Hand preference during unimanual and bimanual reaching actions in Sichuan snub-nosed monkeys (Rhinopithecus roxellana)

Hand preferences were investigated during one unimanual action (food-reaching) and one bimanual action (mount-reaching) in a semi-free-ranging group of Sichuan snub-nosed monkeys (Rhinopithecus roxellana) in Zhouzhi National Nature Reserve, Qinling Mountains of China. Nine of 14 individuals tested on the unimanual food-reaching action and all six individuals tested on the bimanual mount-reaching action exhibited a manual preference. Both significant right- and left-handed preferences were observed in the two actions. Sex did not affect either direction or strength of hand preference in the unimanual action. Hand preference for the bimanual action was stable over time, and the strength of hand preference was significantly stronger in the bimanual action than in the unimanual action.     

Adjuvant actions of polyclonal lymphocyte activators: III. Two distinct types of T-initiating adjuvant action demonstrated under different experimental conditions

We demonstrated that each of various polyclonal lymphocyte activators (PLA) exhibits two types of adjuvant action to initiate the carrier-specific helper T-cell response to otherwise nonimmunogenic antigen. Type 1 action was characterized as that to initiate the T-cell response to subcutaneous injection of soluble bovine γ-globulin (BGG), and type 2 as that to initiate the response to intravenous injection of aggregated BGG. Each of various PLA showed these two types of adjuvant action in a dissociated fashion. The capsular polysaccharide of Klebsiella pneumoniae (CPS-K) showed both types of action to the highest degrees. Lipopolysaccharide of Escherichia coli exhibited type 2 action as markedly as CPS-K, but failed to show type 1 action. Concanavalin A showed definite type 1 action, but not type 2 action. Polyadenylic-uridylic acid showed definite type 2 action, but not type 1 action. Type 1 and type 2 actions of dextran sulfate were minimal. A hypothetical view is presented to consider that type 1 adjuvant action is directed to two mutually independent sites whereas type 2 action is directed to one site.     

Predictors of Intention to Act and Implementation of Action in Dream Sessions: Therapist Skills, Level of Difficulty of Action Plan, and Client Involvement.

The authors examined predictors of intention to act and implementation of action in the C. E. Hill (1996, 2004; see also records 1996-98128-000 and 2003-07019-000) 3-stage (exploration, insight, action) dream model. Thirty adult volunteer clients participated in two 90-min dream sessions. On average, clients said at the end of sessions that they intended to carry out their action plans and then actually did implement their action plans after the sessions. Intention to carry out the action plan was predicted by the client's perceptions of therapist action skills, client involvement, and the level of difficulty of the action plan. Implementation of action was predicted by the level of difficulty of the action plan and the client's intention to carry out the plan. Implications for the Hill dream model and for research are discussed. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

The inhibitory effects of dantrolene on action potential-induced calcium transients in cultured rat dorsal root ganglion neurons

We investigated the actions of dantrolene Ca(2+)-induced on Ca(2+)-release (CICR) evoked by action potentials in cultured rat sensory neurons. The effect of dantrolene on action potential after-depolarization and voltage-activated calcium currents was studied in cultured neonatal rat dorsal root ganglion cells (DRG) using the whole-cell patch-clamp technique. Depolarizing current injection evoked action potentials and depolarizing after-potentials, which are activated as a result of CICR following a single action potential in some cells. The type of after-potentials was determined by inducing action potentials from the resting membrane potential. Extracellular application of dantrolene (10 microM) abolished after-depolarizations without affecting action potential properties. Furthermore, dantrolene significantly reduced repetitive action potentials after depolarizing current injection into these neurons, but had no significant effect on the steady-state current voltage relationship of calcium currents in these neurons. We conclude that dantrolene inhibits the induction of action potential after depolarizations by inhibiting CICR in cultured rat sensory neurons.     

