Bovine P2 Protein: Sequence at the NH2-Terminal of the Protein

Sequence data from key fragments of the P2 protein established the order of cyanogen bromide (CNBr) peptides in the structure of the protein and the primary structure for approximately one-half of the molecule. Data were obtained from the three tryptic peptides of blocked NH2-terminal CNBr peptide (CN3), the large CNBr peptide of P2 protein (CN1), and a fragment obtained from P2 by cleavage at tryptophan with 2-(2-nitrophenylsulfenyl)-3-methyl-3'-bromoindolenine. This last fragment was found to contain an over-lapping sequence that proved the juxtaposition of CN1 and CN3 in P2 protein. Thus, based on this fact and the characteristics of the CNBr peptides, the P2 structure is composed of CNBr peptides in the order: CN3-CN1-CN2(Val)-CN2(Lys). A comparison was made between the partial sequence of P2 protein and the equivalent portion of the structure of bovine myelin basic protein. The structures of these two proteins were found to be distinctly different although certain similarities are found.     

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.     

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.     

Conformations of P2 Protein of Peripheral Nerve Myelin by Nuclear Magnetic Resonance Spectroscopy

High-resolution 1H NMR spectra of P2 protein from bovine peripheral nerve myelin indicate that the protein contains a high degree of tertiary structure in aqueous solution. Denaturation of the protein in urea solutions is a multi-step process. Binding of lysophosphatidylcholine micelles to the protein causes a conformational change and a broadening of NMR peaks from side chains of aromatic amino acid and methionine residues, with much less effect on upfield methyl resonances.     

Partial Structure and Mapping of the Human Myelin P2 Protein Gene

Abstract: The myelin P₂ protein, a 14,800-Da cytosolic protein found primarily in peripheral nerves, belongs to a family of fatty acid binding proteins. Although it is similar in amino acid sequence and tertiary structure to fatty acid binding proteins found in the liver, adipocytes, and intestine, its expression is limited to the nervous system. It is detected only in myelin-producing cells of the central and peripheral nervous systems, i.e., the oligodendrocytes and Schwann cells, respectively. As part of a program to understand the regulation of expression of this gene, to determine its function in myelin-producing cells, and to study its role in peripheral nerve disease, we have isolated and characterized overlapping human genomic clones encoding the P₂ protein. We report here on the partial structure of this gene, and on its localization within the genome. By using a panel of human-hamster somatic cell hybrids and by in situ hybridization, we have mapped the human P₂ gene to segment q21 on the long arm of chromosome 8. This result identifies the myelin P₂ gene as a candidate gene for autosomal recessive Charcot-Marie-Tooth disease type 4A.     

Incorporation of P0 Protein into Liposomes: Demonstration of a Two-Domain Structure by Immunochemical and PAGE Analysis

The amphiphilic nature of P0, the major glycoprotein of peripheral nerve myelin, has been suggested previously. In the present study, purified P0 from human peripheral nerve myelin was incorporated into an artificial lipid bilayer consisting of dimyristoyl lecithin and cholesterol. The liposomes were fractionated on a sucrose gradient. The continued expression of P0 antigenicity by the liposomes was shown by specific complement consumption with a multivalent antiserum against P0 or with an IgM monoclonal antibody. Both antibodies recognized P0 expressed on the surface of peripheral nerve myelin and the P0 liposomes. P0 liposomes and peripheral nerve myelin treated with trypsin lost the surface determinant that reacted with the monoclonal antibody. Analysis of the trypsin-treated liposomes and peripheral nerve myelin by polyacrylamide gel electrophoresis revealed molecular weights for this protein of 19,500 and 20,500, respectively. Similar treatment of the P0 in the fluid phase resulted in many smaller fragments. These results indicate that P0 consists of two domains, a hydrophilic domain accessible to trypsin digestion and a hydrophobic domain, which is potentially trypsin-sensitive, but shielded by the lipid bilayer. Binding studies with an anti-P0 monoclonal antibody and polyacrylamide gel analysis of the lipid-shielded P0 fragment in liposomes and peripheral nerve myelin suggest that the orientation of the protein in the liposome is similar to that in peripheral nerve myelin.     

