Interactions of bacteriophage T4-coded gene 32 protein with nucleic acids: III. Binding properties of two specific proteolytic digestion products of the protein (G32P1I and G32P1III)

Brief treatment of gene 32 protein with proteolytic enzymes produces two specific digestion products in good yield (Moise & Hosoda, 1976). One, representing the native protein with ~60 amino acid residues removed from the C-terminus, is G32P¹I. The other, for which ~20 amino acid residues have been removed from the N-terminus in addition to the 60 residues from the C-terminus, is G32P¹III. Both of these specific “core” fragments of gene 32 protein have been isolated and purified, and their binding properties to single-stranded oligo- and polynucleotides have been studied. We find that the binding properties of G32P¹I are relatively little changed from those characteristic of the native gene 32 protein: (1) the apparent binding constants to short (l = 2 to 8) oligonucleotides are independent of lattice length and essentially independent of base and sugar composition, but do show an increased salt dependence of binding relative to that of the native protein; (2) the intrinsic association constants (K) for polynucleotides binding in the co-operative mode show the same binding specificities as seen with the native protein, but with absolute values increased two to fourfold; (3) the polynucleotide binding co-operativity parameter (ω^?2 × 10³) and the binding site size (n ～-7 nucleotide residues) are the same as for the native protein; (4) essentially the entire salt dependence of the net affinity (Kω) remains in K. However, unlike native gene 32 protein, G32P¹I can melt native DNA to equilibrium (Hosoda et al., 1974; Greve et al., 1978); this suggests that the kinetic pathways for DNA melting by these two species must differ, since the changes in equilibrium binding parameters measured here are far too small to account for the differences in melting behavior. In contrast to G32P¹I, for G32P¹III we find that: (1) binding is non-cooperative (ω ～-1); (2) the binding site size (n) for the protein has decreased by one to two nucleotide residues relative to that characteristic of the native protein and G32P¹I; (3) binding to short (l = 2 to 8) oligonucleotides is length and salt concentration dependent; (4) while binding to polynucleotides continues to show approximately the same base composition dependence as the native protein, the absolute values of K are somewhat different and the salt concentration dependencies of K are less. Polynucleotide ultraviolet light and circular dichroism spectra obtained in the presence of G32P¹I and G32P¹III are indistinguishable from those measured with the native protein at similar binding densities, indicating that all three protein species distort the polynucleotide lattice to comparable extents.These results are combined with the equilibrium binding data for native gene 32 protein (Kowalczykowski et al., 1980a: Newport et al., 1980) to obtain further insight into the molecular details of the interactions of this protein with its nucleic acid binding substrates.     

Interactions of bacteriophage T4-coded gene 32 protein with nucleic acids: II. Specificity of binding to DNA and RNA

In this paper we examine the specificity of the co-operative binding (in the polynucleotide mode) of bacteriophage T4-coded gene 32 protein to synthetic and natural single-stranded nucleic acids differing in base composition and sugar type. It is shown by competition experiments in a tight-binding (low salt) environment that there is a high degree of binding specificity under these (protein-limiting) conditions, with one type of nucleic acid lattice binding gene 32 protein to saturation before any binding to the competing lattice takes place; it is also shown that the same differential specificities apply at high salt concentrations. Procedures developed in the preceding paper (Kowalczykowski et al., 1980) are used to measure the net binding affinities (Kω) of gene 32 protein to a variety of polynucleotides, as well as to determine individual values of K and ω for some systems. For all polynucleotides, virtually the entire specificity and salt dependence of binding of Kω appears to be in K. In ~0.2 m-NaCl, the net binding affinities (Kω) range from ~10⁶ to ~10¹¹m^?1; in order of increasing affinities we find: poly(rC) < poly(rU) < poly(rA) < poly(dA) < poly(dC) < poly(dU) < poly(rI) < poly(dI) < poly-(dT). In general, Kω for a particular homopolyribonucleotide at constant salt concentration is 10¹ to 10⁴smaller than Kω for the corresponding homopoly-deoxyribopolynucleotide. Values of Kω for randomly copolymerized polynucleotides and for natural DNA fall at the compositionally weighted average of the values for the individual homopolynucleotides (except for poly(dT), which appears to bind somewhat tighter), indicating that the net affinity represents the sum of the binding free energy contributions of the individual nucleotides. It is shown that these results, on a competition basis under physiological salt conditions, can account quantitatively for the autogenous regulation of the synthesis of gene 32 protein at the translational level (Russel et al., 1976; Lemaire et al., 1978). In addition, these results suggest possible mechanisms by which gene 32 messenger RNA might be specifically recognized (by gene 32 protein) and functionally discriminated from the other mRNAs of phage T4.     

