Population-specific behavioral electrosensitivity of the European blind cave salamander,Proteus anguinus

In nine salamanders from different Slovenian populations of the urodele Proteus anguinus, including three specimens of its ‘black’ variety, P anguinus parkelj, thresholds of an overt avoidance response to electrical field stimuli were estimated as a function of frequency (continuous sine-waves in water). Thresholds down to 0.3 mV/cm (ca 100 nA/cm²) and up to 2 mV/cm (670 nA/cm²), at ‘best frequencies’ of around 30 Hz were found. Sensitivity covered a total frequency range of below 1 Hz, excluding DC, up to 1–2 kHz with up to 40 dB higher thresholds. Thresholds and tuning curves are compared with those of a Proteus population raised in captivity for more than 35 years. The biological significance and the apparently still ongoing evolution of the electrical sense in urodeles, ie in the genus Proteus, are interpreted in terms of comparative sensory physiology and ethological ecology as a result of more recent evolutionary diversification during and since glaciation in the Pleistocene.     

Acoustic and somatosensory evoked responses in the brain hemispheres of chick embryos.

The author explored the auditory projection in the brain hemispheres of 16- to 21-day-old chick embryos, using biaural stimulation, and the somatosensory projection, using electrical stimulation of the contralateral sciatic nerve. The first auditory evoked responses appeared on the surface of the hemisphere at the beginning of the 18th day of incubation and were localized in its mediolateral part. Up to hatching, the latent period of the surface response shortened from 76.3 msec to 28.9 msec and its amplitude augmented from 10.6 muV to 36.2 muV. If the electrode was plunged into the tissue, the evoked responses with the optimum latent period and amplitude parameters were recorded at a depth of 2-2.5 mm (latent period 20.2 msec, amplitude 40-45 muV). The maximum surface somatosensory responses were found in the medial occipital quadrant of the contralateral hemisphere. They developed from the second half of the 17th day of incubation. Up to the end of incubation the mean latent period shortened from 58.3 msec to 21.6 msec and the mean amplitude increased from 11.8 muV to 28.7 muV. What was at first a simple negative wave developed into a positive-negative complex by the end of incubation. Evoked responses at a depth of about 3.5 mm from the surface of the hemisphere had the optimum parameters (latent period 18.4 msec, amplitude 30.2 muV).     

Electric field strength of membrane lipids from vertebrate species: membrane lipid composition and Na+-K+-ATPase molecular activity

Intramembrane electric field strength is a very likely determinant of the activity of ion-transporting membrane proteins in living cells. In the absence of any transmembrane electrical potential or surface potential, its magnitude is determined by the dipole potential of the membrane's lipid components and their associated water of hydration. Here we have used a fluorometric method to quantify the dipole potential of vesicles formed from lipids extracted from kidney and brain of 11 different animal species from four different vertebrate classes. The dipole potential was compared with the fatty acid composition and with the Na(+)-K(+)-ATPase molecular activity of each preparation. The magnitude of the dipole potential was found to be relatively constant across all animal species, i.e., 236-334 mV for vesicles prepared from the total membrane lipids and 223-256 mV for phospholipids alone. The significantly lower value for phospholipids alone is potentially related to the removal of cholesterol and/or other common soluble lipid molecules from the membrane. Surprisingly, no significant dependence of the dipole potential on fatty acid composition was found. This may, however, be due to concomitant compensatory variations in lipid head group composition. The molecular activity of the Na(+)-K(+)-ATPase was found to increase with increasing dipole potential. The fact that the dipole potential is maintained at a relatively constant value over a wide range of animal species suggests that it may play a fundamental role in ensuring correct ion pump conformation and function within the membrane.     

