-kilodalton band comigrated with the W2 protein and an approximately 45-47-kilodalton band migrated along with, but slightly behind, the W1 Wolfgram doublet.