Fluorescence studies of the complex formation between the gene 5 protein of bacteriophage M13 and polynucleotides

The binding characteristics of the interaction of gene 5 protein with polynucleotides, i.e. poly(dA), poly(dT) and M13 DNA, have been determined by following the quenching of the protein fluorescence. In general, the binding is highly co-operative and for the binding of the protein to poly(dA) and M13 DNA the co-operativity parameter ω is estimated to have values between 50 and 300. Under comparable experimental conditions, the intrinsic binding constant K_int is at least two orders of magnitude higher for poly(dT) than for poly(dA), while the value for M13 DNA is intermediate. For poly(dA), the binding has been studied as a function of ionic strength and temperature. From these experiments it can be concluded that ionic interactions as well as van der Waals interactions (e.g. stacking interactions) are important for the complex formation of the protein with polynucleotides. From a comparison of the binding of the protein to poly(dA) and poly(dT), it is concluded that stacking interactions in the polynucleotide have a negative influence on protein binding. This conclusion, in conjunction with the weak temperature dependence of K_int. indicates that ionic interactions play a major role in the stabilization of the protein-poly(dA) complex. The co-operativity factor ω is little or not dependent on the ionic strength or the type of polynucleotide involved in binding. It is determined by interactions between complexed protein molecules. These interactions are primarily non-electrostatic.The binding characteristics obtained for the gene 5 protein-polynucleotide complexes are compared with those we have found for the binding to small oligonucleotides. It appears that oligonucleotide and polynucleotide binding differ in many aspects; i.e. there is a difference in K_int, ω and the number of nucleotides covered. The validity of linear lattice binding theories is discussed in this context. By comparing the binding parameters found for the gene 5 protein with those of the Escherichia coli DNA binding protein I. it is possible to explain the displacement of the E. coli protein by the gene 5 protein that occurs in vivo.     

Gene 5 protein of bacteriophage fd: A dimer which interacts Co-operatively with DNA

Isolated gene 5 protein from bacteriophage fd-infected Escherichia coli has been shown by sedimentation equilibrium to exist primarily as a dimer under non-denaturing conditions. The dimer was stable under conditions of high ionic strength, extremes in pH, dilution to 0.075 mg/ml, and increased temperature. Gene 5 protein did not undergo the indefinite self-association observed with gene 32 protein.Three lines of evidence for co-operative binding of gene 5 protein to DNA were developed. First, the interaction between gene 5 protein and phage T4 DNA was examined using a nitrocellulose filter assay. Scatchard plots of the binding data indicated that the interaction was co-operative. Similar results were obtained with gene 32 protein. Second, the co-operative binding of both proteins to DNA was shown by the sensitivity of the protein-DNA interaction to increasing ionic strength at various ratios of protein to DNA. Finally, by using the cross-linking agent, dimethyl suberixmidate, oligomeric structures containing at least seven monomers were found when the DNA was less than saturated.The possibility that gene 5 protein dimers undergo indefinite self-association in the presence of oligonucleotides was examined by sedimentation equilibrium. With oligo[d(pT)₄], the protein dimer was complexed with this oligonucleotide but no self-association was observed. With oligo[d(pT)₈], gene 5 protein formed tetramers, but no significant indefinite association was noted. These results do not suggest a DNA-induced conformational change, which results in indefinite association. A model for the co-operative binding of gene 5 protein to DNA is presented.     