SEA0400, a novel Na+/Ca2+ exchanger inhibitor, reduces calcium overload induced by ischemia and reperfusion in mouse ventricular myocytes

Given the potential clinical benefit of inhibiting Na+/Ca2+ exchanger (NCX) activity during myocardial ischemia reperfusion (I/R), pharmacological approaches have been pursued to both inhibit and clarify the importance of this exchanger. SEA0400 was reported to have a potent NCX selectivity. Thus, we examined the effect of SEA0400 on NCX currents and I/R induced intracellular Ca2+ overload in mouse ventricular myocytes using patch clamp techniques and fluorescence measurements. Ischemia significantly inhibited inward and outward NCX current (from -0.04+/-0.01 nA to 0 nA at -100 mV; from 0.23+/-0.08 nA to 0.11+/-0.03 nA at +50 mV, n=7), Subsequent reperfusion not only restored the current rapidly but enhanced the current amplitude obviously, especially the outward currents (from 0.23+/-0.08 nA to 0.49+/-0.12 nA at +50 mV, n=7). [Ca2+]i, expressed as the ratio of Fura-2 fluorescence intensity, increased to 138+/-7% (P<0.01) during ischemia and to 210+/-11% (P<0.01) after reperfusion. The change of NCX current and the increase of [Ca2+]i during I/R can be blocked by SEA0400 in a dose-dependent manner with an EC50 value of 31 nM and 28 nM for the inward and outward NCX current, respectively. The results suggested that SEA0400 is a potent NCX inhibitor, which can protect mouse cardiac myocytes from Ca2+ overload during I/R injuries.     

Electrically induced tentacle contraction in the suctorian protozoonTrichophrya collini

Summary Extracellular electrical stimulation ofTrichophrya collini induces tentacle contraction. There is an inverse relationship between stimulus duration and voltage in producing a threshold response, and at a set voltage the response is graded depending upon duration of stimulus. With a threshold stimulus (6.3 V, 1,000 ms) the response is restricted to the anodal tentacles, and with increasing stimulus intensity or duration the response spreads to the cathodal and finally the intermediate tentacles. With a stimulus of 15 V, 1,000 ms the mean tentacle length is reduced to 28% of the control within 1.2 s. Recordings using intracellular microelectrodes give resting membrane potentials between –10mV and –40mV. Intracellular hyperpolarizing currents of 1nA and 2nA induce tentacle contraction to 50% and 25% of the control length respectively, but depolarizing currents do not induce contraction. SEM studies show that in the initial stages of contraction, only the central region of the tentacle shaft becomes shortened, but on full contraction shortening involves the whole of the shaft. TEM studies show that on contraction no depolymerization of tentacle axoneme microtubules occurs, but that the entire axoneme passes down into the body cytoplasm. These observations are discussed in relation to the possible mechanisms of tentacle contraction.Abbreviations Ax axoneme - C cortex - EDB elongate dense body - SEM scanning electron microscopy - TEM transmission electron microscopy     

Current densities induced in swine and rat models by power-frequency electric fields

Measurements have been made of vector current densities induced by vertical, uniform, 60-Hz electric fields in the torsos of homogeneous models of swine and rats. The observed data were a strong function of the five grounding configurations invested: all four feet grounded, only front feet grounded, only rear feet grounded, left front and right rear feet grounded, and right front and left rear feet grounded. In the first configuration and with an exposure field strength of 10 kV/m, average total current densities induced in the torsos of pigs and rats were 34 nA/cm2 and 20 nA/cm2, respectively. The corresponding value for human exposure is about 250 nA/cm2, 7.3 and 12.5 times larger than for swine and rats, respectively. Current densities measured at 60 Hz can be linearly extrapolated to frequencies in a range extending from at least 1 Hz to 1 MHz. Human and animal current-density data can provide an improved rationale for extrapolating biological data across species. In addition, these data can be used to validate the predictions of numerical models.     

Changes in early acoustic-evoked potentials by mildly arousing priming stimuli in carp (Cyprinus carpio).

1. Averaged acoustic-evoked potential (AEPs) in the medulla and midbrain were recorded, as were changes in heart rate, indicating arousal, to a previous non-acoustic priming stimulus. 2. Useful AEP measures were amplitude of the early biphasic wave (less than 10 msec) in medulla and amplitude and duration of this wave in midbrain. 3. There was a negative regression of heart rate and medullary AEP amplitude especially evident for a 2 sec light stimulus. Decreased AEP amplitude in both regions was induced by water movement and an increase in midbrain AEP duration by the tactile stimulus. 4. Arousal effects even on these early AEP measures are specific to the form of arousing stimulus.     

