Pyramidal unit activity in unanesthetized cats

Pyramidal unit activity in unanesthetized cats at rest and during voluntary movement was recorded by a microelectrode technique from the motor cortex for the forelimb. Some pyramidal neurons were not spontaneously active. The conduction velocity along the axon of these neurons was sometimes high (up to 71.5 m/sec), sometimes low (up to 11.2 m/sec). The remaining pyramidal neurons had spontaneous activity with a mean frequency of 1.29 to 43 spikes/sec. Analysis of interspike interval histograms of spontaneous activity and of autocorrelation histograms showed grouping of the spikes into volleys in most pyramidal neurons (irrespective of the conduction velocity). During voluntary movements the change in the activity of many pyramidal units correlated with changes in the EMG. The firing rate of the pyramidal neurons under these circumstances began to rise at least 50 msec before the increase in amplitude of the EMG and it remained high throughout the movement. The firing rate of most neurons during movement was 40–60/sec. The results are compared with those obtained by other workers who studied pyramidal unit activity of monkeys during voluntary movement.     

Stimulation of neuronal calcium conductance by parathyroid hormone

The effects of 10^–10–10^–5 M parathyroid hormone (PTH) on voltage-dependent potassium channels at theHelix pomatia neuronal membrane were investigated in voltage-clamped experiments using intracellular perfusion techniques. The hormone was found to produce a 2-stage effect on calcium current (I_Ca). The initial, brief stage of PTH action consisted of a minor (7–10%) increase in I_Ca and was partially reversible. This was followed by the second (slow) stage, developing for 60–70 min, whereupon level of I_Ca doubled. This hormonal action was not easily reversed and did not occur unless the intracellular solution contained ATP or the hormone was applied after perfusing the cell. Introducing 10 mM EDTA into the perfusate induced a considerable decline in PTH effects. Adding concentrations of 100 and 60 µM of exogenous cAMP and cGMP, respectively, did not imitate the action of this hormone. The first-mentioned effect is thought to be produced by indirect PTH action on channel protein or structures closely associated with the channel and the second by metabolic processes, possibly the phosphoinositide pathway of signal transmission.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Medical Institute, Erevan. Translated from Neirofiziologiya, Vol. 22, No. 3, pp. 373–380, May–June, 1990.     

Metabolic dependence of ionic channel function studied in the nerve cell membrane

The action of a change in the intracellular 3,5-cAMP (cAMP) level on steady-state and potential-dependent transmembrane ionic currents was investigated in vertebrate and invertebrate nerve cells. The change was produced by injecting cAMP directly into the cell or indirectly, by stimulating or inhibiting activity of various enzymes of the cyclase system. An increase in the intracellular cAMP concentration was found to cause activation of the steady-state two-component transmembrane current, the early component of which is linked mainly with an increase in sodium and calcium, the latter with an increase in potassium conductance of the membrane (possibly due to the entry of calcium ions inside the cell). A decrease in the intracellular cAMP concentration (by intracellular dialysis) evokes weakening of the potential-activated inward calcium current, whereas an increase leads to its restoration. Restoration of the calcium current can also be achieved by activation of the intracellular adenylate cyclase, inhibition of phosphodiesterase, or through direct injection of the catalytic subunit of cAMP-dependent protein kinase inside the cell. Evidence is presented that the regulatory effects obtained are mediated through cAMP-dependent phosphorylation of proteins in the corresponding ionic channels. Elevation of the intracellular calcium ion level interacts closely with the regulatory system described above through activation of some of its enzymic processes.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 16, No. 3, pp. 286–296, May–June, 1984.     

Selectivity of edta-modified calcium channels to monovalent cations

The characteristics of slow inward sodium currents arising in response to membrane depolarization were studied in experiments on isolated dialyzed neurons of the snailHelix pomatia when the calcium-chelating agent EDTA was added to the calcium-free external solution. Values of the relative permeability of the corresponding ionic channels, determined from the shift of the equilibrium potential, were: P_Na+:P_Li+: +=1.00:0.80:0.55:0.21. The ratio between these values for "fast" sodium channels was 1.00:1.04:0.44:0.19. The induced sodium current was blocked by D-600 and nifedipine, which block calcium channels, more effectively than the calcium current of the same membrane (the corresponding dissociation constants were 10^–5 and 0.8·10^–5 mole/liter for the induced sodium current compared with 2.6·10^–5 and 2.3·10^–5 mole/liter for the calcium current). It is postulated on the basis of these data that the calcium channels have a principal selective filter similar to that of sodium channels, but also an additional binding site for bivalent cations, which prevents entry of monovalent cations into the channel. The addition of calcium-chelating agents to the calcium-free external solution liberates this site and thereby modifies the calcium channel into a sodium channel.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 14, No. 5, pp. 491–498, September–October, 1982.     

