The Second Messenger, Cyclic AMP, Is Not Sufficient for Myelin Gene Induction in the Peripheral Nervous System

Abstract: The adenylyl cyclase-cyclic AMP (cAMP) second messenger pathway has been proposed to regulate myelin gene expression; however, a clear correlation between endogenous cAMP levels and myelin-specific mRNA levels has never been demonstrated during the induction or maintenance of differentiation by the myelinating Schwann cell. Endogenous cAMP levels decreased to 8–10% of normal nerve by 3 days after crush or permanent transection injury of adult rat sciatic nerve. Whereas levels remained low after transection injury, cAMP levels reached only 27% of the normal values by 35 days after crush injury. Because P₀ mRNA levels were 60% of normal levels by 14 days and 100% by 21 days after crush injury, cAMP increased only well after P₀ gene induction. cAMP, therefore, does not appear to trigger myelin gene induction but may be involved in myelin assembly or maintenance. Forskolin, an activator of adenylyl cyclase, increased endoneurial cAMP levels only in the normal nerve, and in the crushed nerve beginning at 16 days after injury, but at no time in the transected nerve. Only by treating transected nerve with 3-isobutyl-1-methylxanthine (IBMX), an inhibitor of cAMP phosphodiesterases, in combination with forskolin was it possible to increase cAMP levels. No induction of myelin genes, however, was observed with short- or long-term treatment with IBMX and forskolin in the transected nerve. A three-fold increase in phosphodiesterase activity was observed at 35 days after both injuries, and a nonmyelinated nerve was shown to have even higher activity. These experiments, therefore, suggest an important role for phosphodiesterase in the inactivation of this second messenger-dependent stimuli when Schwann cells are non-myelinating, such as after sciatic nerve injury or in the nonmyelinated nerve, which again implies that cAMP may be required for the maintenance of the myelin sheath.     

Characterisation of Antibodies Specific for Chick Brain Neural Cell Adhesion Molecules Which Cause Amnesia for a Passive Avoidance Task

Abstract: Antisera were prepared against six postsynaptic density glycoprotein fractions (150–180, 62–80, 50, 41, 33, and 28 kDa) that show enhanced fucosylation during memory formation after training day-old chicks in a one-trial passive avoidance task. Each antiserum was tested for its possible effect on memory retention. Bilateral intracranial injections of two of the antisera, R-1 and R-6, or their IgGs (IgG-1 and IgG-6), resulted in amnesia for the passive avoidance task when chicks were tested 24 h later. IgG-1 and IgG-6 antibodies were amnestic only when injected 5.5 h after training, and had no effect when injections were made 30 min before training, thus resembling an effect previously observed with polyclonal or monoclonal anti-N-CAM antibodies. IgG-1 and IgG-6 antibodies were found to be specific for protein epitopes of glycoproteins that contain a high amount of N-linked mannose and fucose, and a very low amount of polysialic acid and O-linked galactose. Absorption of IgG-6 antibodies with neural cell adhesion molecule (N-CAM) isolated from synaptic plasma membranes derived from day-old chick brain resulted in loss of amnestic effect. As we have previously shown that long-term memory for the passive avoidance task requires two waves of glycoprotein synthesis, the first occurring immediately after training and the second 5–8 h later, the present results suggest strongly that isoforms of N-CAM molecules with a low level of sialic acid are involved specifically in the establishment of an enduring memory for the experience of the passive avoidance task in chicks, possibly by stabilising changes in synaptic connectivity that encode the memory.     

Inhibition of Kinesin Synthesis In Vivo Inhibits the Rapid Transport of Representative Proteins for Three Transport Vesicle Classes into the Axon

Abstract: We have previously demonstrated that the in vivo vitreal injection of an antisense oligonucleotide directed to the kinesin heavy chain inhibits retinal kinesin synthesis by 82% and concomitantly inhibits rapid transport of total protein into the optic nerve by 70%. These results establish a major role for kinesin in rapid axonal transport in vivo. Recently, the cloning of a family of kinesin-like molecules from the mammalian brain has been reported, and some of these proteins are also expressed in neurons. To assign a specific function to the kinesin heavy chain we inhibited the kinesin synthesis with an antisense kinesin oligonucleotide and assessed the axonal transport into the optic nerve of representative proteins from each of three vesicle classes that contain rapidly transported proteins. Marker proteins used were substance P for peptide-containing synaptic vesicles, the amyloid precursor protein for plasma membrane precursor vesicles, and several integral synaptic vesicle proteins. Our results indicate that the major anterograde motor protein for all three vesicle classes utilizes kinesin heavy chain, although we discuss alternative explanations.     