Low mass-specific brain Na+/K+-ATPase activity in elasmobranch compared to teleost fishes: implications for the large brain size of elasmobranchs

Elasmobranch fishes have long been noted for having unusually large brains for ectotherms, and therefore may be exceptions to the rule that vertebrates in general devote less than 8% of their resting metabolic rate to the central nervous system. The brain mass of sharks, skates and rays is often several times larger than that of teleost fishes of the same size. Still, the underlying reasons for this have remained unclear. Ion pumping by the Na+/K+-ATPase is the single most energy consuming process in the brain. In this study, Na+/K+-ATPase activity was measured in the brain of four species of elasmobranchs and 11 species of teleosts. While the average brain mass of the elasmobranchs examined was approximately three times that of the teleosts, the mean specific Na+/K+-ATPase activity was only about one-third of that of the teleosts. Thus, the total brain Na+/K+-ATPase activity was similar in elasmobranchs and teleosts. This suggests that the large brain size of elasmobranchs is at least partly related to a low mass-specific rate of brain energy use.     

前庭壶腹嵴内电位的电生理特性

本研究利用高输入阻抗微电极放大器，观察正常豚鼠（ｎ＝３５）前庭壶腹嵴内电位（ＡＥＰ），以及缺氧、缺血、静脉注射速尿对其影响，探讨ＡＥＰ的电生理特性。结果表明正常豚鼠ＡＥＰ为４．５５±１．３５ｍＶ，停止呼吸机２ｍｉｎ，ＡＥＰ下降至２．３±０．８ｍＶ，恢复呼吸后均可观察到超射现象，阻断升主动脉后ＡＥＰ持续下降，达最大负值为－１９．４±１．７ｍＶ，所需时间为５２．５±９．６ｍｉｎ，约１５０ｍｉｎ后缓慢上升至０。静脉注射速尿后与注射前无显著差异。支持ＡＥＰ是不同于耳蜗内电位的正电位，有不同于耳蜗内电位的电生理特性。就其在前庭生理研究中的应用前景进行讨论     

Sodium-pump potentials and currents in guinea-pig ventricular muscles and myocytes.

When guinea-pig papillary muscles were depolarized to ca. -30 mV by superfusion with K+-free Tyrode's solution supplemented with Ba2+, Ni2+, and D600, addition of Cs+ transiently hyperpolarized the membrane in a reproducible manner. The size of the hyperpolarization (pump potential) depended on the duration of the preceding K+-free exposure; peak amplitudes (Epmax) elicited by 10 mM Cs+ after 5-, 10-, and 15-min K+-free exposures were 12.9, 17.7, and 23.2 mV, respectively. Pump potentials were unaffected by external Cl- but suppressed by cardiac glycosides, hyperosmotic conditions, and low-Na+ solution. Using Epmax as an indicator of Na+ pump activation, the half-maximal concentration for activation by Cs+ was 12-16.3 mM. At 6 mM, Cs+ was three times less potent than Rb+ or K+ and five times more potent than Li+. From these findings, and correlative voltage-clamp data from myocytes, we calculate that (i) a pump current of 7.8 nA/cm2 generates an Epmax of 1 mV and (ii) resting pump current in normally polarized muscle (approximately 0.16 microA/cm2) is five times smaller than previously estimated.     

Limulus ventral eye. Physiological properties of photoreceptor cells in an organ culture medium

Ventral photoreceptor cells bathed in an organ culture medium typically have resting potentials of -85 mV and membrane resistances of 35 Momega and, when dark-adapted, exhibit large potential fluctuations (LPFs) of 60 mV and small potential fluctuations (SPFs) of less than 30 mV. LPFs appear to be regenerative events triggered by SPFs, the well-known quantum bumps. In the dark, SPFs and LPFs occur spontaneously. At intensities near threshold, the rate of occurrence is directly proportional to light intensity, indicating that SPFs and LPFs are elicited by single photon events. At higher intensities, SPFs and LPFs sum to produce a receptor potential that is graded over approximately a 9-log-unit range of light intensity. Amplitude histograms of the discrete potential waves are bimodal, reflecting the SPF and LPF populations. Histograms of current waves are unimodal. SPFs and LPFs are insensitive to 1 microgram tetrodotoxin. I-V characteristics show initial inward currents of approximately 15 nA for voltage clamps to - 40 mV and steady-state outward currents for all clamp potentials. Photoreceptor cells bathed in organ culture medium retain these properties for periods of at least 75 days.     

