pH measurements in ultranarrow immobilized pH gradients

It is possible to measure pH values in immobilized pH gradients (IPG) when the polyacrylamide matrix is made to contain an additional, carrier ampholyte-generated pH gradient. After an IPG run, 5 mm gel segments, along the separation axis, are cut and eluted in 300 microliter of 10 mM KCl and the pH read with a standard pH meter. When using ultranarrow pH gradients, larger gel segments (ca. 265 microliter) are eluted in 900 microliter of 100 mM KCl and the pH assessed with a differential pH meter. In the latter case, either internal or external standards are used as a reference, or starting point, to convert delta pH values into an actual pH curve. The reproducibility of the system is better than +/- 0.05 pH units, with a ca. 15% error over a 0.3 pH unit span. In ultranarrow pH gradients, it is imperative to use mixtures of all commercially available carrier ampholytes, so as to smoothen conductivity and buffering capacity gaps. By the present method, it is also possible to convert a wide (2-3 pH unit) carrier ampholyte interval into a narrow (0.2-0.3 pH unit) one.     

Effect of changing venoarterial pH difference on in vivo arterial pH

Plasma pH has been postulated to change slowly in blood leaving the pulmonary capillaries because of the uncatalyzed dehydration of CO2. If so, there could be a difference between in vivo and in vitro arterial pH, the magnitude of which would be dependent on the venoarterial pH difference (v-aDpH). We tested this hypothesis in anesthetized dogs by changing v-aDpH by airway CO2 loading and by comparing arterial pH measured in vivo by a rapidly responding intravascular pH electrode with that measured in vitro by a conventional glass electrode. Using a multiple regression analysis, we found a small but significant contribution of venous pH to in vivo arterial pH, with a regression coefficient of 0.0718 (P less than 0.0001), suggesting a postcapillary increase of in vivo arterial pH. When carbonic anhydrase was inhibited by the administration of acetazolamide, the effect of venous pH on arterial pH was abolished, and a unique relationship between in vivo and in vitro arterial pH was established (regression coefficient 1.02; P greater than 0.05, comparison with unity). These results could be accounted for in a computer simulation of gas exchange among alveolus, plasma, and erythrocyte. We conclude that there exists a small but measurable postcapillary increase in arterial pH.     

Isoelectric focusing in immobilized pH gradients: Generation of extended pH intervals

A new technique for generatiing extended pH gradients (3–4 pH units) in Immobiline gels for isoelectric separations is described. A five-chamber gradient mixer has been built, based on the ‘Varigard’-type mixers of Peterson and Sober (Anal. Chem. 31, 1959, 857–862). Each chamber contains one of the following Immobilines, in this order: pK values 4.4, 4.6, 6.2, 7.0 and 8.5, titrated in the pH 4–8 interval with non-buffering Immobilines pK 9.3 (in the case of the two acidic Immobilines) and pK 3.6 (in the case of the three basic Immobilines). In this way it is possible to cast, in a highly reproducible way, an immobilized pH gradient in thepH range 4.0 to 7.5, which should be ideal for isoelectric separations in the first dimension of two-dimensional techniques. A computer program is also described which, given the molarities and pK values of the different Immobilines in the chambers of the Varigrad mixer, can generate the theoretical pH profile, together with the buffering capacity (β) and ionic strength (I) courses.     

pH microdomains in oligodendrocytes

Oligodendrocytes (OLs) are cells that produce myelin in the central nervous system. Here we use ratiometric pH indicator dye to analyze intracellular pH in OLs in culture. The results reveal alkaline microdomains, which predominate in the perikaryon and proximal dendrites, and acidic microdomains, which predominate in distal dendrites. Spatial nonuniformity of pH is generated by differential subcellular distribution of Na(+)/H(+) exchanger (NHE), which is localized in a punctate distribution in the perikaryon and proximal processes, Na(+)/HCO(3)(-) cotransporter (NBC), which is localized in a punctate distribution in distal dendrites, and carbonic anhydrase isotype II (CAII), which is colocalized with either NHE or NBC. Inhibition of NHE activity by amiloride inhibits regeneration of alkaline microdomains after cytoplasmic acidification, whereas the inhibition of CAII activity with ethoxyzolamide inhibits acidification of dendrites. Fluorescence correlation spectroscopy analysis of CAII microinjected into OLs reveals freely diffusing protein throughout the cell as well as protein associated predominantly with NHE in the perikaryon and predominantly with NBC in the dendrites. Alkaline and acidic microdomains could be generated by transport metabolons consisting of CAII associated with NHE or NBC, respectively. This study provides the first evidence for pH microdomains in cells and describes a mechanism for how they are generated.     

