Isoform-specific interaction of the alpha1A subunits of brain Ca2+ channels with the presynaptic proteins syntaxin and SNAP-25.

Presynaptic Ca2+ channels are crucial elements in neuronal excitation-secretion coupling. In addition to mediating Ca2+ entry to initiate transmitter release, they are thought to interact directly with proteins of the synaptic vesicle docking/fusion machinery. Here we report isoform-specific, stoichiometric interaction of the BI and rbA isoforms of the alpha1A subunit of P/Q-type Ca2+ channels with the presynaptic membrane proteins syntaxin and SNAP-25 in vitro and in rat brain membranes. The BI isoform binds to both proteins, while only interaction with SNAP-25 can be detected in vitro for the rbA isoform. The synaptic protein interaction ("synprint") site involves two adjacent segments of the intracellular loop connecting domains II and III between amino acid residues 722 and 1036 of the BI sequence. This interaction is competitively blocked by the corresponding region of the N-type Ca2+ channel, indicating that these two channels bind to overlapping regions of syntaxin and SNAP-25. Our results provide a molecular basis for a physical link between Ca2+ influx into nerve terminals and subsequent exocytosis of neurotransmitters at synapses that have presynaptic Ca2+ channels containing alpha1A subunits.

Structure and functional expression of a member of the low voltage-activated calcium channel family.

Oscillatory firing patterns are an intrinsic property of some neurons and have an important function in information processing. In some cells, low voltage-activated calcium channels have been proposed to underlie a depolarizing potential that regulates bursting. The sequence of a rat brain calcium channel alpha 1 subunit (rbE-II) was deduced. Although it is structurally related to high voltage-activated calcium channels, the rbE-II channel transiently activated at negative membrane potentials, required a strong hyperpolarization to deinactivate, and was highly sensitive to block by nickel. In situ hybridization showed that rbE-II messenger RNA is expressed in regions throughout the central nervous system. The electrophysiological properties of the rbE-II current are consistent with a type of low voltage-activated calcium channel that requires membrane hyperpolarization for maximal activity, which suggests that rbE-II may be involved in the modulation of firing patterns.

Percutaneous penetration of para-substituted phenols in vitro.

The percutaneous penetration of 11 para-substituted phenols has been measured across full-thickness hairless mouse skin in vitro. The phenols, which spanned more than a 1000-fold range in octanol/water partition coefficient (P), were applied (14C-radiolabeled) to the skin surface in a small volume of volatile organic solvent. Permeation kinetics were continuously monitored and were characterized by the maximum observed flux (Jmax). The linear correlation of log Jmax with log P was very poor. However, inclusion of molecular volume (MV) in a multiple regression analysis considerably improved the relationship between the measured transport parameter and the physicochemical descriptors. Furthermore, significant parabolic (log Jmax = -0.18 + 1.35.log P - 0.30.[log P]2) and bilinear (log Jmax = -0.17 + 1.08.log P - 1.95.[log(beta.10logP + 1)]) dependencies were obtained, suggesting a change in the rate-limiting transport step (for compounds of high log P) from diffusion across the stratum corneum (SC) to partitioning at the SC-viable epidermis interface. Addition of a term in MV (or molar refractivity) further improved the absolute correlations, but with marginal statistical significance. A wider range of molecular size is necessary to unequivocally define the role of permeant dimensions in percutaneous permeability for this group of compounds. The quadratic log Jmax correlation with log P was compared to the previously reported steady-state permeability coefficients (Kp) of a different set of phenol analogs through human epidermis. Despite the different methodologies, different compounds, and different skin membranes employed, the patterns of behavior in the two data sets were consistent, and suggest that the form of this correlation may be suitable description of phenol permeability under a range of experimental conditions.

The effects of zwitterionic surfactants on skin barrier function.

The action of five zwitterionic surfactants on the barrier function of hairless mouse skin has been studied in vitro. The surfactants considered were dodecylbetaine and hexadecylbetaine (C12BET and C16BET, respectively), hexadecylsulfobetaine (C16SUB), N,N-dimethyl-N-dodecylamine oxide (C12AO), and dodecyltrimethylammonium bromide (C12TAB). Excised skin was pretreated with each surfactant, at various concentrations, for 16 hr, following which the permeation of a model compound, nicotinamide, was measured. The action of the surfactants was assessed by comparing nicotinamide flux through surfactant-pretreated skin with that across control membranes which were exposed to buffer alone for 16 hr. All surfactants decreased skin barrier function to some extent. The degree of nicotinamide penetration enhancement induced was correlated with the ratio of the surfactant pretreatment concentration to the surfactant critical micelle concentration, suggesting that solubilization of stratum corneum lipids may be an important mechanism in explaining the effects observed. More detailed studies with 14C-radiolabeled C12BET and C16BET showed that the dodecyl analog was itself well absorbed, whereas the C16 compound partitioned into the skin favorably but then transferred only very slowly into the receptor phase. These observations were consistent with toxicity studies (albeit at much higher concentrations in a different animal model, the rat) which indicated that the dermal LD50 of C12BET was significantly less than that of C16BET (the value for which was so large that it could not be reliably determined). Overall, this study provides, we believe, useful information pertinent to the potential dermal toxicity of the surfactants considered following occupational or environmental exposure.

In vitro percutaneous penetration: evaluation of the utility of hairless mouse skin.

The permeability barrier of hairless mouse skin has been determined in vitro after exposure of the epidermal surface to volumes of acetone typically used in human in vivo skin penetration studies. It has been shown that the transport of tritiated water (when applied for limited 5-h periods) across hairless mouse skin is not affected by acetone treatments of approximately 15 microliters/cm2. Submersion of the membranes between aqueous donor and receptor phases for periods greater than 24 h, however, leads to significant and catastrophic barrier impairment. The acetone dose in the experiments reported is greater than that employed in vivo when the solvent is used to deposit a penetrant on human skin. We suggest, therefore, that acetone-mediated facilitation of percutaneous absorption in humans is unlikely. A further conclusion of this work is that in vitro solvent-deposition penetration experiments using hairless mouse skin should provide reliable transport information for at least 48 h postadministration. Although hairless mouse skin is more permeable than its human counterpart, in vitro measurements using the murine barrier should, therefore, provide useful and relevant guidelines for risk assessment calculations and bioavailability determinations.