Effects of pH conditions on Ca2+ transport catalyzed by ionophores A23187, 4-BrA23187, and ionomycin suggest problems with common applications of these compounds in biological systems.

Phospholipid vesicles loaded with Quin-2 and 2'',7''-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF) have been used to investigate the effects of pH conditions on Ca2+ transport catalyzed by ionophores A23187, 4-BrA23187, and ionomycin. At an external pH of 7.0, a delta pH (inside basic) of 0.4-0.6 U decreases the rate of Ca2+ transport into the vesicles by severalfold under some conditions. The apparent extent of transport is also decreased. In contrast, raising the pH by 0.4-0.6 U in the absence of a delta pH increases both of these parameters, although by smaller factors. The relatively large effects of a delta pH on the transport properties of Ca2+ ionophores seem to reflect a partial equilibration of the transmembrane ionophore distribution with the H+ concentration gradient across the vesicle membrane. This unequal distribution of ionophore can cause a very slow or incomplete ionophore-dependent equilibration of delta pCa with delta pH. A second factor of less certain origin retards full equilibration of delta pCa when delta pH = 0. These findings call into question several ionophore-based methods that are used to investigate the regulatory activities of Ca2+ and other divalent cations in biological systems. Notable among these are the null-point titration method for determining the concentration of free cations within cells and the use of ionophores plus external cation buffers to calibrate intracellular cation indicators. The present findings also indicate that the transport mode of Ca2+ ionophores is more strictly electroneutral than was thought, based upon previous studies.     

Beta-myosin heavy chain myocytes are more resistant to changes in power output induced by ischemic conditions

During ischemia intracellular concentrations of P(i) and H+ increase. Also, changes in myosin heavy chain (MHC) isoform toward beta-MHC have been reported after ischemia and infarction associated with coronary artery disease. The purpose of this study was to investigate the effects of myoplasmic changes of P(i) and H+ on the loaded shortening velocity and power output of cardiac myocytes expressing either alpha- or beta-MHC. Skinned cardiac myocyte preparations were obtained from adult male Sprague-Dawley rats (control or treated with 5-n-propyl-2-thiouracil to induce beta-MHC) and mounted between a force transducer and servomotor system. Myocyte preparations were subjected to a series of isotonic force clamps to determine shortening velocity and power output during Ca2+ activations in each of the following solutions: 1) pCa 4.5 and pH 7.0; 2) pCa 4.5, pH 7.0, and 5 mM P(i); 3) pCa 4.5 and pH 6.6; and 4) pCa 4.5, pH 6.6, and 5 mM P(i). Added P(i) and lowered pH each caused isometric force to decline to the same extent in alpha-MHC and beta-MHC myocytes; however, beta-MHC myocytes were more resistant to changes in absolute power output. For example, peak absolute power output fell 53% in alpha-MHC myocytes, whereas power fell only 38% in beta-MHC myocytes in response to elevated P(i) and lowered pH (i.e., solution 4). The reduced effect on power output was the result of a greater increase in loaded shortening velocity induced by P(i) in beta-MHC myocytes and an increase in loaded shortening velocity at pH 6.6 that occurred only in beta-MHC myocytes. We conclude that the functional response to elevated P(i) and lowered pH during ischemia is MHC isoform-dependent with beta-MHC myocytes being more resistant to declines in power output.     