Action of acetylcholine on the mammalian auricle influenced by verapamil

The action of acetylcholine (ACh) and verapamil (VePa) on the action potential (V(t)), phase plane trajectories of V(t) (dV/dt--V(t) -- plot) and isotonic contractions were investigated using an isolated vegal innervated preparation from rabbit atrium (method I) and investigating action potentials from atrial trabeculae by means a modified sucrose gap technique (method II). If the VePa-concentration increases to 4 mg/1 the duration of the action potential decreases at 20 and 90% repolarization (driving frequencies 2 s-1). In the VePa-solutions phase plane trajectories of the action potential did not change significantly. ACh application favours the disappearance of a region in the repolarization phase plane plot showing anomalous rectification (d(--dV/dt)/dV less than 0) both by control conditions and verapamil. The electrotropic ACh-and vagal effects will be unchanged by verapamil. The inotropic ACh-and vegal action (method I) increases by VePa (2 mg/1). The action of ACh and verapamil will be analysed using a mathematical model for reconstructing the repolarization phase of mammalian atrial myocardium action potentials.     

The ionic requirements for the production of action potential in Achatina fulica Ferussac neuron

The ionic requirement for the production of directly elicited action potentials of a tonically auto-active neuron (TAN) in the subesophageal ganglia of the giant African snail, Achatina fulica Ferussac, was studied electrophysiologically. Calcium free Ringer solution containing 1 mM EDTA reversibly abolished the directly elicited action potential. Verapamil (10 micrograms/ml) or cocaine (4 mg/ml) decreased both amplitude and Vmax of the action potentials. The amplitude of the action potential was also slightly decreased in sodium free choline Ringer. However, tetrodotoxin did not significantly affect either the amplitude or Vmax of the directly elicited action potentials. The results suggest that the ionic requirement for generating action potential in snail neuron is not an ordinary sodium spike. Both calcium and sodium ions may participate in carrying charges across the membrane of the action potential.     

Insulin Action in Rats Is Influenced by Amount and Composition of Dietary Fat

The chronic influence of dietary fat composition on obesity and insulin action is not well understood. We examined the effect of amount (20% vs 60% of total calories) and type (saturated vs polyunsaturated) of fat on insulin action and body composition in mature male rats. Six months of feeding a high fat (HF) diet led to obesity and impaired insulin action (determined by a euglycemic-hyperinsulinemic clamp), neither of which were reversed by a subsequent 6 months of feeding a low fat (LF) diet. Within HF fed rats, type of fat did not affect body composition or insulin action. Six months of feeding a low fat diet led to only a slight decline in insulin action, with no difference due to type of dietary fat. From 6–9 months, insulin action became more impaired in LF rats fed the saturated diet than in LF rats fed the polyunsaturated diet. By 12 months, all groups were obese and had a similar impairment in insulin action. The amount and type of fat in the diet did not influence the overall degree of impairment in insulin action but did affect the time course. Both feeding a high fat diet and feeding a low fat saturated diet accelerated the impairment in insulin action relative to rats fed a low fat polyunsaturated fat diet.     

哺乳动物不活动化肌纤维的动作电位

用河豚毒素(TTX)慢性阻断大鼠坐骨神经的冲动传导,使后肢不活动,经过不同时间(最长7d)后离体观察了快肌伸趾长肌(EDL)和慢肌比目鱼肌(SOL)肌纤维终板区的诱发动作电位。我们发现在不活动期间动作电位超射和上升速率逐步下降,并从第4天起部分肌纤维能在含有1×10~(-7)g/ml TTX的溶液中被诱发产生动作电位(称抗TTX动作电位),待至第7天时全部SOL肌纤维和90％的EDL肌纤维都能被诱发出抗TTX动作电位。与去神经肌纤维相比,不仅抗TTX动作电位出现较晚,并且其超射和上升速率较低。在去掉TTX阻断使肌肉恢复活动后,动作电位超射和上升速率渐趋恢复,抗TTX动作电位逐渐消失。无论是动作电位的恢复还是抗TTX动作电位的消失,EDL肌纤维均快于SOL肌纤维。本文还讨论了不活动化使肌纤维动作电位变化以及快、慢肌差别的可能原因。     

Pattern of insulin delivery affects hepatic insulin sensitizing substance (HISS) action and insulin resistance