Thermodynamics and kinetics of co-operative protein-nucleic acid binding: II. Studies on the binding between protamine and calf thymus DNA

Unspecific binding of a protamine, namely fluorescein-labelled clupeine Z, to double-stranded calf thymus DNA was studied using fluorescence titration methods and chemical relaxation techniques. Both equilibrium and kinetic data have been analysed using general theoretical approaches discussed in the accompanying paper. The results agree well with the predictions made on the basis of a standard co-operative binding model.Basic parameters evaluated are the co-operative binding constant (K), the coefficient measuring co-operative interaction between nearest neighbours (q), the number of nucleotides occupied by one protamine molecule (n) and the rate constant of dissociation at the ends of bound ligand sequences (K_D). Values obtained at 20 °C, pH 7.5 and 0.4 m-NaCl were K = 5.8 × 10⁷m^?1, q = 1700, n = 20 and K_D = 0.29 s^?1. They have been found to be sensitive to the concentration of added salt (NaCl). This effect apparently reflects the essentially electrostatic nature of the binding process. The results can be satisfactorily described in terms of competitive binding of sodium ions.     

DNA-binding properties of gene-5 protein encoded by bacteriophage M13. 2. Further characterization of the different binding modes for poly- and oligodeoxynucleic acids

The binding of gene-5 protein, encoded by bacteriophage M13, to oligodeoxynucleic acids was studied by means of fluorescence binding experiments, fluorescence depolarization measurements and irreversible dissociation kinetics of the protein.nucleotide complexes with salt. The binding properties thus obtained are compared with those of the binding to polynucleotides, especially at very low salt concentration. It appears that the binding to oligonucleotides is always characterized by a stoichiometry (n) of 2-3 nucleotides/protein, and the absence of cooperativity. In contrast the protein can bind to polynucleotides in two different modes, one with a stoichiometry of n = 3 in the absence of salt and another with n = 4 at moderate salt concentrations. Both modes have a high intramode cooperativity (omega about 500) but are non-interacting and mutually exclusive. For deoxynucleic acids with a chain length of 25-30 residues a transition from oligonucleotide to polynucleotide binding is observed at increasing nucleotide/protein ratio in the solution. The n = 3 polynucleotide binding is very sensitive to the ionic strength and is only detectable at very low salt concentrations. The ionic strength dependency per nucleotide of the n = 4 binding is much less and is comparable with the salt dependency of the oligonucleotide binding. Furthermore it appears that the influence of the salt concentration on the oligonucleotide binding constant is to about the same degree determined by the effect of salt on the association and dissociation rate constants. Model calculations indicate that the fluorescence depolarization titration curves can only be explained by a model for oligonucleotide binding in which a protein dimer binds with its two dimer halves to the same strand. In addition it is only possible to explain the observed effect of the chain length of the oligonucleotide on both the apparent binding constant and the dissociation rate by assuming the existence of interactions between protein dimers bound to different strands. This results in the formation of a complex consisting of two nucleotide strands with protein in between and stabilized by the dimer-dimer interactions.     

Kinetics and mechanism of the association of the bacteriophage T4 gene 32 (helix destabilizing) protein with single-stranded nucleic acids. Evidence for protein translocation

We have investigated the association kinetics of the co-operatively binding T4-coded gene 32 (helix destabilizing) protein with a variety of single-stranded homopolynucleotides (both RNA and DNA). Stopped-flow mixing experiments were performed by monitoring the partial quenching of the intrinsic tryptophan fluorescence of the protein upon binding to the nucleic acid under conditions where the nucleic acid concentration is in great excess over the protein concentration. Investigations of the association rate (and rate constants) as a function of solution variables has demonstrated quite different behavior at the extremes of “low” and “high” salt concentration. Under low salt (high binding constant) conditions the non-co-operative association is rate-limiting and we measure a bimolecular rate constant of 3 × 10⁶ to 4 × 10⁶ m^?1 (nucleotide)s^?1 (0·1 m-NaCl, 25·0 °C). However, at higher salt concentrations (lower binding constant) a pre-equilibrium involving non-co-operatively bound protein is established, followed by the rate-limiting formation of co-operatively bound protein clusters.Based on these observations we have proposed a mechanism for the formation of co-operatively bound T4 gene 32 protein clusters, under conditions of low binding density, which consists of three steps: (1) pre-equilibrium formation of non-co-operatively bound protein (nucleation); followed by (2) association of free protein to the singly contiguous sites established in the nucleation step, hence forming the first co-operative interactions (growth step); and (3) a redistribution of the growing protein clusters to form the final equilibrium distribution. From comparisons of our experimental values of the forward rate constant for the second step (growth of clusters) with theoretical estimates based on the work of Berg &; Blomberg (1976,1978) we infer that the T4 gene 32 protein is able to translocate along singlestranded polynucleotides. The implications of these results for the in vivo action of the T4 gene 32 protein are discussed.     

