Changes in the mRNAs encoding subtypes I, II and III sodium channel alpha subunits following kainate-induced seizures in rat brain

Several lines of evidence underscore a possible role of voltage-gated Na+ channels (NaCH) in epilepsy. We compared the regional distribution of mRNAs coding for Na+ channel alpha subunit I, II and III in brains from control and kainate-treated rats using non-radioactive in situ hybridization with subtype-specific digoxigenin-labelled cRNA probes. Labelling intensity was evaluated by a densitometric analysis of digitized images. Heterogeneous distribution of the three Na+ channel mRNAs was demonstrated in brain from adult control rats, which confirmed previous studies. Subtype II mRNAs were shown to be abundant in cerebellum and hippocampus. Subtype I mRNAs were also detected in these areas. Subtype III mRNAs were absent in cerebellar cortex, but significantly expressed in neurons of the medulla oblongata and hippocampus. The three subtypes were differentially distributed in neocortical layers. Subtype II mRNAs were present in all of the layers, but mRNAs for subtypes I and III were concentrated in pyramidal cells of neocortex layers IV-V. During kainate-induced seizures, we observed an increase in Na+ channel II and III mRNA levels in hippocampus. In dentate gyrus, subtype III mRNAs increased 3 h after KA administration to a maximum at 6 h. At this latter time, a lower increase in NaCh III mRNAs was also recorded in areas CA1 and CA3. NaCh III overexpression in dentate gyrus persisted for at least 24 h. In the same area, NaCh II mRNAs were also increased with a peak 3 h after KA injection and a return to control levels by 24 h. No changes in NaCh I mRNAs were seen. The KA-induced up-regulation in NaCh mRNAs probably resulted in an increase in hippocampal neuronal excitability.     

Distribution of mRNA encoding the inwardly rectifying K+ channel, BIR1 in rat tissues

Chinese hamster P-glycoprotein ("multidrug-resistance protein") was purified and reconstituted in proteoliposomes by the procedure of I. L. Urbatsch, M. K. al-Shawi, and A. E. Senior (1994, Biochemistry 33, 7069-7076). The presence of lipid during the octylglucoside solubilization and Reactive Red 120 chromatography steps was found to be mandatory for retention of ATPase activity. Sheep brain or bovine liver lipid extracts could be substituted for the Escherichia coli lipids used previously. Stimulation of ATPase activity of purified, reconstituted P-glycoprotein by vinblastine, colchicine, and daunomycin was seen with sheep brain and bovine liver lipids, but not with E. coli lipids. Basal (i.e., not drug-stimulated) ATPase activity was different in the three lipids. Azidopine labeling of the drug binding sites in purified, reconstituted P-glycoprotein was carried out; vinblastine, colchicine, and daunomycin competed for labeling in all three lipids. It is therefore evident that the lipid environment can significantly influence the characteristics of purified, reconstituted P-glycoprotein ATPase activity and the apparent coupling between drug-binding and catalytic sites.     

Regulation of Na+ channel beta 1 and beta 2 subunit mRNA levels in cultured rat astrocytes

This work describes the molecular mechanism of fatty acid and hormonal modulation of retinoid X receptor (RXR alpha) in rat liver. We examined the effects of different fatty acids (myristic-, stearic-, linolenic-, oleic-, arachidonic- and tetradecylthioacetic acid (TTA)) and the synthetic glucocorticoid dexamethasone on RXR alpha mRNA and protein steady-state levels in hepatoma cells and cultured hepatocytes. Fatty acids induced the RXR alpha gene expression where TTA showed the most inductive effect (three-fold induction). Dexamethasone alone resulted in a stronger induction (up to seven-fold in hepatocytes), and in combination with fatty acids, an additive or synergistic effect was observed. The RXR alpha protein level in cultured hepatocytes showed a similar pattern of regulation, with a slight inductive effect of fatty acids and an additive or synergistic effect was observed in combination with dexamethasone. Our results indicate that the RXR alpha gene expression is under distinct regulation by fatty acids and dexamethasone acid which strongly suggests a coupling with the lipid metabolizing system and the retinoid signaling pathway.     

