A novel SDS-stable dimer of a heterogeneous nuclear ribonucleoprotein at presynaptic terminals of squid neurons.

The presence of mRNAs in synaptic terminals and their regulated translation are important factors in neuronal communication and plasticity. Heterogeneous nuclear ribonucleoprotein (hnRNP) complexes are involved in the translocation, stability, and subcellular localization of mRNA and the regulation of its translation. Defects in these processes and mutations in components of the hnRNP complexes have been related to the formation of cytoplasmic inclusion bodies and neurodegenerative diseases. Despite much data on mRNA localization and evidence for protein synthesis, as well as the presence of translation machinery, in axons and presynaptic terminals, the identity of RNA-binding proteins involved in RNA transport and function in presynaptic regions is lacking. We previously characterized a strongly basic RNA-binding protein (p65), member of the hnRNPA/B subfamily, in squid presynaptic terminals. Intriguingly, in sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), p65 migrated as a 65-kDa protein, whereas members of the hnRNPA/B family typically have molecular masses ranging from 35 to 42kDa. In this report we present further biochemical and molecular characterization that shows endogenous p65 to be an SDS-stable dimer composed of ∼37-kDa hnRNPA/B-like subunits. We cloned and expressed a recombinant protein corresponding to squid hnRNPA/B-like protein and showed its propensity to aggregate and form SDS-stable dimers in vitro. Our data suggest that this unique hnRNPA/B-like protein co-localizes with synaptic vesicle protein 2 and RNA-binding protein ELAV and thus may serve as a link between local mRNA processing and presynaptic function and regulation.

Characterization of the shark myelin Po protein.

Myelin, the insulating sheath made by extensive plasma membrane wrapping, is dependent on the presence of highly adhesive molecules that keep the two sides of the membrane in tight contact. The Po glycoprotein (Po) is the major component of the peripheral nervous system (PNS) myelin of mammals. The exact role that Po protein has played in the evolution of myelin is still unclear, but several phylogenetic observations suggest that it is a crucial component in the development of myelin as a multi-lamellar membrane structure. Sharks, which appeared in the fossil record about 400 million years ago, are the first fully myelinated organisms. In this study we investigated the expression pattern of shark myelin Po to suggest a way it might have played a role in the evolution of myelin in the central nervous system. We found that sharks have more than two isoforms (32, 28 and 25 kD), and that some of these might not be fully functional because they lack the domains known for Po homophilic adhesion.

GFAP-immunopositive structures in spiny dogfish, Squalus acanthias, and little skate, Raia erinacea, brains: differences have evolutionary implications.

GFAP expression patterns were compared between the brains of a spiny dogfish (Squalus acanthias) and a little skate (Raia erinacea). After anesthesia, the animals were perfused with paraformaldehyde. Serial vibratome sections were immunostained against GFAP using the avidin-biotin method. Spiny dogfish brain contained mainly uniformly-distributed, radially arranged ependymoglia. From GFAP distribution, the layered organization in both the telencephalon and the tectum were visible. In the cerebellum, the molecular and granular layers displayed conspicuously different glial structures; in the former a Bergmann glia-like population was found. No true astrocytes (i.e., stellate-shaped cells) were found. Radial glial endfeet lined all meningeal surfaces. Radial fibers also seemed to form endfeet and en passant contacts on the vessels. Plexuses of fine perivascular glial fibers also contributed to the perivascular glia. Compared with spiny dogfish brain, GFAP expression in the little skate brain was confined. Radial glia were limited to a few areas, e.g., segments of the ventricular surface of the telencephalon, and the midline of the diencephalon and mesencephalon. Scarce astrocytes occurred in every brain part, but only the optic chiasm, and the junction of the tegmentum and optic tectum contained large numbers of astrocytes. Astrocytes formed the meningeal glia limitans and the perivascular glia. No GFAP-immunopositive Bergmann glia-like structure was found. Astrocytes seen in the little skate were clearly different from the mammalian and avian ones; they had a different process system - extra large forms were frequently seen, and the meningeal and perivascular cells were spread along the surface instead of forming endfeet by processes. The differences between Squalus and Raia astroglia were much like those found between reptiles versus mammals and birds. It suggests independent and parallel glial evolutionary processes in amniotes and chondrichthyans, seemingly correlated with the thickening of the brain wall, and the growing complexity of the brain. There is no strict correlation, however, between the replacement of radial ependymoglia with astrocytes, and the local thickness of the brain wall.