Nucleic acid binding properties of Escherichia coli ribosomal protein S1. I. Structure and interactions of binding site I.

Escherichia coli ribosomal protein S1 plays a central role in initiation of protein synthesis, perhaps via participation in the binding of messenger RNA to the ribosome. S1 protein has two nucleic acid binding sites with very different properties: site I binds either single-stranded DNA or RNA, while site II binds single-stranded RNA only (Draper et al., 1977). The nucleic acid binding properties of these sites have been explored using the quenching of intrinsic protein fluorescence which results from binding of oligo- and polynucleotides, and are reported in this and the accompanying paper (Draper &; von Hippel, 1978).Site I has been studied primarily using DNA oligomers and polymers, and has been found to have the following properties. (1) The intrinsic binding constant (K) of site I for poly(dA) and poly(dC) is ~3 × 10⁶m^?1 at 0.12 m-Na⁺, and the site size (n, the number of nucleotide residues covered per S1 bound) is 5.1 ± 1.0 residues. (2) Binding of site I to polynucleotides is non-co-operative. (3) The K value for binding of S1 to single-stranded polynucleotides is ~10³ larger than K for binding to double-stranded polynucleotides, meaning that S1 (via site I) is a potential “melting” or “double-helix destabilizing” protein. (4) The dependence of log K on log [Na⁺] is linear, and analysis of the data according to Record et al. (1976) shows that two basic residues in site I form charge-charge interactions with two DNA phosphates. In addition, a major part of the binding free energy of site I with the nucleic acid chain appears to involve non-electrostatic interactions. (5) Oligonucleotides bound in site II somewhat weaken the binding affinity of site I. (6) Binding affin is virtually independent of base and sugar composition of the nucleic acid ligand; in fact, the total absence of the base appears to have little effect on the binding, since the association constant for 2′-deoxyribose 5′-phosphate is approximately the same as that for dAMP or dCMP. (7) Two molecules of d(ApA) can bind to site I, suggesting the presence of two “subsites” within site I. (8) Iodide quenching experiments with S1-oligonucleotide complexes show differential exposure of tryptophans in and near the subsites of site I, depending upon whether neither, one, or both subsites are complexed with an oligonucleotide.     

Specificity of the Binding of Bacteriophage M13 Encoded Gene-5 Protein to DNA and RNA Studied by Means of Fluorescence Titrations

Abstract

The fluorescence quenching of the bacteriophage M13 encoded gene-5 protein was used to study its binding characteristics to different polynucleotides. Experiments were performed at different salt concentrations and in some instances at different temperatures. The affinity of the protein depends on the base and sugar composition of the polynucleotides involved and may differ appreciably, i.e. by orders of magnitude. The salt dependence of binding is within experimental accuracy equal for all single stranded polynucleotides. A method is presented to estimate values of the cooperativity constant from salt titration curves. These values are systematically higher than those obtained from titration experiments in which protein is added to a polynucleotide solution. A comparison is made between the binding constants of the gene-5 protein and the gene-32 protein encoded by the T4 phage. Possible implications of the binding characteristics of the gene-5 protein for an understanding of its role in vivo are discussed.     

4-Azidophlorizin,a high affinity probe and photoaffinity label for the glucose transporter in brush border membranes

