Behavioral and thyroid effects of in utero and lactational exposure of Sprague-Dawley rats to the polybrominated diphenyl ether mixture DE71.

Exposure of rodents during gestation and lactation to polybrominated diphenyl ethers (PBDEs) has been reported to disrupt neurobehavioral function in offspring, as well as to disrupt thyroid function. To assess this we evaluated development and behavior after gestational and lactational exposure to the technical PBDE mixture DE71. Pregnant Sprague-Dawley rats were exposed to 0, 0.3, 3.0 or 30 mg/kg/day of DE71 from gestation day 1 to postnatal day (PND) 21 and were assessed on a wide range of behavioral functions from early postnatal period until old age (PND 450). DE71 exposure decreased thyroid hormone levels (T3 and T4) in mothers and offspring with offspring being more sensitive that mothers. Developmental landmarks, neuromotor function, anxiety, learning and memory were not affected by DE71 at any age. DE71 produced small changes in motor activity rearing only at PND 110 but not at any other age and no other activity measure was altered by DE71. Cholinergic sensitivity measured by nicotine-stimulated motor activity was not affected by perinatal DE71 exposure. Acoustic startle responses were potentiated by DE71 at PND 90 indicating delayed effects on sensory reactivity. Habituation was measured in motor activity tests at five ages but was not altered by DE71 at any age. Habituation measured in startle tests was also not affected by exposure to DE71. For thyroid hormone levels at PND 21, the lowest adverse effect level was 3.0 mg/kg. Few behavioral effects were observed and the lowest adverse effect level was 30 mg/kg. Our results confirm that DE71 produces transient effects on thyroid hormone levels but does not result in learning or motor impairment and does not alter non-associative learning (habituation).

JSAP1/JIP3 and JLP regulate kinesin-1-dependent axonal transport to prevent neuronal degeneration.

Axonal transport is critical for neuronal development and function, and defective axonal transport has been implicated in neurodegenerative diseases. However, how axonal transport is regulated, or how defective transport leads to neuronal degeneration, remains unclear. Here, we report that c-Jun NH2-terminal kinase (JNK)/stress-activated protein kinase-associated protein 1 (JSAP1, also known as JNK-interacting protein 3 (JIP3)) and JNK-associated leucine zipper protein (JLP) are essential for postnatal brain development. Mice with a double-knockout (dKO) in Jsap1 and Jlp in the dorsal telencephalon developed progressive neuron loss. Using a primary neuron culture system with induced disruption of targeted genes, combined with gene rescue experiments, we show that JSAP1 and JLP regulate kinesin-1-dependent axonal transport with functional redundancy. We also show that the binding of JSAP1 and JLP to kinesin-1 heavy chain is crucial for interactions between kinesin-1 and microtubules. Furthermore, we describe a molecular mechanism by which defective kinesin-1-dependent axonal transport in Jsap1:Jlp dKO neurons causes axonal degeneration and subsequent neuronal death. JNK hyperactivation because of increased intra-axonal Ca(2+) in the Jsap1:Jlp dKO neurons was found to mediate both the axonal degeneration and neuronal death, in cooperation with the Ca(2+)-dependent protease calpain. Our results indicate that axonal JNK may relocate to the nucleus in a dynein-dependent manner, where it activates the transcription factor c-Jun, resulting in neuronal death. Taken together, our data establish JSAP1 and JLP as positive regulators of kinesin-1-dependent axonal transport, which prevents neuronal degeneration.

Pretreatment of donor islets with the Na(+) /Ca(2+) exchanger inhibitor improves the efficiency of islet transplantation.

Pancreatic islet transplantation is an attractive therapy for the treatment of insulin-dependent diabetes mellitus. However, the low efficiency of this procedure necessitating sequential transplantations of islets with the use of 2-3 donors for a single recipient, mainly due to the early loss of transplanted islets, hampers its clinical application. Previously, we have shown in mice that a large amount of HMGB1 is released from islets soon after their transplantation and that this triggers innate immune rejection with activation of DC, NKT cells and neutrophils to produce IFN-γ, ultimately leading to the early loss of transplanted islets. Thus, HMGB1 release plays an initial pivotal role in this process; however, its mechanism remains unclear. Here we demonstrate that release of HMGB1 from transplanted islets is due to hypoxic damage resulting from Ca(2+) influx into ß cells through the Na(+) /Ca(2+) exchanger (NCX). Moreover, the hypoxia-induced ß cell damage was prevented by pretreatment with an NCX-specific inhibitor prior to transplantation, resulting in protection and long-term survival of transplanted mouse and human islets when grafted into mice. These findings suggest a novel strategy with potentially great impact to improve the efficiency of islet transplantation in clinical settings by targeting donor islets rather than recipients.