Messenger RNAs located in myelin sheath assembly sites.

The targeting of mRNAs to specific subcellular locations is believed to facilitate the rapid and selective incorporation of their protein products into complexes that may include membrane organelles. In oligodendrocytes, mRNAs that encode myelin basic protein (MBP) and select myelin-associated oligodendrocytic basic proteins (MOBPs) locate in myelin sheath assembly sites (MSAS). To identify additional mRNAs located in MSAS, we used a combination of subcellular fractionation and suppression subtractive hybridization. More than 50% of the 1,080 cDNAs that were analyzed were derived from MBP or MOBP mRNAs, confirming that the method selected mRNAs enriched in MSAS. Of 90 other cDNAs identified, most represent one or more mRNAs enriched in rat brain myelin. Five cDNAs, which encode known proteins, were characterized for mRNA size(s), enrichment in myelin, and tissue and developmental expression patterns. Two of these, peptidylarginine deiminase and ferritin heavy chain, have recognized roles in myelination. The corresponding mRNAs were of different sizes than the previously identified mRNA, and they had tissue and development expression patterns that were indistinguishable from those of MBP mRNA. Three other cDNAs recognize mRNAs whose proteins (SH3p13, KIF1A, and dynein light intermediate chain) are involved in membrane biogenesis. Although enriched in myelin, the tissue and developmental distribution patterns of these mRNAs differed from those of MBP mRNA. Six other cDNAs, which did not share significant sequence homology to known mRNAs, were also examined. The corresponding mRNAs were highly enriched in myelin, and four had tissue and developmental distribution patterns indistinguishable from those of MBP mRNA. These studies demonstrate that MSAS contain a diverse population of mRNAs, whose locally synthesized proteins are placed to contribute to myelin sheath assembly and maintenance. Characterization of these mRNAs and proteins will help provide a comprehensive picture of myelin sheath assembly.

Myelin-associated oligodendrocytic basic protein mRNAs reside at different subcellular locations.

The mRNAs for two myelin proteins, myelin basic protein (MBP) and myelin-associated oligodendrocytic basic protein (MOBP)-81A, are uniquely located at sites where myelin sheaths are assembled. Here, we use subcellular fractionation to show that four MOBP mRNAs, like MBP mRNA, are located at sites of myelin sheath assembly, and that three other MOBP mRNAs are located in oligodendrocyte soma. The MOBP-81 protein is found in myelin and in another subcellular fraction, whereas other myelin proteins, including MBP, 2',3'-cyclic nucleotide 3'-phosphodiesterase, and myelin-associated glycoprotein, are largely restricted to myelin. Different MBP mRNAs are generated by alternative splicing. All of them contain an RNA transport sequence (RTS) that directs them to sites in oligodendrocytes, where myelin sheaths are assembled. Consequently, all are enriched in myelin. After fractionation, four MOBP mRNAs, MOBP-71, MOBP-81A, MOBP-99, and MOBP-169 (identified in this study), are enriched in myelin. These mRNAs contain a common exon, exon 8b, which has a nucleotide sequence that is similar to MBP mRNA RTS. This sequence likely directs these mRNAs to sites of myelin sheath assembly. Three other MOBP mRNAs, MOBP-69, MOBP-81B, and MOBP-170, lack this exon. Their subcellular distribution indicates that they are largely retained in oligodendrocyte soma. We conclude that the distribution of MOBPs in oligodendrocytes is strongly influenced by alternative splicing of the corresponding mRNAs.

Cloning, expression and map assignment of chicken prosaposin.

