Photoelectric conversion by bacteriorhodopsin in charged synthetic membranes.

Photoelectroactivity of oriented purple membrane layers attached to an ion exchange film has been investigated. The action spectrum of the photocurrent followed the absorption spectrum of bacteriorhodopsin. The intactness of structure and function of bacteriorhodopsin was demonstrated by studies of absorption and photocycle kinetics. The direction of the photocurrent suggests that the extracellular surface of purple membrane is more positive. Photocurrents as high as 20 microA cm-2 were obtained in some preparations. The dependence of steady-state photocurrents on intensity of illumination and temperature was also studied. The initial rate of build-up of photocurrent depends linearly on the intensity of illumination while the off rate does not exhibit any dependence on the intensity of illumination. With rise in temperature an increase in the steady state photocurrent has been observed. This dependence was found to be linear when increase of the photocurrent due to proton translocation alone was considered.     

ATP synthesis catalyzed by the ATPase complex from Rhodospirillum rubrum reconstituted into phospholipid vesicles together with bacteriorhodopsin

The coupling factor ATPase complex extracted by Triton X-100 from the photosynthetic bacterium Rhodospirillum rubrum could be incorporated into phospholipid vesicles after removal of the Triton. Vesicles reconstituted with this F₀ · F₁-type ATPase together with bacteriorhodopsin were found to catalyze, in the light, net ATP synthesis which was inhibited by the energy transfer inhibitors oligomycin and N,N-dicyclohexylcarbodiimide as well as by uncouplers. In vesicles reconstituted with the crude ATPase up to 50% of the observed rate of phosphorylation was independent on light and bacteriorhodopsin and insensitive to the above-listed inhibitors. This dark activity was, however, completely blocked by the adenylate kinase inhibitor, p¹,p⁵-di(adenosine-5′)pentaphosphate, which did not affect at all the net light-dependent phosphorylation nor the ATP-³²P_i exchange reaction. Vesicles reconstituted with the purified ATPase catalyzed only the light- and bacteriorhodopsin-dependent diadenosine pentaphosphate-insensitive phosphorylation. The rate of this photophosphorylation was found to be proportional to the amount of ATPase and bacteriorhodopsin, and linear for at least 20 min of illumination. These results indicate that the purified ATPase contains the complete assembly of subunits required to transduce electrochemical gradient energy into chemical energy.     

Light-dependent rubidium transport in intact Halobacterium halobium cells

The uptake of rubidium in intact Halobacterium halobium cells was followed, and found to be light-dependent. The exchange process is slow, the steady-state rate of ⁸⁶Rb⁺/Rb⁺ exchange being given by k = 6.3 · 10^?4 min^?1. Starved cells exhibited a faster rate than unstarved cells. The influx of ⁸⁶Rb⁺ was almost completely blocked in the presence of proton conductors (CCCP, FCCP, and SF 6847), and was sensitive to the presence of the permeant cation TPMP⁺. Valinomycin very slightly increased the rate of uptake, while 1 · 10^?6 M nigericin showed significant inhibition. On the other hand, release of ⁸⁶Rb⁺ was not light-dependent, although still affected by uncouplers, TPMP⁺, and nigericin. These experimental observations may be explained in terms of a passive flux driven by an electrical potential difference, and influenced by positive isotope interaction within the membrane. In carefully matched influx-efflux studies, the extent of the positive isotope interaction was measured. Using the formal treatment of Kedem and Essig, the ratio (exchange resistance)/(resistance to net flow) for ⁸⁶Rb⁺ was found to be 1.7.     

Na+-coupled Cl− transport in the gastric mucosa of the guinea pig

The Cl^–/HCO ₃ ^– exchange mechanism usually postulated to occur in gastric mucosa cannot account for the Na⁺-dependent electrogenic serosal to mucosal Cl^– transport often observed. It was recently suggested that an additional Cl^– transport mechanism driven by the Na⁺ electrochemical potential gradient may be present on the serosal side of the tissue. To verify this, we have studied Cl^– transport in guinea pig gastric mucosa. Inhibiting the (Na⁺, K⁺) ATPase either by serosal addition of ouabain or by establishing K⁺-free mucosal and serosal conditions abolished net Cl^– transport. Depolarizing the cell membrane potential with triphenylmethylphosphonium (a lipid-soluble cation), and hence reducing both the Na⁺ and Cl^– electrochemical potential gradients, resulted in inhibition of net Cl^– flux. Reduction of short-circuit current on replacing Na⁺ by choline in the serosal bathing solution was shown to be due to inhibition of Cl^– transport. Serosal addition of diisothiocyanodisulfonic acid stilbene (an inhibitor of anion transport systems) abolished net Cl^– flux but not net Na⁺ flux. These results are compatible with the proposed model of a Cl^–/Na⁺ cotransport mechanism governing serosal Cl^– entry into the secreting cells. We suggest that the same mechanism may well facilitate both coupled Cl^–/Na⁺ entry and coupled HCO ₃ ^– /Na⁺ exit on the serosal side of the tissue.     

