Purification of P0 Myelin Glycoprotein by a Cu2+-Immobilized Metal Affinity Chromatography

P0 is an abundant myelin glycoprotein of peripheral nerves of vertebrates. Various point mutations of this protein are responsible for hereditary neuropathies. In this paper we described purification of P0 glycoprotein using SDS and a metal chelate affinity chromatography. Purified myelin fraction from bovine spinal roots in 0.5% SDS, 0.5 M NaCl, 50 mM Tris-HCl, pH 7.4 is filtered and applied directly to the Cu²⁺-immobilized affinity chromatography column, equilibrated with the same buffer. After eluting a void volume (or pass through) fraction, P0 protein was eluted by the same buffer but without salt. To remove contamination from the eluent, further purification is continued on a Concanavalin-A coupled agarose column. We purify within two days, 30 mg of P0 protein of apparent molecular weight 27 kDa. The method can be used to purify recombinant or mutated P0 protein found in severe pathologies.     

IMMUNOCHEMICAL AND BIOCHEMICAL STUDIES DEMONSTRATING THE IDENTITY OF A BOVINE SPINAL CORD PROTEIN (SCP) AND A BASIC PROTEIN OF BOVINE PERIPHERAL MYELIN (BF)

A protein extracted from bovine peripheral myelin (BF) and a protein extracted from bovine spinal cord (SCP) have been shown to be identical: the proteins cross-react immunochemicaliy with each other but not with highly purified CNS myelin basic protein. Neither BF nor SCP have anti-encephalitogenic activity. Their electrophoretic behavior is the same at three different pH values. Their apparent molecular weight by sodium dodecyl sulfate-gel electrophoresis is 13,800 ± 550. The amino acid compositions of the proteins are essentially identical. BF and SCP each contain 2 cysteine residues and have valine at the C terminus. The 23 major tryptic peptides are identical on peptide maps. Circular dichroic analyses yield essentially identical curves, which, when computed by best-fit curve analysis, indicate that each has 0%α helix and a large percentage of β structure.     

Further characterization of the anti-encephalitogenic protein (SCP): isolation from bovine spinal cord and spinal roots.

The three molecular forms of the anti-encephalitogenic protein, beta-SCP, gamma-SCP, and SCP-peptide were isolated in higher yield by a shortened procedure, which involved 1) extraction of bovine spinal cord (BSC) or bovine spinal roots (BSR) with 0.05 M sodium acetate buffer, pH 4.5, 2) batch absorption on CM-52 cellulose, 3) stepwise elution with sodium acetate buffers, pH 5.8, containing increasing concentrations of sodium chloride and finally, 4) removal of trace contaminants by gel-exclusion chromatography on Sephadex G-50 superfine. The m.w. of the purified proteins determined by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis was 13,200 daltons. The same value for the molecular sizes was obtained by gel-exclusion chromatography by using 0.1% SDS in 0.05M sodium chloride as eluant. In the absence of SDS the molecular sizes estimated by gel exclusion chromatography ranged from 14,000 to 18,500. The amino acid compositions of the beta-SCP and gamma-SCP from BSC and BSR were similar except that beta-SCP from BSR lacked half-cystine whereas gamma-SCP from BSR contained three times as much half-cystine as the SCP forms prepared from BSC. All forms of SCP showed reactions of identity when compared by immunodiffusion analyses with a rabbit anti-bovine SCP serum; none formed precipitin lines with a rabbit anti-bovine myelin basic protein (MyBP) serum.     

The complete amino acid sequence of the rabbit P2 protein

P2 protein is a small basic protein (Mr = 14,820) found in peripheral nerve myelin and spinal cord myelin. There is now overwhelming evidence that P2 protein is the crucial antigen involved in the induction of experimental allergic neuritis, an autoimmune disease of the peripheral nervous system. The complete amino acid sequence of rabbit P2 protein was derived by sequence analysis of cyanogen bromide peptides and peptides obtained by proteolysis using Staphylococcus aureus V8 enzyme, trypsin, or clostripain. There are 131 amino acids and an excess of the basic amino acids lysine and arginine; histidine is absent. There are 3 highly hydrophobic regions in the P2 molecule. Probability analysis of the sequence predicts a high degree of beta structure, essentially in agreement with CD data.     

