Electrogenic Cl− absorption byAmphiuma small intestine: Dependence on serosal Na+ from tracer and Cl− microelectrode studies

Summary The Na⁺ requirement for active, electrogenic Cl^– absorption byAmphiuma small intestine was studied by tracer techniques and double-barreled Cl^–-sensitive microelectrodes. Addition of Cl^– to a Cl^–-free medium bathingin vitro intestinal segments produced a saturable (K _m =5.4mm) increase in shortcircuit current (I _sc) which was inhibitable by 1mm SITS. The selectivity sequence for the anion-evoked current was Cl^–=Br^–>SCN^–>NO ₃ ^– >F^–=I^–. Current evoked by Cl^– reached a maximum with increasing medium Na concentration (K _m =12.4mm). Addition of Na⁺, as Na gluconate (10mm), to mucosal and serosal Na⁺-free media stimulated the Cl^– current and simultaneously increased the absorptive Cl^– flux (J _ms ^Cl ) and net flux (J _net ^Cl ) without changing the secretory Cl^– flux (J _sm ^Cl ). Addition of Na⁺ only to the serosal fluid stimulatedJ _ms ^Cl much more than Na⁺ addition only to the mucosal fluid in paired tissues. Serosal DIDS (1mm) blocked the stimulation. Serosal 10mm Tris gluconate or choline gluconate failed to stimulateJ _ms ^Cl . Intracellular Cl^– activity (a _Cl ⁱ ) in villus epithelial cells was above electrochemical equilibrium indicating active Cl^– uptake. Ouabain (1mm) eliminated Cl^– accumulation and reduced the mucosal membrane potential _m over 2 to 3 hr. In contrast, SITS had no effect on Cl^– accumulation and hyperpolarized the mucosal membrane. Replacement of serosal Na⁺ with choline eliminated Cl^– accumulation while replacement of mucosal Na⁺ had no effect. In conclusion by two independent methods active electrogenic Cl^– absorption depends on serosal rather than mucosal Na⁺. It is concluded that Cl^– enters the cell via a primary (rheogenic) transport mechanism. At the serosal membrane the Na⁺ gradient most likely energizes H⁺ export and regulates mucosal Cl^– accumulation perhaps by influencing cell pH or HCO ₃ ^– concentration.     

Effects of caffeine and raynodine on low pHi-induced changes in gap junction conductance and calcium concentration in crayfish septate axons

Summary Electrical uncoupling of crayfish septate axons with acidification has been shown to cause a substantial increase in [Ca²⁺]_i which closely matches in percent the increase in junctional resistance. To determine the origin of [Ca²⁺]_i increase, septate axons have been exposed either to drugs that influence Ca²⁺ release from internal stores, caffeine and ryanodine, or to treatments that affect Ca²⁺ entry. A large increase in junctional resistance and [Ca²⁺]_i maxima above controls resulted from addition of caffeine (10–30mm) to acetate solutions, while a substantial decrease in both parameters was observed when exposure to acetate-caffeine was preceded by caffeine pretreatment. In contrast, ryanodine (1–10 m) always caused a significant decrease in junctional resistance and [Ca²⁺]_i maxima when applied either together with acetate or both before and with acetate. Calcium channel blockers such as La³⁺, Cd²⁺ and nisoldipine had no effect, while an increase in the [Ca²⁺] of acetate solutions either decreased junctional resistance and [Ca²⁺]_i maxima or had no effect. The data suggest that cytoplasmic acidification causes an increase in [Ca²⁺]_i by releasing Ca²⁺ from caffeine and ryanodine-sensitive Ca²⁺ stores. The increase in [Ca²⁺]_i results in a decrease in gap junction conductance.     

Rhizosphere pH along different root zones of Douglas-fir (Pseudotsuga menziesii), as affected by source of nitrogen

Douglas-fir, grown on strongly acid soil (pH-H₂O 3.87), was fertilized with ammonium, nitrate or ammonium nitrate as N-source. Rhizosphere pH along the root axis was measured with microelectrodes. Pure ammonium supply resulted in acidification of the rhizosphere, almost along the entire root axis; only the extreme root tip was slightly alkaline compared with the bulk soil. With nitrate supply, the alkalization of the rhizosphere at the root tip was considerably stronger than with ammonium supply and the length of the alkalization zone greater, extending over the entire growth zone of the root. Acidification of the rhizosphere along the older parts of the root was less pronounced in the case of nitrate. It is concluded that nitrate nutrition enables the plant to protect its most essential root zone from the adverse effects of strong acidity by locally raising the rhizosphere pH.     

