Oligomerization is a necessary step in channel formation by the bacterial toxin aerolysin. We have identified a region of aerolysin containing two tryptophans which influence the ability of the protein to oligomerize. Changing the tryptophan at position 371 or 373 to leucine resulted in mutant proteins that oligomerized at much lower concentrations than the wild-type toxin. Near-ultraviolet circular dichroism measurements showed that the tertiary structures of the L-371 and L-373 mutant toxins may be slightly different from the structure of wild type. Other single amino acid replacements in the same region of the protein as the two tryptophans appeared to have little or no effect on any properties of the protein. None of the changes we made had any measured effect on secretion of the protein by the bacteria. The L-373 and L-371 proteins induced chloride release from liposomes at lower concentrations than native toxin. Wild-type aerolysin solutions were completely unable to cause release when oligomeric toxin was absent or when it was removed by centrifugation. Aerolysin changed at H-132, which cannot form oligomers, was also inactive against liposomes. We conclude that aerolysin channels are produced by direct insertion of oligomers formed in solution, or assembled on the surface of the cell after binding to the receptor, and not by lateral diffusion of the monomer after it enters the lipid bilayer.
Diffusional water permeability was measured in renal proximal tubule cell membranes by pulsed nuclear magnetic resonance using proton spin-lattice relaxation times (T1). A suspension of viable proximal tubules was prepared from rabbit renal cortex by Dounce homogenization and differential sieving. T1 measured in a tubule suspension (22% of exchangeable water in the intracellular compartment) containing 20 mM extracellular MnCl2 was biexponential with time constants 1.8 +/- 0.1 ms and 8.3 +/- 0.2 ms (mean +/- SD, n = 8, 37 degrees C, 10 MHz). The slower time constant, representing diffusional exchange of water between intracellular and extracellular compartments, increased to 11.6 +/- 0.6 ms (n = 6) after incubation of tubules with 5 mM parachloromercuribenzene sulfonate (pCMBS) for 60 min at 4 degrees C and was temperature dependent with activation energy Ea = 2.9 +/- 0.4 kcal/mol. To relate T1 data to cell membrane diffusional water permeabilities (Pd), a three-compartment exchange model was developed that included intrinsic decay of proton magnetization in each compartment and apical and basolateral membrane water transport. The model predicted that the slow T1 was relatively insensitive to apical membrane Pd because of low luminal/cell volume ratio. Based on this analysis, basolateral Pd (corrected for basolateral membrane surface convolutions) is 2.0 X 10(-3) cm/s, much lower than corresponding values for basolateral Pf (10-30 X 10(-3) cm/s) measured in the intact tubule and in isolated basolateral membrane vesicles. The measured P,/Pd> 1, low Ea and inhibition of Pd by pCMBS provide strong evidence that water transport in the proximal tubule basolateral membrane is facilitated by a specialized aqueous pore or narrow channel.
The regulation of cardiac electrical activity is critically dependent on the distribution of ion channels in the heart. For most ion channels, however, the patterns of distribution and what regulates these patterns are not well characterized. The most likely candidates for the genes that encode the cAMP- and swelling-activated chloride conductances in the heart are an alternatively spliced variant of CFTR and ClC-3, respectively. In this study we have 1) measured the density of CFTR and ClC-3 mRNA levels across the left ventricular free wall (LVFW) of the rabbit heart using in situ hybridization and 2) measured the corresponding current density of cAMP- and swelling-activated chloride channels in myocytes isolated from subepicardial, midmyocardial, and subendocardial regions of the LVFW. There was a highly significant gradient in the whole cell slope conductance of cAMP-activated chloride currents; normalized slope conductance at 0 mV was 15.7 +/- 1.8 pS/pF (n = 9) in subepicardial myocytes, 7.8 +/- 1.5 pS/pF (n = 11) in midmyocardial myocytes, and 4.9 +/- 1.1 pS/pF (n = 9) in subendocardial myocytes. The level of CFTR mRNA was closely correlated with the density of cAMP-activated chloride conductances in different regions of the heart, with the level of CFTR mRNA being three times higher in the subepicardium than in the subendocardium. The whole cell slope conductance of swelling-activated chloride channel activity, measured 3-5 min after the commencement of cell swelling, was higher in myocytes isolated from the subepicardium than in myocytes isolated from the midmyocardium or subendocardium. In contrast, there was a uniform expression of ClC-3 mRNA across the LVFW of the rabbit heart. These results suggest that the control of gene expression is an important contributor in regulating the distribution of cAMP-activated chloride channels in the rabbit heart but that it may be less important for the swelling-activated chloride channels.
The bacterial RNA polymerase sigma subunits are key participants in the early steps of RNA synthesis, conferring specificity of promoter recognition, facilitating promoter opening and promoter clearance, and responding to diverse transcriptional regulators. The T4 gene 55 protein (gp55), the σ protein of the bacteriophage T4 late genes, is one of the smallest and most divergent members of this family. Protein footprinting was used to identify segments of gp55 that become buried upon binding to RNA polymerase core, and are therefore likely to constitute its interface with the core enzyme. Site-directed mutagenesis in two parts of this contact surface generated gene 55 proteins that are defective in polymerase-binding to different degrees. Alignment with the sequences of the σ proteins and with a recently determined structure of a large segment of σ 70 suggests that the gp55 counterpart of σ 70 regions 2.1 and 2.2 is involved in RNA polymerase core binding, and that σ 70 and gp55 may be structurally similar in this region. The diverse phenotypes of the mutants implicate this region of gp55 in multiple aspects of σ function.
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