ATP-dependent and DCCD-insensitive Cl- uptake by membrane vesicles from the rat brain plasma membrane fractions

ATP-dependent Cl- uptake by membrane vesicles from the rat brain plasma membrane fractions was not affected by the addition of 40 mM of K+, Na+ or HCO3- to the assay medium. Na+ and K+ did not alter the uptake even in the presence of a K+ ionophore, valinomycin (10 microM), or a H+/K+ exchanger, nigericin (10 microM), whereas in the presence of both of these ionophores, K+, but not Na+, reduced the Cl- uptake. Inhibitors of proton pump activity, N,N'-dicyclohexylcarbodiimide (1 mM) and 5-(N,N-hexamethylene)amiloride (40 microM), however, did not affect the Cl- uptake. These findings suggest the presence of a primary Cl- transport system probably associated with passive H+ flux in the brain plasma membranes.     

Porton uptake by isolated chloroplasts during cyclic and non-cyclic electron transport catalyzed by photosystem I in the presence of ferredoxin]

Proton uptake by isolated chloroplasts during cyclic electron transport in the presence of ferredoxin and under NADP+ reduction from the ascorbate--TMPD donor pair under anaerobic conditions was studied. It was found that during cyclic transport the proton uptake is less intensive than under NADP+ reduction. In the presence of ATP the proton uptake is increased in the first case and is decreased in the second one. During cyclic transport in the presence of gramicidin D the proton uptake is completely suppressed and under NADP+ reduction is decreased down to 0,08--0,09 mk equiv H+ per mg of chlorophyll, irrespective of ferredoxin or NADP+ concentrations. The role of ferredoxin NADP+ reductase in a proton uptake by thylakoids is discussed.     

Trans-potassium effects on the chloride/proton symporter activity of guinea-pig ileal brush-border membrane vesicles.

To investigate the inhibitory effect of trans potassium on the Cl-/H+ symporter activity of brush-border membrane vesicles from guinea pig ileum, we measured both 36Cl uptake and, by the pyranine fluorescence method, proton fluxes, in the presence of appropriate H+ and K+ gradients. In the absence of valinomycin, a time-dependent inhibitory effect of chloride uptake by trans K+ was demonstrated. This inhibition was independent of the presence or absence of any K+ gradient. Electrical effects cannot be involved to explain these inhibitions because the intrinsic permeability of these vesicles to Cl- and K+ is negligibly small. Rather, our results show that, in the absence of valinomycin, the inhibitory effect of intravesicular K+ involves an acceleration of the rate of dissipation of the proton gradient through an electroneutral exchange of trans K+ for cis H+, catalyzed by the K+/H+ antiporter also present in these membranes. Valinomycin can further accelerate the rate of pH gradient dissipation by facilitating an electrically-coupled exchange between K+ and H+. To evaluate the apparent rate of pH-dissipating, downhill proton influx, we measured chloride uptake by vesicles preincubated in the presence of alkaline-inside pH gradients (pHout/pHin = 5.0/7.5), charged or not with K+. In the absence of intravesicular K+, proton influx exhibited monoexponential kinetics with a time constant k = 11 s-1. Presence of 100 mM K+ within the vesicles significantly increased the rate of pH gradient dissipation which, furthermore, became bi-exponential and revealed the appearance of an additional, faster proton influx component with k = 71 s-1. This new component we interpret as representing the sum of the electroneutral and the electrically-coupled exchange of trans K+ for cis H+, mentioned above. Finally, by using the pH-sensitive fluorophore, pyranine, we demonstrate that, independent of the absence or presence of a pH gradient, either vesicle acidification or alkalinisation can be generated by adding, respectively, Cl- or K+ to the extravesicular medium. Such results confirm the independent existence of both Cl-/H+ symporter and K+/H+ antiporter activities in our vesicle preparations, the relative activity of the former being larger under the conditions of the present experiments. The possible interplay of these two proton-transfer mechanisms in the regulation of the intracellular pH is discussed.     

Sodium/proton antiport in brush-border-membrane vesicles isolated from rat small intestine and kidney.

