Chloride ion efflux during an action potential in the main pulvinus ofMimosa pudica

The shortening, action potential and Cl⁻-efflux of the excised lower half cortex in the main pulvinus ofMimosa pudica were simultaneously recorded. The mean values±(S.E.) for Cl⁻-efflux and shortening were 183±18 picomoles/mg fresh weight/impulse and 87.0±2.2 μm, respectively.     

Persistence of the electrophysiologic effects of mexiletine in canine Purkinje fibers alters the response to subsequent hypoxia

The persistence of cellular electropharmacologic effects of mexiletine on canine Purkinje fibers was studied utilizing standard microelectrode techniques and two different protocols. In the first, the tissue was exposed to hypoxic perfusion before and 30 min after perfusion with one of the following: mexiletine hydrochloride 6.25 microM solution, mexiletine hydrochloride 12.5 microM solution, or drug-free Tyrode's solution. With the higher concentration of mexiletine, depression of the maximal upstroke velocity (Vmax) persisted 30 min after drug washout and subsequent exposure to hypoxia did not result in the anticipated shortening of action potential duration but did prevent the restoration of normal Vmax. After perfusion with the lower concentration of mexiletine, Vmax was not depressed and hypoxic action potential duration shortening was not prevented. In the second protocol, Purkinje fibers were perfused with 12.5 microM mexiletine hydrochloride solution and then exposed to hypoxia after 15, 30, 45, or 60 min of perfusion with drug-free solution. Depression of maximal upstroke velocity and shortening of action potential duration persisted during washout, returning to control values by 45 min, although mexiletine was not detectable in the tissue bath after 10 min of washout. Hypoxia initiated at 15 or 30 min of washout failed to produce the anticipated shortening of action potential duration. At 45 and 60 min, action potential duration was shortened by hypoxia. We concluded that mexiletine depression of Vmax and shortening of action potential duration may persist in the absence of drug. Further shortening of action potential duration in response to hypoxia is prevented during this period. The persistence of Vmax depression is prolonged by hypoxia.     

Effects of osmotic concentrations and IAA on the rapid shortening of the cortex in the main pulvinus ofMinosa pudica

In 0.8 M mannitol solution, no rapid shortening was recorded, while normal action potential was recorded. This result suggests that motive force of rapid shortening is an elastic stretch of the cell wall caused by the turgor pressure, and that osmotic concentration of motor cell is 0.6–0.7 M. IAA increased the rapid shortening, recovery rate and Cl⁻-efflux. The magnitudes of rapid shortening in IAA were 3–10 times as large as those in APW. The mean and maximum values of the rapid shortening in IAA were 87.0±2.2μm and 207 μm, respectively, or 1.6 and 3.9% of the whole length of motor tissue. When the large rapid shortening occurred, the large recovery rate was observed. These results suggest that both mechanisms, expulsion and re-entry of cell sap, are enhanced by IAA treatment. IAA-induced hyperpolarization was observed with a short time lag, which suggests that IAA enhances the electrogenic ion pump.     

紫菀根的结构与主要药用成分积累研究

为揭示紫菀根的结构、主要药用成分积累部位和含量,用石蜡切片法研究不同发育阶段根的结构、组织化学法定位三萜皂苷和黄酮类成分的积累部位、HPLC法测定根中紫菀酮、槲皮素和山奈酚的含量。结果表明,紫菀根的初生结构包括表皮、皮层和维管柱。次生结构包括外皮层、皮层和维管组织,其中分泌道位于皮层内侧,数量与韧皮部束一致,随着根的增粗,中央分化出髓部。三萜皂苷成分在韧皮部和皮层内侧积累较多;黄酮类成分积累于皮层和髓部。紫菀根下部的紫菀酮含量高于上部,槲皮素和山萘酚仅为上部的1/3。因此,建议加工时保留下部细根,实现资源综合利用。     

The role of the epidermis and cortex in gravitropic curvature of maize roots

In order to determine the role of the epidermis and cortex in gravitropic curvature of seedling roots of maize (Zea mays L. cv. Merit), the cortex on the two opposite flanks was removed from the meristem through the growing zone; gravitropic curvature was measured with the roots oriented horizontally with the cut flanks either on the upper and lower side, or on the lateral sides as a wound control. Curvature was slower in both these treatments (53° in 5 h) than in intact roots (82°), but there was no difference between the two orientations in extent and rate of curvature, nor in the latent time, showing that epidermis and cortex were not the site of action of the growth-regulating signal. The amount of cortex removed made no difference in the extent of curvature. Curvature was eliminated when the endodermis was damaged, raising the possibility that the endodermis or the stele-cortex interface controls gravitropic curvature in roots. The elongation rate of roots from which just the epidermis had been peeled was reduced by 0.01 mM auxin (indole-3-acetic acid) from 0.42 to 0.27 mm h^-1, contradicting the hypothesis that only the epidermis responds to changes in auxin activity during gravistimulation. These observations indicate that gravitropic curvature in maize roots is not driven by differential cortical cell enlargement, and that movement of growth regulator(s) from the tip to the elongating zone is unlikely to occur in the cortex.Abbreviations df degrees of freedom - IAA indole-3-acetic acid     