Characterization of a cloned cDNA encoding rabbit myelin P2 protein

Myelin P2 is a 14,800-Da cytosolic protein found in rabbit sciatic nerves. It belongs to a family of fatty acid binding proteins and shows a 72% amino acid sequence similarity to aP2/422, the adipocyte lipid binding protein, a 58% sequence similarity to rat heart fatty acid binding protein, and a 40% sequence similarity to cellular retinoic acid binding protein. In order to isolate cDNA clones representing P2, a cDNA library was constructed from poly(A+) RNA isolated from sciatic nerves of 10-day-old rabbit pups. By use of a mixed synthetic oligonucleotide probe based on the rabbit P2 amino sequence, 12 cDNA clones were selected from about 25,000 recombinants. Four of these were further characterized. They contained an open reading frame, which when translated, agreed at 128 out of 131 residues with the known rabbit P2 amino acid sequence. These cDNAs recognize a 1.9-kilobase mRNA present in sciatic nerve, spinal cord, and brain, but not present in liver or heart. The levels of P2 mRNA parallel myelin formation in sciatic nerve and spinal cord with maximal amounts being detected at about 15 postnatal days. This initial study will allow characterization of the P2 gene and its regulation, as well as further studies into the role of P2, the first metabolically active myelin-specific protein to be characterized at the genetic level.     

Isolation and sequence determination of cDNA encoding P2 protein of human peripheral myelin.

A full length cDNA of P2 protein of peripheral myelin has been isolated from a cDNA library of human fetus spinal cord. The clone is 2150 base pairs (bp) in length and contains a 393 bp open reading frame encoding a polypeptide of 131 residues. The deduced amino acid sequence is highly homologous to P2 protein from other species.     

Distribution of Myelin Basic Protein and P2 mRNAs in Rabbit Spinal Cord Oligodendrocytes

Myelin basic protein (MBP) and P2 protein are small positively charged proteins found in oligodendrocytes of rabbit spinal cord. Both proteins become incorporated into compact myelin. We have begun investigations into the mechanisms by which MBP and P2 become incorporated into the myelin membrane. We find that P2, like the MBPs, is synthesized on free polysomes in rabbit spinal cord. Cell fractionation experiments reveal that rabbit MBP mRNAs are preferentially segregated to the peripheral myelinating regions whereas P2 mRNAs are predominantly localized within the perikaryon of the cell. In vitro synthesized rabbit MBP readily associates with membranes added to translation mixtures, whereas P2 protein does not. It is possible that P2 requires a "receptor" molecule, perhaps a membrane-anchored protein, for association with the cytoplasmic face of the myelin membrane.     

Crystals of P2 myelin protein in lipid-bound form

The P2 protein of peripheral nervous system myelin induces experimental allergic neuritis in rats, a model of Guillain-Barré syndrome in humans. Previous purification procedures have used acid extraction to obtain the protein in lipid-free form (LF-P2). Here, we have purified the P2 protein in lipid-bound form (LB-P2) by extracting myelin with the detergent CHAPS, followed by Cu(2+)-affinity column chromatography. All myelin lipids were present in the preparation as shown by high-performance thin-layer chromatography and mass spectrometry. The LB-P2 preparation, which differs from LF-P2 in solubility and in the secondary-structure composition, was dialyzed to remove unbound lipids and excess detergent and crystallized using the hanging-drop vapor diffusion technique. Crystals of lipid-bound P2 appeared usually very reproducibly within 2 weeks at pH 5.7 in polyethylene glycol 6000 (PEG6000) at concentrations of 20-30% (w/v), and larger crystals were obtained by additional sitting-drop crystallization. X-ray diffraction showed reflections up to 2.7A. The crystallization conditions (25-30% PEG6000, pH 5.0) and the unit cell dimensions (a = 94.5A, b = 94.5A, c=74.2A, alpha = beta = 90 degrees, gamma = 120 degrees ) of LB-P2 were different from those earlier described for LF-P2 (10% PEG4000, pH 3, and unit cell dimensions a = 91.8A, b = 99.5A, c = 56.5A, alpha = beta = gamma = 90.0 degrees ). It is important that P2 has been crystallized with specifically bound lipids; therefore, solving this new crystal structure will reveal details of this protein's behavior and role in the myelin sheath.     