Studies on proton and Na+ transport by isolated intestinal and renal brush-border-membrane vesicles were carried out to test for the presence of an Na+/H+-exchange system. Proton transport was evaluated as proton transfer from the intravesicular space to the incubation medium by monitoring pH changes in the membrane suspension induced by sudden addition of cations. Na+ transport was determined as Na+ uptake into the vesicles by filtration technique. A sudden addition of sodium salts (but not choline) to the membrane suspension provokes an acidification of the incubation medium which is abolished by the addition of 0.5% Triton X-100. Pretreatment of the membranes with Triton X-100 prevents the acidification. The acidification is also not observed if the [K+] and proton conductance of the membranes have been increased by the simultaneous addition of valinomycin and carbonyl cyanide p-trifluoromethoxyphenylhydrazone to the K+-rich incubation medium. Either valinomycin or carbonyl cyanide p-trifluoromethoxyphenylhydrazone when added alone do not alter the response of the membranes to the addition of Na+. Na+ uptake by brush-border microvilli is enhanced in the presence of a proton gradient directed from the intravesicular space to the incubation medium. Under these conditions a transient accumulation of Na+ inside the vesicles is observed. It is concluded that intestinal and renal brush-border membranes contain a NA+/H+ antiport system which catalyses an electroneutral exchange of Na+ against protons and consequently can produce a proton gradient in the presence of a concentration difference for Na+. This system might be involved in the active proton secretion of the small intestine and the proximal tubule of the kidney.     

Proton potential-dependent polyamine transport by vacuolar membrane vesicles of Saccharomyces cerevisiae.

Vacuolar membrane vesicles of Saccharomyces cerevisiae accumulated spermine and spermidine in the presence of ATP, not in the presence of ADP. Spermine and spermidine transport at pH 7.4 showed saturation kinetics with Km values of 0.2 mM and 0.7 mM, respectively. Spermine uptake was competitively inhibited by spermidine and putrescine, but was not affected by seven amino acids, substrates of active transport systems of vacuolar membrane. Spermine transport was inhibited by the H(+)-ATPase-specific inhibitors bafilomycin A1 and N,N'-dicyclohexylcarbodiimide, but not by vanadate. It was also sensitive to Cu2+ or Zn2+ ions, inhibitors of vacuolar H(+)-ATPase. Both 3,5-di-tert-butyl-4-hydroxybenzilidenemalononitrile (SF6847) and nigericin blocked completely the spermine uptake, but valinomycin did not. [14C]Spermine accumulated in the vesicles was exchangeable with unlabeled spermine and spermidine. However, it was released by a protonophore only in the presence of a counterion such as Ca2+. These results indicate that a polyamine-specific transport system depending on a proton potential functions in the vacuolar membrane of this organism.     

Probing the structure of bacterial deoxyribonucleoproteins with exogenous and endogenous nucleases

During digestion of deoxyribonucleoproteins (DNP) of gram-negative bacteria by micrococcal nuclease and Ca2+, Mg2+-dependent endonuclease in situ regular series fragments-and large nuclease-resistent fragments of DNP were revealed by electrophoresis. The DNP length of the smallest DNP-fragment was tentatively 120-140 base pairs. In investigated bacterial species DNP contained at least two basic proteins which had electrophoretic mobility similar to that of histone H4 of eucaryot. It is suggested that bacterial DNPs have common regular structure.     

The C-terminally truncated NuoL subunit (ND5 homologue) of the Na+-dependent complex I from Escherichia coli transports Na+

The NADH:quinone oxidoreductase (complex I) from Escherichia coli acts as a primary Na+ pump. Expression of a C-terminally truncated version of the hydrophobic NuoL subunit (ND5 homologue) from E. coli complex I resulted in Na+-dependent growth inhibition of the E. coli host cells. Membrane vesicles containing the truncated NuoL subunit (NuoLN) exhibited 2-4-fold higher Na+ uptake activity than control vesicles without NuoLN. Respiratory proton transport into inverted vesicles containing NuoLN decreased upon addition of Na+, but was not affected by K+, indicating a Na+-dependent increase of proton permeability of membranes in the presence of NuoLN. The His-tagged NuoLN protein was solubilized, enriched by affinity chromatography, and reconstituted into proteoliposomes. Reconstituted His6-NuoLN facilitated the uptake of Na+ into the proteoliposomes along a concentration gradient. This Na+ uptake was prevented by EIPA (5-(N-ethyl-N-isopropyl)-amiloride), which acts as inhibitor against Na+/H+ antiporters.     

Factors controlling the binding of two protons per electron transferred through the ubiquinone and cytochrome b/c2 segment of Rhodopseudomonas sphaeroides chromatophores.