Prosaposin is the precursor of four small glycoproteins, saposins A-D, that activate lysosomal sphingolipid hydrolysis. A full-length cDNA encoding prosaposin from chicken brain was isolated by PCR. The deduced amino acid sequence predicted that, similarly to human and other mammalian species studied, chicken prosaposin contains 518 residues, including four domains that correspond to saposins A-D. There was 59% identity and 76% similarity of human and chicken prosaposin amino acid sequences. The basic three-dimensional structures of these saposins is predicted to be similar on the basis of the conservation of six cysteine residues and an N-glycosylation site. Identity of amino acid sequences was higher among saposins A, B and D than in saposin C. The predicted amino acid sequence of saposin B matched exactly that of purified chicken saposin B protein. The chicken prosaposin gene was mapped to a single locus, PSAP, in chicken linkage group E11C10 and is closely linked to the ACTA2 locus. This confirms the homology between chicken and human prosaposins and defines a new conserved segment with human chromosome 10q21-q24.

Differentiating oligodendrocytes inhibit neuronal growth cone motility in different ways.

Oligodendrocyte-specific proteins are thought to limit regeneration by inhibiting motility of the neuronal growth cone. These inhibitory proteins are among an array of molecules, each expressed in a stage-specific fashion as an oligodendrocyte differentiates. Here we show that neuronal growth cone response to contact with differentiating oligodendrocytes does not strictly correlate with the expression of inhibitory proteins. This suggests that the neuronal growth cone response depends on the context in which inhibitory molecules are encountered. In addition, we provide evidence that there are at least two cellular pathways, within the same growth cones, that lead to growth cone collapse.

Neural cells from dogfish embryos express the same subtype-specific antigens as mammalian neural cells in vivo and in vitro.

Neural cells are classically identified in vivo and in vitro by a combination of morphological and immunocytochemical criteria. Here, we demonstrate that antibodies used to identify mammalian oligodendrocytes, neurons, and astrocytes recognize these cell types in the developing spiny dogfish central nervous system and in cultures prepared from this tissue. Oligodendrocyte-lineage-specific antibodies O1, O4, and R-mAb labeled cells in the 9 cm dogfish brain stem's medial longitudinal fascicle (MLF) and in areas lateral to it. Process-bearing cells, cultured from the dogfish brain stem, were also labeled with these antibodies. An anti-lamprey neurofilament antibody (LCM), which recognized 60 and 150 kDa proteins in dogfish brain stem homogenates, labeled axons and neurons in the brain stem and axons in the cerebellum of the dogfish embryo. It also labeled cell bodies and/or processes of some cultured cerebellar cells. An anti-bovine glial fibrillary acidic protein antibody, which recognized 42-44 kDa protein(s) in dogfish brain stem homogenates, labeled astrocyte-like processes in the brain stem and cerebellum of the dogfish embryo and numerous large and small flat cells in the cerebellar cultures. These results demonstrate that dogfish oligodendrocytes, neurons, and astrocytes express antigens that are conserved in mammalian neural cells. The ability to culture and identify neural cell types from cartilaginous fish sets the stage for studies to determine if proliferation, migration, and differentiation of these cell types are regulated in a similar fashion to mammalian cells.

Expression of neurofilament proteins during development of the nervous system in the squid Loligo pealei.