Hepatic insulin sensitizing substance (HISS) action accounts for 55% of the glucose disposal effect of a bolus of insulin in the fed state. To determine the effect of continuous versus pulsatile insulin delivery on HISS action in male Sprague-Dawley rats, insulin sensitivity was assessed using the rapid insulin sensitivity test (RIST) before and after a continuous, pulsatile, or bolus insulin (60 mU/kg i.v.) delivery. There was a significant difference in the RIST index after a continuous insulin infusion (247.9 mg/kg before, 73.2 mg/kg after) but not after 3 pulses where insulin action returned to baseline between pulses (211.6 mg/kg before, 191.0 mg/kg after) or single bolus (205.8 mg/kg before, 189.9 mg/kg after) insulin infusion. If a 3-pulse infusion was timed so that insulin action did not return to baseline between pulses, HISS action was suppressed. Continuous insulin infusion (10-30 min) showed progressive postinfusion blockade of HISS action. To maintain HISS-dependent insulin action, continuous insulin infusions should be avoided.     

Effects of ACh and adenosine mediated by Kir3.1 and Kir3.4 on ferret ventricular cells

The inotropic effects of ACh and adenosine on ferret ventricular cells were investigated with the action potential-clamp technique. Under current clamp, both agonists resulted in action potential shortening and a decrease in contraction. Under action potential clamp, both agonists failed to decrease contraction substantially. In the absence of agonist, application of the short action potential waveform (recorded previously in the presence of agonist) also resulted in a decrease in contraction. Under action potential clamp, application of ACh resulted in a Ba(2+)-sensitive outward current with the characteristics of muscarinic K+ current (I(K,ACh)); the presence of the muscarinic K+ channel was confirmed by PCR and immunocytochemistry. In the absence of agonist, on application of the short ACh action potential waveform, the decrease in contraction was accompanied by loss of the inward Na(+)/Ca(2+) exchange current (I(NaCa)). ACh also inhibited the background inward K+ current (I(K,1)). It is concluded that ACh activates I(K,ACh), inhibits I(K,1), and indirectly inhibits I(NaCa); this results in action potential shortening, decrease in contraction, and, as a result of the inhibition of I(K,1), minimum decrease in excitability.     

Radial propagation of muscle action potential along the tubular system examined by potential-sensitive dyes

Isolated single (Xenopus) muscle fibers were stained with a non-permeant potential-probing dye, merocyanine rhodanine (WW375) or merocyanine oxazolone (NK2367). When the fiber was massively stimulated, an absorption change (wave a), which seemed to reflect the action potential, occurred. Simultaneous recording of optical changes and intracellular action potentials revealed that the time-course of wave a was slower than the action potential: the peak of wave a was attained at 1 ms, and the peak of action potential was reached at 0.5 ms after the stimulation. This difference suggests that wave a represents the potential changes of the whole tubular membrane and the surface membrane, whereas the action potential represents a surface potential change. This idea was substantiated by recording absorption signals preferentially from the surface membrane by recording the absorption changes at the edge of the fiber. Wave a obtained by this method was as quick as the intracellular action potential. The value of radial conduction velocity of action potential along the T system, calculated by comparing the action potential with wave a, was 6.4 cm/s at 24.5 degrees C, in fair agreement with González-Serratos (1971. J. Physiol. [Lond.]. 212:777-799). The shape of wave a suggests the existence of an access delay (a conduction delay at the orifice of the T system) of 130 microseconds.     

Analysis of the transient increase in cytosolic Ca2+ during the action potential of higher plants with high temporal resolution: requirement of Ca2+ transients for induction of jasmonic acid biosynthesis and PINII gene expression

Plants respond to various abiotic stimuli by activation and propagation of fast electrical signals, action potentials. To resolve the temporal increase in cytosolic Ca(2)(+) during the action potentials of higher plants, we regenerated transgenic potato plants that expressed the Ca(2)(+) photoprotein apoaequorin. These genetically engineered potato plants were used for simultaneous measurements of transient changes in the membrane potential and the Ca(2)(+) luminescence triggered by heat-induced action potentials. High temporal resolution for recording of the fast transient electrical and light signals was accomplished by a sampling rate of 1 kHz. Upon elicitation by heat the membrane potential depolarization preceded the rise of cytosolic Ca(2)(+) by 50-100 ms. Several Ca(2)(+) channel blockers were tested to inhibit the rise in cytosolic Ca(2)(+). Treatment of plants with Ruthenium Red blocked the elevation in cytosolic Ca(2)(+) that was associated with heat-stimulated action potentials. Furthermore, action potentials have been demonstrated to stimulate jasmonic acid biosynthesis and PINII gene expression. Therefore, we measured jasmonic acid and PINII gene expression levels subsequent to action potential initiation by a short heating pulse. As expected, jasmonic acid biosynthesis and PINII gene expression were induced by action potentials. Pretreatment of potato plants with Ruthenium Red inhibited induction of jasmonic acid biosynthesis and PINII gene expression that was generally triggered by heat-activated action potentials.     