Evoked potentials of the human cerebral cortex to perceptible and imperceptible sound stimuli

Evoked potentials averaged with the help of an electronic computer (AEP) to brief sound stimuli of subthreshold (3–10 dB below the threshold of the signal's audibility), threshold, and superthreshold (10–60 dB above the threshold) intensity were recorded from the vertex and occipital region of the cranium in healthy people. The dynamics of the changes in the AEP with an increase in the intensity of the sound from subthreshold to superthreshold (60 dB) values was shown. The time and amplitude parameters of AEP to imperceptible and perceptible sound stimuli differed significantly. The most constant, and in many cases the only component of the AEP to an imperceptible stimulus was a long-latent, low-amplitude, slow positive oscillation. The participation of the cerebral cortex in the neural mechanisms of reactions to imperceptible sound stimuli is discussed.V. P. Serbskii Central Scientific-Research Institute of Forensic Psychiatry, Moscow. Translated from Neirofiziologiya, Vol. 3, No. 2, pp. 115–122, March–April, 1971.     

Biophysical properties of hypoglossal neurons in vitro: intracellular studies in adult and neonatal rats

A brain stem slice preparation from adult and neonatal (less than or equal to 12 days old) rats and intracellular recordings were used to examine the cellular properties of neurons within the hypoglossal (HYP) nucleus. Resting membrane potential (Vm) for adult hypoglossal neurons was -80 +/- 2 (SE) mV. Rheobase was 2.1 +/- 0.4 nA, and input resistance (RN) was 20.8 +/- 1.5 M omega and decreased during the hyperpolarizing period ("sag"). Compared with adult HYP cells, newborn HYP neurons had significantly lower resting potentials (Vm = -73 +/- 2 mV), lower rheobase (0.7 +/- 0.2 nA), and higher RN (27.6 +/- 3.9 M omega). Single action potentials, elicited by short depolarizing-current pulses, were followed by a slow afterhyperpolarization in adult [6.4 +/- 0.3 mV, time constant (tc) 31.0 +/- 1.2 ms] and newborn cells (7.4 +/- 0.2 mV, tc 37.2 +/- 8.2 ms). Prolonged outward current (2 s) produced little spike frequency adaptation in either adult or newborn neurons. Onset of spike activity was not delayed by hyperpolarizing pulses preceding depolarizations. In addition, pharmacological experiments showed that HYP neurons have a tetrodotoxin-sensitive Na+ current and a delayed and an inward rectifier current but no major Ca2+ current. We conclude the following. 1) Electrophysiological membrane properties mature postnatally in HYP neurons; some of these developmental changes can be ascribed to an increase in soma size and dendritic outgrowth but others cannot. 2) Adult HYP neurons, compared with other brain stem neurons (i.e., vagal cells or cells in the nucleus tractus solitarius), are not endowed with major Ca2+ currents or K+ currents such as the A current and the Ca2(+)-activated K+ current.     

Spatial localization and properties of pacemaker potentials in the canine rectoanal region

The present study investigated the spatial organization of electrical activity in the canine rectoanal region and its relationship to motility patterns. Contraction and resting membrane potential (E(m)) were measured from strips of circular muscle isolated 0.5-8 cm from the anal verge. Rapid frequency [25 cycles/min (cpm)] E(m) oscillations (MPOs, 12 mV amplitude) were present across the thickness of the internal anal sphincter (IAS; 0.5 cm) and E(m) was constant (-52 mV). Between the IAS and the proximal rectum an 18 mV gradient in E(m) developed across the muscle thickness with the submucosal edge at -70 mV and MPOs were replaced with slow waves (20 mV amplitude, 6 cpm). Slow waves were of greatest amplitude at the submucosal edge. Nifedipine (1 micro M) abolished MPOs but not slow waves. Contractile frequency changes were commensurate with the changes in pacemaker frequency. Our results suggest that changing motility patterns in the rectoanal region are associated with differences in the characteristics of pacemaker potentials as well as differences in the sites from which these potentials emanate.     

