Relationship between energy expenditure and ion channel density in the turtle and rat brain

1989 ◽  
Vol 257 (6) ◽  
pp. R1354-R1358 ◽  
Author(s):  
R. A. Edwards ◽  
P. L. Lutz ◽  
D. G. Baden
Keyword(s):  
Energy Consumption ◽  
Energy Expenditure ◽  
Ion Channel ◽  
Rat Brain ◽  
Receptor Interaction ◽  
Na Channel ◽  
Apparent Difference ◽  
Na Channels ◽  
Channel Density ◽  
Rat Synaptosomes

Synaptosomes were isolated from turtle and rat brains to determine whether differences in brain ion channel densities accounted for the turtle's ability to survive anoxia compared with the mammal. The Na(+)-channel binding neurotoxin brevetoxin showed high-affinity specific binding in both turtle and rat synaptosomes, suggesting specific ligand-receptor interaction. The maximum binding capacity (Bmax) value for the turtle was only about one-third of that found for the rat synaptosomes, suggesting that the turtle synaptosome has a correspondingly lower Na+ channel density than the rat. This apparent difference in Na+ channel density is not reflected in metabolic rates, since at the same temperature (31 degrees C) the O2 consumption of both the rat and turtle synaptosome was almost identical. The large reductions in energy expenditure seen in synaptosomes incubated in Na(+)-free media and in media containing ouabain (approximately 50% turtle, 80% rat) are probably related to the halting of transmembrane Na(+)-K+ exchange. The greater reduction in the rat may be related to the apparent greater density of Na+ channels in the rat brain. However, compared with the 90% reduction in brain metabolism that occurs when the turtle brain becomes anoxic, the differences in ion channel density and in the costs of ion pumping between the rat and turtle brain are trivial. Closing Na+ channels with tetrodotoxin and increasing Na+ channel activation with veratridine caused substantial decreases and increases in synaptosome energy consumption, respectively. This suggests that the modulation of ion channel conductance has a significant effect on metabolic cost and may be an important mechanism to reduce energy consumption and electrical activity in the anoxic turtle brain, while still maintaining ionic gradients.

scholarly journals The Human Heart and Rat Brain IIA Na+ Channels Interact with Different Molecular Regions of the β1 Subunit

2002 ◽  
Vol 120 (6) ◽  
pp. 887-895 ◽  
Author(s):  
Thomas Zimmer ◽  
Klaus Benndorf
Keyword(s):  
Rat Brain ◽  
Human Heart ◽  
Xenopus Oocytes ◽  
Extracellular Domain ◽  
Na Channel ◽  
Na Channels ◽  
Membrane Anchor ◽  
Α Subunit ◽  
Extracellular Region ◽  
Recovery From Inactivation

The α subunit of voltage-gated Na+ channels of brain, skeletal muscle, and cardiomyocytes is functionally modulated by the accessory β1, but not the β2 subunit. In the present study, we used β1/β2 chimeras to identify molecular regions within the β1 subunit that are responsible for both the increase of the current density and the acceleration of recovery from inactivation of the human heart Na+ channel (hH1). The channels were expressed in Xenopus oocytes. As a control, we coexpressed the β1/β2 chimeras with rat brain IIA channels. In agreement with previous studies, the β1 extracellular domain sufficed to modulate IIA channel function. In contrast to this, the extracellular domain of the β1 subunit alone was ineffective to modulate hH1. Instead, the putative membrane anchor plus either the intracellular or the extracellular domain of the β1 subunit was required. An exchange of the β1 membrane anchor by the corresponding β2 subunit region almost completely abolished the effects of the β1 subunit on hH1, suggesting that the β1 membrane anchor plays a crucial role for the modulation of the cardiac Na+ channel isoform. It is concluded that the β1 subunit modulates the cardiac and the neuronal channel isoforms by different molecular interactions: hH1 channels via the membrane anchor plus additional intracellular or extracellular regions, and IIA channels via the extracellular region only.