Subchronic toxicity of chloral hydrate on rats: a drinking water study.

The subchronic toxicity of chloral hydrate, a disinfection byproduct, was studied in rats following 13 weeks of drinking water exposure. Male (262 +/- 10 g) and female (190 +/- 8 g) Sprague-Dawley rats, ten animals per group, were administered chloral hydrate via drinking water at 0.2, 2, 20 and 200 ppm. Control animals received distilled water only. Gross and microscopic examinations, serum chemistry, hematology, biochemical analysis, neurogenic amine analysis and serum trichloroacetic acid (TCA) analysis were performed at the end of the treatment period. Bronchoalveolar fluids were collected at necropsy and urine specimens were collected at weeks 2, 6 and 12 for biochemical analysis. No treatment-related changes in food and water intakes or body weight gains were observed. There were no significant changes in the weights of major organs. Except for a mild degree of vacuolation within the myelin sheath of the optic nerves in the highest dose males, there were no notable histological changes in the tissues examined. Statistically significant treatment-related effects were biochemical in nature, with the most pronounced being increased liver catalase activity in male rats starting at 2 ppm. Liver aldehyde dehydrogenase (ALDH) was significantly depressed, whereas liver aniline hydroxylase activity was significantly elevated in both males and females receiving the highest dose. A dose-related increase in serum TCA was detected in both males and females starting at 2 ppm. An in vitro study of liver ALDH confirmed that chloral hydrate was a potent inhibitor, with an IC(50) of 8 micro M, whereas TCA was weakly inhibitory and trichloroethanol was without effect. Analysis of brain biogenic amines was conducted on a limited number (n = 5) of male rats in the control and high dose groups, and no significant treatment-related changes were detected. Taking into account the effect on the myelin sheath of male rats and the effects on liver ALDH and aniline hydroxylase of both males and females at the highest dose level, the no-observed-effect level (NOEL) was determined to be 20 ppm or 1.89 mg kg(-1) day(-1) in males and 2.53 mg kg(-1) day(-1) in females. This NOEL is ca. 1000-fold higher than the highest concentration of chloral hydrate reported in the municipal water supply.

A high signal-to-noise Ca(2+) probe composed of a single green fluorescent protein.

Recently, several groups have developed green fluorescent protein (GFP)-based Ca(2+) probes. When applied in cells, however, these probes are difficult to use because of a low signal-to-noise ratio. Here we report the development of a high-affinity Ca(2+) probe composed of a single GFP (named G-CaMP). G-CaMP showed an apparent K(d) for Ca(2+) of 235 nM. Association kinetics of Ca(2+) binding were faster at higher Ca(2+) concentrations, with time constants decreasing from 230 ms at 0.2 microM Ca(2+) to 2.5 ms at 1 microM Ca(2+). Dissociation kinetics (tau approximately 200 ms) are independent of Ca(2+) concentrations. In HEK-293 cells and mouse myotubes expressing G-CaMP, large fluorescent changes were observed in response to application of drugs or electrical stimulations. G-CaMP will be a useful tool for visualizing intracellular Ca2+ in living cells. Mutational analysis, together with previous structural information, suggests the residues that may alter the fluorescence of GFP.

Effects of subchronic exposure of rats to dichloramine and trichloramine in drinking water.