Distribution Patterns of Strongylocentrotus Sea Urchins along the Coast of Eastern Kamchatka

The distribution patterns of three sea urchin species of the genus Strongylocentrotus in relation to depth, type of substrate, surf action, and to some hydrological parameters were studied along the coast of eastern Kamchatka and in adjacent waters in 1984–1996. The sea urchin Strongylocentrotus polyacanthus dominated the open coast on rocky subintertidal sites with increased surf action and standard oceanic salinity. S. droebachiensis prevailed in shoals with lower salinity, higher water temperature and lower turbulence (enclosed and semienclosed bays). S. pallidus dominated at depths corresponding to the position of the cold intermediate layer deeper than 30–50 m with normal oceanic salinity and lower temperature.     

The structural elements responsible for contraction in the ciliateSpirostomum

Summary The surface of the contractile ciliateSpirostomum contains continuous spiral ciliated grooves traversing its length. Bundles of microtubules run parallel to the base of the grooves and appear to be part of a cohesive, semi-rigid cortex. Beneath this, a network of microfilament bundles occurs which is attached to the peristomal membranelle apparatus, also part of the cortex. The possible roles played by these structures during contraction of the organism were examined.During contraction, the entire cortex twists and the spiral arrangement of the grooves and microtubules decreases in pitch and increases in diameter. Simultaneously, the bundles of microfilaments change in distribution and appearance so as to suggest that they are undergoing an active shortening process. Based on these observations, two models for contraction are presented. In one, shortening of the animal arises from a smooth muscle-like contraction of the microfilament network whose attachment to the basal bodies of the membranellar cilia guarantees shortening and widening of the cortex and consequently the whole animal. In the second, a shortening (or sliding) of external microtubules relative to internal ones in the cortical microtubule bundles would result in an increase in diameter, a decrease in pitch, and a decrease in axial length of the bundles, resulting in contraction of the animal. The observations do not allow a choice between these alternatives to be made, and they may not, in fact, be mutually exclusive.     

Effect of static magnetic fields on bioelectric properties of the Br and N1 neurons of snail Helix pomatia

The effects of 2.7 mT and 10 mT static magnetic fields were investigated on two identified neurons with different bioelectric properties of the snail Helix pomatia. Membrane resting potential, amplitude, spiking frequency, and duration of action potential were measured. The two neurons of H. pomatia, parabolic burster Br and silent N₁, showed different responses to a static magnetic field. The magnetic field of 2.7 mT intensity caused changes in the amplitude and duration of action potential of the Br neuron, whereas the 10 mT magnetic field changed the resting potential, amplitude spike, firing frequency, and duration of action potential of the Br neuron. Bioelectric parameters measured on the N₁ neuron did not change significantly in these magnetic fields.     

Partial contribution of the ATP-sensitive K+ current to the effects of mild metabolic depression in rabbit myocardium

The object of the study was to compare the capability of glibenclamide to block the effects of K⁺-ATP channel activators on action potential duration and steady state whole cell current to its efficiency in counteracting the effects of hypoxia or metabolic poisons in the presence of glycolytic substrate. The modulation of action potential duration by 30 M glibenclamide was tested in perfused hearts subjected to hypoxia or to the K⁺-ATP channel opener pinacidil. Similar protocols were used to study the modifications of the steady state whole cell current in isolated ventricular myocytes. It was found that glibenclamide did not prevent early action potential shortening induced by hypoxia but produced a partial recovery after 15 min of exposure. At the steady state the action potential duration had lengthened by 53±6% at plateau level and 42±3% at 95% repolarization. In contrast, action potential shortening induced by 100 M pinacidil was fully reversed by glibenclamide within 2 min. Freshly dispersed ventricular myocytes were characterized in control conditions as for the properties of the steady state current. This current, measured at the end of 450 ms long pulses showed typical inward rectification that was abolished by 50 M Ba²⁺. Cyanide (2 mM), carbonyl-cyanide m-chlorophenylhydrazone (CCCP, 200 nM) and BRL 38227 (30 M) produced characteristic increases in time independent outward currents. Glibenclamide abolished the outward current induced by BRL 38227 and the concomitant action potential shortening. Addition of cyanide in the presence of glibenclamide and BRL 38227 produced a new increase in outward current accompanied by action potential shortening. In the absence of K⁺-ATP channel activators, glibenclamide partly inhibited the CCCP induced current. Our data suggested that the delayed onset of glibenclamide action in hypoxic hearts is not due to diffusion barriers. They rather support the view that mechanisms other than K⁺-ATP channel activation could determine the early action potential shortening in whole hearts. The partial recovery observed under glibenclamide may be due, in part, to channel desensitization but also reflect the contribution of more than one current system to the action potential shortening because the glibenclamide insensitive fraction of the CCCP induced current is partly blocked by low concentrations of Ba²⁺. Differences with other data in the literature are attributed to the degree to metabolic blockade, to species differences, and to the inherent heterogeneities of the whole heart model where non-muscle cells may modulate the response to hypoxia.     