Ion-selective Microelectrodes: Their Use and Importance in Modern Plant Cell Biology

The exact ion gradients across cellular membranes and their changes due to metabolic or transport processes can be best studied with the use of ion-selective microelectrodes. The last decade of research using ion-selective microelectrodes in intact cells has proven this technique to be indispensable for the investigation of a variety of physiological questions of regulatory processes, membrane transport, cellular signalling, developmental biology and plant nutrition. Their application to selected problems has led to numerous exciting observations, many of which have changed our view concerning cellular responses to environmental stimuli and in many instances have led to a new understanding of plant cell physiology. Since, with these electrodes, intracellular as well as extracellular free ion concentrations can be simultaneously detected with electrical transport parameters such as membrane potential and membrane conductance, they can be powerful tools in the hands of many plant cell biologists.     

BACTERIAL ASSOCIATIONS WITH MARINE OSCILLATORIA SP. (TRICHODESMIUM SP.) POPULATIONS: ECOPHYSIOLOGICAL IMPLICATIONS1

On three separate occasions we investigated morphological and physiological aspects of bacterial associations with planktonic aggregates of the ubiquitous marine N₂ fixing cyanobacterium Trichodesmium sp. Close associations generally characterized Trichodesmium blooms; associations were present during day- and night-time. Colonization by both rod-shaped and filamentous heterotrophic bacteria occurred on Trichodesmiun aggregates actively fixing N₂ (acetylene reduction). Scanning electron and optical microscopy showed bacteria located both around and within aggregates. Microautoradiography demonstrated that associated bacteria largely mediated utilization of trace additions of ³H-labeled carbohydrates (fructose, glucose, mannitol) and amino acids, whereas Trichodesmium utilized amino acids only. Oxygen measurements using microelectrodes revealed high localized oxygen consumption among aggregates, with rapid (within a minute) changes from supersaturated to subsaturated oxygen following the transition from photosynthetic illuminated to dark periods. Stab culturing techniques confirmed the presence of heterotrophic N₂ fixers among aggregate-associated bacteria. Parallel deployment of oxygen microelectrodes, the tetrazolium salt 2,3,5 triphenyl tetrazolium chloride (TTC) and acetylene reduction assays demonstrated microaerophilic requirements for expression of nitrogenase activity among cultured bacteria. Trichodesmium aggregates are characterized by dynamic nutrient and oxygen regimes, which promote and maintain simultaneous and contiguous oxygenic photosynthesis and N₂ fixation. In part, the above-mentioned consortial interactions with a variety of heterotrophic bacteria facilitate Trichodesmium biomass production and bloom formation in nitrogen depleted, oligotrophic tropical/subtropical waters.     

Oscillations of apoplasmic K+ and H+ activities in Desmodium motorium (Houtt.) Merril. pulvini in relation to the membrane potential of motor cells and leaflet movements

The lateral leaflets of Desmodium motorium exhibit rhythmic upward and downward movements with a period in the minute range. Apoplasmic K⁺ and H⁺ activities were monitored in situ in the abaxial part of the pulvini with ion-selective microelectrodes. An extracellular electric potential was recorded simultaneously. The apoplasmic H⁺ activity of all pulvini exhibiting a regular rhythm of the extracellular electric potential oscillated with the same period between about 10 and 20 mM. The apoplasmic K⁺ activity was high when the membrane potential of the motor cells was depolarized (about 36 mV) and the cells were shrunken. In contrast, the apoplasmic K⁺ activity was low in the swollen state of the motor cells, when the membrane potential was hyperpolarized (about -136 mV). The volatile anesthetic enflurane suppressed reversibly the movement of the leaflets. The same treatment also arrested spontaneous oscillations in the apoplasmic K⁺ activity in the pulvinus. The apoplasmic K⁺ activity oscillated roughly in phase with the K⁺ activity between pH 6.6 and 6.0. Application of white light disturbed the rhythm and increased the extracellular pH. Our results indicate that the physiological mechanism that drives the lateral leaflet movements of Desmodium motorium is closely related to the osmotic motors mediating the leaf movements of Mimosa, Samanea and Phaseolus.Abbreviations E_m membrane potential - E_ex extracellular electric potential - H_ex extracellular H⁺ activity - K_ex extracellular K⁺ activity - R_ex extracellular electrical resistance B. Antkowiak was supported by the Stiftung Volkswagenwerk.     

Comparison of a lipophilic cation and microelectrodes to measure membrane potentials of the giant-celled algae,Chara australis (Charophyta) andGriffithsia monilis (Rhodophyta)

Summary The vacuolar equilibrium potential of the lipophilic cation TPMP⁺ (triphenyl methyl phosphonium) in the giant algaeChara australis andGriffithsia monilis was directly measured. The TPMP⁺ equilibrium potential was approximately 100mV less negative than the measured vacuolar electrical potential. Thus TPMP⁺ does not act as a probe of the vacuolar electrical potential and appears to be extruded against an electrochemical gradient. Measurement of the plasmalemma equilibrium potential of TPMP⁺ showed that extrusion of TPMP⁺ apparently occurred at both the tonoplast and plasmalemma inChara and at the plasmalemma inGriffithsia. It is concluded that TPMP⁺ cannot be used as a membrane potential probe inChara orGriffithsia.     