The subchronic toxicity of 0.2-200 ppm dichloramine and 0.2-90 ppm trichloramine in the drinking water of rats was investigated using biochemical, hematological, and histopathological parameters. Animals in the highest dose groups consumed 5-15% less fluid than controls with no significant decrease in body weight gain. No clinical signs of toxicity were observed in either case. Both males and females dosed with 90 ppm trichloramine had significantly increased relative kidney/body weights and the females had increased hepatic glutathione S-transferase and UPD-glucuronosyltransferase activities. No significant changes were detected in other xenobiotic metabolizing enzymes or in serum biochemistry, urine biochemistry, or hematology. Both dichloramine and trichloramine induced minimal to mild adaptive histopathological changes in thyroids and kidneys of animals of both sexes. Dichloramine, but not trichloramine, was associated with histological changes in the gastric cardia characterized by epithelial hyperplasia at concentrations of 2 ppm and above in the males and 200 ppm in the females. This study indicates that dichloramine produced mild histological effects at drinking water concentrations of >0.2 ppm in males (0.019 mg/kg/day) and >2 ppm in females (0.26 mg/kg/day) while trichloramine produced biochemical and mild histological effects at levels of >2 ppm both in males (0.23 mg/kg/day) and in females (0.29 mg/kg/day).

Penetration of chloroform, trichloroethylene, and tetrachloroethylene through human skin.

In vitro dermal absorption was measured for three volatile organic compounds in dilute aqueous solution through freshly prepared and previously frozen human skin. The permeability coefficients at 26 degrees C for chloroform (0.14 cm/h) and trichloroethylene (0.12 cm/h) were similar but much larger than that for tetrachloroethylene (0.018 cm/h). Storage of the skin at -20 degrees C did not significantly affect the penetration of these chemicals. The dermal absorption of chloroform through freshly prepared human skin was not changed significantly by pretreatment of the skin with commonly used consumer products (moisturizer, baby oil, insect repellent, sunscreen); however, the permeability coefficient was found to increase from 0.071 cm/h at 11 degrees C to 0.19 cm/h at 50 degrees C. These data suggest that exposure estimates for chloroform and other contaminants in water should consider the appropriate exposure scenario to properly assess the dermal dose.

Evidence for a role of C-terminus in Ca(2+) inactivation of skeletal muscle Ca(2+) release channel (ryanodine receptor).

Six chimeras of the skeletal muscle (RyR1) and cardiac muscle (RyR2) Ca(2+) release channels (ryanodine receptors) previously used to identify RyR1 dihydropyridine receptor interactions [Nakai et al. (1998) J. Biol. Chem. 273, 13403] were expressed in HEK293 cells to assess their Ca(2+) dependence in [(3)H]ryanodine binding and single channel measurements. The results indicate that the C-terminal one-fourth has a major role in Ca(2+) activation and inactivation of RyR1. Further, our results show that replacement of RyR1 regions with corresponding RyR2 regions can result in loss and/or reduction of [(3)H]ryanodine binding affinity while maintaining channel activity.

Localization in the II-III loop of the dihydropyridine receptor of a sequence critical for excitation-contraction coupling.

Skeletal and cardiac muscles express distinct isoforms of the dihydropyridine receptor (DHPR), a type of voltage-gated Ca2+ channel that is important for excitation-contraction (EC) coupling. However, entry of Ca2+ through the channel is not required for skeletal muscle-type EC coupling. Previous work (Tanabe, T., Beam, K. G., Adams, B. A., Niidome, T., and Numa, S. (1990) Nature 346, 567-569) revealed that the loop between repeats II and III (II-III loop) is an important determinant of skeletal-type EC coupling. In the present study we have further dissected the regions of the II-III loop critical for skeletal-type EC coupling by expression of cDNA constructs in dysgenic myotubes. Because Ser687 of the skeletal II-III loop has been reported to be rapidly phosphorylated in vitro, we substituted this serine with alanine, the corresponding cardiac residue. This alanine-substituted skeletal DHPR retained the ability to mediate skeletal-type EC coupling. Weak skeletal-type EC coupling was produced by a chimeric DHPR, which was entirely cardiac except for a small amount of skeletal sequence (residues 725-742) in the II-III loop. Skeletal-type coupling was stronger when both residues 725-742 and adjacent residues were skeletal (e.g. a chimera containing skeletal residues 711-765). However, residues 725-742 appeared to be critical because skeletal-type coupling was not produced either by a chimera with skeletal residues 711-732 or by one with skeletal residues 734-765.

Two regions of the ryanodine receptor involved in coupling with L-type Ca2+ channels.