A new phlorizin derivative ($\text{2′-O-(β-}\text{d}\text{-}\text{glucopyranosyl}\text{)-4-}\text{azidophloretin}$, 4-azidophlorizin) has been synthesized and its affinity for the d-glucose, Na⁺ co-transport system in brush border vesicles from intestinal and renal membranes has been compared with that of phlorizin. The extent of the reversible interaction of the ligand with the transporter in dim light has been evaluated from three separate measurements: (1) K′_i, the constant for fully-competitive inhibition of (Na⁺, Δψ)-dependent d-glucose uptake, (2) K′_d, the dissociation constant of 4-azido[³H]phlorizin binding in the presence of an NaSCN inward gradient, and (3) K″_i, the constant for fully-competitive inhibition of the specific ((Na⁺, Δψ)-dependent, d-glucose protectable) high-affinity [³H]phlorizin binding. In experiments with vesicles derived from rat kidney, all three constants (K′_i, K′_d and K″_i) were essentially equal and ranged between 3.2 and 5.2 μM, that is, the azide derivative has almost the same affinity for this transporter as phlorizin itself. On the other hand, compared to phlorizin, the 4-azidophlorizin has a lower affinity for the transporter in vesicles prepared from rabbit; its K′_i values are some 15–20-times larger than those determined with rat membranes. However, the affinity of the azide for the sugar transporter in membranes from either the intestine or kidney of the same animal species (rabbit or rat) was essentially the same. In spite of the lower affinity for the transporter in either membrane system from the rabbit, results described elsewhere (Hosang, M., Gibbs, E.M., Diedrich, D.F. and Semenza, G. (1981) FEBS Lett., 130, 244–248) indicate that 4-azidophlorizin is an effective photoaffinity label in this species also. Photolysis of the azide yields a reactive intermediate which reacts with a 72 kDa protein in rabbit intestine brush borders. Covalent labeling of this protein occurred under conditions which suggests that it is (a component of) the glucose transporter.     

Mechanism of action of a wound-induced omega-hydroxyfatty acid:NADP oxidoreductase isolated from potato tubers (Solanum tuberosum L).

ω-Hydroxyfatty acid:NADP oxidoreductase, an enzyme involved in suberin biosynthesis, is induced by wounding potato tubers. Initial velocity and product inhibition studies with the purified enzyme suggested an ordered sequential mechanism, where NADPH is added first, followed by 16-oxohexadecanoate, and NADP is released after 16-hydroxyhexadecanoate. Substrate inhibition by NADPH was observed at concentrations higher than 0.2 mm. The inhibitory NADPH molecule competes with 16-oxohexadecanoate, indicating that it forms a dead-end complex with the E-NADPH form of the enzyme. The kinetics for the NADPH inhibition suggested that n > 1 in the rate equation $\text{v}\text{=}\text{V[NADPH]}\text{(K}{}_{\mathrm{m}}\text{+}\text{[NADPH]}\text{+}\text{[NADPH]}{}^{\mathrm{n+1}}\text{K}{}_{\mathrm{i}}\text{)}$; i.e., more than two NADPH molecules bind to enzyme. The K_m for 16-oxohexadecanoate did not change from pH 7.5 to 9.0 but increased about 10-fold from pH 9.0 to 10.0, whereas the K_m for NADPH and hexadecanal did not vary significantly in this pH range. Phenylglyoxal inactivated the enzyme; NADPH and AMP (which competes with NADPH; K_i = 1.1 mM) provided protection against such inactivation. Diethylpyrocarbonate also caused inactivation which was reversed by hydroxylamine; NADPH but not AMP protected the enzyme from this inhibition. Pyridoxal-5′-phosphate reversibly inactivated the enzyme and NaBH₄ reduction of the pyridoxal phosphate-treated enzyme resulted in irreversible inhibition; a combination of NADPH and ω-oxo C₁₆ acid provided protection against such inactivation. As the chain length of alkanals increased from C₃ to C₈, the K_m for the substrate decreased drastically from 7000 to 90μm and a further increase in chain length from C₈ to C₂₀ resulted in only a small decrease in K_m. The K_m and V for 8-oxooctanoate and 10-oxodecanoate are compared with the values obtained for 16-oxohexadecanoate. Based on these results, it is proposed that arginine acts as the binding site for NADPH, a hydrophobic crevice with lysine at the bottom forms the binding site for 16-oxohexadecanoate and histidine participates in the reaction as the proton donor.     

Phosphate transport in Neurospora: Kinetic characterization of a constitutive,low-affinity transport system

Log-phase cells of Neurospora crassa, grown in standard minimal medium, possess an energy-dependent transport system for inorganic phosphate, with a $\text{K}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ (at pH 5.8) of 0.123 mM and a J_max of 1.64 mmoles/l cell water per min. Like the PO₄^3? transport system in yeast, the Neurospora system is stimulated by high intracellular K⁺. In addition, it is inhibited by high extracellular salt concentrations, an effect which may be related to the known depolarization of the Neurospora plasma membrane at high salt concentrations.The most striking property of the system is its strong dependence upon the extracellular pH. From pH 4.0 to pH 7.3, the J_max remains essentially constant but the $\text{K}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ increases nearly 400-fold, from 0.01 to 3.62 mM. The increase cannot be accounted for by a single system with a preference for H₂PO₄^? (which would show only a 3-fold increase in apparent $\text{K}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ over this pH range) nor by two systems with different affinities and pH optima (which would display nonlinear double-reciprocal plots at intermediate pH values). It can be explained, however, by a model in which OH^? or H⁺ is assumed to act as a modifier of the transport system, altering its affinity for substrate.     