Tyrosine Kinase Activity Is Essential for Interleukin-1β-Stimulated Production of Interleukin-6 in U373 Human Astrocytoma Cells

Abstract: Previous studies have shown that PC12 cells depend on growth factors for their survival. When deprived of growth factors, the cells undergo a dying process termed "apoptosis" (programed cell death). We show here that muscarinic agonists inhibited the apoptotic death of growth factor-deprived PC12M1 cells (PC12 cells stably expressing cloned m1 muscarinic acetylcholine receptors). This protective effect of the muscarinic agonists was observed in both proliferating and neuronal PC12M1 cells, was blocked by the muscarinic antagonist atropine, and was not observed in PC12 cells lacking m1 receptors. Muscarinic receptors therefore mediate inhibition of apoptosis in these cells. In addition to its effect on survival, the muscarinic agonist oxotremorine induced inhibition of DNA synthesis as well as growth arrest of exponentially growing PC12M1 cells at the S and G₂/M phases of the cell cycle. Muscarinic receptors in these cells may therefore mediate inhibition of cell cycle progression.     

GROWTH OF HETEROSIGMA CARTERAE (RAPHIDOPHYCEAE) ON NITRATE AND AMMONIUM AT THREE PHOTON FLUX DENSITIES: EVIDENCE FOR N STRESS IN NITRATE-GROWING CELLS

The marine alga Heterosigma carterae Hulburt (Raphidophyta) was grown in N-limiting batch cultures using either nitrate or ammonium as the N source, at photon flux densities (PFDs) of 50, 200, and 350 μmol·m^-2·s^-1 in a 12:12 h LD cycle. Carbon content could be estimated from biovolume (μg C = 0.278 × nL; R = 0.98) but not reliably from pigment content. During exponential growth, ammonium-grown cells (in comparison with nitrate-grown cells at the same PFD) attained higher growth rates by at least 20%, contained more N, and had a lower C:N ratio, higher concentrations of intracellular free amino acids, and higher ratios of glutamine: glutamate (Gln: Glu) and asparagine: aspartate (Asn:Asp). Growth was nearly light-saturated on ammonium at 200 μmol·m^-2·s^-1 (cell-specific growth rate of 1.2 d^-1) but probably not saturated in nitrate-grown cells at 350 μmol·m^-2·s^-1. PFD did not affect Gln: Glu or Asn: Asp for a given N source. These results indicate that the nitrate-growing cells were more N-stressed than those using ammonium (which in contrast were relatively C-stressed) and that this organism would show an enhanced competitive advantage against other species when supplied with a transient supply of ammonium rather than nitrate .     

Identification of New Oligodendrocyte- and Myelin-Specific Genes by a Differential Screening Approach

Abstract: We have isolated several new genes that are specifically expressed by oligodendrocytes in the CNS. This was achieved by differential screening of a rat spinal cord cDNA library with probes derived from normal and from oligodendrocyte-free spinal cord mRNAs. Four of these genes are exclusively expressed by oligodendrocytes: Three of these are not related to known genes, whereas one encodes the myelin oligodendrocyte glycoprotein (MOG). Four other genes are expressed by oligodendrocytes as well as by Schwann cells. One gene codes for apolipoprotein D, which is thought to be involved in lipid metabolism. A second cDNA sequence codes for the recently identified galactosylceramide-synthesizing enzyme UDP-galactose:ceramide galactosyl-transferase. The third gene encodes a small protein with four putative transmembrane domains that is related to a T-lymphocyte-specific membrane protein, MAL. The fourth gene encodes the rat homologue of the stearyl-CoA-desaturase 2 (SCD2) gene, which is specifically expressed in the nervous system and involved in the synthesis and regulation of long-chain unsaturated fatty acids essential for myelination. Finally, we found that a member of the β-tubulin family is highly expressed in oligodendrocytes as well as neurons. The identification of several new proteins that may play a role in myelin synthesis and sheath formation will lead to new insight into this complex mechanism.     

DIVISION APPARATUS OF THE CHLOROPLAST IN NANNOCHLORIS BACILLARIS (CHLOROPHYTA)1

Chloroplast division in Nannochloris bacillaris Naumann (Chlorophyta) was examined by electron microscopy after preparation of samples by freeze-substitution. A pair of belts appeared on the surface of the outer and inner envelope membranes at the middle of the chloroplast. These belts seemed to be constructed of thin fibrils that run parallel to the longitudinal direction of the belts. The outer fibrillar belt increased in width as the constriction of the chloroplast advanced. It appears that the fibrillar belt is the division apparatus of the chloroplast. It encircles the chloroplast and finally divides the chloroplast in two as the diameter of the belt decreases.     

GROWTH CHARACTERISTICS OF PHYTOPLANKTON DETERMINED BY CELL CYCLE PROTEINS: PCNA IMMUNOSTAINING OF DUNALIELLA TERTIOLECTA (CHLOROPHYCEAE)1