Electrical properties of the rabbit urinary bladder assessed using gramicidin D

Summary Recently, antibiotics have enjoyed widespread usage as tools in studies of epithelial transport. In the present study we assess the usefulness of the pore-forming antibiotic gramicidin D as a means for probing the electrical properties of the tight epithelium rabbit urinary bladder. Addition of 50 M gramicidin to the mucosal bath (either a NaCl or KCl Ringer's solution) led to a large irreversible increase in the transepithelial conductance (G _T ) within 800 sec.G _T increased by approximately 1200% and 500% in KCl and NaCl Ringer's solutions, respectively. Microelectrode measurements of the resistance ration (the ration of apical membrane resitance to basolateral membrane resistance) showed that apical membrane resistance is dereased by the drug. Measurements of the basolateral membrane resistance (R _bl ) and tight junctional resistance (R _j ) using a new and independent method (based on the perturbation of basolateral membrane electrogenic Na⁺ pump) demonstrated thatR _bl andR _j were unaffected, suggesting that the effects of gramicidin are restricted to the apical membrane for periods of at least 2 hours after drug addition. The selectivity of the gramicidin-induced permeability in the apical membrane was calculated from measurements of the apical membrane potential after ion substitutions using a modified version of the constant field equation. The selectivity sequence for cations was Cs⁺>K⁺>Na⁺>Li⁺>choline. Unlike the commonly used polyene antibiotics nystatin and amphotericin B, gramicidin did not induce a significant Cl^– permeability. In addition, the dose-response curve had a slope of 1. A method is described for calculating membrane resistances directly from transepithelial measurements under some conditions of gramicidin use, without requiring the use of microlectrode measurements.     

Cyclic AMP and intracellular ionic activities innecturus gallbladder

Summary Open-tip and liquid ion-exchanger microelectrodes were used to study the effects of cAMP (6mm, added to the serosal medium) on apical membrane potential (E _m ) and intracellular sodium, potassium, and chloride activities (a _Na ⁱ ,a _K ⁱ ,a _Cl ⁱ ) inNecturus gallbladder under open-circuit conditions. Transepithelial potential difference (E _Tr ) was also measured. In the presence of cAMP,a _Cl ⁱ fell from about 1.5 times its equilibrium value to a level that corresponded to electrochemical equilibrium across the apical and basolateral cell membranes. Under these conditionsa _Na ⁱ decreased anda _K ⁱ increased,E _m was unchanged andE _Tr increased from virtually zero to a small but significant serosal positive value. The cAMP-induced increase ina _K ⁱ was abolished when Cl^–-free incubation media were used. Addition of the Ca⁺⁺-ionophore A23187 (0.5 g/ml) to the serosal medium had no effect onE _m ,E _Tr , ora _Cl ⁱ . When A23187 was added to the mucosal medium,E _m and the basolateral membrane potential hyperpolarized by about 20 mV and an increase in the outwardly directed electrochemical driving force for Cl^– was observed. These results indicate that cAMP inhibits coupled transapical Na–Cl entry into epithelial cells ofNecturus gallbladder and suggest that this inhibition may not be mediated by an increase in intracellular Ca⁺⁺ concentration.     

Intracellular ionic activities in frog skin

Summary Asymmetrical displacement currents are measured in the absence and in the presence of the lipophilic anion dipicrylamine (DPA) in the extracellular solution of nerve fibres of the frogRana esculenta. DPA (30nM-3 M) enhances the current by a component that has the properties expected for a translocation current of DPA ion across the lipid membrane. Analysis in terms of a single-barrier model yields the translocation rate constant (k), the total surface density of DPA absorbed to the membrane (N _t ), and the equidistribution voltage (). The value ofk of about 10⁴ s^–1 is similar to that for a solvent-free artificial bilayer formed by the Montal-Mueller method. The surface densityN _t varies with the DPA concentration as it does in the artificial bilayer, but is about tenfold smaller at all concentrations. The DPA ions sense an intrinsic electric field that is offset by a transmembrane voltage between 0 and 30 mV (inside positive). The part of the axolemma probed by the DPA ion appears as a thin (<2.5 nm), fluid bilayer of lipids. DPA ions seem, however, to be excluded from the major part of the axolemma as if this area is occupied by integral proteins or negative charges.