Interaction of manganese with fragments, complementary fragment recombinations, and whole molecules of yeast phenylalanine specific transfer RNA

Binding of Mn²⁺ to the whole molecule, fragments and complementary fragment recombinations of yeast tRNA^Phe, and to synthetic polynucleotides was studied by equilibrium dialysis. The comparison of the binding patterns of the fragments, fragment recombinations and synthetic polynucleotides with that of intact tRNA^Phe permits reasonable conclusions concerning the nature and location of the various classes of sites on tRNA^Phe. Binding of Mn²⁺ to intact tRNA^Phe consists of a co-operative and a non-co-operative phase. There are about 17 “strong” sites and several “weak” ones. Five of the 17 strong sites are associated with the co-operative phase. This phase is completely lacking in the binding of Mn²⁺ to tRNA^Phe fragments (5′-$\text{1}\text{2}$, 3′-$\text{1}\text{2}$, 5′-$\text{3}\text{5}$, 3′-$\text{2}\text{5}$), poly-(A):poly(U) and poly(I):poly(C) helices, and single stranded poly(A) and poly(U). This argues that the co-operative sites arise from the tRNA tertiary structure. This conclusion is further strengthened by the observation that cooperativity is present in a tRNA^Phe molecule which has been split in the anticodon loop, but it is absent in one which has been split in the extra loop. It is in the vicinity of the latter loop, but not the former, that tertiary interactions are seen in the crystal structure. The remaining 12 strong sites are “independent” and appear to be associated with cloverleaf helical sections.     

Guanine nucleotides modulate cell surface cAMP-binding sites in membranes from Dictyostelium discoideum

D. discoideum contains kinetically distinguishable cell surface cAMP binding sites. One class, S, is slowly dissociating and has high affinity for cAMP (K_d = 15 nM, $\text{t}\text{1}\text{2}\text{= 15 s}$). A second class is fast dissociating ($\text{t}\text{1}\text{2}$ about 1 s) and is composed of high affinity binding sites H (K_d ≈ 60 nM), and low affinity binding sites L (K_d = ≈ 450 nM) which interconvert during the binding reaction. Guanine nucleotides affect these three binding types in membranes prepared by shearing D.discoideum cells through Nucleopore filters. The affinity of S for cAMP is reduced by guanine nucleotides from 13 nM to 25 nM, and the number of S-sites is reduced about 50%. The number of fast dissociating sites is not altered by guanine nucleotides, but these sites are mainly in the low affinity state. Half-maximal effects are obtained at about 1 μM GTP, 2 μM GDP and 10 μM Gpp(NH)p(guanyl-5′-yl-imidodiphosphate); ATP and ADP are without effect up to 1 mM. These results indicate that D.discoideum cells have a functionally active guanine nucleotide binding protein involved in the transduction of extracellular cAMP signals via cell surface cAMP receptors.     

Acyl phosphate and cyclic AMP inhibition of reactions of d-glyceraldehyde-3-phosphate dehydrogenase with aldehyde and acyl phosphate substrates: Multiple inhibition analysis