Kinetics of Entry of P0 Protein into Peripheral Nerve Myelin

Abstract: Sciatic nerves from 9-day-old rat pups were removed, sliced into 0.4-mm sections, and incubated with [³H]fucose or [¹⁴C]glycine precursors. The nerve slice system gave nearly linear incorporation of [³H]fucose as a function of time for 3 h, after an initial lag of ˜30 min for homogenate and ˜60 min for myelin. Incorporation of [³H]fucose at constant specific radioactivity was directly proportional to exogenous fucose levels over the range 3.0 × 10⁻⁸ m to 1.5 × 10⁻⁶ m . Analysis of labeled proteins by sodium dodecyl sulfate polyacrylamide gel electrophoresis showed that greater than 50% of labeled glycoprotein was P₀, with no other major constituents. This system was used in fucose-chase experiments to determine that a period of ˜20 min elapses between fucosylation and assembly of P₀ into myelin. Cycloheximide inhibition of protein synthesis was used to determine that a period of ˜33 min elapses between protein synthesis and appearance of P₀ myelin.     

Structure of Bovine P2 Basic Protein: Sequence of a Carboxyterminal Segment That Is a Neuritogen in Rabbits

The sequence of the carboxyterminal 18 amino acids released by cyanogen bromide digestion of the bovine P2 protein was determined. It has several interesting structural and immunological properties. It contains the only two half-cystines in the molecule that have the capacity to form an intrachain disulfide bond. Using the rabbit as a test animal, this carboxyterminal peptide was capable of producing experimental allergic neuritis. The sequence of this peptide is Val-Val-Glu-Cys-Lys-Met-Lys-Asp-Val-Val-Cys-Thr-Arg-Ile-Tyr-Glu-Lys-Val.     

Production and Characterization of Monoclonal Antibodies to the Major Peripheral Myelin Glycoprotein P0

Several monoclonal antibodies were generated against the major glycoprotein P0 of human peripheral nervous system myelin. Antibodies were selected for their reactivity with P0 in Western blots. The antibodies were of the immunoglobulin G subclass and reacted with the glycopeptidase F-treated P0, indicating that the reactive epitope resides in the protein backbone. In fresh frozen and paraffin-embedded sections of central and peripheral nervous system of rat and human, P0 antibody 592 reacted with myelin sheaths of peripheral, but not central, nervous system.     

Ultrastructural Localization of P2 Protein in Actively Myelinating Rat Schwann Cells

Abstract: The myelin specific protein, P₂, was localized immunocytochemically in electron micrographs of 4-day-old rat peripheral nerve by a preembedding technique. P₂ staining was restricted to Schwann cells that had established a one-to-one relationship with an axon. P₂ antiserum produced a diffuse staining throughout the entire cytosol of myelinating Schwann cells. In addition, the cytoplasmic side of Schwann cell plasma membranes and the membranes of cytoplasmic organelles that were exposed to cytosol were stained by P₂ antiserum. This cytoplasmic localization of P₂ protein is similar to that described for soluble or peripheral membrane proteins that are synthesized on free ribosomes. P₂ antiserum stained the cytoplasmic side of Schwann cell membranes that formed single or multiple loose myelin spirals around an axon. In the region of the outer mesaxon, P₂ antiserum stained the major dense line of compact myelin. These results demonstrate that P₂ protein is located on the cytoplasmic side of compact myelin membranes and are consistent with biochemical studies demonstrating P₂ to be a peripheral membrane protein.     

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.     

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.     