Gravitropism of the primary root of maize: a complex pattern of differential cellular growth in the cortex independent of the microtubular cytoskeleton

The spatio-temporal sequence of cellular growth within the post-mitotic inner and outer cortical tissue of the apex of the primary root of maize (Zea mays L.) was investigated during its orthogravitropic response. In the early phase (0–30 min) of the graviresponse there was a strong inhibition of cell lengthening in the outer cortex at the lower side of the root, whereas lengthening was only slightly impaired in the outer cortex at the upper side. Initially, inhibition of differential cell lengthening was less pronounced in the inner cortex indicating that tissue tensions which, in these circumstances, inevitably develop at the outer-inner cortex interface, might help to drive the onset of the root bending. At later stages of the graviresponse (60 min), when a root curvature had already developed, cells of the inner cortex then exhibited a prominent cell length differential between upper and lower sides, whereas the outer cortex cells had re-established similar lengths. Again, tissue tensions associated with the different patterns of cellular behaviour in the inner and outer cortex tissues, could be of relevance in terminating the root bending. The perception of gravity and the complex tissue-specific growth responses both proceeded normally in roots which were rendered devoid of microtubules by colchicine and oryzalin treatments. The lack of involvement of microtubules in the graviresponse was supported by several other lines of evidence. For instance, although taxol stabilized the cortical microtubules and prevented their re-orientation in post-mitotic cortical cells located at the lower side of gravistimulated roots, root bending developed normally. In contrast, when gravistimulated roots were physically prevented from bending, re-oriented arrays of cortical microtubules were seen in all post-mitotic cortical cells, irrespective of their position within the root.Abbreviations CMTs cortical microtubules - CW Cholodny-Went - FF form factor - MT microtubule The research was supported by a fellowship from the Alexander von Humboldt Stiftung (Bonn, Germany) to F.B. Financial support to AGRAVIS by Deutsche Agentur für Raumfahrtangelegenheiten (DARA, Bonn) and Ministerium für Wissenschaft und Forschung (Düsseldorf) is gratefully acknowledged. IACR receives grant-aided support from the Biotechnology and Biological Sciences Research Council of the United Kingdom.     

Morphological and electrophysiological aspects of dorsal median paired neurons generating plateau action potentials in the terminal abdominal ganglion of the insect central nervous system

Among the three clusters of dorsal unpaired median neurons of the Periplaneta americana terminal abdominal ganglion, another type of neuron has been characterized by anterograde cobalt stainings and microelectrode technique. These neurons are bilaterally distributed in the ganglion. Their axons ipsilaterally exit the ganglion via the anterior proctodeal nerves, to innervate the proctodeum. They are characterized by a long-duration overshooting action potentials and a low firing frequency. Most often the depolarizing phase is composed of two peaks: a fast spike followed by a slow phase. Tetrodotoxin suppressed the fast peak and blocked the spontaneous activity suggesting that sodium channels are involved in the depolarizing phase as well as in the initiation of the action potential. Calcium channel blockers induced a disappearing of the slow depolarizing phase indicating the participation of calcium ions and a reduction of the afterhyperpolarization reflecting the participation of calcium-activated potassium channels. Furthermore, cadmium, as lanthanum or barium, induced a long-lasting plateau potential, which would be due to a persistent sodium conductance. Tetraethylammonium increased the duration of the action potential indicating that potassium channels are implicated in the falling phase. The results demonstrate that these neurons are different from other cells, especially dorsal unpaired median neurons, of the central nervous system of the cockroach.Abbreviations DUM dorsal unpaired median - SDP slow depolarizing phase - AP action potential - PAP plateau action potential - TAG terminal abdominal ganglion - CNS central nervous system     