Ryanodine receptors (RyRs) are present in the endoplasmic reticulum of virtually every cell type and serve critical roles, including excitation-contraction (EC) coupling in muscle cells. In skeletal muscle the primary control of RyR-1 (the predominant skeletal RyR isoform) occurs via an interaction with plasmalemmal dihydropyridine receptors (DHPRs), which function as both voltage sensors for EC coupling and as L-type Ca2+ channels (Rios, E., and Brum, G. (1987) Nature 325, 717-720). In addition to "receiving" the EC coupling signal from the DHPR, RyR-1 also "transmits" a retrograde signal that enhances the Ca2+ channel activity of the DHPR (Nakai, J., Dirksen, R. T., Nguyen, H. T., Pessah, I. N., Beam, K. G., and Allen, P. D. (1996) Nature 380, 72-76). A similar kind of retrograde signaling (from RyRs to L-type Ca2+ channels) has also been reported in neurons (Chavis, P., Fagni, L., Lansman, J. B., and Bockaert, J. (1996) Nature 382, 719-722). To investigate the molecular mechanism of reciprocal signaling, we constructed cDNAs encoding chimeras of RyR-1 and RyR-2 (the predominant cardiac RyR isoform) and expressed them in dyspedic myotubes, which lack an endogenous RyR-1. We found that a chimera that contained residues 1,635-2,636 of RyR-1 both mediated skeletal-type EC coupling and enhanced Ca2+ channel function, whereas a chimera containing adjacent RyR-1 residues (2, 659-3,720) was only able to enhance Ca2+ channel function. These results demonstrate that two distinct regions are involved in the reciprocal interactions of RyR-1 with the skeletal DHPR.

Molecular cloning and characterization of a human brain ryanodine receptor.

We have cloned and sequenced the cDNA of the human brain ryanodine receptor (RyR3), which is composed of 4866 amino acids and shares characteristic structural features with the rabbit RyR3. Northern blot analysis shows that the human RyR3 mRNA is abundantly expressed in hippocampus, caudate nucleus and amygdala as well as in skeletal muscle. The human RyR3 mRNA is also detected in several cell lines derived from human brain tumors. Functional expression of RyR3 and a chimeric RyR suggests that RyR3 forms a calcium-release channel with a very low Ca2+ sensitivity.

The S5-S6 linker of repeat I is a critical determinant of L-type Ca2+ channel conductance.

The alpha1-subunits of the skeletal and cardiac L-type calcium channels (L-channels) contain nearly identical pore regions (P-regions) in each of the four internal homology repeats. In spite of this high conservation of the P-regions, native skeletal L-channels exhibit a unitary conductance that is only about half that of native cardiac L-channels. To identify structural determinants of this difference in L-channel conductance, we have characterized unitary activity in cell-attached patches of dysgenic myotubes expressing skeletal, cardiac, and chimeric L-channel alpha1-subunits. Our results demonstrate that the S5-S6 linker of repeat I (IS5-IS6 linker) is a critical determinant of the difference in skeletal and cardiac unitary conductance. The unitary conductances attributable to the wild-type skeletal (CAC6; approximately 14 pS) and cardiac (CARD1; approximately 25 pS) alpha1-subunits expressed in dysgenic myotubes are identical to those observed in native tissues. Chimeric alpha1-subunits containing skeletal sequence for the first internal repeat and all of the putative intracellular loops (SkC15), the IS5-IS6 linker and the intracellular loops (SkC51), or only the IS5-IS6 linker (SkC49) each exhibit a low, skeletal-like unitary conductance (< or = 17 pS). Constructs in which the IS5-IS6 linker is of cardiac origin (CARD1 and CSk9) display cardiac-like conductance (approximately 25 pS). Unitary conductance and the rate of channel activation are apparently independent processes, since both SkC51 and SkC49 exhibit low, skeletal-like conductance and rapid, cardiac-like rates of ensemble activation. These results demonstrate that the IS5-IS6 linker strongly influences the single channel conductance of L-channels in a manner that is independent from the rate of channel activation.

Effect of environmental conditions on the penetration of benzene through human skin.