Localization of Ca2+ channel subtypes on rat spinal motor neurons, interneurons, and nerve terminals

Ca2+ channels in distinct subcellular compartments of neurons mediate voltage-dependent Ca2+ influx, which integrates synaptic responses, regulates gene expression, and initiates synaptic transmission. Antibodies that specifically recognize the alpha1 subunits of class A, B, C, D, and E Ca2+ channels have been used to investigate the localization of these voltage-gated ion channels on spinal motor neurons, interneurons, and nerve terminals of the adult rat. Class A P/Q-type Ca2+ channels were present mainly in a punctate pattern in nerve terminals located along the cell bodies and dendrites of motor neurons. Both smooth and punctate staining patterns were observed over the surface of the cell bodies and dendrites with antibodies to class B N-type Ca2+ channels, indicating the presence of these channels in the cell surface membrane and in nerve terminals. Class C and D L-type and class E R-type Ca2+ channels were distributed mainly over the cell soma and proximal dendrites. Class A P/Q-type Ca2+ channels were present predominantly in the presynaptic terminals of motor neurons at the neuromuscular junction. Occasional nerve terminals innervating skeletal muscles from the hindlimb were labeled with antibodies against class B N-type Ca2+ channels. Staining of the dorsal laminae of the rat spinal cord revealed a complementary distribution of class A and class B Ca2+ channels in nerve terminals in the deeper versus the superficial laminae. Many of the nerve terminals immunoreactive for class B N-type Ca2+ channels also contained substance P, an important neuropeptide in pain pathways, suggesting that N-type Ca2+ channels are predominant at synapses that carry nociceptive information into the spinal cord.     

Ion transport across leech integument. I. Electrogenic Na+ transport and current fluctuation analysis of the apical Na+ channel

BACKGROUND: The development of functional diversity through gene duplication and subsequent divergent evolution can give rise to proteins that have little or no sequence similarity, but retain similar topologies. RESULTS: The crystal structures of nerve growth factor, transforming growth factor-beta 2 and platelet-derived growth factor-BB show that all three are based on a cystine-knot plus beta-strands topology. There is very little sequence identity between the three proteins and the relationship between the structures had not been deduced from sequence comparisons. Each growth factor is usually active as a dimer; each exists as a dimer in the crystal, but the relative orientations of the protomers are different in each case. CONCLUSION: The structural motif of disulphide bonds and hydrogen-bonded beta-strands unexpectedly found in these three growth factors acts as a stable framework for elaboration of loops of low sequence similarity that contain the specificity for receptor interaction.     

Characterization of rat brain kynurenine aminotransferases I and II

Congenital choanal atresia is a challenging clinical problem requiring prompt diagnosis and intervention. The method of repair is controversial, with no technique having gained universal acceptance. Proponents of the transnasal repair must acknowledge the variability of results, especially with thick bony plates, and the technical difficulties associated with this method. Advocates of the transpalatal route must recognize the associated morbidity of this technique in the newborn. The adaptation of the endoscopic technique and the development of new powered instrumentation have significantly improved the transnasal technique so that safe controlled repair may now be accomplished in the newborn.     

Potentiometric study of resting potential, contributing K+ channels and the onset of Na+ channel excitability in embryonic rat cortical cells

Resting membrane potential (RMP), K+ channel contribution to RMP and the development of excitability were investigated in the entire population of acutely dissociated embryonic (E) rat cortical cells over E11-22 using a voltage-sensitive fluorescent indicator dye and flow cytometry. During the period of intense proliferation (E11-13), two cell subpopulations with distinct estimated RMPs were recorded: one polarized at approximately -70 mV and the other relatively less-polarized at approximately -40 mV. Ca2+o was critical in sustaining the RMP of the majority of less-polarized cells, while the well-polarized cells were characterized by membrane potentials exhibiting a approximately Nernstian relationship between RMP and [K+]o. Analysis of these two subpopulations revealed that > 80% of less-polarized cells were proliferative, while > 90% of well-polarized cells were postmitotic. Throughout embryonic development, the disappearance of Ca2+o-sensitive, less-polarized cells correlated with the disappearance of the proliferating population, while the appearance of the K+o-sensitive, well-polarized population correlated with the appearance of terminally postmitotic neurons, immuno-identified as BrdU-, tetanus toxin+ cells. Differentiating neurons were estimated to contain increased K+i relative to less-polarized cells, coinciding with the developmental expression of Cs+/Ba2+-sensitive and Ca2+-dependent K+ channels. Both K+ channels contributed to the RMP of well-polarized cells, which became more negative toward the end of neurogenesis. Depolarizing effects of veratridine, first observed at E11, progressively changed from Ca2+o-dependent and tetrodotoxin-insensitive to Na+o-dependent and tetrodotoxin-sensitive response by E18. The results reveal a dynamic development of RMP, contributing K+ channels and voltage-dependent Na+ channels in the developing cortex as it transforms from proliferative to primarily differentiating tissue.     