Ion channels in spinal cord astrocytes in vitro. III. Modulation of channel expression by coculture with neurons and neuron-conditioned medium

1993 ◽  
Vol 69 (3) ◽  
pp. 819-831 ◽  
Author(s):  
C. L. Thio ◽  
S. G. Waxman ◽  
H. Sontheimer
Keyword(s):  
Spinal Cord ◽  
Steady State ◽  
Conditioned Media ◽  
Na Channel ◽  
Na Channels ◽  
Drg Neurons ◽  
Channel Density ◽  
Na Currents ◽  
Channel Expression

1. Astrocytes cultured from rat spinal cord express voltage-activated Na+ channels in high densities (up to 8 channels per microns2). Stellate astrocytes express Na+ currents at all times in vitro. In pancake astrocytes, Na+ channel expression shows a distinct temporal pattern, an absence of channel expression at 1–3 days in vitro (DIV), and peak Na+ channel density at 7–8 DIV. 2. Coculture of spinal cord astrocytes with dorsal root ganglion (DRG) neurons substantially reduces the expression of voltage-activated Na+ channels in both spinal cord astrocyte types. In pancake spinal cord astrocytes, both the percentage of cells expressing Na+ channels and the channel density in Na+ channel-expressing cells are markedly reduced. In stellate spinal cord astrocytes, the percentage of Na+ channel-expressing cells is unchanged, but the Na+ channel density per cell is markedly reduced in coculture. 3. Culturing spinal cord astrocytes in neuron-conditioned media reduces Na+ channel expression in both spinal cord astrocyte types to levels intermediate between coculture and control, suggesting that, at least in part, neuronal effects on Na+ channel expression are mediated by a soluble factor secreted into the media by neurons. 4. As with the expression of voltage-activated Na+ channels, the expression of voltage-activated K+ channels is reduced in both spinal cord astrocyte types cocultured with DRG neurons. The effect is not mimicked by culturing cells in neuron-conditioned media, suggesting that effects on K+ channel expression are mediated by a less stable and more readily degradable factor. 5. Coculture with DRG neurons or culture in neuron-conditioned media do not alter the biophysical properties of voltage-activated Na+ currents in pancake spinal cord astrocytes. Thus steady-state activation, steady-state inactivation, and the time constants of activation and inactivation are virtually unchanged under the various culture conditions.

scholarly journals The Effect of Cell Size and Channel Density on Neuronal Information Encoding and Energy Efficiency

2013 ◽  
Vol 33 (9) ◽  
pp. 1465-1473 ◽  
Author(s):  
Biswa Sengupta ◽  
A Aldo Faisal ◽  
Simon B Laughlin ◽  
Jeremy E Niven
Keyword(s):  
Energy Efficiency ◽  
Energy Consumption ◽  
Ion Channel ◽  
Cell Size ◽  
Information Coding ◽  
Information Encoding ◽  
Information Rates ◽  
Synaptic Inputs ◽  
Voltage Gated ◽  
Channel Density

Identifying the determinants of neuronal energy consumption and their relationship to information coding is critical to understanding neuronal function and evolution. Three of the main determinants are cell size, ion channel density, and stimulus statistics. Here we investigate their impact on neuronal energy consumption and information coding by comparing single-compartment spiking neuron models of different sizes with different densities of stochastic voltage-gated Na+ and K+ channels and different statistics of synaptic inputs. The largest compartments have the highest information rates but the lowest energy efficiency for a given voltage-gated ion channel density, and the highest signaling efficiency (bits spike −1) for a given firing rate. For a given cell size, our models revealed that the ion channel density that maximizes energy efficiency is lower than that maximizing information rate. Low rates of small synaptic inputs improve energy efficiency but the highest information rates occur with higher rates and larger inputs. These relationships produce a Law of Diminishing Returns that penalizes costly excess information coding capacity, promoting the reduction of cell size, channel density, and input stimuli to the minimum possible, suggesting that the trade-off between energy and information has influenced all aspects of neuronal anatomy and physiology.

scholarly journals Neuromuscular junction-specific genes screening by deep RNA-seq analysis