Short-term exposure to waterborne free silver has acute effects on membrane current of Xenopus oocytes

Waterborne free silver can cause osmo- and ionoregulatory disturbances in freshwater organisms. The effects of a short-term exposure to extracellular Ag+ ions on membrane currents were investigated in voltage-clamped defolliculated Xenopus oocytes. At a holding potential of -60 mV, ionic silver (1 microM Ag+) increased inward currents (=I(Ag)) from -8+/-2 nA to -665+/-41 nA (n=74; N=27). I(Ag) activated within 2 min of silver exposure and then rose impetuously. This current was largely reversible by washout and repeatable. I(Ag) reversed around -30 mV and rectified slightly at more positive potentials. Na+-free bath conditions reduced the silver-induced current to a smaller but sustained current. The response to silver was abolished by the Cl- channel blockers DIDS and SITS, whereas niflumic acid strongly potentiated I(Ag). Intraoocyte injection of AgNO3 to about 1 mM [Ag]i strongly potentiated I(Ag). Extracellular application of either dithiothreitol (DTT), a compound known to reduce disulfide bridges, or L-cysteine abolished Ag+-activated increase of membrane current. In contrast, n-ethylmaleimide (NEM) which oxidizes SH-groups potentiated I(Ag). Hypoosmotic bath solution significantly increased I(Ag) whereas hyperosmolar conditions attenuated I(Ag). The activation of I(Ag) was largely preserved after chelation of cytosolic Ca2+ ions with BAPTA/AM. Taken together, these data suggest that Xenopus oocytes are sensitive to short-term exposure to waterborne Ag+ ions and that the elicited membrane currents result from extra- and intracellular action of Ag+ ions on peptide moieties at the oocyte membrane but may also affect conductances after internalization.     

Anatomy and physiology of identified wind-sensitive local interneurons in the cricket cercal sensory system

1. A group of wind sensitive local interneurons (9DL Interneurons) in the terminal abdominal ganglion of the cricket Acheta domesticus were identified and studied using intracellular staining and recording techniques. 2. The 9DL interneurons had apparent resting potentials ranging from -38 mV to -45 mV. At this membrane potential, these cells produced graded responses to wind stimuli; action potentials were never observed at these resting potentials. However, when the 9DL interneurons were hyperpolarized to a membrane potential of approximately -60 mV, a single action potential at the leading edge of the wind stimulus response was sometimes observed. 3. The wind stimulus threshold of the 9DL interneurons to the types of stimuli used in these studies was approximately 0.01 cm/s. Above this threshold, the excitatory responses increased logarithmically with increasing peak wind velocity up to approximately 0.5 cm/s. 4. The 9DL interneurons were directionally sensitive; their response amplitudes varied with wind stimulus orientation. 9DL1 cells responded maximally when stimulated with wind directed at the front of the animal. The apparent peak in directional sensitivity of the 9DL2 interneurons varied between the side and the rear of the animal, depending upon the site of electrode penetration within the cell's dendritic arbor. 5. The locations of dendritic branches of the 9DL interneurons within the afferent map of wind direction were used to predict the excitatory receptive field of these interneurons.     

A DiI-tracing study of the neural connections of the pineal organ in two elasmobranchs (Scyliorhinus canicula and Raja montagui) suggests a pineal projection to the midbrain GnRH-immunoreactive nucleus

The pineal organ of elasmobranchs is an elongated photoreceptive organ. In order to investigate the afferent and efferent connections of the pineal organ of two elasmobranchs, the skate (Raja montagui) and the dogfish (Scyliorhinus canicula), a fluorescent carbocyanine (DiI) was applied to the pineal organ of paraformaldehyde-fixed brains. This application strongly labeled the pineal tract, which formed extensive bilateral projections. In both species, the pinealofugal fibers coursed to the dorsomedial thalamus, the medial pretectal area, the posterior tubercle, and the medial mesencephalic tegmentum and branched profusely in these areas. Application of DiI to the pineal organ also labeled occasional perikarya in the dorsomedial thalamus, posterior commissural region, posterior tubercle, and mesencephalic tegmentum. A comparison of these results with those of immunocytochemical analyses of the dogfish brain with an anti-salmon gonadotropin-releasing hormone (sGnRH) antiserum revealed a close topographical relation between the pineal projections and the midbrain sGnRH-immunoreactive (ir) nucleus, the only structure in the dogfish brain that contained sGnRHir neurons. This and the widespread distribution of sGnRHir fibers in the brain suggest that the midbrain sGnRHir nucleus is a part of the secondary pineal pathways and may be involved in light-mediated pineal regulation of brain function. Although GnRH distribution has not been studied in the skate, a midbrain GnRHir nucleus has been identified in three other elasmobranchs, including a skate relative. The probable existence of direct pineal projections to the GnRHir midbrain nucleus in elasmobranchs and other anamniotes is discussed.     