The mechanism of the rate-dependent changes of the conducted action potential in rabbit ventricle

Blockers of the transient outward current (4-aminopyridine) and the Ca current (Co2+) as well as injection of polarizing current during the plateau were used to assess the role of these current systems as determinants of action potential duration at different pacing rates. Papillary muscles and ventricular trabecula were superfused with oxygenated Krebs solution at 33 degrees C and driven at a basic rate of 1 Hz. The effects of varying the frequency of stimulation between 0.1 and 4 Hz on action potential parameters were determined under control conditions and during exposure to 2 mM 4-aminopyridine, 1-3 mM CoCl2, or a mixture of 4-aminopyridine and CoCl2. The control relationship between action potential duration and pacing rate showed a maximum between 1 and 2 Hz. Under 4-aminopyridine, the plateau height and the action potential duration increased. The rate-dependent shortening of the action potential at frequencies below 1 Hz was reduced or abolished, and enhanced shortening was observed at rates above 1 Hz. Exposure to Co2+ reduced the action potential shortening at rates higher than 1 Hz. Both blockers, 4-aminopyridine and Co2+ were necessary to eliminate the rate-dependent changes of the action potential duration. Our results indicated that both the transient outward current and the inward calcium current determine the plateau height and duration for frequencies less than or equal to 2 Hz, whereas at higher rates, the Ca current plays a dominant role.     

Effect of wheat resistance, the parasitoid Aphidius rhopalosiphi, and the entomopathogenic fungus Pandora neoaphidis, on population dynamics of the cereal aphid Sitobion avenae

The influence of wheat (Triticum aestivumL.) resistance, the parasitoid Aphidius rhopalosiphiDe Stephani-Perez (Hymenoptera: Braconidae) and the entomopathogenic fungus Pandora neoaphidis(Remaudière et Hennebert) Humber (Zygomycetes: Entomophthorales) on the density and population growth rate of the cereal aphid Sitobion avenae(F.) (Hemiptera: Aphididae) was studied under laboratory conditions. Partial wheat resistance was based on hydroxamic acids, a family of secondary metabolites characteristic of several cultivated cereals. The partial resistance of wheat cultivar Naofén, the action of the parasitoid and the joint action of the parasitoid and fungus, reduced aphid density. The lowest aphid densities were obtained with the combination of the parasitoid and the fungus, but wheat resistance under these circumstances did not improve aphid control. Significant reductions of population growth rate (PGR) of aphids were obtained with the joint action of wheat resistance and natural enemies. In particular, the combined effects of parasitoids and fungi showed significantly lower PGR than the control without natural enemies in both wheat cultivars. Our results support the hypothesis that wheat resistance and the utilization of biological control agents could be complementary strategies in an integrated pest management program against cereal aphids.     

喀斯特地区莎叶兰的解剖构造及其环境适应性

以广西西北部雅长兰科植物保护区的莎叶兰( Cymbidium cyperifolium)为对象,采用石蜡切片法对莎叶兰叶片和根的解剖构造及其对喀斯特环境的适应性进行了研究。结果表明：(1)莎叶兰叶片的上表皮覆盖有较厚的角质层,气孔均分布于下表皮,且凸出表皮细胞之上;各表皮性状在叶片不同部位存在显著差异,叶片下部的气孔密度、气孔指数和气孔长度最大,表皮细胞密度以叶片上部的最大;叶片属于等面叶,叶肉无栅栏组织和海绵组织的分化;叶脉为明显的平行脉,且粗细交互分布;(2)莎叶兰根的横切面包括根被、皮层、中柱3部分,其中根被细胞排列紧密,为生活细胞;皮层由薄壁细胞组成;根部维管束属于辐射维管束,14原型。菌根粗壮,稀根毛,共生真菌主要分布于根被及皮层中,菌丝体通过根被薄壁细胞间隙及内、外皮层的通道细胞进行侵染。(3)莎叶兰叶片和根的结构不仅有湿生植物特征,如叶片相对较薄、气孔少且凸出表皮细胞、冠/根比值大等;还有旱生植物的特征,如叶片角质层较厚、机械组织发达、细胞结构紧密、具含晶细胞,肉质根具根被,内、外皮层细胞壁明显增厚等。这些结构是莎叶兰对当地缺水、干湿季明显、分布于林下多石砾土壤的生长环境的一种高度适应性表现。     

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.     