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Tiankun Hui ◽  
Hongyang Jing ◽  
Xinsheng Lai
Keyword(s):  
Ion Channel ◽  
Neuromuscular Junctions ◽  
Gene Set Enrichment Analysis ◽  
Differentially Expressed ◽  
Muscle Membrane ◽  
Receptor Interaction ◽  
Specific Gene ◽  
Rna Seq ◽  
Channel Activity ◽  
Ppi Networks

Abstract Background Neuromuscular junctions (NMJs) are chemical synapses formed between motor neurons and skeletal muscle fibers and are essential for controlling muscle contraction. NMJ dysfunction causes motor disorders, muscle wasting, and even breathing difficulties. Increasing evidence suggests that many NMJ disorders are closely related to alterations in specific gene products that are highly concentrated in the synaptic region of the muscle. However, many of these proteins are still undiscovered. Thus, screening for NMJ-specific proteins is essential for studying NMJ and the pathogenesis of NMJ diseases. Results In this study, synaptic regions (SRs) and nonsynaptic regions (NSRs) of diaphragm samples from newborn (P0) and adult (3-month-old) mice were used for RNA-seq. A total of 92 and 182 genes were identified as differentially expressed between the SR and NSR in newborn and adult mice, respectively. Meanwhile, a total of 1563 genes were identified as differentially expressed between the newborn SR and adult SR. Gene Ontology (GO) enrichment analyses, Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis and gene set enrichment analysis (GSEA) of the DEGs were performed. Protein–protein interaction (PPI) networks were constructed using STRING and Cytoscape. Further analysis identified some novel proteins and pathways that may be important for NMJ development, maintenance and maturation. Specifically, Sv2b, Ptgir, Gabrb3, P2rx3, Dlgap1 and Rims1 may play roles in NMJ development. Hcn1 may localize to the muscle membrane to regulate NMJ maintenance. Trim63, Fbxo32 and several Asb family proteins may regulate muscle developmental-related processes. Conclusion Here, we present a complete dataset describing the spatiotemporal transcriptome changes in synaptic genes and important synaptic pathways. The neuronal projection-related pathway, ion channel activity and neuroactive ligand-receptor interaction pathway are important for NMJ development. The myelination and voltage-gated ion channel activity pathway may be important for NMJ maintenance. These data will facilitate the understanding of the molecular mechanisms underlying the development and maintenance of NMJ and the pathogenesis of NMJ disorders.

Whole cell and unitary amiloride-sensitive sodium currents in M-1 mouse cortical collecting duct cells

1996 ◽  
Vol 270 (4) ◽  
pp. C998-C1010 ◽  
Author(s):  
M. L. Chalfant ◽  
T. G. O'Brien ◽  
M. M. Civan
Keyword(s):  
Collecting Duct ◽  
Cell Permeability ◽  
Na Channel ◽  
Na Channels ◽  
Cortical Collecting Duct ◽  
Ionic Selectivity ◽  
Whole Cell ◽  
Duct Cells ◽  
Excised Patches ◽  
Collecting Duct Cells

Amiloride-sensitive whole cell currents have been reported in M-1 mouse cortical collecting duct cells (Korbmacher et al., J. Gen. Physiol. 102: 761-793, 1993). We have confirmed that amiloride inhibits the whole cell currents but not necessarily the measured whole cell currents. Anomalous responses were eliminated by removing external Na+ and/or introducing paraepithelial shunts. The amiloride-sensitive whole cell currents displayed Goldman rectification. The ionic selectivity sequence of the amiloride-sensitive conductance was Li+ > Na+ >> K+. Growth of M-1 cells on permeable supports increased the amiloride-sensitive whole cell permeability, compared with cells grown on plastic. Single amiloride-sensitive channels were observed, which conformed to the highly selective low-conductance amiloride-sensitive class [Na(5)] of epithelial Na+ channels. Hypotonic pretreatment markedly slowed run-down of channel activity. The gating of the M-1 Na+ channel in excised patches was complex. Open- and closed-state dwell-time distributions from patches that display one operative channel were best described with two or more exponential terms each. We conclude that 1) study of M-1 whole cell Na+ currents is facilitated by reducing the transepithelial potential to zero, 2) these M-1 currents reflect the operation of Na(5) channels, and 3) the Na+ channels display complex kinetics, involving > or = 2 open and > or = 2 closed states.