The effects of the inhibitors trimethylacetyl phosphate and cAMP have been determined in reactions catalyzed by d-glyceraldehyde-3-phosphate dehydrogenase. These inhibitors must influence the oxidation of aldehydes through substrate dependent co-operative conformational changes. Both trimethylacetyl phosphate and cAMP give sigmoidal $\text{1}\text{V}$ vs (I) plots in oxidation of glyceraldehyde 3-phosphate, but exert linear competitive effects on the acyl phosphatase site in acylation reactions of β-(2-furyl) acryloyl phosphate. The linear inhibition in the latter reactions indicates that one inhibitor molecule is bound per active site. Hydride transfer to NAD⁺ is the ratedetermining step in oxidation of benzaldehyde to an acylenzyme, as shown by the threefold decrease in V_max without change in K_m when 1-deuterobenzaldehyde is the substrate; it is very likely this step that is affected by acyl phosphate inhibitors. Plots of $\text{1}\text{V}$ vs cAMP concentration for oxidation of benzaldehyde at a series of trimethylacetyl phosphate concentrations are parallel at concentrations of acyl phosphate less than 0.00625 m, which demonstrates that binding of the inhibitors is mutually exclusive. However, at higher concentrations of trimethylacetyl phosphate, the slopes are affected, which shows that both inhibitors are then binding. Thus, the binding of high concentrations of acyl phosphate must result in a conformational change of the enzyme that permits binding of both inhibitors. A number of conformations with different kinetic properties are formed with the various substrate and inhibitor combinations. In reactions of muscle d-glyceraldehyde-3-phosphate dehydrogenase, binding of these inhibitors is best explained in terms of induced fit and a sequential model of conformational changes.     

Purification and characterization of an intracellular N-terminal exopeptidase from Streptococcus durans

An intracellular N-terminal exopeptidase isolated from cell extracts of Streptococcus durans has been purified 470-fold to homogeneity (specific activity of 12.0 μmol/min per mg). In the absence of thiol compounds, the purified aminopeptidase undergoes a slow oxidation with a 70% loss of activity, which can be restored by the addition of 2 mM β-mercaptoethanol. The purified aminopeptidase (M_r 300 000) preferred L-peptide and arylamide substrates with small nonpolar or basic side chains. SDS electrophoresis yielded a single protein band corresponding to a molecular weight of 49 400, suggesting that the native enzyme is a hexameric protein. The enzyme-catalyzed hydrolysis of $\text{L}\text{-}\text{alanyl}\text{-p-}\text{nitroanilide}$ exhibited a bell-shaped pH dependence for log V_max/K_m(pK₁ = 6.35; pK₂ = 8.50) while the log V_max versus pH profile showed only an acid limb (pK = 6.35). Methylene blue-sensitized photooxidation of the enzyme resulted in the complete loss of activity, while L-leucine, a competitive inhibitor, partially protected against this inactivation. Amino acid analysis indicated that this photooxidative loss of activity corresponded to the modification of one histidine residue per enzyme monomer. N-Ethylmaleimide (100 mM) caused a 78% reduction in enzyme activity. Treatment of the enzyme with 1.0 mM hydrogen peroxide resulted in the oxidation of two cysteine residues per enzyme monomer and caused a 70% decrease in the catalytic activity.     

A fluorimetric study of Mg2]nduced structural changes in thylakoid membrane protein.

Low concentrations of Mg²⁺ (concn < 10 mm) generate structural changes in delipidated spinach chloroplast lamellae, that appear as changes in the fluorescence yield of native tryptophyl residues and of the externally added polarity probe magnesium 1-anilinonaphthalene-8-sulfonate.The delipidated lamellae, consisting essentially of structural protein monomers and aggregates, bind magnesium 1-anilinonaphthalene-8-sulfonate to the extent of 126 ± 13 nmol/mg protein, and with a dissociation constant K_D = 167 μM. Bound ANS fluoresces at 458 nm with a quantum yield Φ = 0.121. Tryptophyls sensitize the fluorescence of bound ANS with a maximal efficiency T_max = 0.85. Assuming completely random orientation of the interacting chromophores, an interchromophore separation $\text{R = 17.3}\text{A}\text{?}$ is calculated. Only two-thirds of the membrane tryptophyls have ANS-binding sites in their vicinity.Mg²⁺ binds to the delipidated membranes with a dissociation constant K_D = 2 mM. The binding is attended by enhancement of magnesium 1-anilinonaphthalene-8-sulfonate fluorescence, and deenhancement of tryptophyl fluorescence, while the efficiency of interchromophore excitation transfer increases only slightly. These effects suggest that Mg²⁺ generates a structural change which lowers the polarity of the membrane region where tryptophyl and magnesium 1-anilinonaphthalene-8-sulfonate are situated, but which has a minor effect only on the interchromophore separation.     