Calcium-induced calcium release mechanism in guinea pig taenia caeci

Fura-2 was used to measure the amount of Ca released from the intracellular Ca store of a saponin-skinned smooth muscle fiber bundle of the guinea pig taenia caeci (width, 150-250 microns) placed in a capillary cuvette at 20-22 degrees C. The amount of Ca actively loaded into the store was assayed when released by the application of 50 mM caffeine and/or 10 microM inositol 1,4,5-trisphosphate (IP3) in the absence of ATP, and was found to have a biphasic dependence on the loading [Ca2+] with a peak near pCa 6. After Ca loading at pCa 6, IP3 released almost all the releasable Ca, whereas caffeine discharged Ca from only approximately 40% of the store. The maximum amount of Ca in the store was some 220 mumol/liter cell water. Ca in the caffeine-releasable store was released approximately exponentially to zero with time when Ca2+ was applied in the absence of ATP, and the rate constant of the Ca-induced Ca release (CICR) increased steeply with the concentration of Ca2+ applied. Increase in [Mg2+] (0.5-5.0 mM) or decrease in pH (7.3-6.7) shifted the relation between pCa and the rate of CICR roughly in parallel toward the lower pCa. An adenine nucleotide increased the rate of the CICR, but it did not change the range of effective [Ca2+]. 5 mM caffeine greatly enhanced the CICR mechanism, making it approximately 30 times more sensitive to [Ca2+]. However the drug had no Ca-releasing action in the absence of Ca2+. Procaine in millimolar concentrations inhibited the rate of the CICR. These properties are similar to those of the skeletal muscle CICR and ryanodine receptor channels. Rates of the CICR under a physiological ionic milieu were estimated from the results, and a [Ca2+] greater than 1 microM was expected to be necessary for the activation of the Ca release. This Ca sensitivity seems too low for the CICR mechanism to play a primary physiological role in Ca mobilization, unless assisted by other mechanisms.     

Determination of ionic calcium in frog skeletal muscle fibers

Ionic calcium concentrations were measured in frog skeletal muscle fibers using Ca-selective microelectrodes. In fibers with resting membrane potentials more negative than -85 mV, the mean pCa value was 6.94 (0.12 microM). In fibers depolarized to -73 mV with 10-mM K the mean pCa was 6.43 (0.37 microM). This increase in the intracellular [Ca2+] could be related to the higher oxygen consumption and heat production (Solandt effect) reported to occur under these conditions. Caffeine, 3 mM, also produced an increase in the free ionic calcium to a pCa of 6.52 (0.31 microM) without changes in the membrane potential. Lower caffeine concentrations, 1 and 2 mM, did not change the fiber pCa. Lower Ca concentrations in the external medium effectively reduced the internal ionic calcium to an estimated pCa of 7.43 (0.03 microM).     

Calcium mediates the light-induced decrease in maintained K+ current in Limulus ventral photoreceptors

In addition to increasing the conductance to sodium, light reduces the maintained voltage-dependent potassium current (iK) in Limulus ventral photoreceptors. We have investigated the mechanism underlying this long-lasting decrease in ik. Intracellular injection of calcium produced a similar reduction of the voltage-dependent outward current. This reduction was not due to an activation of the voltage-dependent inward current (iin) because calcium injection reduced the outward current even under conditions where iin was blocked with Ni2+, and because calcium injection produced a decrease in conductance, as measured from the slope of the instantaneous i-V curve. The effect of light on ik could be blocked by injection of the calcium buffer EGTA (pCa 7.1) to an intracellular concentration of 50-70 mM. Even larger injections of the pH buffer MOPS (100-200 mM) did not reduce the effect of light on ik. These experiments show that intracellular free calcium (Cai2+) can reduce ik. Furthermore, since Cai2+ is known to increase in light, our results are consistent with the hypothesis that calcium is the internal transmitter for the light-induced decrease in ik.     

Interactive signal transfer between host and pathogen during successful infection of barley leaves by Blumeria graminis and Bipolaris sorokiniana

