Enzymatic function in crystals of delta 5-3-ketosteroid isomerase. Catalytic activity and binding of competitive inhibitors

Crystals of the steroid-metabolizing enzyme, delta 5-3-ketosteroid isomerase (EC 5.3.3.1) from Pseudomonas testosteroni, exhibit many enzymatic properties. Each enzyme subunit in the lattice binds a competitive inhibitor, progesterone, with the same stoichiometry (1:1) and affinity (KD = 6 X 10(-6) M) as the enzyme in solution. Another competitive inhibitor, 19-nortestosterone, competes with progesterone for the same binding sites in the crystal. The enzyme crystals catalyze the conversion of delta 5- to delta 4-ketosteroids, but because the enzyme is so efficient, and substrate diffusion into the crystal is so slow, substrate cannot penetrate deeply into the crystal before being converted to product. A general theoretical formulation is presented to account for the effects of substrate diffusion into enzyme crystals of different shapes and sizes. The dependence of apparent mean enzyme activity in steroid isomerase crystals as a function of crystal size is shown to be consistent with this theoretical formulation. These inhibitor binding and catalytic properties suggest that the enzyme is in an active conformation within these crystals.     

Rubidium transport in X-irradiated human erythrocytes

Outflow of 86Rb, a radioactive analogue of potassium, from human erythrocytes X-irradiated in vitro was studied with the following results. (1) The 86Rb level in the supernatants of irradiated and control cell suspensions reflected mainly 86Rb outflow and much less its active re-uptake. (2) The effect of irradiation on 86Rb outflow was more pronounced at a low temperature (4 degrees C) than at 37 degrees C; the lowest dose of X-radiation exhibiting a significant effect on 86Rb outflow at 4 degrees C was 2.5 Gy. (3) K/Rb exchange did not seem to play an appreciable role in radiation-induced 86Rb outflow. (4) Calcium and its accumulation in irradiated cells was not found to be the cause of the effect of radiation on 86Rb outflow. (5) The effect of radiation on 86Rb outflow was higher in low Na medium but it was not inhibited by bumetanide. Rb/Na counter- or co-transport do not therefore seem to be involved in radiation-induced Rb+ outflow.     

Proton extrusion inSaccharomyces cerevisiae mutants in very dilute suspensions

Substrate-induced H⁺ extrusion was studied in dilute (0.04–0.5 mg dry mass per mL) unbuffered suspensions ofS. cerevisiae. Wild-type strains 196-2 and K and 196-2-derived mutants altered in hexose transport, glucosephosphate isomerase, mannosephosphate isomerase, pyruvate kinase, and arho petite mutant were characterized as to growth, biochemical and H⁺-pumping properties. Their H⁺ extrusion differed, depending on strain, growth conditions, and the H⁺-efflux-inducing substrate; the efficiency of the process depended critically on the balance between substrate uptake, its dissimilation, attendant mobilization of energy sources and build-up of acidity sources in the cell, and the energy supply to H⁺excreting systems.     

Functional inferences from crystals of Escherichia coli trp repressor

We have reproducibly grown crystals of L-tryptophan . trp aporepressor and indole-3-propionate . trp aporepressor complexes from Escherichia coli which are suitable for x-ray diffraction analysis. The active repressor, L-tryptophan . aporepressor, crystallizes in both trigonal (P3(1)21 or P3(2)21) and tetragonal (P4(1)22 or P4(3)22) forms which diffract to at least 2.0 and 2.5 A, respectively. The trigonal form has one-half of the functional dimer/asymmetric unit; therefore, the trp repressor molecule has an axis of 2-fold rotational symmetry corresponding to the lattice dyad. The inactive complex, indole-3-propionate . aporepressor, or "pseudorepressor," forms tetragonal crystals that also diffract to at least 2.5 A and are isomorphous to those of the active repressor. Slight differences between their diffraction patterns indicate modest structural differences between active and inactive complexes that are presumably mediated by the alpha-amino group of L-tryptophan and account for operator-specific binding.     