Functional Modulation of P2×2 Receptors by Cyclic AMP-Dependent Protein Kinase

Abstract: It is generally believed that protein phosphorylation is an important mechanism through which the functions of voltage- and ligand-gated channels are modulated. The intracellular carboxyl terminus of P_2×2 receptor contains several consensus phosphorylation sites for cyclic AMP (cAMP)-dependent protein kinase (PKA) and protein kinase C (PKC), suggesting that the function of the P_2×2 purinoceptor could be regulated by the protein phosphorylation. Whole-cell voltage-clamp recording was used to record ATP-evoked cationic currents from human embryonic kidney (HEK) 293 cells stably transfected with the cDNA encoding the rat P_2×2 receptor. Dialyzing HEK 293 cells with phorbol 12-myristate 13-acetate, a PKC activator, failed to affect the amplitude and kinetics of the ATP-induced cationic current. The role of PKA phosphorylation in modulating the function of the P_2×2 receptor was investigated by internally perfusing HEK 293 cells with 8-bromo-cAMP or the purified catalytic subunit of PKA. Both 8-bromo-cAMP and PKA catalytic subunit caused a reduction in the magnitude of the ATP-activated current without affecting the inactivation kinetics and the value of reversal potential. Site-directed mutagenesis was also performed to replace the intracellular PKA consensus phosphorylation site (Ser⁴³¹) with a cysteine residue. In HEK 293 cells expressing (S431C) mutant P_2×2 receptors, intracellular perfusion of 8-bromo-cAMP or purified PKA catalytic subunit did not affect the amplitude of the ATP-evoked current. These results suggest that as with other ligand-gated ion channels, protein phosphorylation by PKA could play an important role in regulating the function of the P_2×2 receptor and ATP-mediated physiological effects in the nervous system.     

Phosphorylation of P0 Glycoprotein in Peripheral Nerve Myelin

The P0 protein in mammalian PNS myelin is known to undergo several posttranslational modifications, such as glycosylation, acylation, sulfation, and phosphorylation. Phosphorylation of purified P0 protein in vitro was studied comparatively using three enzymes, i.e., calcium/phospholipid-dependent protein kinase (protein kinase C), calcium/calmodulin-dependent protein kinase II (CaM kinase II), and the catalytic subunit of cyclic AMP-dependent protein kinase (A kinase). The phosphorylation of P0 protein by CaM kinase II was the greatest, followed by that by protein kinase C; phosphorylation by A kinase, however, was much lower. In order to identify phosphorylation sites, P0 protein was phosphorylated with [32P]ATP and each kinase and then digested with lysylendopeptidase. The resulting phosphopeptides were isolated by HPLC. Subsequent amino acid sequence analysis and comparison with the known sequence of P0 protein revealed that Ser181 and Ser204 were strongly phosphorylated by both protein kinase C and CaM kinase II. In addition, Ser214 was also phosphorylated by protein kinase C, but not by CaM kinase II. Because all of these sites are located in the cytoplasmic domain of P0 protein, phosphorylation may be important for maintenance of the major dense line of PNS myelin.     

Phosphorylation of P400 Protein by Cyclic AMP-Dependent Protein Kinase and Ca2+/Calmodulin-Dependent Protein Kinase II

Purified P400 protein was phosphorylated by both purified Ca2+/calmodulin-dependent protein kinase II (CaM kinase II) and the catalytic subunit of cyclic AMP-dependent protein kinase (A-kinase). Because P400 protein was suggested to function as an integral membrane protein, we investigated the phosphorylation of P400 protein using crude mitochondrial and microsomal fractions (P2/P3 fraction). Incubation of the P2/P3 fraction from mouse cerebellum with cyclic AMP or the catalytic subunit of A-kinase stimulated the phosphorylation of P400 protein. The phosphorylation of P400 protein was not observed in the P2/P3 fraction from mouse forebrain. Cyclic AMP and A-kinase enhanced the phosphorylation of several proteins, including P400 protein, suggesting that P400 protein is one of the best substrates for A-kinase in the P2/P3 fraction. Although endogenous and exogenous CaM kinase II stimulated the phosphorylation of some proteins in the P2/P3 fraction, the phosphorylation of P400 protein was weak. Immunoprecipitation with the monoclonal antibody to P400 protein confirmed that the P400 protein itself was definitely phosphorylated by the catalytic subunit of A-kinase and CaM kinase II. A-kinase phosphorylated only the seryl residue in P400 protein. Immunoblot analysis of the cells in primary culture of mouse cerebellum confirmed the expression of P400 protein, which migrated at the same position on sodium dodecyl sulfate-polyacrylamide gel electrophoresis as that in the P2/P3 fraction. Incubation of the cultured cerebellar cells with [32P]orthophosphate resulted in the labeling of P400 protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Degradation of the P0, P1, and Pr, Proteins in Peripheral Nervous System Myelin by Plasmin: Implications Regarding the Role of Macrophages in Demyelinating Diseases