Using ion-selective microprobes, interactive signalling between barley and Blumeria graminis or Bipolaris sorokiniana has been investigated. The question was raised whether a biotrophically growing fungus manipulates the electrical driving forces (membrane potential, transmembrane pH), required for H+ cotransport of energy-rich compounds. Electrodes were positioned in the substomatal cavity of open stomata or on the leaf surface, and pH was measured continuously up to several days during fungal development. We demonstrate that surface and apoplastic fluids are electrically coupled and respond in a similar manner to stimuli. Apoplastic pH, monitored from the moment of inoculation with conidia, reveals several phases: 2-4h after inoculation of the barley leaf with either fungus, the host displays rapid transient responses after its first contact with the fungal cell wall; apoplastic pH and pCa increases, cytoplasmic pH and pCa decreases. About 1 day after inoculation, the apoplastic pH increases by up to 2 pH units, which is thought to reflect a resistance response against the intruder. Whereas barley leaf cells possess a membrane potential of -152+/-5 mV, hyphae of B. graminis yield -251+/-8 mV, indicative of a substantial driving force advantage for the fungus. Although the resting membrane potential of barley remains constant during the first days after inoculation, leaves infected with B. sorokiniana get confronted with an energy problem, indicated by a retarded repolarization following a "light-off" stimulus. Five days after inoculation, apoplastic pH has increased to 5.97+/-0.47 (n=11) and does no longer respond to "light-off" when measured within lesions. In contrast, it stays at near normal values outside the lesions and responds to "light-off". It is concluded that biotrophically growing fungi do not manipulate the cotransport driving forces since (i) any change in apoplastic pH would be experienced by both partners; (ii) the resting membrane potential is not changed. It is suggested that measured pH changes reflect defence responses of the host against the fungus rather than fungal action to increase compatibility.     

Study on Conformational Changes in Hemoglobin Protoporphyrin in Essential Hypertension

Changes in protoporphyrin conformation, partial pressures of O₂ and CO₂, and the mechanisms responsible for regulation of pCa and pH in erythrocytes were studied in essential hypertension (EH). Changes in protoporphyrin conformation in EH were accompanied by a decrease in the partial pressure of O₂ and an increase in the partial pressure of CO₂. This was associated with increased activities of Na⁺/H⁺-exchange and Ca²⁺-dependent K⁺-channels and with a decreased activity of Ca²⁺-ATPase. The changes in protoporphyrin conformation in EH are suggested to decrease the efficiency of O₂ metabolism in hemoglobin and increase the values of intracellular pCa and pH of erythrocytes.     

Generation of intracellular pH gradients in single cardiac myocytes with a microperfusion system

This study describes the use of a microperfusion system to create rapid, large regional changes in intracellular pH (pH(i)) within single ventricular myocytes. The spatial distribution of pH(i) in single myocytes was measured with seminaphthorhodafluor-1 fluorescence using confocal imaging. Changes in pH(i) were induced by local external application of NH(4)Cl, CO(2), or sodium propionate. Local application was achieved by simultaneously directing two parallel square microstreams, each 275 microm wide, over a single myocyte oriented perpendicular to the direction of flow. One stream contained the control solution, and the other contained a weak acid or base. End-to-end, stable pH(i) gradients as large as 1 pH unit were readily created with this technique. This result indicates that pH within a single cardiac cell may not always be spatially uniform, particularly when weak acid or base gradients are present, which can occur, for example, in regional myocardial ischemia. The microperfusion method should be useful for studying the effects of localized acidosis on myocyte function, estimating intracellular ion diffusion rates, and, possibly, inducing regional changes in other important intracellular ions.     

Intracellular compartmentation of cardiac fibres from rainbow trout and Atlantic cod--a general design of heart cells

In mammalian cardiomyocytes, mitochondria and adjacent ATPases with participation of creatine kinase (CK) constitute functional compartments with an exchange of ADP and ATP delimited from cytosolic bulk solution. The question arises if this extends to ectothermic vertebrates: their low body temperature and thinner cardiomyocytes with a lower density of membrane structures may reduce the need and structural basis for compartmentation. In saponin-skinned cardiac fibres from rainbow trout and Atlantic cod, we investigated mitochondrial respiration induced by endogenous ADP generated by ATPases and its competition for this ADP with pyruvate kinase (PK) in excess. At low Ca(2+) activity (pCa = 7.0), PK lowered ATP-induced respiration by 40% in trout and 26% in cod. At high Ca(2+) activity (pCa = 5.41), PK had no effect. Additionally, ADP release from the fibres was almost zero but increased drastically upon inhibition of respiration with 1 mM Na-azide. This suggests that fibres are compartmented. PK abolished creatine-stimulated respiration in trout suggesting a less tight coupling of CK to respiration than in mammals. In conclusion, intracellular compartmentation seems to be a general feature of vertebrate cardiomyocytes, whereas the role of CK is unclear, but it seems to be less important for energy transport in species with lower metabolism.     