Stereochemical effects of L-tryptophan and its analogues on trp repressor's affinity for operator-DNA

We have employed a filter binding assay to help study the mechanism by which bound L-tryptophan enables the Escherichia coli trp repressor to bind its operators. We have prepared variants of the trp repressor using structural analogues of the natural corepressor, L-tryptophan, and measured the affinity of these variants for a 20-base pair oligonucleotide duplex containing a symmetrical idealization of the trp operator from the E. coli trpEDCBA operon. By normalizing for each analogue's previously determined affinity for the trp aporepressor, we have estimated the extent to which each of the functional groups of bound L-tryptophan contributes to operator affinity. We discuss the likely role of these functional groups in the context of the crystal structures of the inactive, unliganded trp aporepressor, the liganded, active repressor, an inactive pseudorepressor (Pseudorepressors are formed by analogues of L-tryptophan that bind at the tryptophan-binding site but form near isomorphs of the repressor that have poor affinity for operator-DNA.) and the trp repressor/operator complex. We find that the alpha-amino group and an unsubstituted amino (-NH-) nitrogen of L-tryptophan's indole ring are essential for operator affinity. The former properly orients the corepressor and the latter interacts directly with the DNA. The alpha-carboxyl group, on the other hand, greatly enhances but is not essential for operator binding. The alpha-carboxylate's role, which is dependent on the corepressor's orientation in the binding pocket, is apparently to position the guanidinium group of Arg-84 for favorable contacts with the operator's sugar-phosphate backbone.     

Three fluorescent probes for the flow-cytometric assessment of membrane potential inSaccharomyces cerevisiœ

Three fluorescent probes, tetramethyl rhodamine ethyl ester (TMRE), 3,3′-dipropylthiacarbocyanine iodide (diS-C₃(3)) and 3,3′-dipropyloxacarbocyanine iodide (diO-C₃(3)), were tested for their suitability as fluorescent indicators of membrane potential inSaccharomyces cerevisiœ in studies performed by flow cytometry. For all these dyes the intensity of fluorescence of stained cells increased with probe concentration in the range of 60–3000 nmol/L. The optimum staining period was 15–20 min for diS-C₃(3). Depolarization of cells by increased extracellular potassium level and by valinomycin elicited with all probes a drop in fluorescence intensity. In some yeast batches this depolarization was accompanied by a separation of subpopulations with different fluorescence properties.     

Effect of hydrogen peroxide on sugar transport inSchizosaccharomyces pombe. Absence of membrane lipid peroxidation

Stationary unaerated cells ofS. pombe containing endogenous substrates but not energized by any exogenous ones take up 2-deoxy-d-glucose, 6-deoxy-d-glucose,d-xylose andd-arabinose actively over diffusion equilibrium. The active uptake is inhibited by 20–100 mmol/L H₂O₂ which causes an increase inK _T but has no effect onJ _max. This “competitive inhibition” indicates that H₂O₂ affects directly the sugar binding sites of the transporters. The ATP-binding site of the plasma membrane H⁺-ATPase is also affected by 100 mmol/L H₂O₂; theK _T decreases 7-fold,J _max about 2.5-fold. These effects are not likely to be mediated by membrane lipid peroxidation which appears to be lacking inS. pombe, and this lack may be one of the reasons for the high resistance of this yeast to H₂O₂. Because of thisS. pombe represents a suitable system for studying direct effects of oxidants on membrane proteins.     

Effects of pH and calcium ion on self-association properties of two dimeric phospholipases A2

The monomer-dimer equilibria of the dimeric phospholipases A2 from Crotalus atrox and Agkistrodon piscivorus piscivorus venoms were examined chromatographically as a function of pH and in the presence versus absence of the essential cofactor, calcium ion. At neutral pH without calcium, the subunits of both enzymes reequilibrated sufficiently slowly that dimer and monomer were separated by size exclusion chromatography. At pH 4.2 and lower, the dimers underwent rapid dissociation and reassociation, eluting as single broad peaks whose position as a function of applied protein concentration could be analyzed to determine association constants using an algorithm that estimates these values based on elution positions. Lowering the pH from 7.0 to 4.2 increased the self-association constant of the C. atrox enzyme by 1 order of magnitude and that of the A. p. piscivorus dimer by a factor of 3. Calcium ion, an essential cofactor of phospholipase A2, converted the kinetic behavior of the dimers at neutral pH from slow to virtually instantaneous on the time scale of the chromatography runs, 40 min. Calcium ion also altered the thermodynamic stability of the enzymes; the association constant of A. p. piscivorus phospholipase A2 in neutral pH buffer was reduced by approximately 2 orders of magnitude, whereas that of C. atrox was increased by a factor of 6. The structural basis for the disparate effects of calcium ion on these two acidic, dimeric venom phospholipases A2 is uncertain. This study illustrates the importance of calcium ion and pH on the solution behavior of the dimeric members of this class of enzymes.