Isoelectric focusing in immobilized pH gradients in the pH 10-11 range

With the synthesis of a new, strongly basic Immobiline (pK 10.3 at 10 degrees C) it has been possible to formulate a new pH 10-11 recipe for focusing very alkaline proteins, not amenable to fractionation with conventional isoelectric focusing in carrier ampholyte buffers. In this formulation, water is added as an acidic Immobiline having pK = 14 and a unit molar concentration (or with a pK = 15.74 and standard 55.56 molarity) since around pH 11 its buffering power becomes significant. The gel contains a 'conductivity quencher', i.e. a density gradient incorporated in the matrix, with the dense region located on the cathodic side (pH 11) for (a) smoothing the voltage gradient on the separation cell and (b) reducing the anodic electrosmotic flow due to the net positive charge acquired by the matrix at pH 11 (1 mM excess protonated amino groups to act as counterions to the 1 mm OH- groups in the bulk water solution generated by the local value of pH 11). Excellent focusing is obtained for such alkaline proteins as lysozyme (pI 10.55), So-6 (a leaf protein, pI 10.49), cytochrome c (pI 10.45) and ribonuclease (pI 10.12).     

Light-induced pH changes and changes in absorbance of pH indicators in Rhodospirillum rubrum chromatophores.

1. The light-induced pH change of chromatophore suspensions from Rhodospirillum rubrum was stimulated significantly and similarly by KCl, NaCl, LiCl, RbCl, CsCl, MgCl2, MnCl2, and CaCl2. In the dark, the pH of chromatophore suspensions decreased immediately and markedly on adding these salts. 2. The light-induced pH change stimulated by KCl plus valinomycin was inhibited by LiCl and NaCl, but not by RbCl. 3. The optimum pH values for light-induced pH change and photosynthetic ATP formation were around 5 and 8, respectively. The amount of chromatophore-bound ubiquinone-10 reduced in the light was independent of pH from 5 to 9. At pH 8, the number of protons incorporated into chromatophores in the light was one-half of the number of ubiquinone-10 molecules reduced in the light. 4. Among several pH indicators tested, bromothymol blue (BTB) and neutral red (NR) showed absorbance changes on illumination of chromatophores. Although the pH change indicated by the absorbance change was opposite to the light-induced pH change of the medium, the effect of KCl on the absorbance changes of BTB and NR, and the effect of valinomycin on that of NR, but not on that of BTB, were similar to those on the light-induced pH change. 5. The light-induced absorbance change of BTB was significantly inhibited by NR, whereas that of NR was hardly influenced by BTB. 6. Oligomycin stimulated the light-induced absorbance change of BTB under either non-phosphorylating or phosphorylating conditions. On the other hand, that of NR under phosphorylating conditions was 50% of that under non-phosphorylating conditions, and was increased by oligomycin.     

Measurement of mitochondrial pH in situ

In this article, we describe the advantages and disadvantages of procedures for monitoring mitochondrial pH in situ using optical microscopic techniques. The first method employs the combination of the fluorescent pH-sensitive indicator carboxy-SNARF and laser scanning confocal microscopy. Manipulation of the loading and post-loading conditions enables relatively specific accumulation of carboxy-SNARF into mitochondria. With the use of a mitochondrial-specific marker, mitochondrial pH can be accurately monitored. More recently, mitochondrial-targeted, pH-sensitive probes have been used to monitor mitochondrial pH. In particular, mitochondrial targeting of the yellow fluorescent protein (YFP) mutant of green fluorescent protein (GFP) combines the advantages of specific mitochondrial localization, high-fluorophore quantum yield, and extinction coefficient with an appropriate pKa for measuring mitochondrial pH. The use of dual-excitation ratiometry with mitochondrially targeted YFP increases the dynamic range of mitochondrial pH measurements and corrects for differences in the amount of expression of mitochondrially targeted YFP at the level of individual mitochondria.     

植物细胞内pH值的测定

介绍了植物细胞内pH值的测定方法和各种方法的优缺点.     