The P2 protein of bovine root myelin: partial chemical characterization.

The P2 protein of bovine root myelin has chemical characteristics which differentiate it from other myelin basic proteins. The tryptic peptide map of the bovine P2 protein is distinctly different from the map of either the rabbit PI protein or the bovine CNS myelin basic protein. The tryptic peptides of the P2 protein show no overlap in either map positions or amino acid content with the peptides of the CNS myelin basic protein. Analysis of the individual peptides in the P2 map accounted for all of the amino acids present in the analysis of the whole protein. The P2 protein has a blocked NH₂-terminus, lysine at its COOH-terminus and no hexosamine. CD studies revealed that the P2 protein has a very stable β-structure in aqueous solution at neutral or basic pH and retains much of this structure in acid and in 8 M urea. It is suggested that these structural properties are relevant to the dual role of the P2 protein as a membrane constituent and as an antigen.     

Parital characterization of the rat anti-encephalitogenic protein (RSCP).

A protein antigenically similar to the anti-encephalitogenic bovine spinal cord protein (BSCP) was detected in saline extracts of rat nervous tissues by immunodiffusion analyses using a rabbit anti-BSCP serum. Rat SCP (RSCP) appears to be evenly distributed throughout all parts of the rat nervous system and occurs also in the thymus, thyroid, and adrenal glands. Although immunodiffusion analyses indicated that RSCP shares some antigenic sites with BSCP, anti-RSCP sera reacted only with RSCP, indicating that the major immunogenic determinants of the RSCP are peculiar to the rat and differ from the immunogenic determinants of human, monkey, rabbit, guinea pig, or bovine SCP. Immunoelectrophoretic analyses of concentrated pastes of rat brain (RB) or rat spinal cord (RSC) in agar at pH 8.6 revealed that RSCP occurs in two molecular forms having the electrophoretic mobilities of a serum beta-globulin and a serum gamma-globulin, respectively. However, gamma-RSCP is the predominant component of extracts of brain or spinal cord. Gamma-RSCP was isolated from RB and RSC by a procedure which involved: a) extraction with 0.05 M ammonium acetate buffer, pH 4.0; b) batch absorption of impurities on CM-52 cellulose; c) batch absorption of RSCP on SP-Sephadex, pH 3.5; d) elution of RSCP from SP-Sephadex, pH 5.5; and finally, e) gel filtration on Sephadex G-50 superfine. Purified gamma-RSCP formed one band when analyzed by polyacrylamide electrophoresis in acid gels containing 8 M urea. In contrast, two bands were always present when gamma-RSCP from brain or spinal cord were subjected to SDS-polyacrylamide electrophoresis in 15% gels. The larger of the two components of brain gamma-RSCP had a m.w. of 12,400 daltons, whereas the two components of spinal cord gamma-RSCP were smaller. The molecular sizes of brain RSCP and spinal cord RSCP was estimated by gel filtration chromatography to be 12,400 daltons. The amino acid compositions of gamma-RSCP prepared from RB or RSC were similar except that gamma-RSCP from RSC contained twice as much half-cystine and a slightly higher proportion of basic amino acid than gamma-RSCP from RB.     