Nucleic acid binding properties of Escherichia coli ribosomal protein S1. II. Co-operativity and specificity of binding site II.

The following properties characterize the interaction of nucleic acid binding site II of Escherichia coli ribosomal protein S1 with oligo- and polyribonucleotides; all have been determined with site I complexed with oligo- or polydeoxyribonucleotides. (1) The intrinsic binding constant (K) of site II to single-stranded polyribonucleotides is fairly independent of base composition, though cytidinecontaining polymers bind with approximately threefold higher intrinsic affinities than do the comparable adenine-containing species. (2) Poly(rC) is bound to site II co-operatively; the co-operativity parameter (ω) ? 31. Poly(rA) shows no binding co-operativity. The site size (n) for both polyribonucleotides binding at site II is about ten nucleotide residues. (3) The K value for site II is ? 4 × 10⁵m^?1 for poly(rA), and ? 1 × 10⁶m^?1 for poly(rC), in 0.12 m-Na⁺. Unlike site I, the binding affinity of site II increases somewhat with increasing salt concentration, suggesting that phosphate—basic protein residue contacts are not involved. (4) Varying Mg^{2 +} concentration has no effect on K, and changes in the concentration of either Mg²⁺ or Na⁺ do not affect the magnitude of site II co-operativity. (5) Reaction of the exocyclic amino groups of poly (rC) with formaldehyde drastically reduces the affinity of site II for this polynucleotide, while the affinity of poly (rC) for site I is not altered by this treatment. (6) No major sequence specificity of K for site II is found with either homogeneous polynucleotides or the 3′ terminal dodecanucleotide of 16 S ribosomal RNA; we conclude that selectivity of S1 binding via site II depends largely on the presence or absence of base compositiondependent binding co-operativity.The binding properties of site II probably account for the ability of S1 to inhibit translation at high S1 to ribosome ratios (“factor i” activity). Possible mechanisms for the role of S1 protein as a part of the phage Qβ replicase complex and in protein synthesis are discussed in relation to the binding properties of site I and site II.     

Oligomeric BAX induces mitochondrial permeability transition and complete cytochrome c release without oxidative stress

In the present study, we investigated the mechanism of cytochrome c release from isolated brain mitochondria induced by recombinant oligomeric BAX (BAX_oligo). We found that BAX_oligo caused a complete release of cytochrome c in a concentration- and time-dependent manner. The release was similar to those induced by alamethicin, which causes maximal mitochondrial swelling and eliminates barrier properties of the OMM. BAX_oligo also produced large amplitude mitochondrial swelling as judged by light scattering assay and transmission electron microscopy. In addition, BAX_oligo resulted in a strong mitochondrial depolarization. ATP or a combination of cyclosporin A and ADP, inhibitors of the mPT, suppressed BAX_oligo-induced mitochondrial swelling and depolarization as well as cytochrome c release but did not influence BAX_oligo insertion into the OMM. Both BAX_oligo- and alamethicin-induced cytochrome c releases were accompanied by inhibition of ROS generation, which was assessed by measuring mitochondrial H₂O₂ release with an Amplex Red assay. The mPT inhibitors antagonized suppression of ROS generation caused by BAX_oligo but not by alamethicin. Thus, BAX_oligo resulted in a complete cytochrome c release from isolated brain mitochondria in the mPT-dependent manner without involvement of oxidative stress by the mechanism requiring mitochondrial remodeling and permeabilization of the OMM.     

Specificity of the binding of bacteriophage M13 encoded gene-5 protein to DNA and RNA studied by means of fluorescence titrations

The fluorescence quenching of the bacteriophage M13 encoded gene-5 protein was used to study its binding characteristics to different polynucleotides. Experiments were performed at different salt concentrations and in some instances at different temperatures. The affinity of the protein depends on the base and sugar composition of the polynucleotides involved and may differ appreciably, i.e. by orders of magnitude. The salt dependence of binding is within experimental accuracy equal for all single stranded polynucleotides. A method is presented to estimate values of the cooperativity constant from salt titration curves. These values are systematically higher than those obtained from titration experiments in which protein is added to a polynucleotide solution. A comparison is made between the binding constants of the gene-5 protein and the gene-32 protein encoded by the T4 phage. Possible implications of the binding characteristics of the gene-5 protein for an understanding of its role in vivo are discussed.