Role of pH in fibroblast proliferation

Secondary cultures of human diploid fibroblasts were used to study the effect of pH on cellular proliferation. In nonconfluent cultures, the growth rate at pH 7.1 was similar to that at pH 7.7 regardless of serum concentration. However, the saturation density achieved at pH 7.7 at any serum concentration was always 2–4 times that achieved at pH 7.1, although the greatest differences in saturation density were observed at the higher serum levels. The results suggest that the effect of pH on saturation density is due to two factors. One, cells at pH 7.1 seem to have a greater ability to undergo contact-inhibition than at pH 7.7, independent of any serum functions; and, two, confluent cells in medium at pH 7.1 are somewhat less sensitive to growth stimulation by increasing serum concentration than are confluent cells raised in medium at pH 7.7.     

Methods of pH calibration of sedimentary diatom remains for reconstructing history of pH in lakes

The pH history of lakes can be inferred from diatom remains in dated sediment cores. To derive transfer functions for pH inference in acidic lakes, we counted diatoms in surface-sediment from 31 soft-water lakes in n. New England (NE) and 36 in Norway (N), covering pH 4.4–7.1. Cluster analysis of each data set indicates that pH 6 is an upper limit for a group of similar diatom assemblages. For each set, we developed multiple linear regressions to relate three versions of the diatom data to pH of surface-waters: (1) relative frequencies of selected diatom taxa, (2) the first principal component (1 PC) of these frequencies, and (3) the frequencies of Hustedt pH groups. Also, simple linear regressions were developed for two versions: (1) Index B and (2) Index Alpha, both based on pH groups. Regressions were run separately for lakes with pH 6; these are most relevant for pH inference in acidic lakes. The best regressions (N: taxa & 1 PC taxa) have r² 0.69–0.91 and S_e 0.24–0.31 pH units, the worst (NE: log alpha) have r² 0.27–0.57 and S_e 0.51. In all cases, errors for NE are greater than N, partly due to greater diversity of NE lakes. Regressions based on pH groups (directly & by indices) have smaller r² and larger S_e than those based on taxa and 1 taxa. The Index Alpha is least useful because its requirement for alkaline diatom units is unsatisfied at many acidic lakes. Regressions based on taxa may give erratic pH inferences due to sensitivity to unusual frequencies of individual taxa; this effect is reduced by using 1 PC taxa. Four regressions based on pH 6 lakes were used for inferring pH in a ²¹⁰Pb dated core from Nedre Målmesvatn, N (now pH 4.6). There is good agreement among three of the four (not for the regression based directly on taxa) that there has been a decrease of ca. 0.6 pH units starting in the late 1800's.     

Rhizosphere pH dynamics in trace-metal-contaminated soils, monitored with planar pH optodes

The present study presents new insights into pH dynamics in the rhizosphere of alpine pennycress (Noccaea caerulescens (J. Presl & C. Presl) F.K. Mey), maize (Zea mays L.) and ryegrass (Lolium perenne L.), when growing on three soils contaminated by trace metals with initial pH values varying from 5.6 to 7.4. The pH dynamics were recorded, using a recently developed 2D imaging technique based on planar pH optodes. This showed that alpine pennycress and ryegrass alkalinized their rhizosphere by up to 1.7 and 1.5 pH units, respectively, whereas maize acidified its rhizosphere by up to ?0.7 pH units. The alkalinization by the roots of alpine pennycress and ryegrass was permanent and not restricted to specific root zones, whereas the acidification along the maize roots was restricted to the elongation zone and thus only temporary. Calculations showed that such pH changes should have noticeable effects on the solubility of the trace metal in the rhizosphere, and therefore on their uptake by the plants. As a result, it is suggested that models for trace metal uptake should include precise knowledge of rhizospheric pH conditions.     

Continuous measurement of the cytoplasmic pH in Lactococcus lactis with a fluorescent pH indicator

The cytoplasmic pH of Lactococcus lactis was studied with the fluorescent pH indicator 2',7'-bis-(2-carboxyethyl)-5 (and-6)-carboxyfluorescein (BCECF). A novel method was applied for loading bacterial cells with BCECF, which consists of briefly treating a dense cell suspension with acid in the presence of the probe. This results in a pH gradient, which drives accumulation of the probe in the cytoplasm. After neutralization the probe was well retained in cells stored on ice. BCECF-loaded cells were metabolically active, and were able to generate a pH gradient upon energization. The probe leaks out slowly at elevated temperatures. Efflux is stimulated upon energization of the cells, and is most likely catalyzed by an active transport system. It is a first-order process, and the rate constant could be deduced from the decrease of the fluorescence signal in periods of constant intracellular pH. This allowed a correction of the fluorescence signal for efflux of the probe. After calibration the cytoplasmic pH could be calculated from efflux-corrected fluorescence traces.