Sodium and calcium currents in action potentials of rat somatotrophs: their possible functions in growth hormone secretion

We report that both Na+ and Ca2+ currents are involved in the action potentials and in the hormone release from rat somatotrophs in primary culture. Single somatotrophs were identified by reverse hemolytic plaque assay (RHPA) and transmembrane voltage and currents were recorded using the whole-cell mode of the patch-clamp technique. Somatotrophs displayed a mean resting potential of -80mV and an average input resistance of 5.7G omega. Most of the cells showed spontaneous or evoked action potentials. Single action potentials or the initial spike in a burst were characterized by their high amplitude and short duration. Tetrodotoxin (TTX, 1 microM) blocked single action potentials and the initial spikes in a burst, whereas action potentials of long duration and low amplitude persisted. Cobalt (2 mM) plus TTX (1 microM) blocked all the action potentials. Voltage-clamp experiments confirmed the presence of both a TTX-sensitive Na+ current and Co2(+)-sensitive Ca2+ currents. TTX or Na(+)-free medium slightly decreased the basal release of GH but did not markedly modify hGRF-stimulated GH release. However, Co2+ (2 mM), which partially decreased the basal release, totally blocked hGRF-stimulated release. We conclude that (1) Na+ currents which initiate rapid action potentials may participate in spontaneous GH release; (2) Ca2+ currents, which give rise to long duration action potentials and membrane voltage fluctuation, are probably involved in both basal and hGRF-stimulated GH releases.     

Changes in sensitivity to anoxia of the cardiac action potential plateau during chick embryonic development.

The effects of anoxia on cardiac action potentials were studied at different stages of development of embryonic chick heart. The plateau phase of the action potential was markedly depressed by anoxia in old (15–16 days old) embryonic hearts without any significant change in other configurations of the action potential. Raising the concentration of glucose in the external fluid prevented the shortening of the action potential plateau by anoxia, and, conversely, a further reduction was observed in glucose-free media. In young (3–4 days old) embryonic hearts, the shortening of the action potential plateau was not produced by anoxia, but was produced by a combination of anoxia and glucose deprivation. When the action potential was shortened by anoxia in old hearts and by anoxia plus glucose deprivation in young hearts, isoproterenol (10^?5M), dibutyryl cyclic 3′,5′-adenosine monophosphate (dBcAMP: 1 mM) plus aminophylline (1 mM), and calcium ion (3–6 mM), partially reversed the shortened action potential in old hearts, but did not produce any prolongation in the young hearts. Therefore, the cation channels responsible for the action potential plateau in young hearts may be pharmacologically different from those in old hearts. The differences in action potential plateau between young and old hearts were discussed in relation to dependence upon energy.     

Dynamics of the inward rectifier K+ current during the action potential of guinea pig ventricular myocytes.

The potassium selective, inward rectifier current (IK1) is known to be responsible for maintaining the resting membrane potential of quiescent ventricular myocytes. However, the contribution of this current to the different phases of the cardiac action potential has not been adequately established. In the present study, we have used the action potential clamp (APC) technique to characterize the dynamic changes of a cesium-sensitive (i.e., Ik1) current which occur during the action potential. Our results show that (a) Ik1 is present during depolarization, as well as in the final phase of repolarization of the cardiac action potential. (b) The current reaches the zone of inward-going rectification before the regenerative action potential ensues. (c) The maximal outward current amplitude during repolarization is significantly lower than during depolarization, which supports the hypothesis that in adult guinea pig ventricular myocytes, Ik1 rectification is accentuated during the action potential plateau. Our results stress the importance of Ik1 in the modulation of cell excitability in the ventricular myocyte.     