Distribution of I, II and III subtypes of voltage-sensitive Na+ channel mRNA in the rat brain

1993 ◽  
Vol 17 (1-2) ◽  
pp. 169-173 ◽  
Author(s):  
T. Furuyama ◽  
Y. Morita ◽  
S. Inagaki ◽  
H. Takagi
Keyword(s):  
Rat Brain ◽  
Na Channel

MODELING OF WOLFF–PARKINSON–WHITE SYNDROME

2003 ◽  
Vol 13 (12) ◽  
pp. 3827-3834
Author(s):  
ROBERT HINCH
Keyword(s):  
Asymptotic Analysis ◽  
Ion Channel ◽  
Sodium Channel ◽  
Channel Model ◽  
Accessory Pathway ◽  
Simplified Model ◽  
Channel Kinetics ◽  
White Syndrome ◽  
Channel Density ◽  
Wolff Parkinson White Syndrome

Wolff–Parkinson–White syndrome is a disease where an arrhythmia is caused by the ventricles being electrically excited by an additional accessory pathway that links the atria to the ventricles. The spread of the activation wave from this pathway to the ventricles is modeled using a simplified model of Hodgkin–Huxley sodium channel kinetics, in a two ion-channel model. The model is investigated both analytically (using an asymptotic analysis) and numerically, and both methods are shown to give the same result. It is found that for a given width of the accessory pathway, there is a critical sodium channel density needed for the activation wave to spread from the pathway to the tissue. This result provides an explanation for the success of class-I anti-arrhythmic drugs in treating Wolff–Parkinson–White syndrome.

Block of Human Heart hH1 Sodium Channels by the Enantiomers of Bupivacaine

2000 ◽  
Vol 93 (4) ◽  
pp. 1022-1033 ◽  
Author(s):  
Carla Nau ◽  
Sho-Ya Wang ◽  
Gary R. Strichartz ◽  
Ging Kuo Wang
Keyword(s):  
Human Heart ◽  
Point Mutations ◽  
Cell Voltage ◽  
Site Directed Mutagenesis ◽  
Na Channel ◽  
Amino Acid Residues ◽  
Na Channels ◽  
State Dependent ◽  
Positively Charged

Background S(-)-bupivacaine reportedly exhibits lower cardiotoxicity but similar local anesthetic potency compared with R(+)-bupivacaine. The bupivacaine binding site in human heart (hH1) Na+ channels has not been studied to date. The authors investigated the interaction of bupivacaine enantiomers with hH1 Na+ channels, assessed the contribution of putatively relevant residues to binding, and compared the intrinsic affinities to another isoform, the rat skeletal muscle (mu1) Na+ channel. Methods Human heart and mu1 Na+ channel alpha subunits were transiently expressed in HEK293t cells and investigated during whole cell voltage-clamp conditions. Using site-directed mutagenesis, the authors created point mutations at positions hH1-F1760, hH1-N1765, hH1-Y1767, and hH1-N406 by introducing the positively charged lysine (K) or the negatively charged aspartic acid (D) and studied their influence on state-dependent block by bupivacaine enantiomers. Results Inactivated hH1 Na+ channels displayed a weak stereoselectivity with a stereopotency ratio (+/-) of 1.5. In mutations hH1-F1760K and hH1-N1765K, bupivacaine affinity of inactivated channels was reduced by approximately 20- to 40-fold, in mutation hH1-N406K by approximately sevenfold, and in mutations hH1-Y1767K and hH1-Y1767D by approximately twofold to threefold. Changes in recovery of inactivated mutant channels from block paralleled those of inactivated channel affinity. Inactivated hH1 Na+ channels exhibited a slightly higher intrinsic affinity than mu1 Na+ channels. Conclusions Differences in bupivacaine stereoselectivity and intrinsic affinity between hH1 and mu1 Na+ channels are small and most likely of minor clinical relevance. Amino acid residues in positions hH1-F1760, hH1-N1765, and hH1-N406 may contribute to binding of bupivacaine enantiomers in hH1 Na+ channels, whereas the role of hH1-Y1767 remains unclear.

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