Effect of phosphate and acidosis on the calcium sensitivity of the cardiac myofibrils

The treatment of the bundles of rat myocardial fibers with ethyleneglycol-bis(beta-aminoethyl ether)-N,N-tetraacetate (EGTA) made the sarcolemma permeable for ions and small molecules. At the incubation medium pH 7.0 the EGTA-treated fibers developed a half-maximal tension at pCa 5.4, and the maximal tension at pCa 4.8. Inorganic phosphate (10 mM) reduced the maximal tension by 18 +/- 3% and decreased the calcium sensitivity of the myofibrils so that there was a shift of the pCa/tension curve by 0.3 unit to the right. Acidosis (pH 6.6) also decreased significantly the calcium sensitivity, while the presence of 10 mM phosphate produced additional depression of the calcium sensitivity. It is concluded that phosphate accumulation by the ischemic myocardium combined with acidosis may depress the contractility not only due to depletion of the free calcium concentration in the myoplasm but also as a result of the reduced calcium sensitivity of myofibrils.     

Calcium-induced Mechanical Change in the Neck Domain Alters the Activity of Plant Myosin XI

Plant myosin XI functions as a motor that generates cytoplasmic streaming in plant cells. Although cytoplasmic streaming is known to be regulated by intracellular Ca(2+) concentration, the molecular mechanism underlying this control is not fully understood. Here, we investigated the mechanism of regulation of myosin XI by Ca(2+) at the molecular level. Actin filaments were easily detached from myosin XI in an in vitro motility assay at high Ca(2+) concentration (pCa 4) concomitant with the detachment of calmodulin light chains from the neck domains. Electron microscopic observations showed that myosin XI at pCa 4 shortened the neck domain by 30%. Single-molecule analysis revealed that the step size of myosin XI at pCa 4 was shortened to 27 nm under low load and to 22 nm under high load compared with 35 nm independent of the load for intact myosin XI. These results indicate that modulation of the mechanical properties of the neck domain is a key factor for achieving the Ca(2+)-induced regulation of cytoplasmic streaming.     

The regulation of extramitochondrial free calcium ion concentration by rat liver mitochondria

The mechanism whereby rat liver mitochondria regulate the extramitochondrial concentration of free Ca(2+) was investigated. At 30 degrees C and pH7.0, mitochondria can maintain a steady-state pCa(2+) (0) (the negative logarithm of the free extramitochondrial Ca(2+) concentration) of 6.1 (0.8mum). This represents a true steady state, as slight displacements in pCa(2+) (0) away from 6.1 result in net Ca(2+) uptake or efflux in order to restore pCa(2+) (0) to its original value. In the absence of added permeant weak acid, the steady-state pCa(2+) (0) is virtually independent of the Ca(2+) accumulated in the matrix until 60nmol of Ca(2+)/mg of protein has been taken up. The steady-state pCa(2+) (0) is also independent of the membrane potential, as long as the latter parameter is above a critical value. When the membrane potential is below this value, pCa(2+) (0) is variable and appears to be governed by thermodynamic equilibration of Ca(2+) across a Ca(2+) uniport. Permeant weak acids increase, and N-ethylmaleimide decreases, the capacity of mitochondria to buffer pCa(2+) (0) in the region of 6 (1mum-free Ca(2+)) while accumulating Ca(2+). Permeant acids delay the build-up of the transmembrane pH gradient as Ca(2+) is accumulated, and consequently delay the fall in membrane potential to values insufficient to maintain a pCa(2+) (0) of 6. The steady-state pCa(2+) (0) is affected by temperature, incubation pH and Mg(2+). The activity of the Ca(2+) uniport, rather than that of the respiratory chain, is rate-limiting when pCa(2+) (0) is greater than 5.3 (free Ca(2+) less than 5mum). When the Ca(2+) electrochemical gradient is in excess, the activity of the uniport decreases by 2-fold for every 0.12 increase in pCa(2+) (0) (fall in free Ca(2+)). At pCa(2+) (0) 6.1, the activity of the Ca(2+) uniport is kinetically limited to 5nmol of Ca(2+)/min per mg of protein, even when the Ca(2+) electrochemical gradient is large. A steady-state cycling of Ca(2+) through independent influx and efflux pathways provides a model which is kinetically and thermodynamically consistent with the present observations, and which predicts an extremely precise regulation of pCa(2+) (0) by liver mitochondria in vivo.     