1. On every turnover, 2.0 protons can be bound by the membrane for each single electron moving through the Q-b/c2 oxidoreductase. 2. One proton (H+II) binding reaction is, and one (H+I) is not, sensitive to antimycin. 3. The redox states of electron transfer components other than the proton binding agents can affect both the rate of proton uptake and the apparent pK values on the agents binding the protons. 4. The presence of valinomycin under certain well-defined conditions can strongly influence the value of the measured pK on the H+II binding agent.     

Kinetics of sulfate uptake by yeast.

Uptake of sulfate by yeast requires the presence of a metabolic substrate and is dependent on the time during which the cells have been metabolizing in the absence of sulfate. At low concentrations of sulfate, uptake can be described by simple saturation kinetics. Uptake of sulfate is accompanied by a net proton influx of 3 H+ and an efflux of 1 K+ for each sulfate ion taken up. Divalent cations stimulate sulfate uptake at low concentrations of sulfate; the maximal rate of uptake is not significantly affected but Km is lowered. Stimulation by divalent cations shows an optimum at a cation concentration of about 4 mM. Monovalent cations are less effective, trivalent cations are more effective in stimulating sulfate uptake. The results are qualitatively in accordance with the notion, that the effect of cations is due to an effect via the surface potential.     

Evidence for a zinc/proton antiporter in rat brain

The data presented in this paper are consistent with the existence of a plasma membrane zinc/proton antiport activity in rat brain. Experiments were performed using purified plasma membrane vesicles isolated from whole rat brain. Incubating vesicles in the presence of various concentrations of 65Zn2+ resulted in a rapid accumulation of 65Zn2+. Hill plot analysis demonstrated a lack of cooperativity in zinc activation of 65Zn2+ uptake. Zinc uptake was inhibited in the presence of 1 mM Ni2+, Cd2+, or CO2+. Calcium (1 mM) was less effective at inhibiting 65Zn2+ uptake and Mg2+ and Mn2+ had no effect. The initial rate of vesicular 65Zn2+ uptake was inhibited by increasing extravesicular H+ concentration. Vesicles preloaded with 65Zn2+ could be induced to release 65Zn2+ by increasing extravesicular H+ or addition of 1 mM nonradioactive Zn2+. Hill plot analysis showed a lack of cooperativity in H+ activation of 65Zn2+ release. Based on the Hill analyses, the stoichiometry of transport may include Zn2+/Zn2+ exchange and Zn2+/H+ antiport, the latter being potentially electrogenic. Zinc/proton antiport may be an important mode of zinc uptake into neurons and contribute to the reuptake of zinc to replenish presynaptic vesicle stores after stimulation.     

Functional reconstitution of the gamma-aminobutyric acid transporter from synaptic vesicles using artificial ion gradients.

The gamma-aminobutyric acid transporter of rat brain synaptic vesicles was reconstituted in proteoliposomes, and its activity was studied in response to artificially created membrane potentials or proton gradients. Changes of the membrane potential were monitored using the dyes oxonol VI and 3,3'-diisopropylthiodicarbocyanine iodide, and changes of the H+ gradient were followed using acridine orange. An inside positive membrane potential was generated by the creation of an inwardly directed K+ gradient and the subsequent addition of valinomycin. Under these conditions, valinomycin evoked uptake of [3H]GABA which was saturable. Similarly, [3H]glutamate uptake was stimulated by valinomycin, indicating that both transporters can be driven by the membrane potential. Proton gradients were generated by the incubation of K(+)-loaded proteoliposomes in a buffer free of K+ or Na+ ions and the subsequent addition of nigericin. Proton gradients were also generated via the endogenous H+ ATPase by incubation of K(+)-loaded proteoliposomes in equimolar K+ buffer in the presence of valinomycin. These proton gradients evoked nonspecific, nonsaturable uptake of GABA and beta-alanine but not of glycine in proteoliposomes as well as protein-free liposomes. Therefore, transporter activity was monitored using glycine as an alternative substrate. Proton gradients generated by both methods elicited saturable glycine uptake in proteoliposomes. Together, our data confirm that the vesicular GABA transporter can be energized by both the membrane potential and the pH gradient and show that transport can be achieved by artificial gradients independently of the endogenous proton ATPase.     