The squid nervous system includes various brain ganglia, optic lobes (the visual center), and the stellate ganglia, the system of giant motor fibers responsible for rapid jet-propelled escape behavior. The large caliber of giant fibers is due, in part, to the accumulation of squid-specific neurofilaments (NFs) made up of a heavily phosphorylated NF 220 protein together with NF 70 and NF 60 subunits. Using antibodies prepared against known peptide sequences in these proteins, together with a mammalian-derived antibody that specifically recognizes phosphorylated squid NF 220, we studied the localization of NFs in adult tissues and during neural development. Immunoblot and immunohistochemical analyses showed that NFs were present in adult neural tissues, primarily in selected fibers, with giant axons showing the most robust expression. After the first neurons differentiated at stage 22, immunoblots showed NF 60- and NF 70-immunoreactive proteins at all stages. The NF 220 subunit, however, was not detected in immunoblots at any developmental stage. Phosphorylated NF 220 immunoreactivity, although absent in immunoblots, was first seen in selected fibers of the stellate ganglia at stage 25, increasing thereafter in all giant fibers until hatching (stage 30). The stellate ganglion is the first neural tissue to acquire a mature neurofilament complement (i.e., phosphorylated NF 220), shortly before the onset of jet-propelled escape behavior. The temporal pattern of expression of the NFs during development resembled that seen in vertebrates; i.e., the smaller NFs appeared before the larger subunit in most neural tissues. In the squid, the expression pattern seems to depend upon the post-transcriptional regulation of a single gene rather than upon transcriptional regulation of three independent genes as in vertebrates.

A simple biochemical approach to quantitate rough endoplasmic reticulum.

In this report we demonstrate that the changes in size of the rough endoplasmic reticulum (RER) can be determined by quantifying the membrane-bound ribosomal population separated by cell fractionation and sucrose density gradient analysis. Total cell membranes, rather than microsomes, were used as the source of membrane-bound ribosomes to eliminate potential losses during the preparation of microsomes. Bound ribosomes were assayed after quantitative release and recovery from total cell membranes using puromycin in the presence of high-salt buffer. Using this analysis, we demonstrate a 4.2-fold increase in RER in estrogen-treated male Xenopus laevis liver. Furthermore, we show that the ratio of the distribution of free to membrane-bound ribosomes in a nonsecretory cell line (HeLa) was 3.3, while this ratio in a secretory cell line (AR42J) was 1.2, indicating that cells active in secretion contain more RER. We suggest that this biochemical technique provides a simpler assay to detect changes in the size of the RER.

The number of Schmidt-Lanterman incisures is more than doubled in shiverer PNS myelin sheaths.

In the PNS, myelin basic protein (MBP) appears not to be essential for myelination, for in shiverer (shi) and mld mutant mice peripheral nerves, where MBP is not or only poorly expressed, myelination occurs normally. Only a few morphological abnormalities, i.e. reduction in axon calibre and myelin sheath thickness, and aberrant Schwann cell-axon contacts, have been reported. Here, we document a consistent difference between shi and wild type (wt) myelinated sciatic nerve fibres. The number of Schmidt-Lanterman incisures seen in longitudinally and transversely-sectioned sciatic nerves, or in teased fibres stained for the presence of F-actin, is dramatically increased in homozygous shi mice. With both methods, a twofold increase in Schmidt-Lanterman incisure number is seen in 15-day-old mice, the earliest time examined. The increase is slightly greater in nerve fibres from 30- and 90-day-old mice. The overproduction of Schmidt-Lanterman incisures in shi occurs in spite of the fact that the mean diameter of myelinated fibres in shi sciatic nerves is smaller than in wt sciatic nerves. These results lead us to suggest that the increase in Schmidt-Lanterman incisure density in shi compensates for a defect in Schwann cell-axon communication.

Tissue lipoproteins revisited: new proteolipid protein gene family members in elasmobranchs.

The proteolipids (PLPs) are abundant components of mammalian CNS myelin. Recombinant DNA methodologies have enabled us to search for evolutionary antecedents of PLP/DM20. Polymerase chain reactions of Torpedo and Squalus brain cDNA were performed with degenerate primers designed according to the mammalian PLP/DM20 sequence. Three DM20-related products (DM alpha, DM beta, and DM gamma) were amplified; no cDNAs containing the PLP-specific segment were found. Regions of the DM alpha and DM gamma are similar to the pore-forming segments of certain ligand-gated channels. In embryonic Squalus CNS, DM alpha and DM gamma appear to be co-expressed with P0. Antiserum raised against Torpedo DM alpha recognizes a protein in mouse CNS myelin, demonstrating that at least one of the newly recognized fish DMs is also in mammals. Our data, as well as that of other laboratories, supports the existence of a ubiquitously expressed proteolipid gene family.