Thomas V. Waehneldt

Differential ultrastructural localization of myelin basic protein, myelin/oligodendroglial glycoprotein, and 2',3'-cyclic nucleotide 3'-phosphodiesterase in the CNS of adult rats.

Abstract: In a light and electron microscopic immunocytochemical study we have examined the distribution of myelin basic protein (MBP), 2′,3′‐cyclic nucleotide 3′‐phosphodiesterase (CNP), and myelin/oligodendroglial glycoprotein (MOG) within CNS myelin sheaths and oligodendrocytes of adult Sprague–Dawley rats. Ultrastructural immunocytochemistry allowed quantitative analysis of antigen density in different myelin and oligodendrocyte zones: MBP was detectable in high density over the whole myelin sheath, but not in regions of loops, somata, or the oligodendrocyte plasma membrane. CNP reactivity was highest at the myelin/axon interface, and found in lower concentration over the outer lamellae of myelin sheaths, at the cytoplasmic face of oligodendrocyte membranes, and throughout the compact myelin. MOG was preferentially detected at the extracellular surface of myelin sheaths and oligodendrocytes and in only low amounts in the lamellae of compacted myelin and the myelin/axon border zone. Our studies, thus, indicate further the presence of different molecular domains in compact myelin, which may be functionally relevant for the integrity and maintenance of the myelin sheath.

Phylogeny of Myelin Proteins

Myelin is characterized by the spiral stacking of closely packed glial membrane pairs’ and functions as an insulator to increase the velocity of nerve impulses.2 It is synthesized by oligodendroglial cells in the central nervous system (CNS) and by Schwann cells in the peripheral nervous system (PNS).’ The membrane-spanning proteolipid protein (PLP) in CNS myelin and the major glycoprotein (Po) in PNS myelin serve as spacers predominantly at the extracellular sides of the oligodendroglial and Schwann cell plasma membranes, respectively, whereas the peripheral myelin basic protein (MBP) is localized at the cytoplasmic apposition in both CNS and PNS myelin.) This brief description of myelination and its major protein constituents is valid for mammalian vertebrates. Occasional observations have demonstrated that myelin proteins from bony and cartilaginous fishes differ from those of mammals,a whereas those of lower tetrapods appear similar.’.* However, in view of diseases affecting myelination, i t is understandable that the overwhelming majority of data have been obtained from mammals, specifically domestic animals as well as man. On the other hand, the mammals just cited, including humans, represent a vanishingly small fraction of the total of about 4,000 mammalian species, not to mention the nonmammalian vertebrates (approximately 45,000 species). These considerations, as well as sheer curiosity, have prompted us to analyze CNS myelin proteins in members of all myelin-synthesizing vertebrate classes in a systematic way,9 having also in mind that “comparative studies provide the evidence for generalizations which in turn lead to new insights into old problems and stimulate fresh ideas.”I0.l’ Surprisingly, these studies revealed that fish contain at least two major intrinsic proteins in their CNS myelin which are glycosylated, in contrast to the major nonglycosylated PLP of mammalian CNS myelin. These comparisons suggest that the protein composition of CNS myelin may be dramatically different in vertebrates other than mammals. Herein an attempt is made to give an account of what has been learned about the CNS myelin proteins during phylogeny. Major emphasis will be placed on vertebrates; however, data on invertebrates are also included, although these are at present rudimentary. Maybe we can abandon our myelin anthropocentrism for a while and pay attention to the ‘‘lowly’’ frogs and fish as well as crabs and worms. They too have a story.

Appearance of Myelin proteins during vertebrate evolution.

Myelin, defined as an arrangement of spirally fused unit membranes, is an acquisition of vertebrates and first appeared during evolution in Gnathostomata. In all species studied PNS and CNS myelins contain the myelin-associated glycoprotein (MAG) and the myelin basic protein (MBP). Throughout phylogeny PNS myelin is characterized by the major P(0) glycoprotein which is called IP in fishes. The PNS myelin proteins did not evolve further except for the addition of P(2) protein from reptiles onward. In Elasmobranchii and Chondrostei, PNS and CNS myelin proteins are similar. CNS myelin of actinopterygian fishes possesses a 36,000 Da protein (36K) in addition to P(0)-like IP glycoproteins. In tetrapod CNS myelin, P(0) is replaced by the proteolipid protein (PLP) and the Wolfgram protein (WP). Of particular interest in a transitional phylogenetic sense are the lungfish Protopterus, carrying glycosylated PLP (g-PLP) but no P(0), 36K or WP, and the bichir Polypterus, showing simultaneous presence of P(0), 36K and PLP. These results indicate that myelin proteins could be valuable molecular markers in establishing vertebrate phylogenetic relationships and in reconstructing the fish-tetrapod transition.

Phylogenetic examination of vertebrate central nervous system myelin proteins by electro-immunoblotting

Central nervous system (CNS) myelin proteins from vertebrate classes were examined by immunoblotting with antisera against mammalian CNS myelin proteins. Higher vertebrates possessed proteolipid (PLP), DM-20 and Wolfgram (WP) proteins, except that DM-20 was missing in amphibia. Fish CNS myelins contained neither PLP nor WP; instead they bound antisera to mammalian peripheral nervous system P0 protein. All classes carried myelin basic protein, but only mammals exhibited a component equivalent to rat 21.5K (21,500 dalton). These phylogenetic data are consistent with major changes in CNS myelin protein composition at the transition from fishes to higher vertebrates.