Activated macrophages secrete a variety of neutral proteinases, including plasminogen activator. Since macrophages are implicated in primary demyelination in the peripheral nervous system (PNS) in Guillain-Barré syndrome and experimental allergic neuritis, we have investigated the ability of plasmin and of conditioned media from cultured macrophages, in the presence of plasminogen, to degrade the proteins in bovine and rat PNS myelin. The results indicate that (a) the major glycoprotein P0 and the basic P1 and Pr proteins in PNS myelin are extremely sensitive to plasmin, perhaps more so than is the basic protein in CNS myelin; (b) the initial product of degradation of P0 by plasmin has a molecular weight higher than that of the "X" protein; (c) large degradation products of P0 are relatively insensitive to further degradation; and (d) the neuritogenic P2 protein in PNS myelin is quite resistant to the action of plasmin. Results similar to those with plasmin were obtained with conditioned media from macrophages and macrophage-like cell lines together with plasminogen activator, and the degradation of the PNS myelin proteins, Po and P1, under these conditions was inhibited by p-nitrophenylguanidinobenzoate, an inhibitor of plasmin and plasminogen activator. The results suggest that the macrophage plasminogen activator could participate in inflammatory demyelination in the PNS.     

Two Distinct P2 Purinergic Receptors, P2Y and P2U, Are Coupled to Phospholipase C in Mouse Pineal Gland Tumor Cells

Abstract: We found that extracellular ATP can increase the intracellular Ca²⁺ concentration ([Ca²⁺]_i) in mouse pineal gland tumor (PGT-β) cells. Studies of the [Ca²⁺]_i rise using nucleotides and ATP analogues established the following potency order: ATP, adenosine 5′-O-(3-thiotriphosphate) ≥ UTP > 2-chloro-ATP > 3′-O-(4-benzoyl)benzoyl ATP, GTP ≥ 2-methylthio ATP, adenosine 5′-O-(2-thiodiphosphate) (ADPβS) > CTP. AMP, adenosine, α,β-methyleneadenosine 5′-triphosphate, β,γ-methyleneadenosine 5′-triphosphate, and UMP had little or no effect on the [Ca²⁺]_i rise. Raising the extracellular Mg²⁺ concentration to 10 mM decreases the ATP-and UTP-induced [Ca²⁺]_i rise, because the responses depend on the ATP^4? and UTP^4? concentrations, respectively. The P_2U purinoceptor-selective agonist UTP and the P_2Y purinoceptor-selective agonist ADPβS induce inositol 1,4,5-trisphosphate generation in a concentration-dependent manner with maximal effective concentrations of ～100 µM. In sequential stimulation, UTP and ADPβS do not interfere with each other in raising the [Ca²⁺]_i. Costimulation with UTP and ADPβS results in additive inositol 1,4,5-trisphosphate generation to a similar extent as is achieved with ATP alone. Pretreatment with pertussis toxin inhibits the action of UTP and ATP by maximally 45–55%, whereas it has no effect on the ADPβS response. Treatment with 1 µM phorbol 12-myristate 13-acetate inhibits the ADPβS-induced [Ca²⁺]_i rise more effectively than the ATP- and UTP-induced responses. These results suggest that P_2U and P_2Y purinoceptors coexist on PGT-β cells and that both receptors are linked to phospholipase C.