Role of α-Factor and the Mfα1 α-Factor Precursor in Mating in Yeast

The peptide pheromones secreted by a and α cells (called a-factor and α-factor, respectively) are each encoded by two structural genes. For strains of either mating type, addition of exogenous pheromone does not alleviate the mating defect of mutants with disruptions of both structural genes. In addition, a particular insertion mutation in the major α-factor structural gene (MFα1) that should result in an altered product inhibits α mating. These results suggested that the pheromone precursors (the MFα1 pro region in particular) might play a second role in mating separate from the role of pheromone production. To analyze the role of α-factor and the MFα1 precursor in α mating, we have constructed two classes of mutants. The mating defects of mutants that should produce the MFα1 pro region peptide but no α-factor could not be alleviated by addition of exogenous α-factor in crosses to a wild-type a strain, indicating that the previous results were not due to an inability of the disruption mutants to produce the pro region peptide. Mutants able to produce α-factor, but with a variety of alterations in MFα1 precursor structure, mated at levels proportional to the levels of α-factor produced, suggesting that the only role of the α-factor precursor in mating is to produce α-factor. Both of these results argue against a role for the MFα1 pro region separate from its role in α-factor production. We also describe results that show that in vivo production of α-factor'' (the form of α-factor encoded by one of the two α-factor repeats of MFα2) is equivalent to the major form of α-factor for induction of all responses necessary for mating. We discuss the implications of these results on the role of the pheromones in mating.     

Glycosylation and structure of the yeast MF alpha 1 alpha-factor precursor is important for efficient transport through the secretory pathway

The MF alpha 1 gene encodes a precursor, prepro-alpha-factor, that undergoes several proteolytic processing steps within the classical secretory pathway to produce the mature peptide pheromone, alpha-factor. To investigate the role of structural features of the MF alpha 1 precursor in alpha-factor production, we analyzed the effect of mf alpha 1 mutations that alter precursor structure in a number of ways. These mutations resulted in decreased alpha-factor secretion and intracellular accumulation of pro-alpha-factor. With the exception of the mutant lacking all three N glycosylation sites, the pro-alpha-factor forms that accumulated were core glycosylated but had not yet undergone the addition of outer chain carbohydrate. The delay, therefore, occurred at a step prior to the first proteolytic processing step involved in maturation of the precursor and was probably due to inefficient endoplasmic reticulum-to-Golgi transport. Elimination of all three N-glycosylation sites caused a delay in disappearance of intracellular precursor, and alpha-factor secretion was also slowed. These data indicate that N glycosylation is important but not essential for transport of the precursor through the secretory pathway. The decreased alpha-factor secretion and increased precursor accumulation seen with many different structural changes of pro-alpha-factor indicate that the secretory pathway is extremely sensitive to changes in precursor structure. This sensitivity could cause inefficient secretion of heterologous proteins and hybrids between MF alpha 1 and heterologous proteins in yeast cells.     

YDJ1p facilitates polypeptide translocation across different intracellular membranes by a conserved mechanism.

The role of S. cerevisiae YDJ1 protein (YDJ1p) in polypeptide translocation across membranes has been examined. A conditional ydj1 mutant strain (ydj1-151TS) is defective for import of several polypeptides into mitochondria and alpha factor into the endoplasmic reticulum at 37 degrees C. These defects are suppressed by E. coli dnaJ or overexpression of S. cerevisiae SIS1 proteins. A different ydj1 mutant, which cannot be farnesylated (ydj1-S406), displays similar transport defects to the ydj1-151 strain. Furthermore, the ability of purified ydj1-151p to stimulate the ATPase activity of hsp70SSA1 was greatly diminished compared with the wild-type protein. Together, these data suggest that YDJ1p functions in polypeptide translocation in a conserved manner, probably acting at organelle membranes and in association with hsp70 proteins.