Parallel dose-response studies of the voltage-dependent Na+ channel antagonist BW619C89, and the voltage-dependent Ca2+ channel antagonist nimodipine, in rat transient focal cerebral ischaemia

We have compared two classes of putative neuroprotectants, the voltage-dependent Na+ channel antagonist BW619C87 [4-amino-2-(4-methyl-1-piperazinyl)-5-(2,3,5-trichlorophenyl) pyrimidine], and the voltage-dependent Ca2+ channel antagonist nimodipine, in a rat model of transient focal cerebral ischaemia. BW619C87 (10-50 mg/kg) or nimodipine (10-100 microg/kg) were injected intravenously 5 min before induction of 2 h transient focal cerebral ischaemia via intraluminal thread occlusion of the middle cerebral artery. BW619C87 was a potent neuroprotectant over the range tested, maximally reducing the volume of hemispheric ischaemic damage by 51% at the 50 mg/kg dose. Nimodipine maximally reduced ischaemic damage by 33% at the 50 microg/kg dose, although the maximal level of neuroprotection afforded by BW619C89 and nimodipine was not significantly different. This is the first study to compare these two classes of drug directly in a model of middle cerebral artery occlusion with reperfusion, and it supports the effectiveness of both as neuroprotectants.     

Renal handling and plasma elimination kinetics of carbonic anhydrase isoenzymes I, II and III in the rat

Using a radio-immunosorbent technique, the levels of the carbonic anhydrase (CA) isoenzymes CA I, II and III in plasma (1-3 micrograms ml-1), lymph (0.5-1.6 micrograms ml-1) and urine (0.03-0.06 micrograms ml-1), were determined in the rat. The renal clearances of CA I, II and III were 11 +/- 3, 42 +/- 11 and 35 +/- 4 nl min-1 (g kidney wet wt)-1 (n = 4-5), respectively. After a single i.v. injection of purified native or 125I-labelled isoenzymes, the elimination of CA I, and CA III from plasma followed a bi-exponential decline, with half-times of 7 and 9 min for the rapid phase and 112 min for the slow phase, respectively. Nephrectomy decreased the rapid phase and the build-up of catabolites. Therefore, the rapid phase of CA I and III elimination is probably explained by filtration of unbound isoenzyme at the glomeruli and subsequent degradation by the proximal tubules. The plasma elimination curve for CA II was different and followed a mono-exponential decline, with a half-time of 210 min both in normal and nephrectomized animals. This indicates that CA II is not filtered at the glomeruli. However, in acute renal failure, with leaking tubular cells, CA II was excreted into the urine. The slow elimination of the major part of the isoenzymes from plasma is explained by the binding of CA I, II and III to a plasma protein, immunochemically similar to transferrin, forming a macromolecular complex with a mol wt of 114 +/- 2 kDa.     

Regional and cellular expression patterns of four K+ channel mRNAs in the adult rat brain

Potassium (K+) channels are involved in the modulation and fine tuning of the excitable properties of neurons and glia in the nervous system. In the present report, in situ hybridization histochemistry was used to determine the regional and cellular distribution patterns in the adult rat brain of four mRNAs encoding subunits of voltage-gated K+ channels. These are Kv1.1, Kv1.6, K13 and IK8. All K+ channels examined showed distinct yet overlapping expression patterns. Expression of Kv1.1 mRNA was high in cells of certain motor-related structures of the brainstem. Kv1.6 mRNA expression was observed in cerebellar Purkinje cells and in various olfactory and amygdaloid structures. K13 was the only mRNA expressed in both neuronal and non-neuronal cell populations, including the cells of choroid plexus and pia. IK8 expression was observed only in the forebrain structures. In many brain regions, mRNAs for Kv1.1 and Kv1.6, both encoding K+ channel subunits belonging to the Shaker subfamily, were co-expressed, a necessary condition for heteromultimer formation.     