The in vitro penetration of [14C]benzene through freshly prepared human skin was examined under a variety of skin conditions associated with swimming and bathing. The experimental system utilized a recirculating donor solution and a flow-through receiver solution, and was modified to accommodate the analysis of volatiles. The permeability coefficient of 0.14 cm/h under standard conditions at 26 degrees C was found to increase to 0.26 cm/h at 50 degrees C and decrease to 0.10 cm/h at 15 degrees C. Storage of the skin at- 20 degrees C did not affect the penetration of benzene. Application of baby oil, moisturizer, or insect repellant to the skin before exposure under standard conditions did not affect the flux of benzene, but a significant increase was observed when the skin was pretreated with sunscreen (permeability coefficient 0.24 cm/h). These results suggest that risk assessment or exposure modeling for benzene and other environmental contaminants should account for appropriate changes in the environmental conditions when considering the dermal route of exposure.

Role of S4 segments and the leucine heptad motif in the activation of an L-type calcium channel.

Basic residues in the S4 segments of voltage-dependent channels and leucines within the heptad repeat motif in the S4-S5 region of Shaker potassium channels have been shown to have important influences on activation. Here we have compared the relative importance for activation of S4 arginines (mutated to neutral or negative residues) in each of the four repeats of a chimeric L-type calcium channel. Significant effects on midpoint potential and time constant of activation were produced by mutations in repeats I and III but not in repeats II and IV. Leucine or isoleucine mutations in repeats I and III had the same effect on the voltage dependence of calcium channel activation as the mutations at equivalent positions in the Shaker channel, indicating that the heptad motif plays a fundamental role in channel activation.

Functional nonequality of the cardiac and skeletal ryanodine receptors.

Dihydropyridine receptors (DHPRs), which are voltage-gated Ca2+ channels, and ryanodine receptors (RyRs), which are intracellular Ca2+ release channels, are expressed in diverse cell types, including skeletal and cardiac muscle. In skeletal muscle, there appears to be reciprocal signaling between the skeletal isoforms of both the DHPR and the RyR (RyR-1), such that Ca2+ release activity of RyR-1 is controlled by the DHPR and Ca2+ channel activity of the DHPR is controlled by RyR-1. Dyspedic skeletal muscle cells, which do not express RyR-1, lack excitation-contraction coupling and have an approximately 30-fold reduction in L-type Ca2+ current density. Here we have examined the ability of the predominant cardiac and brain RyR isoform, RyR-2, to substitute for RyR-1 in interacting with the skeletal DHPR. When RyR-2 is expressed in dyspedic muscle cells, it gives rise to spontaneous intracellular Ca2+ oscillations and supports Ca2+ entry-induced Ca2+ release. However, unlike RyR-1, the expressed RyR-2 does not increase the Ca2+ channel activity of the DHPR, nor is the gating of RyR-2 controlled by the skeletal DHPR. Thus, the ability to participate in skeletal-type reciprocal signaling appears to be a unique feature of RyR-1.

A Novel Type of D-Mannitol Dehydrogenase from Acetobacter xylinum: Occurrence, Purification, and Basic Properties.

We purified a novel type of D-mannitol dehydrogenase, which contains a c-type cytochrome and an unknown chromophore in the soluble fraction of an acetic acid bacterium, Acetobacter xylinum KU-1, to homogeneity. The enzyme showed the maximum activity at pH 5 and 40°C. It was stable up to 60°C at pH 6, and was inhibited by Hg(2+) and p-quinone (Ki = 0.18 mm). The molecular weight of the enzyme was about 140,000, and those of the subunits were 69,000, 51,000, and 20,000; the enzyme is hetero-trimeric and contained 8 g-atoms of Fe per mole. The α-helix content was estimated to be about 52.9%. The enzyme catalyzed phenazine methosulfate dependent oxidation of d-mannitol with an apparent Km of 98 µm (for d-mannitol) and Vmax of 213 µmol/min/mg. The reduced form of the enzyme showed the absorption maxima at 386, 416, 480, 518, 550, and 586 nm, which are attributable to a c-type cytochrome in the enzyme.

Enhanced dihydropyridine receptor channel activity in the presence of ryanodine receptor.