天冬酰胺内肽酶和胶质细胞在创伤性脑损伤中的激活

摘要 目的：创伤性脑损伤（traumatic brain injury, TBI）缺乏安全有效的治疗手段,亟须寻找新的干预靶点。天冬酰胺内肽酶 (asparaginyl endopeptidase, AEP)在免疫和神经系统疾病中起重要作用,本研究观察了小鼠TBI模型中AEP的激活和变化,探讨AEP对脑损伤和修复的意义。方法：控制性皮层撞击法在小鼠右脑半球制作TBI损伤,在造模后的不同时间点,测定受损脑组织内的乳酸含量和AEP的活性变化,免疫荧光化学染色观察TBI之后3天的胶质细胞活化,以及AEP在其中的表达。结果：TBI造成乳酸在受损脑组织内逐渐堆积,导致小胶质细胞和星形胶质细胞的反应性活化和增生,AEP的上调和激活出现在TBI的继发性脑损伤阶段,AEP在小胶质细胞和星形胶质细胞内均出现上调。结论：AEP有可能参与调控TBI引发的胶质细胞活化,在神经损伤和修复中发挥重要作用。     

Reversal potential for monosynaptic EPSP in frog motoneurons

Experiments were conducted on brain isolated from the frogRana ridibunda using a current chop technique of transmembrane polarization and discrete measurement of membrane potential by a single microelectrode during intervals between waves of current. It was found that the current-voltage relationship of the motorneuron is non-linear; i.e., membrane resistance decreases considerably in step with increased depolarizing current. After the initial reduction, membrane resistance began to climb back when a more protracted current lasting 1–2 min was applied; consequently membrane potential level shifted towards more positive values of +50 mV and above at current levels of 40–60 nA. It then became possible to bring about complete reversal of monosynaptic EPSP produced in the lumbar motoneurons by stimulation of the brainstem reticular formation or by microelectrode stimulation of the ventrolateral tract descending fibers and to measure reversal potential of these EPSP directly, without resorting to computing or extrapolation. Measurements varied mainly between 0 and –10 mV.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 18, No. 4, pp. 534–542, July–August, 1986.     

Plasma non-esterified fatty acids of elasmobranchs: comparisons of temperate and tropical species and effects of environmental salinity.

We investigated the influence of environments with different average temperatures and different salinities on plasma NEFA in elasmobranchs by comparing species from tropical vs. cold temperate marine waters, and tropical freshwater vs. tropical marine waters. The influence of the environment on plasma NEFA is significant, especially with regard to essential fatty acids (EFA) and the n-3/n-6 ratio. n-3/n-6 ratios in tropical marine elasmobranchs were lower by two-fold or more compared with temperate marine elasmobranchs, because of higher levels of arachidonic acid (AA, 20:4n-6) and docosatetraenoic acid (22:4n-6), and less docosahexaenoic acid (DHA, 22:6n-3), in the tropical species. These results are similar to those in earlier studies on lipids in teleosts. n-3/n-6 ratios and levels of EFA were similar between tropical freshwater and tropical marine elasmobranchs. This suggests that the observation in temperate waters that marine fishes have higher levels of n-3 fatty acids and n-3/n-6 ratios than freshwater fishes may not hold true in tropical waters, at least in elasmobranchs. It also suggests that plasma NEFA are little affected by freshwater vs. seawater adaptation in elasmobranchs. Likewise, we found that plasma NEFA composition and levels were not markedly affected by salinity acclimation (2 weeks) in the euryhaline stingray Himantura signifer. However, in contrast to our comparisons of freshwater-adapted vs. marine species, the level of n-3 fatty acids and the n-3/n-6 ratio were observed to significantly decrease, indicating a potential role of n-3 fatty acids in salinity acclimation in H. signifer.