Electrolyte transport across the basolateral membrane of the parietal cells

The ion-transport properties of the basal lateral membranes of intact isolated parietal cells were studied at the cellular and subcellular level. The presence of an amiloride-sensitive Na+:H+ exchange was demonstrated in cells by proton gradient-driven Na+ uptake and by changes in cell pH as monitored by dimethylcarboxylfluorescein fluorescence both in a fluorimeter and on single isolated cells using a fluorescence microscope and an attached intensified photodiode array spectrophotometer. The presence of the Na+:H+ antiport in vesicles was shown both by intravesicular acidification monitored by acridine orange fluorescent quenching and by proton gradient-dependent Na+ uptake. The presence of Cl-:HCO-3 exchange was determined in intact cells by monitoring changes in cell pH due to Cl- uptake and was shown to be 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid- and 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid-sensitive. In vesicles, Cl-:HCO-3 exchange was demonstrated by Cl- flux measurement. The apparent affinities for both Cl- and HCO-3 on either side of the membrane were determined to be Km Cli = 20 mM, Km Clout = 17.5 mM, Km HCO-3in = 2.5 mM, and Km HCO-3out = 7.5 mM. A K+ conductance in cells and vesicles was demonstrated by monitoring K+ gradient-dependent 86Rb uptake. No evidence was found for the presence of a Cl- conductance in either cells or vesicles but a H+ conductance was found to be present in vesicles but not in intact cells. In the latter, by determining the effect of either Na+ or Cl- gradients on cell pH and by flux calculations it was concluded that the Cl-:HCO-3 exchange was the major passive flux mechanism for pH regulation in this cell type.     

The proton/sodium antiporter (exchanger) in the oocyte membrane of Dysdercus intermedius is electrogenic (2H(+)/Na(+)) and causes perioocytic proton accumulation

Vitellogenic follicles of Dysdercus intermedius (Heteroptera: Pyrrhocoridae) were treated with sodium azide (NaN(3)) or 2,4 dinitrophenol (DNP) in order to load the ooplasm with protons along their electrochemical gradient. Ooplasmic pH (pH(OOC)) was recorded using proton-specific microelectrodes. Treatment for six min with 0.5 mM of DNP (dissolved in physiological saline solution; PSS) resulted in acidification of the ooplasm from 7.41+/-0.05 in PSS to pH(OOC(DNP))=7.09+/-0.04. Immersing follicles in PSS after DNP treatment resulted in reactivation of a proton/sodium antiporter and recovery of the initial pH(OOC). Additionally, the proton-specific microelectrodes were placed at a distance of approximately 10 &mgr;m from the surface of the vitellogenic follicle. The extracellular pH (pH(EX)) was measured before (pH(EX(PSS))), during (pH(EX(DNP))) and after (pH(EX(PSS))) DNP treatment. Along the lateral surface of the follicle, the recorded pH(EX(PSS)) was initially 6.79+/-0.02, similar to the pH of the medium (pH(MED)=6.80; recorded at a distance of 300 &mgr;m from the surface of the follicle) and higher than the pH(EX(PSS)) of 6.52+/-0.03 measured in the interfollicular constriction between individual vitellogenic follicles (interfollicular region). During DNP treatment, values changed to 6.80+/-0.03 in the constriction and 6.80+/-0.01 along the lateral surface. After removal of DNP the initial control pH values were reestablished. These extrafollicular H(+) distributions fit into a model of extrafollicular currents reported earlier for D. intermedius.Proton distribution between the ooplasm and the medium was also affected in the presence of 5 mM NaN(3), resulting in a drop in ooplasmic pH from 7.40+/-0.05 down to pH(OOC(NaN3))=7.07+/-0.03. Changes in cytosolic proton activities after DNP or NaN(3) treatment were evidenced by monitoring both the increase in ooplasmic pH (DeltapH) and, simultaneously, the change in the resting potential (DeltaEm). Recovery of the ooplasmic pH depended on the transfer of approximately 6x10(9) H(+)/oocyte (after DNP treatment) or approximately 3x10(9) H(+)/oocyte (after NaN(3) treatment), whereas recovery of Em by charging the capacitance of the oocyte membrane could be attributed to a net efflux of approximately 3x10(9) H(+)/oocyte (after DNP treatment) or approximately 1.7x10(9) H(+)/oocyte (after NaN(3) treatment). In the light of previous reports on the monensin-sensitive proton/sodium antiporter (external Na(+) for ooplasmic H(+)), the operating efficiency of this antiporter is 2H(+)/Na(+).VITELLOGENESIS DURING AND AFTER DNP TREATMENT WAS DEMONSTRATED BY THE ACCUMULATION OF FLUORESCENCE LABELLED HEMOLYMPH PROTEINS IN YOLK SPHERES IN THE CORTEX OF THE OOCYTE: vitellogenesis came to a halt in PSS containing DNP when the ooplasm was acidified and no H(+) accumulation around the follicle was detectable. Vitellogenesis stopped under the condition of DNP(MED)=0.5 mM, but resumed again by exchanging the medium for PSS without DNP. Simultaneously with the appearance of the regular pH(OOC(PSS))=7.40+/-0.03 (efflux of H(+) out of the ooplasm), extrafollicular proton accumulation by H(+) influx into the constriction reappeared within 10 minutes. The results obtained with proton-specific microelectrodes and the in vitro assay to detect vitellogenesis indicate that electrogenic H(+) extrusion out of the ooplasm plays an important role in both maintaining the ooplasmic pH 0.6 units above pH(MED)=6.8 and in the generation of the external current pattern. A model is discussed explaining the acidification of endosomes as a prerequisite for endosomal processing leading to yolk spheres.     