Excitation-contraction coupling in skeletal muscle involves a voltage sensor in the plasma membrane which, in response to depolarization, causes an intracellular calcium-release channel to open. The skeletal isoform of the ryanodine receptor (RyR-1) functions as the Ca2+-release channel and the dihydropyridine receptor (DHPR) functions as the voltage sensor and also as an L-type Ca2+ channel. Here we examine the possibility that there is a retrograde signal from RyR-1 to the DHPR, using myotubes from mice homozygous for a disrupted RyR-1 gene (dyspedic mice). As expected, we find that there is no excitation-contraction coupling in dyspedic myotubes, but we also find that they have a roughly 30-fold reduction in L-type Ca2+-current density. Injection of dyspedic myotubes with RyR-1 complementary DNA restores excitation-contraction coupling and causes the density of L-type Ca2+ current to rise towards normal. Despite the differences in Ca2+-current magnitude, measurements of charge movement indicate that the density of DHPRs is similar in dyspedic and RyR-1-expressing myotubes. Our results support the possibility of a retrograde signal by which RyR-1 enhances the function of DHPRs as Ca2+ channels.

Characterization of the Ah receptor from human placental tissue.

The rate of thermal inactivation of the unliganded human Ah receptor, studied by sucrose density gradient centrifugation, with respect to loss of ligand binding ability, was found to be greater than those of most rodents at 20 degrees C, but the temperature coefficient of the rate constant was much smaller than for the rodent species. This implies that the unliganded human Ah receptor would be thermally more stable than the rodent analogs at physiological temperatures. The liganded form of the human Ah receptor was found to be less stable with respect to ligand release than the rodent receptors. These differences in behavior between human and rodent Ah receptors underline the difficulties in using rodent data in the development of receptor-based models of dioxin toxicity. Attempts to develop an alternative to sucrose density gradient centrifugation, comparable with the hydroxylapatite adsorption method used to assay rodent hepatic Ah receptor, were unsuccessful.

Involvement of the brain type of ryanodine receptor in T-cell proliferation.

Cloning and sequence analysis of cDNA showed that the brain type of ryanodine receptor (RYR) is expressed in human Jurkat T-lymphocyte cells. Fura-2 measurements revealed that the RYR in T-cells functions as a ryanodine-sensitive, caffeine-insensitive Ca2+ release channel. Furthermore, ryanodine stimulated proliferation and altered the growth pattern of cultured human T-cells when added together with FK506.

Multiple types of ryanodine receptor/Ca2+ release channels are differentially expressed in rabbit brain.

The neuronal Ca2+ signal is induced by a rise in the intracellular free Ca2+ concentration ([Ca2+]i), and is thought to be important for higher brain function. Dynamic changes in [Ca2+]i are affected by the spatial distributions of various Ca(2+)-increasing molecules (channels and receptors). The ryanodine receptor (RyR) is an intracellular channel through which Ca2+ is released from intracellular stores. To define the contribution of neuronal Ca2+ signaling via the RyR channel, we examined RyR type-specific gene expression in rabbit brain by in situ hybridization histochemistry. The neuronal RyR was composed of three distinct types, two types dominant in skeletal (sRyR) and cardiac (cRyR) muscle, respectively, and a novel brain type (bRyR). sRyR was distinguished by its high level of expression in cerebellar Purkinje cells. cRyR was predominantly expressed throughout nearly the entire brain, and was characterized by its markedly high level of expression in the olfactory nerve layer, layer VI of the cerebral cortex, the dentate gyrus, cerebellar granule cells, the motor trigeminal nucleus, and the facial nucleus. bRyR expression was the least widely distributed throughout the brain, and was high in the hippocampal CA1 pyramidal layer, caudate, putamen, and dorsal thalamus. This investigation demonstrates that the heterogeneous distribution of neuronal RyRs may be implicated in distinct Ca(2+)-associated brain functions. Moreover, it should be noted that cRyR, a typical CICR channel, is distributed widely throughout the brain, suggesting that in a variety of cell types, the amplification of neuronal Ca2+ signals is functionally accompanied by a rise in [Ca2+]i, such as Ca2+ influx stimulated by neuronal activity. This widespread distribution of the neuronal RyR family indicates that Ca2+ signals via the intracellular stores should be considered in studies of neuronal Ca2+ dynamics.