Action of calcium ions on channels of inward and outward currents in the molluscan neuron membrane

Changes in the characteristics of activity of sodium, calcium, and potassium channels in the surface membrane during variation of the calcium ion concentration in the extracellular and intracellular medium were investigated by the voltage clamp method during intracellular dialysis of isolated neurons of the mollusksLimnea stagnalis andHelix pomatia. Besides their direct role in passage of the current through the membrane, calcium ions were shown to have two actions, differing in their mechanism, on the functional properties of this membrane. The first was caused by the electrostatic action of calcium ions on the outer surface of the membrane and was manifested as a shift of the potential-dependent characteristics of the ion transport channels along the potential axis; the second is determined by closer interaction of calcium ions with the specific structures of the channels. During the action of calcium-chelating agents EGTA and EDTA on the inner side of the membrane the conductivity of the potassium channels is substantially reduced. With an increase in the intracellular free calcium concentration the conductivity is partially restored. The action of EGTA and EDTA on the outer side of the membrane causes a substantial decrease in the ion selectivity of the calcium channels and changes the kinetics of the portal mechanism. These changes are easily abolished by rinsing off the chelating agents or by returning calcium ions to the external medium. A specific blocking action of an increase in the intracellular free calcium concentration on conductivity of the calcium channels was found.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 9, No. 1, pp. 69–77, January–February, 1977.     

Activity of lumbosacral interneurons during fictitious scratching

Activity of lumbosacral spinal interneurons was studied during fictitious scratching in decerebrate, immobilized cats. Neurons whose activity changed during fictitious scratching were located in the substantia intermedia lateralis and ventral horn. Among these neurons cells were distinguished whose activity was modulated in rhythm with motor discharges to different muscles (61.6%) and cells which were activated tonically (21.4%) or inhibited tonically (17%). By correlation of activity with discharges to corresponding muscles the rhythmically activated neurons were divided into "aiming" (36.6%) and "scratching" (25%). Neurons whose activity was unchanged during fictitious scratching also were observed. These cells were located mainly in the more dorsal regions of gray matter. Neurons to which wide convergence of excitatory influences from high-threshold cutaneous and muscular afferents was observed were mainly placed in the "aiming" group. "Scratching" neurons, compared with "aiming," more often received inputs only from low-threshold cutaneous or high-threshold muscular afferents. Group Ia interneurons were activated in phase with the corresponding motoneurons. Passive displacement of the limb in a forward direction predominantly inhibited spike activity of the "aiming" and potentiated activity of the "scratching" neurons. The neuronal organization of the spinal scratch generator is discussed on the basis of the results.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 13, No. 1, pp. 57–66, January–February, 1981.     

An Exposure to the Oxidized DNA Enhances Both Instability of Genome and Survival in Cancer Cells

Background

Cell free DNA (cfDNA) circulates throughout the bloodstream of both healthy people and patients with various diseases and acts upon the cells. Response to cfDNA depends on concentrations and levels of the damage within cfDNA. Oxidized extracellular DNA acts as a stress signal and elicits an adaptive response.

Principal Findings

Here we show that oxidized extracellular DNA stimulates the survival of MCF-7 tumor cells. Importantly, in cells exposed to oxidized DNA, the suppression of cell death is accompanied by an increase in the markers of genome instability. Short-term exposure to oxidized DNA results in both single- and double strand DNA breaks. Longer treatments evoke a compensatory response that leads to a decrease in the levels of chromatin fragmentations across cell populations. Exposure to oxidized DNA leads to a decrease in the activity of NRF2 and an increase in the activity of NF-kB and STAT3. A model that describes the role of oxidized DNA released from apoptotic cells in tumor biology is proposed.

Conclusions/Significance

Survival of cells with an unstable genome may substantially augment progression of malignancy. Further studies of the effects of extracellular DNA on malignant and normal cells are warranted.     

Alkalinization-Induced Changes in Intracellular Calcium in Rat Spinal Cord Neurons

It is well-known that pH changes can influence a lot of cellular processes. In this work, we have specifically studied the influence of alkalinization, which can be developed in spinal cord neurons during hyperventilation (respiratory alkalosis) and chronic renal failure (metabolic alkalosis) on calcium homeostasis. Application of Tyrode solution with increased pH (pH = 8.8) to secondary sensory neurons isolated from rat spinal dorsal horn induced elevation of intracellular free calcium concentration in the cytosol ([Ca2+]i) if applied after membrane depolarization. Repetitive application of alkaline solution led to disappearance of such elevations. Depletion of endoplasmic reticulum (ER) calcium stores by 30 mM caffeine almost completely blocked the effect of elevated extracellular pH. If caffeine-induced [Ca2+]i transients were evoked during alkalinization, their amplitudes were decreased by 41%. Preapplication of 500 nM ionomycin resulted in disappearance of alkalinization-induced [Ca2+]i transients, whereas prolonged applications (for 20 min) of 200 nM thapsigargin, a blocker of Ca2+ ATPase of the endoplasmic reticulum, resulted in disappearance of the rapid phase of the [Ca2+]i transients induced by alkalinization. Preapplication of the mitochondrial protonophore CCCP (10 microM) also induced changes in the alkalinization-induced calcium response--it lost its peak and was transformed into an irregular wave terminating in several seconds. The data obtained indicate that alkalinization induces an increase of [Ca2+]i level in the investigated neurons via a combined action of both intracellular Ca2+-accumulating structures--the endoplasmic reticulum and mitochondria. This suggestion was supported by morphological data that both structures in these neurons are tightly connected and may interact during release of accumulated calcium ions.