Simultaneous pH Measurement in Endocytic and Cytosolic Compartments in Living Cells using Confocal Microscopy

Intracellular pH is tightly regulated and differences in pH between the cytoplasm and organelles have been reported¹. Regulation of cellular pH is crucial for homeostatic control of physiological processes that include: protein, DNA and RNA synthesis, vesicular trafficking, cell growth and cell division. Alterations in cellular pH homeostasis can lead to detrimental functional changes and promote progression of various diseases². Various methods are available for measuring intracellular pH but very few of these allow simultaneous measurement of pH in the cytoplasm and in organelles. Here, we describe in detail a rapid and accurate method for the simultaneous measurement of cytoplasmic and organellar pH by using confocal microscopy on living cells³. This goal is achieved with the use of two pH-sensing ratiometric dyes that possess selective cellular compartment partitioning. For instance, SNARF-1 is compartmentalized inside the cytoplasm whereas HPTS is compartmentalized inside endosomal/lysosomal organelles. Although HPTS is commonly used as a cytoplasmic pH indicator, this dye can specifically label vesicles along the endosomal-lysosomal pathway after being taken up by pinocytosis^3,4. Using these pH-sensing probes, it is possible to simultaneously measure pH within the endocytic and cytoplasmic compartments. The optimal excitation wavelength of HPTS varies depending on the pH while for SNARF-1, it is the optimal emission wavelength that varies. Following loading with SNARF-1 and HPTS, cells are cultured in different pH-calibrated solutions to construct a pH standard curve for each probe. Cell imaging by confocal microscopy allows elimination of artifacts and background noise. Because of the spectral properties of HPTS, this probe is better suited for measurement of the mildly acidic endosomal compartment or to demonstrate alkalinization of the endosomal/lysosomal organelles. This method simplifies data analysis, improves accuracy of pH measurements and can be used to address fundamental questions related to pH modulation during cell responses to external challenges.     

Ratiometric measurement of intracellular pH in cultured human keratinocytes using carboxy-SNARF-1 and flow cytometry

In this study we describe a method to measure intracellular pH in cultured human keratinocytes using flow cytometry. Keratinocytes pose a technical problem because the population is heterogeneous with respect to size and metabolic activity (nonspecific esterase activity), resulting in variability in dye uptake. In order to compensate for this, dyes were selected that change colour with pH. The ratio of fluorescence intensities at two wavelengths was recorded and used as a measure of intracellular pH by reference to the pH in the presence of the proton ionophore nigericin. However, methods published till now do not routinely combine the ratiometric technique and excitation with an argon ion laser set at 488 nm. Therefore we have tested the recently developed pH-sensitive dye carboxyseminaphthorhodafluor-1 (SNARF-1) as a possible candidate for flow cytometric pH measurements and compared it with 2',7'-bis(carboxyethyl)-5,6-carboxyfluorescein (BCECF) and 2,3-dicyanohydroquinone (DCH) with respect to emission spectra, resolution, range, and stability of cellular fluorescence. SNARF-1 had a practical and stable excitation wavelength of 488 nm rather than UV, it offered the possibility of ratiometric measurements on the basis of a real emission shift, and had superior resolution for the pH range 7-8. With SNARF-1 we found that keratinocytes cultured under low serum conditions (0.2%) contain a higher proportion of cells with relatively low intracellular pH compared to high serum cultures (6%). Furthermore, pH changes were followed by changes in relative DNA content. These findings suggest that intracellular pH can be an early functional proliferation marker for human keratinocytes.     