Inactivation of rat brain Na+ K+ ATPase by sodium dodecylsulfate: effect of pH, magnesium ions and temperature

The relative stabilities to SDS inactivation of the rat brain Na(+)-ATPase catalytic subunit isoforms in the conditions of the surface charge modulation and temperature modification of the physical state of the membrane lipids were examined. The higher sensitivity of the Na+,K(+)-ATPase a1-isoform than a+ to SDS inactivation occurs under the conditions of the detergent treatment of microsomes at pH 7.5 and room temperature. The decrease in pH in ATP-free medium up to 6.2 or temperature elevation up to 37 degrees C eliminates the differences in SDS sensitivity of the Na+,K(+)-ATPase isoforms. The enhancement of the SDS binding with a subunit due to changes in membrane surface charge in the first case or increase of accessibility of the protein intramembrane regions for detergent due to the decrease of the packing density of the boundary lipids in the second case are supposed.     

Na+ channel modulation and force-frequency relationship in human myocardium

Insect cell lines in culture are used for a variety of studies. In this laboratory imaginal disc cell lines have been established from primary cultures from third instar larvae, and used for a number of experiments. The effect of ageing on the morphology and physiology of Drosophila cell lines has received very little attention, although problems of genotypic or phenotypic changes in cell lines with age are recognized in other areas of animal cell culture. We tested our cell line Cl8+ for any difference in growth, morphology and response to 20-hydroxyecdysone (20HE) at different ages (passage numbers). The cells were found to multiply faster, adhere less firmly to the substrate and to lose the tendency to aggregate at higher passages. The response to 20HE in terms of cell numbers and induction of beta-galactosidase was similar at all passage numbers but morphological changes in hormone-treated cells were less obvious in the higher passages. Cell lines are likely to vary in the extent of ageing effects but workers are advised to be aware of the possibilities. We suggest the effects of age on cell lines should be established, and passage numbers noted in experimental reports.     

Expression of collagens I, III, IV and V mRNA in excimer wounded rat cornea: analysis by semi-quantitative PCR

A semi-quantitative polymerase chain reaction (PCR) methodology was used to evaluate the kinetic changes occurring in collagens I, III, IV and V mRNA in rat cornea following excimer laser keratectomy. cDNA was synthesized from RNA extracted from rat cornea at various times following excimer laser photoablative keratectomy. Collagen cDNA sequences were subsequently amplified using specific sets of oligonucleotide primers. Competitive PCR amplification was carried out using an internal standard so that a semi-quantitative analysis of message for synthesis of collagen types I, III, IV and V could be performed and time course dynamics of message for these collagens studied. There was a biphasic increase in the levels of collagens III, IV and V mRNA following excimer laser keratectomy. Collagen I mRNA levels demonstrated a more sustained increase and were still elevated at 6 weeks following wounding. Collagens IV and V mRNA showed the largest increase with an approximate three fold increase over controls between 4 days and 1 week. Our results demonstrate that upregulation of stromal collagens I, III, and V mRNA and basement membrane collagen IV mRNA occurs in rat cornea following excimer laser keratectomy.     

Rancinamycins I, II, III and IV structural studies

Rancinamycins are secondary metabolites produced by Streptomyces lincolnensis in a sulfur-depleted culture medium. The structures (except stereochemistry) of the main components of the rancinamycin-complex were determined by the use of IR, UV, PMR, and CMR spectra.     

Complex association and dissociation kinetics of brevetoxin binding to voltage-sensitive rat brain sodium channels

31P magnetic resonance spectroscopy measurements of pH and the concentrations of orthophosphate and phosphocreatine were used to estimate rates of glycogenolytic and oxidative ATP synthesis in rat leg muscle during 6 min sciatic nerve stimulation at different rates (1-4 Hz). To study the regulation of glycogenolysis during exercise, the apparent 'glycogenolytic capacity' (L(MAX)) was calculated from glycogenolytic ATP synthesis rate and orthophosphate concentration as a measure of the Ca2+-dependent activation of glycogen phosphorylase. This was found to be proportional to the total ATP synthesis rate (F), and to decline with time; expressed relative to total ATP turnover rate as L(MAX)/F, its initial value was 2.9+/-0.6, declining with half-time 1.4+/-0.4 min. The apparent 'mitochondrial capacity' (Q(MAX)), calculated from oxidative ATP synthesis rate and [ADP], was independent of ATP turnover rate, but increased with half-time 0.8+/-0.1 min to 29+/-2 mmol kg(-1) min(-1): thus [ADP] was the predominant but not the only influence on oxidative ATP synthesis. Numerical simulation shows that time-dependent changes in L(MAX)/F exert a strong influence on pH and on the concentrations of phosphocreatine and ADP.