DISTRIBUTION AND OPTICAL ACTIVITY OF THE BASIC PROTEIN IN BOVINE PERIPHERAL NERVE MYELIN

Abstract— Antiserum to BF protein isolated from bovine spinal roots has been used to study the distribution of the protein in other species and tissues.
Significant amounts of protein could be demonstrated in bovine, pig and rabbit peripheral nerve myelin. It was, however, scarcely detectable in guinea pig peripheral nerve myelin. There was BF protein in rabbit spinal cord as well as in peripheral nerve, but little or no BF protein in the liver, kidney, muscle or brain. BF protein in bovine spinal cord was localized in the myelin. The ratio of the BF protein to the encephalitogenic protein in the spinal cord myelin was around 0.15:1.0. BF protein was extractable from peripheral nerve myelin by saline as well as by acid solutions.
The circular dichroism spectrum of the BF protein in aqueous solution suggested that this protein contained a very large amount of β-structure. This structure was not considered to be the result of acid denaturation because the protein purified from the saline extract of peripheral nerve also showed a similar spectrum.     

Calcium Requirement for Fast Axonal Transport in Frog Motoneurons

Abstract: Calcium is required to sustain fast axonal transport in sensory neurons of frog and cat. We studied the Ca²⁺ dependence of fast axonal transport in the motoneurons of the lower spinal cord from frog. The accumulation of acetylcholinesterase at a crush on the ventral roots was used to follow axonal transport. Two types of experiments were performed: modification of the medium bathing the ventral roots, alone, and modification of the medium bathing the spinal cord and ventral roots. Incubation (17-18 h) of the ventral roots in Ca²⁺-free medium markedly inhibited acetylcholinesterase transport, a finding that demonstrates a Ca²⁺ requirement for fast axonal transport in motoneurons; when 4 m M MgCl₂ was added to the Ca²⁺-free medium, transport was also greatly reduced. During incubation of the ventral roots in normal medium supplemented with 0.18 m M CoCl₂ transport proceeded normally; but when the Co²⁺ concentration was raised to 1.8 m M , transport was diminished as drastically as in the Ca²⁺-free medium. Incubation of the spinal cord and ventral roots in medium containing 0.18 m M CoCl₂ did not reduce the accumulation of acetylcholinesterase at the crush. Similarly, accumulation of acetylcholinesterase at a crush on the dorsal root was not significantly reduced by exposure of the dorsal root ganglion and root to 0.18 m M Co²⁺. Exposure of sensory cell bodies to 0.18 m M Co₂₊ thus produces differential effects on transport of acetylcholinesterase and on transport of newly synthesized radiolabeled protein.     

The composition of the myelin proteins of the central nervous system

Abstract— The amino acid composition of human, monkey and bovine centrum ovale myelin, of bovine optic nerve myelin, and of bovine spinal cord white matter myelin has been determined. In general, the amino acid patterns of the centrum ovale myelin of these species and the optic nerve myelin are identical. Differences are noted when these are compared to the spinal cord white matter myelin. It is shown that the amino acid composition of myelin cannot be duplicated by any combination of the Folch–Lees proteolipid protein and the basic protein fraction of myelin. It is necessary to postulate the existence of a third protein fraction that is rich in dicarboxylic amino acids.     

P2 Protein in Oligodendrocytes and Myelin of the Rabbit Central Nervous System

P2 protein, a myelin-specific protein, was detected immunocytochemically and biochemically in rabbit central nervous system (CNS) myelin. P2 protein was synthesized by rabbit oligodendrocytes and was present in varying amounts throughout the rabbit CNS. Comparison of P2 and myelin basic protein (MBP) stained sections revealed that P2 antiserum did not stain all myelin sheaths within the rabbit CNS. The proportion of myelin sheaths stained by P2 antiserum and the amount of P2 detected biochemically were greater in more caudal regions of the rabbit CNS. The highest concentration of P2 protein was found in rabbit spinal cord myelin, where P2 antiserum stained the majority of myelin sheaths. P2 protein was barely detectable biochemically in myelin isolated from frontal cortex, and in sections of frontal cortex only occasional myelin sheaths reacted with P2 antiserum. These results suggest the the regional variations in the amount of P2 protein are dut to regional differences in the number of myelin sheaths that contain P2 protein. P2 protein was detected immunocytochemically and biochemically in rabbit sciatic nerve myelin. Immunocytochemically, P2 antiserum only stained a portion of the myelin sheaths present. The myelin sheaths not reacting with P2 antiserum had small diameters and represented less than 10% of the total myelinated fibers.     