Quick and accurate method to convert BCECF fluorescence to pHi: calibration in three different types of cell preparations.

A rapid, easy, and accurate method for converting the fluorescence of BCECF to pH, as an alternative to the nigericin method, is described. The ratio of the fluorescence intensities for BCECF can be converted to pH between 4 and 9 by a formula similar to the one used to calculate [Ca2+]i from the fluorescence of fura2. The formula is inverted because H+ binding to BCECF causes a decrease in fluorescence, whereas Ca2+ binding to fura2 causes an increase in fluorescence. The ratio of the fluorescence intensities is a sigmoidal function of the [H+] between pH 4 and 9 with an essentially linear mid region from pH 6 to 8. This calibration procedure in cells is similar to the popular method for fura2 where ionomycin, Ca2+, and an alkaline EGTA solution are added in succession to change the intracellular pCa from 4 to 9. For BCECF in cells, a protonophore, FCCP or CCCP, is added and the cells are titrated with acid to an intracellular pH of 4 and then back to pH 9 with base by observing the gradual change in fluorescence as it asymptotically reaches its limiting minimum and maximum values. This method does not require changing the medium to one with high KCl to depolarize the membrane potential nor does the proton concentration need to be equilibrated across the plasma membrane. The technique can be used to calibrate BCECF in sheets of cells, as well as suspensions of cells over a wide range of pH sensitivities.     

A calcium-stimulated, ouabain-inhibited ATPase in a myocardial fraction enriched with sarcolemma

An active intracellular to extracellular Ca²⁺ efflux has been proposed in heart muscle. A myocardial sarcolemmal ATPase stimulated by an intracellular pCa and serving as a Ca²⁺ pump has been postulated. A recently developed myocardial sarcolemmal preparation has not permitter a search for such an enzymatic activity. In these studies, an ATPase has been demonstrated in the sarcolemma which is activated by Mg²⁺, stimulated as the Ca²⁺ is raised to a pCa of 6, and is inhibited by ouabain. These findings suggest a mechanism by which Ca²⁺ within the myocardium may be modulated and thus how the force of contraction may be altered by cardiac glycosides.     

Force generation and shift of mass between myosin and actin in skinned striated muscle fibres at low calcium concentrations

Skinned muscle fibres from the gracilis muscle of the rabbit were used to record small angle X-ray diffraction spectra under various contractile conditions. The intracellular calcium concentration, expressed as pCa, was varied between 8.0 and 5.74. Equatorial diffraction spectra were fitted by a function consisting of five Gaussian curves and a hyperbola to separate the (1.0), (1.1), (2.0), (2.1) and Z-line diffraction peaks. The hyperbola was used to correct for residual scattering in the preparation. The ratio between the intensities of the (1.1) and (1.0) peaks was defined as the relative transfer of mass between myosin and actin, due to crossbridge formation after activation by calcium. The relation between the ratio and the relative force of the fibre (normalized to the force at pCa 5.74 and sarcomere length 2.0 μm) was linear. At high pCa (from pCa 6.34 to 8.0) no active force was observed, while the ratio still decreased. Sarcomere length was recorded by laser diffraction. The laser diffraction patterns did not show changes in sarcomere length due to activation in the high pCa range (between 8.0 and 6.34). From these results the conclusion is drawn that crossbridge movement occurs even at subthreshold calcium concentrations in the cell, when no active force is exerted. Since no force is generated this movement may be related to crossbridges in the weakly bound state. Received: 20 June 1996 / Revised version: 12 January 1998 / Accepted: 18 March 1998     

Glycoprotein B of herpes simplex virus 2 has more than one intracellular conformation and is altered by low pH