Relationship of the light-induced proton uptake in bovine retinal outer segment fragments to triton-induced membrane disruption and to volume changes.

Light-induced proton uptake in bovine retinal outer segment (ROS) fragments was shown to be closely related to pH, salt concentration, membrane integrity, and perhaps secondarily to the volume of osmotic compartments. The principal findings were as follows: 1. As pH increased, both the discs and the plasmalemma swelled, and proton uptake markedly diminished. 2. As the discs were disrupted by increasing concentrations of Triton, proton uptake at slightly alkaline pH was supplanted by proton release. 3. Increasing the concentration of chloride salts caused increased H+ uptake roughly proportional to osmotic shrinkage of the ROS. Buffering by acetate prevented the measurement of proton uptake in the presence of acetate salts, although osmotic behavior of the ROS was similar to that observed in chloride salts. Although increasing the concentration of sucrose also resulted in osmotic shrinkage of the ROS, it was not accompanied by a systematic increase in the magnitude of proton uptake. 4. Light-induced H+ uptake was accompanied by small but reproducible changes in volume, probably of the discs. The magnitude and direction of these rapid volume changes were subject to influence by pH, solute, and other variables.     

Dissociation of 5' AMP-activated protein kinase activation and glucose uptake stimulation by mitochondrial uncoupling and hyperosmolar stress: differential sensitivities to intracellular Ca2+ and protein kinase C inhibition

2,4-dinitrophenol (DNP) compromises ATP production within the cell by disrupting the mitochondrial electron transport chain. The resulting loss of ATP leads to an increase in glucose uptake for anaerobic generation of ATP. In L6 skeletal muscle cells, DNP increases the rate of glucose uptake by twofold. We previously showed that DNP increases cell surface levels of glucose transporter 4 (GLUT4) and hexose uptake via a Ca2+-sensitive and conventional protein kinase C (cPKC)-dependent mechanism. Recently, 5' AMP-activated protein kinase (AMPK) has been proposed to mediate the stimulation of glucose uptake by energy stressors such as exercise and hypoxia. Changes in Ca2+ and cPKC have also been invoked in the stimulation of glucose uptake by exercise and hypoxia. Here we examine whether changes in cytosolic Ca2+ or cPKC lead to activation of AMPK. We show that treatment of L6 cells with DNP (0.5 mM) or hyperosmolar stress (mannitol, 0.6 M) increased AMPK activity by 3.5-fold. AMPK activation peaked by 10-15 min prior to maximal stimulation of glucose uptake. Intracellular Ca2+ chelation and cPKC inhibition prior to treatment with DNP and hyperosmolarity significantly reduced cell surface GLUT4 levels and hexose uptake but had no effect on AMPK activation. These results illustrate a break in the relationship between AMPK activation and glucose uptake in skeletal muscle cells. Activation of AMPK does not suffice to stimulate glucose uptake in response to DNP and hyperosmolarity.     

Fragmentation of chromatin by endogenous nucleases, accumulation of the subnucleosomal fragments with high electrophoretic mobility]

Digestion of chromatin by endogenous nucleases to nucleosomes (140-160 base pairs of DNA) is accompanied by the accumulation of subnucleosomal DNP particles with high electrophoretic mobility (20-40 base pairs of DNA). All histones associate with the 140-160 base pairs fragment. The production of subnucleosomal DNP particles does not correlate with the degradation of histone H1 and the appearance of nucleosomes lacking histone H1. Degradation of the protein in this fragment is accompanied by the appearance of free DNA. The data obtained are in agreement with the hypothesis on the origin of subnucleosomes from the nucleosomal locus preferentially associated with the non-histone proteins and on the autonomy of these loci and of the loci associated with histone H1 in the nucleosome.     