By immunohistochemistry and immunofluorescence methods, we observed that the analog of proliferating cell nuclear antigen (PCNA) in Dunaliella tertiolecta Butcher (Chlorophyceae) was exclusively located in the nucleus. Among positively stained cells, PCNA abundance varied, being highest in S-phase cells, lower in others, and undetectable in early G1- or late M-phase cells. In exponentially growing and partially synchronized cultures, the percentage of PCNA-stained cells (% PCNA-stained cells) oscillated in the photocycle (12:12 h LD). It increased during the light period and reached a peak (75%) before the onset of the dark period when the culture was mainly (71%) in the S phase of the cell cycle. The DNA synthesis inhibitor, hydroxyurea, depressed PCNA abundance, whereas no effect was detected for the mitosis inhibitor colchicine. We conclude that PCNA in D. tertiolecta is associated with the S phase of the cell cycle where it is accumulated and functioning. PCNA was used to characterize the growth pattern of cultures grown in different media, temperatures, and growth stages. The time lag between the PCNA-stained phase and the M phase was very short in a continuous culture grown in reduced f/2 medium at 22°C and was considerably longer in the cultures grown in f/2 at 15°C. When an exponentially growing culture grew older, % PCNA-stained cells decreased. In a late stationary culture where there was no net growth, a small number of cells were still cycling through the PCNA-stained phase and cell division. In the continuous culture grown at 22°C, the duration of the PCNA-stained phase (T_s) was 13 h. Calculations with this T_s and % PCNA-stained cells yielded a growth rate of 0.77 d^?1, which was close to that obtained by cell counts (0.69 d^?1). Taken together, the results suggest that PCNA is a useful indicator of growth status and a promising cell cycle marker for estimation of species-specific growth rate.     

DNA damage and repair in somatic and germ cells in vivo

Alkylation-induced germ cell mutagenesis in the mouse versus Drosophila is compared based on data from forward mutation assays (specific-locus tests in the mouse and in Drosophila and multiple-locus assays in the latter species) but not including assays for structural chromosome aberrations. To facilitate comparisons between mouse and Drosophila, forward mutation test results have been grouped into three categories. Representatives of the first category are MMS (methyl methanesulfonate) and EO (ethylene oxide), alkylating agents with a high s value which predominantly react with ring nitrogens in DNA. ENU (N-ethyl-N-nitrosourea), MNU (N-methyl-N-nitrosourea), PRC (procarbazine), DEN (N-nitrosodiethylamine), and DMN (N-nitrosodimethylamine) belong to the second category. These agents have in common a considerable ability for modification at oxygens in DNA. Cross-linking agents (melphalan, chlorambucil, hexamethylphosphoramide) from the third category.The most unexpected, but encouraging outcome of this study is the identification of common features for three vastly different experimental indicators of genotoxicity: hereditary damage in Drosophila males, genetic damage in male mice, and tumors (TD₅₀ estimates) in rodents. Based on the above three category classification scheme the following tentative conclusions are drawn. Monofunctional agents belonging to category 1, typified by MMS and EO, display genotoxic effects in male germ cell stages that have passed meiotic division. This phenomenon seems to be the consequence of a repair deficiency during spermiogenesis for a period of 3–4 days in Drosophila and 14 days in the mouse. We suggest that the reason for the high resistance of premeiotic stages, and the generally high TD₅₀ estimates observed for this class in rodents, is the efficient error-free repair of N-alkylation damage. If we accept this hypothesis, then the increased carcinogenic potential in rodents, seen when comparing category 2 (ENU-type mutagens) to category 1 (MMS-type mutagens), along with the ability of category 2 genotoxins to induce genetic damage in premeiotic stages, must presumably be due to their enhanced ability for alkylations at oxygens in DNA; it is this property that actually distinguishes the two groups from each other. In contrast to category 1, examination of class 2 genotoxins (ENU and DEN) in premeiotic cells of Drosophila gave no indication for a significant role of germinal selection, and also removal by DNA repair was less dramatic compared to MMS. Thus category 2 mutagens are expected to display activity in a wide range of both post- and premeiotic germ cell stages. A number of these agents have been demonstrated to be among the most potent carcinogens in rodents. In terms of both hereditary damage and the initiation of cancers (low TD₅₀), cross-linking agents (category 3) comprise a considerable genotoxic hazard. Doubling doses for the mouse SLT have been determined for four cross-linking agents not requiring metabolic conversion and in all four cases the doubling doses for these agents were lower than those for MMS, DES and EMS. In support of this conclusion, two of 10 genotoxic agents, for which data on chromosomal aberrations were available for both somatic cells and germ cells in mice, were cross-linking agents and again the doubling dose estimates are lower than for monofunctional agents. Four cross-linking agents induced mutations in stem cell spermatogonia indicating that this type of agent can be active in a wide range of germ cell stages.Quite in contrast to what is generally observed in unicellular systems and in mammalian cells in culture, both cross-linking agents and MMS-type mutagens (high s value) predominantly produce deletion mutations in postmeiotic male germ cell stages. This is the uniform picture found for both Drosophila and the mouse. It is concluded that in vitro systems, in contrast to Drosophila germ cells, fail to predict this very intriguing feature of mouse germ line mutagenesis. In addition to their potential for induction of deletions and other rearrangements, cross-linking agents are among the most efficient inducers of mitotic recombination in Drosophila. Thus there are several mechanisms by which cross-linking agents may cause loss of heterozygosity for long stretches of DNA sequences, leading to expression of recessive genes. Since a substantial portion of agents used in the chemotherapy of cancers have cross-linking potential, the potential hazards of hereditary damage and cancers associated with this class of genotoxins should, in our opinion, receive more attention than they have in the past.