The crystal structure of herpes simplex virus (HSV) gB identifies it as a class III fusion protein, and comparison with other such proteins suggests this is the postfusion rather than prefusion conformation, although this is not proven. Other class III proteins undergo a pH-dependent switch between pre- and postfusion conformations, and a low pH requirement for HSV entry into some cell types suggests that this may also be true for gB. Both gB and gH undergo structural changes at low pH, but there is debate about the extent and significance of the changes in gB, possibly due to the use of different soluble forms of the protein and different assays for antigenic changes. In this study, a complementary approach was taken, examining the conformations of full-length intracellular gB by quantitative confocal microscopy with a panel of 26 antibodies. Three conformations were distinguished, and low pH was found to be a major influence. Comparison with previous studies indicates that the intracellular conformation in low-pH environments may be the same as that of the soluble form known as s-gB at low pH. Interestingly, the antibodies whose binding was most affected by low pH both have neutralizing activity and consequently must block either the function of a neutral pH conformation or its switch from an inactive form to an activated form. If one of the intracellular conformations is the fusion-active form, another factor required for fusion is presumably absent from wherever that conformation is present in infected cells so that inappropriate fusion is avoided.     

Bi-directional regulation of dephosphorylation of cAMP-dependent phosphorylated proteins by cAMP and calcium in permeabilized rat heart cells

We studied the regulation of dephosphorylation of cAMP-dependent phosphorylated proteins of isolated, permeabilized (skinned) myocardial cells from adult rat. Staurosporine, a potent inhibitor of protein kinase, inhibited cAMP-dependent phosphorylation of phospholamban and troponin-I, the key proteins in the control of contraction and relaxation of the myocardial cells. Staurosporine antagonized the stimulatory action of cAMP on the spontaneous beating of the myocytes accompanied by dephosphorylation of phospholamban but not of troponin-I at pCa 7-8. In cold ATP dilution experiments with apparent stoppage of protein phosphorylation, dephosphorylation of phospholamban was accelerated both by Ca2+ and staurosporine but that of troponin-I took place only in the presence of Ca2+ ion (pCa less than 6.5). These phenomena suggest a bi-directional regulation of dephosphorylation of the key proteins by the intracellular messengers cAMP and Ca2+.     

Interactive signal transfer between host and pathogen during successful infection of barley leaves by Blumeria graminis and Bipolaris sorokiniana

Using ion-selective microprobes, interactive signalling between barley and Blumeria graminis or Bipolaris sorokiniana has been investigated. The question was raised whether a biotrophically growing fungus manipulates the electrical driving forces (membrane potential, transmembrane pH), required for H⁺ cotransport of energy-rich compounds. Electrodes were positioned in the substomatal cavity of open stomata or on the leaf surface, and pH was measured continuously up to several days during fungal development. We demonstrate that surface and apoplastic fluids are electrically coupled and respond in a similar manner to stimuli. Apoplastic pH, monitored from the moment of inoculation with conidia, reveals several phases: 2–4 h after inoculation of the barley leaf with either fungus, the host displays rapid transient responses after its first contact with the fungal cell wall; apoplastic pH and pCa increases, cytoplasmic pH and pCa decreases. About 1 day after inoculation, the apoplastic pH increases by up to 2 pH units, which is thought to reflect a resistance response against the intruder. Whereas barley leaf cells possess a membrane potential of −152±5 mV, hyphae of B. graminis yield −251±8 mV, indicative of a substantial driving force advantage for the fungus. Although the resting membrane potential of barley remains constant during the first days after inoculation, leaves infected with B. sorokiniana get confronted with an energy problem, indicated by a retarded repolarization following a “light-off” stimulus. Five days after inoculation, apoplastic pH has increased to 5.97±0.47 (n=11) and does no longer respond to “light-off” when measured within lesions. In contrast, it stays at near normal values outside the lesions and responds to “light-off”.It is concluded that biotrophically growing fungi do not manipulate the cotransport driving forces since (i) any change in apoplastic pH would be experienced by both partners; (ii) the resting membrane potential is not changed. It is suggested that measured pH changes reflect defence responses of the host against the fungus rather than fungal action to increase compatibility.