Developmental regulation of plasticity along neurite shafts

Although it is becoming increasingly clear that structural dynamics on neurite shafts play important roles in establishing neuronal architecture, the underlying mechanisms are unknown. The present study investigates local induction of filopodia along the shafts of neurites, a process that, by analogy to the growth cone, can represent the first stage in the generation of a new neuronal process. We show that filopodia can be induced reliably along the neurite shaft in response to a localized electric field stimulus that evokes large local intracellular calcium increases. Neither induction of filopodia nor a local rise in intracellular calcium occurred in calcium free medium. Although calcium induction of neurite filopodia is highly reliable, forming in response to more than 90% of attempts, it is developmental state-dependent, since neurite filopodia could not be induced in neurons previously defined as “stable state.” We have found two distinct changes in stable state neurons that can decrease the ability to induce new neurites. The first is a reduced calcium response: Field stimulation produced large local rises (280 nM) in stable state neurons. Second, stable state neurons change so that even when the stimulus intensity was increased to elicit a calcium response that would have been sufficient to induce filopodia in growing neurites, neurite filopodia were still not induced. Thus, intracellular calcium plays a key role in structural changes along the shafts of neurites. Furthermore, developmental changes in both calcium homeostatic components, and in calcium responsiveness (i.e., the sensitivity of cellular components that modulate neurite morphology) underlie shifts from plasticity to stability of neuronal architecture in this system. © 1995 John Wiley & Sons, Inc.     

A mechanism for the transfer of the carboxyl-group from 1'-N-carboxybiotin to acceptor substrates by biotin-containing enzymes

Previous proposals for the mechanism by which biotin-dependent enzymes catalyse the transfer of the carboxyl group from 1'-N-carboxybiotin to acceptor molecules do not appear to be consistent with all of the experimental observations now available. We propose a multi-step mechanism in which (a) substrate and then carboxybiotin bind at the second partial reaction site, (b) a base positioned adjacent to the 3'-N of the carboxybiotin abstracts a proton from the 3'-N and (c) the resulting enolate ion and the acceptor substrate undergo a concerted reaction resulting in carboxyl-group transfer.     

Mutagenic activation of dialkylnitrosamines by intact urothelial cells

Intact urothelial cells isolated from bladders of untreated inbred NZO/BIGd or NZC/BIGd mice and NZR/Gd rats activated dimethyl, diethyl, dipropyl, and dibutyl nitrosamines in a liquid culture mutagenesis fluctuation assay using Salmonella typhimurium TA100 as target organism. Rat and mouse urothelial cells were highly effective at 1.5 X 10(5) cells/ml, in O2 gas phase, and no cofactors were required. Relative mutagenic activities were estimated at equitoxic (LD50) concentrations of the 4 nitrosamines. Nitrosamines with odd-carbon chain substitutents were more active than the C-even compounds. Although dibutylnitrosamine is a powerful bladder carcinogen in both rats and mice while the other 3 compounds very rarely cause bladder tumours, the most active promutagens were dipropyl and dimethyl, followed by diethyl and dibutyl nitrosamines. None were active in absence of urothelial cells. Mouse bladder cells were more active than those from NZR rats. There were sex differences in the mice with NZC males and NZO females predominating, but in NZR rats urothelial cells from male and female animals were equally active. These dialkylnitrosamines are widely distributed in the environment, and our results indicate that direct mutagenic activation in the urothelium could be one factor contributing to the incidence of bladder cancer.     

Activation of Protein Kinase C-α and Translocation of the Myristoylated Alanine-Rich C-Kinase Substrate Correlate with Phorbol Ester-Enhanced Noradrenaline Release from SH-SY5Y Human Neuroblastoma Cells

Abstract: The aim of this study was to investigate the mechanism by which short-term pretreatment with the phorbol ester 12- O -tetradecanoylphorbol 13-acetate (TPA; 100 n M ) enhances noradrenaline (NA) release from the human neuroblastoma cell line SH-SY5Y. Subcellular fractionation and immunocytochemical studies demonstrated that an 8-min TPA treatment caused translocation of the α-subtype of protein kinase C (PKC) from the cytosol to the plasma membrane. In contrast, TPA altered the distribution of PKC-ε from cytosolic and membrane-associated to cytoskeleton- and membrane-associated TPA had no effect on the cytosolic location of PKC-ζ. Subcellular fractionation studies also showed that the myristoylated alanine-rich C-kinase substrate (MARCKS), a major neuronal PKC substrate that has been implicated in the mechanism of neurotransmitter release, translocated from membranes to cytosol in response to an 8-min TPA treatment. Under these conditions the level of phosphorylation of MARCKS increased threefold. The ability of TPA to enhance NA release and to cause the translocation and phosphorylation of MARCKS was inhibited by the PKC inhibitor Ro 31-8220 (10 µ M ). Selective down-regulation of PKC subtypes by prolonged exposure to phorbol 12,13-dibutyrate (100 n M ) attenuated the TPA-induced enhancement of NA release and the translocation of MARCKS over an interval similar to that of down-regulation of PKC-α (but not -ε or -ζ). Thus, we have demonstrated a strong correlation between the translocation of MARCKS and the enhancement of NA release from SH-SY5Y cells due to the TPA-induced activation of PKC-α.     

Occurrence of Two Types of Secretory Vesicles in the Human Neuroblastoma SH-SY5Y

Abstract: Western blot analysis showed that the human neuroblastoma SH-SY5Y expresses the proteins synaptotagmin I, synaptobrevin, synapsin I, rab3a, syntaxin, SNAP-25, NSF, α-SNAP, and munc-18, which have been implicated in the movement, docking, and fusion of vesicles during exocytosis from other neuroendocrine cells. The subcellular localization of secretogranins I and II, synaptotagmin I, neuropeptide Y, rab3a, synaptobrevin, synaptophysin, and syntaxin was investigated by immunofluorescence microscopy and revealed punctate staining patterns characteristic of secretory vesicles. The comigration of noradrenaline, secretogranin II, and dopamine-β-hydroxylase on sucrose-D₂O gradient fractions indicates the presence of a population of noradrenaline-containing large dense-cored vesicles (LDCVs). In addition, a lighter vesicle population is also present that does not appear to be noradrenergic and contains a 48-kDa synaptophysin antigen absent from the large dense-cored vesicles. Immunocytochemical experiments show that not all of the vesicles that express synaptotagmin I contain secretogranin II. Thus, our studies suggest that two types of vesicle are present in SH-SY5Y cells, one of which, the LDCVs, contains noradrenaline. These findings confirm our previous studies suggesting that depolarization-evoked release of noradrenaline from SH-SY5Y occurs by LDCV exocytosis. This enhances the value of SH-SY5Y as a cell line in which to study the mechanism by which noradrenaline release is regulated.