Bioenergetic aspects of aerobic glucose metabolism of Escherichia coli K-12 under varying specific growth rates and glucose concentrations.

An attempt was made to find a bioenergetical explanation for the differential effect of specific growth rate and glucose concentration on glucose metabolism of Escherichia coli K-12 with the help of 2,4-dinitrophenol (DNP). The effect of DNP on biomass occurred only at high glucose concentrations. The presence of this uncoupler strongly stimulated glucose uptake rates and oxygen uptake rates, but repressed severly Yg values. Increase in glucose concentration, however, sharply decreased QO2. The amount of oxygen required for maintenance was not affected by DNP, but Yomax values were much lower in the presence of DNP. The results are discussed and it is suggested that aerobic fermentation is caused by a severe reduction of site 1 of the respiratory chain region, whereas biomass formation is affected by repression of the terminal cytochrome a2. In comparing the effect of glucose on biomass formation at similar Qglucose levels aerobic and anaerobic fermentation, repression occurred in both cases at glucose concentrations of 0.3% and above. Although the analyses of 15 enzymes established the metabolic differences, the repression of growth was common to both fermentation types.     

Interactions Between Nitrate Assimilation and 2,4-Dinitrophenol Cometabolism in Rhodobacter capsulatus E1F1

The phototrophic, nitrate-photoassimilating bacterium Rhodobacter capsulatus E1F1 cometabolizes 2,4-dinitrophenol (DNP) by photoreducing it to 2-amino-4-nitrophenol under anaerobic conditions. DNP uptake and nitrate metabolism share some biochemical features, and in this article we show that both processes are influenced by each other. Thus, as was demonstrated for nitrate assimilation, DNP uptake requires a thermolabile periplasmic component. Nitrate assimilation is inhibited by DNP, which probably affects the nitrite reduction step because neither nitrate reductase activity nor the transport of nitrate or nitrite is inhibited. On the other hand, DNP uptake is competitively inhibited by nitrate, probably at the transport level, because the nitroreductase activity is not inhibited in vitro by nitrate, nitrite, or ammonium. In addition, the decrease in the intracellular DNP concentration in the presence of nitrate probably inactivates the nitroreductase. These results allow prediction of a negative environmental effect if nitrate and DNP are released together to natural habitats, because it may lead to a lower rate of DNP metabolism and to nitrite accumulation.     

Physical studies of chromatin. The recombination of histones with DNA.

Experiments have been carried out to define clearly which histone combinations can induce a higher order structure when combined with DNA. The criterion for a higher order structure being the series of low-angle X-ray diffraction maxima nominally at 5.5 nm, 3.7 nm, 2.7 nm and 2.2 nm. Such a pattern, with resolution similar to that of H1-depleted chromatin, is readily attainable by recombining histones H2A + H2B + H3 + H4 with DNA using a salt-gradient dialysis method. However, the use of urea in the recombination procedure is shown to be detrimental to the production of a higher order structure. Low-angle ring patterns are not obtained by recomgining DNA with single pure histones or any combination of histone pairs exept H3 + H4. The diffraction maxima from the latter are, however, weaker than those from chromatin and there are pronounced semi-equatorial arcs. The presence of a third histone, either H2A or H2B in the H3 + H4 recombination mixture tends to distort the recognised low-angle pattern. It is concluded that the histone pair H3 + H4 is essential for the formation of a regular higher order structure in chromatin, although for a complete structural development the presence of H2A + H2B is also required.     

Leucine transport coupled to proton movement in membrane vesicles from Chang liver cells

Leucine transport into membrane vesicles obtained from Chang liver cells was stimulated by an inward H+ gradient. The stimulatory effect of the proton gradient on the rate of leucine uptake (1 min) was inhibited by the presence of carbonyl cyanide p-trifluoromethoxyphenylhydrazone. When the vesicles had been preloaded with a high concentration of KCl, addition of valinomycin stimulated leucine uptake by the vesicles, showing that the leucine transport is dependent on potential gradient. Leucine-coupled H+ accumulation inside the vesicles was confirmed by measuring leucine dependent quenching of the fluorescence of 9-aminoacridine added to medium. These results imply that electrochemical gradient of proton can serve as a driving force for leucine transport across the cell membrane and proton movement is coupled to leucine transport.