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

Abstract: 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 IPO. 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. These results differ completely from those observed in mammalian myelins albeit “normal” features of the glia‐myelin morphologies in trout PNS and CNS tissues.

MEMBRANE PROTEINS OF RAT BRAIN: COMPOSITIONAL CHANGES DURING POSTNATAL DEVELOPMENT

Abstract— Membrane fractions from forebrain of rat were isolated at ages ranging from 5 to 93 days. Among these fractions were total membranes, three fractions isolated by density gradient centrifugation, and three subfractions which consisted of purified myelin and of two supernatant fractions. All membrane fractions showed an increase in protein content during the first postnatal month; however, only the myelin fraction and one of its supernatant fractions showed a prolonged accumulation. Myelin protein increased continually from 0.17 mg/g brain at 15 days to 8.3 mg/g brain at 93 days.

Biochemical characterization of the central nervous system myelin proteins of the rainbow trout,Salmo gairdneri

Central nervous system myelin isolated from the rainbow trout (Salmo gairdneri) displays a very low median density on zonal gradient centrifugation, banding at approximately 0.32 M sucrose. Its proteins consist of a 36 K (36,000 mol.wt.) component, two Concanavalin A-reactive intermediate proteins IP1 (23,000 mol.wt.) and IP2 (26,200 mol.wt.), and two basic proteins BP1 and BP2, of which the latter co-migrates with rat SBP while BP1 is of slightly smaller size. The trout myelin proteins electrofocus at pH positions similar to those of their mammalian counterparts. Immunoblotting shows that antibodies against rat PNS myelin P0 glycoprotein are bound by IP1 and IP2, but not by 36K. None of the trout myelin proteins react with anti-rat CNS myelin proteolipid protein (PLP) antiserum. The basic proteins BP1 and BP2 bind strongly to antibodies directed against human myelin basic protein. In vivo injection of tritiated fucose or palmitate leads to radiolabeling of IP1 and IP2. Under autolytic in situ conditions the appearance of a glycosylated 20,000 mol.wt. component (IP0) is noted, with parallel reduction of both IP1 and IP2, indicating sequence homologies between IP1 and IP2. The 36K protein is not affected by autolysis.

Nervous system myelin in the electric ray, Torpedo marmorata: Morphological characterization of the membrane and biochemical analysis of its protein components

In Torpedo, PNS as well as CNS myelines are characterized by clearly separated double intraperiod lines. CNS myelin of Torpedo contains two glycosylated hydrophobic proteins labelled T1 (25,800 Da1) and T2 (29,700 Da1), and two basic proteins BP1 and BP2, migrating like mammalian large basic protein (BP2) and pre-small basic protein (BP1) (Barbarese et al., 1977). PNS myelin of Torpedo carries only BP1 and is characterized by a closely spaced doublet of the glycosylated hydrophobic proteins Con A+ (29,700 Da1) and Con A? (31,000 Da1); the latter does not bind Concanavalin A. These glycosylated proteins (T1, T2, Con A+, Con A?) contain mannose, N-acetylglucosamine and galactose, but lack fucose and sialic acids. They have isoleucine at their amino terminus. They bind anti-rat PNS myelin P(0) antibodies but do not react with anti-rat CNS myelin PLP antibodies. Limited proteolyses of isolated proteins suggest sequence homologies between T1 and T2, and possibly between Con A+ and Con A?. The two basic proteins BP1 and BP2 bind antibodies directed against human myelin basic protein. All Torpedo myelin proteins electrofocus in pH regions characteristic of their mammalian counterparts.

Myelin lipids: A phylogenetic study

AbstractThe lipid composition of CNS and PNS myelin was studied in rat,Xenopus, trout andTorpedo. The main difference lay in the proportion of cerebrosides, which decreased in the sequence rat > Xenopus > Torpedo > trout. In additionTorpedo CNS and PNS myelins were extremely rich in sulfatides. In some respects,Torpedo appeared closer to tetrapods than trout. Otherwise the proportion of the different lipid classes did not reveal any clear evolutionary trends.The presence of hydroxylated galactolipids in CNS myelin was investigated in several additional species. Considerable amounts were found inTorpedo, Polypterus, Protopterus, lizard, and chicken, with the highest values in rat and anurans. Only very small amounts of hydroxylated cerebrosides were detected in trout and in axolotl, while newt had none. This parameter appears therefore of doubtful usefulness for phylogenetic studies. In contrast to myelin proteins, myelin lipids are of limited value for establishing phylogenetic relationship among vertebrates.

Changes of myelin proteins during Wallerian degeneration in situ and in millipore diffusion chambers preventing active phagocytosis

Changes of myelin proteins in mouse sciatic nerves were studied comparing nerves degenerating in situ with nerves enclosed in millipore diffusion chambers which eliminate invasion of non-resident cells. Nerves kept in chambers showed nearly complete preservation of myelin sheaths with a very slow degradation of myelin proteins. Nerves degenerating in situ showed rapid myelin phagocytosis by macrophages with almost complete disappearance of myelin proteins after 28 days. These data elucidate the role of macrophages for removal of myelin proteins.