Membrane potential responses controlling chemodispersal of Paramecium caudatum from quinine

Membrane potential responses of a ciliate protozoan Paramecium caudatum to the external application of quinine were investigated in relation to its motile activities. Wild-type specimens swimming in the reference solution did not enter into a quinine-containing (0.5 mM) test solution due to avoiding responses exhibited at the border between the two solutions, and therefore stayed in the reference solution (chemodispersal). Squirting of a quinine-containing test solution over a wild-type specimen evoked a train of action potentials superimposed on a depolarizing chemoreceptor potential. Squirting of a quinine-containing test solution over a CNR-mutant specimen defective in voltage-gated Ca²⁺ channel evoked only chemoreceptor potentials, which consisted of an initial transient depolarization, a following transient hyperpolarization and a sustained depolarization. A current-evoked action potential became larger in its amplitude and longer in its duration with the external application of quinine. Under the voltage-clamp condition, the fast inward current did not change whereas the delayed outward current decreased with the external application of quinine. It is concluded that quinine is a potent repellent for Paramecium because it produces a depolarizing chemoreceptor potential which evokes action potentials and prolongs the duration of the action potential.     

Reduction in number of sarcolemmal KATP channels slows cardiac action potential duration shortening under hypoxia

The cardiovascular system operates under demands ranging from conditions of rest to extreme stress. One mechanism of cardiac stress tolerance is action potential duration shortening driven by ATP-sensitive potassium (K_ATP) channels. K_ATP channel expression has a significant physiologic impact on action potential duration shortening and myocardial energy consumption in response to physiologic heart rate acceleration. However, the effect of reduced channel expression on action potential duration shortening in response to severe metabolic stress is yet to be established. Here, transgenic mice with myocardium-specific expression of a dominant negative K_ATP channel subunit were compared with littermate controls. Evaluation of K_ATP channel whole cell current and channel number/patch was assessed by patch clamp in isolated ventricular cardiomyocytes. Monophasic action potentials were monitored in retrogradely perfused, isolated hearts during the transition to hypoxic perfusate. An 80–85% reduction in cardiac K_ATP channel current density results in a similar magnitude, but significantly slower rate, of shortening of the ventricular action potential duration in response to severe hypoxia, despite no significant difference in coronary flow. Therefore, the number of functional cardiac sarcolemmal K_ATP channels is a critical determinant of the rate of adaptation of myocardial membrane excitability, with implications for optimization of cardiac energy consumption and consequent cardioprotection under conditions of severe metabolic stress.     

Cessation of cytoplasmic streaming follows an increase of cytoplasmic Ca2+ during action potential inNitella

Summary Taking advantage of prolonged action potential under low temperature, we studied temporal relationship among the action potential, increase of cytoplasmic Ca²⁺ concentration and cessation of cytoplasmic streaming inNitella. The Ca²⁺ concentration began to increase at a very early stage of the action potential and the cessation of streaming followed that increase.Abbreviations APW artificial pond water     

Action potential and rapid movement in the main pulvinus ofMimosa pudica

Relationships between action potential and rapid bending movement in the main pulvinus ofMimosa pudica L. were studied. The pulvinar action potential consisted of a fast-rising spike of 40 to 70 mV and a long-lasting plateau. It had a nature of propagating in both basipetal and acropetal directions at the rate of about 4 cm/sec. The rapid bending movement occurred 10 to 20 msec after the pulvinar action potential. The action potential and movement were both found only in the lower half of the main pulvinus, no response being observed in the upper half. The results suggested that the excitable cells which elicit the action potential as well as the rapid contraction exist only in the lower half of the pulvinus. Some possible mechanisms concerning the coupling between the electrical excitation and the contraction are discussed. This work was supported by the Grant in Aid for Scientific Research of the Ministry of Education.     

Molecular mass control using polyanionic cyclodextrin derivatives for the epsilon-poly-l-lysine biosynthesis by Streptomyces

To control the molecular mass of a natural polycationic, antimicrobial, Streptomyces-biosynthesized polymer, epsilon-poly-l-lysine, addition of polyanionic cyclodextrin derivatives to the culture medium was evaluated. Chemically modified cyclodextrins such as a sulfated cyclodextrin caused a notable shortening of the polymer length of epsilon-poly-l-lysine from 3.5 to 4.5 kDa to less than 2.5 kDa by the enforcing action of glycerol, which has a weak potential to inhibit polymer elongation by terminal esterification. Meanwhile, polyanionic cyclodextrin inhibited the shortening action with n-octanol, which has a strong ability to inhibit polymer elongation through an undetermined function. The design of chemical structures of polyanionic cyclodextrin, optimization of their addition concentrations, and selection of hydroxyl compounds coexisting with them are critical for this simple and easy method for polymer length control and terminal modification of epsilon-poly-l-lysine.