Uniform and Complementary Social Interaction: Distinct Pathways to Solidarity

We examine how different forms of co-action give rise to feelings of solidarity. We propose that (a) coordinated action elicits a sense of solidarity, and (b) the process through which such solidarity emerges differs for different forms of co-action. We suggest that whether solidarity within groups emerges from uniform action (e.g. synchronizing, as when people speak in unison) or from more complementary forms of action (e.g. alternating, when speaking in turns) has important consequences for the emergent position of individuals within the group. Uniform action relies on commonality, leaving little scope for individuality. In complementary action each individual makes a distinctive contribution to the group, thereby increasing a sense of personal value to the group, which should contribute to the emergence of solidarity. The predictions receive support from five studies, in which we study groups in laboratory and field settings. Results show that both complementary and uniform co-action increase a sense of solidarity compared to control conditions. However, in the complementary action condition, but not in the uniform action (or synchrony) condition, the effect on feelings of solidarity is mediated by a sense of personal value to the group.     

Ephaptic Transmission and Conduction Velocity of an Action Potential in Chara Internodal Cells Placed in Parallel and in Contact with One Another

When two separated Chara internodal cells were kept in contactover a length of 14 mm or more in moist air, an action potentialof one cell could be transmitted to the other cell in about40% of cases (ephaptic transmission). The action potential ofthe former cell was sometimes eliminated transiently when anew action potential was elicited in the latter cell. The newaction potential reactivated the former cell. The conductionvelocity of the action potential was reduced from 0.30?0.11cm/s (mean?SD) to 0.15?0.05 cm/s by ephaptic transmission ofthe action potential. Substitution of an artificial pond waterfor moist air or contact over a shorter length (4 mm insteadof 14 mm or more) between the two cells reduced the couplingratio, the ratio of the change in membrane potential of onecell to that of the other cell, and no transmission was observed.After ephaptic transmission, the action potentials of the twocells were conducted at almost the same velocity along the cells.The velocity was increased to 0.68?0.06 cm/s by simultaneousconduction of the action potentials in the two adjacent cells.When the simultaneously conducted action potentials reachedthe node of one cell, at the point at which another cell madecontact, they were able very frequently to trigger a new actionpotential in the adjoining cell. (Received September 28, 1989; Accepted April 5, 1990)     

Sensitivity of BALB/c and WR strain mice to the immunodepressive action of cyclophosphamide and thiophosphamide

Experiments were made on BALB/cJ YSto and WR/Y mice to study the immunosuppressant action of cyclophosphamide (CP) and thiophosphamide (thiotepa) in vivo. WR mice were found to be significantly more sensitive to the immunosuppressant action of thiotepa than BALB/c mice and to have similar sensitivity to the action of CP. BALB/c mice appeared highly resistant to the action of both the drugs. Based on the data obtained and those reported in the literature a possible parallelism is suggested between the mutagenic and immunosuppressant action of CP and thiotepa.     

Ionic basis for excitability of normal rat kidney (NRK) fibroblasts

Ionic membrane conductances of normal rat kidney (NRK) fibroblasts were characterized by whole-cell voltage-clamp experiments on single cells and small cell clusters and their role in action potential firing in these cells and in monolayers was studied in current-clamp experiments. Activation of an L-type calcium conductance (GCaL) is responsible for the initiation of an action potential, a calcium-activated chloride conductance (GCl(Ca)) determines the plateau phase of the action potential, and an inwardly rectifying potassium conductance (GKir) is important for the generation of a resting potential of approximately -70 mV and contributes to action potential depolarization and repolarization. The unique property of the excitability mechanism is that it not only includes voltage-activated conductances (GCaL, GKir) but that the intracellular calcium dynamics is also an essential part of it (via GCl(Ca)). Excitability was found to be an intrinsic property of a fraction (approximately 25%) of the individual cells, and not necessarily dependent on gap junctional coupling of the cells in a monolayer. Electrical coupling of a patched cell to neighbor cells in a small cluster improved the excitability because all small clusters were excitable. Furthermore, cells coupled in a confluent monolayer produced broader action potentials. Thus, electrical coupling in NRK cells does not merely serve passive conduction of stereotyped action potentials, but also seems to play a role in shaping the action potential.