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.     

DNA-synthesizing activity of the nucleoid protein core in Escherichia coli

Nucleoids obtained from E. coli cells by extraction with 1 M NaCl and detergents containing solution were further extracted with 2 M NaCl. From these samples, that contain only tightly bound proteins, fractions of protein core and peripheral nucleoprotein were obtained. It is shown that DNA synthesis proceeds mainly in the core structures. We have found that DNA polymerase I, which is bound with DNA nucleoid loops and with the above mentioned core structures, is not dissociating in 2M NaCl solution.     

Allergic neuritis: phospholipid requirement for the disease-inducing conformation of the P2 protein

The P2 protein, a small, highly ordered basic protein of peripheral nerve myelin, is a potent inducer of allergic neuritis in rats when complexed with phospholipids such as phosphatidylserine. Isolated P2 protein administered without lipid is a poor neuritogen, and if first oxidized with performic acid, aminoethylated in 8 M urea or heat denatured, it loses nearly all activity. When the aminoethylated or oxidized forms are combined with phosphatidylserine, however, they recover essentially full neuritogenic activity. Complexing with lipid also greatly enhances the activity of the heart denatured form. Spleen cells sensitized to the aminoethylated and heated forms of P2 protein show a pronounced mitogenic response to either of these forms as well as to the P2 protein itself, but only when sensitization is initiated with the lipid complex. These data indicate that the lipid complex reverses the distortion acquired by chemical treatment or denaturation and converts the P2 molecule into a conformation approximating that of the native P2 protein in myelin. These studies imply that the neuritogenic domain, while highly sensitive to denaturing conditions, requires interaction with phospholipids in order to attain the most favourable conformation for inducing a cell-mediated response that leads to disease.     

Distribution of the myelin-associated glycoprotein and P0 protein during myelin compaction in quaking mouse peripheral nerve

Ultrastructural studies have shown that during early stages of Schwann cell myelination mesaxon membranes are converted to compact myelin lamellae. The distinct changes that occur in the spacing of these Schwann cell membranes are likely to be mediated by the redistribution of (a) the myelin-associated glycoprotein, a major structural protein of mesaxon membranes; and (b) P0 protein, the major structural protein of compact myelin. To test this hypothesis, the immunocytochemical distribution of these two proteins was determined in serial 1-micron-thick Epon sections of ventral roots from quaking mice and compared to the ultrastructure of identical areas in an adjacent thin section. Ventral roots of this hypomyelinating mouse mutant were studied because many fibers have a deficit in converting mesaxon membranes to compact myelin. The results indicated that conversion of mesaxon membranes to compact myelin involves the insertion of P0 protein into and the removal of the myelin-associated glycoprotein from mesaxon membranes. The failure of some quaking mouse Schwann cells to form compact myelin appears to result from an inability to remove the myelin-associated glycoprotein from their mesaxon membranes.     

The pH-dependent unfolding mechanism of P2 myelin protein: an experimental and computational study

The P2 protein is a small, extrinsic protein of the myelin membrane in the peripheral nervous system that structurally belongs to the fatty acid binding proteins (FABPs) family, sharing with them a 10 strands beta-barrel structure. FABPs appear to be involved in cellular fatty acid transport, but very little is known about the role of P2 in the metabolism of peripheral myelin lipids. Study of protein conformation at different pHs is a useful tool for the characterization of the unfolding mechanisms and the intrinsic conformational properties of the protein, and may give insight into factors that guide protein folding pathways. In particular, low pH conditions have been shown to induce partially folded states in several proteins. In this paper, the acidic unfolding of purified P2 protein was studied with both spectroscopic techniques and molecular dynamics simulation. Both experimental and computational results indicate the presence of a partly folded state at low pH, which shows structural changes mainly involving the lid that is formed by the helix-turn-helix domain. The opening of the lid, together with a barrel relaxation, could regulate the ligand exchanges near the cell membrane, supporting the hypothesis that the P2 protein may transport fatty acids between Schwann cells and peripheral myelin.