A new affinity adsorbent for guanyloribonuclease. Guanylyl-(2'-5')-guanosine coupled to aminohexyl-Sepharose.

Guanylyl-(2'-5')-guanosine binds to RNase T1 in 1:1 stoichiometry with a dissociation constant of 0.22 mM at pH 5.0 and 25 degrees C. This nucleotide, coupled to aminohexyl-Sepharose 4B, is able to serve as an affinity adsorbent for guanyloribonuclease [EC 3.1.4.8]. The strength of interaction between the adsorbent and various guanyloribonucleases at pH 5.0 was found to decrease in the following order: RNase N1 greater than RNase F1 greater than RNase T1 greater than RNase St. The bound enzymes can be released from the adsorbent either by increase of ionic strength or by increasing the pH from 5.0 to 7.5. The interaction between RNase T1 and the adsorbent is weakened by the presence of a low concentration of 2', 3'-, or 5'-GMP, which are competitive inhibitors of the enzyme. RNase F1 was purified to homogeneity by use of this affinity adsorbent.     

The interaction of a tyrosyl residue and carboxyl groups in the specific interaction between Streptomyces subtilisin inhibitor and subtilisin BPN'. A chemical modification study.

An ultraviolet absorption difference spectrum that is typical of a change in ionization state (pKa 9.7 leads to greater than 11.5) of a tyrosyl residue has been observed on the binding between Streptomyces subtilisin inhibitor (SSI) and subtilisin BPN' [EC 3.4.21.14] at alkaline pH, ionic strength 0.1 M, at 25 degrees C (Inouye, K., Tonomura, B., and Hiromi, K., submitted). When the complex of SSI and subtilisin BPN' is formed at an ionic strength of 0.6 M and pH 9.70, the characteristic features of the protonation of a tyrosyl residue in the difference spectrum are diminished. These results suggest that the pKa-shift of a tyrosyl residue observed at alkaline pH and lower ionic strength results from an electrostatic interaction. Nitration of tyrosyl residues of SSI and of subtilisin BPN' was performed with tetranitromethane (TNM). By measurements of the difference spectra observed on the binding of the tyrosyl-residue-nitrated SSI and the native subtilisin BPN', and on the binding of the native SSI and the tyrosyl-residue-nitrated subtilisin BPN' and alkaline pH, the tyrosyl residue in question was shown to be one out of the five tyrosyl residues of pKa 9.7 of the enzyme. This tyrosyl residue was probably either Tyr 217 or Tyr 104 on the basis of the reactivities of tyrosyl residues of the enzyme with TNM and their locations on the enzyme molecule. Carboxyl groups of SSI were modified by covalently binding glycine methyl ester with the aid of water-soluble carbodiimide, in order to neutralize the negative charges on SSI. In the difference spectrum which was observed on the binding of subtilisin BPN' and the 5.3-carboxyl-group-modified SSI at alkaline pH, the characteristic features of the protonation of a tyrosyl residue were essentially lost, and the difference spectrum is rather similar to that observed on the binding of the native SSI and the enzyme at neutral pH. This phenomenon indicates that the pKa of a tyrosyl residue of the enzyme is shifted upwards by interaction with carboxyl group(s) of SSI on the formation of the enzyme-inhibitor complex.     

Ribose recognition by ribonuclease T1: difference spectral binding studies with guanosine and deoxyguanosine.

The binding of ribonuclease T1 with guanosine (Guo) and deoxyguanosine (dGuo) was studied in experiments employing ultraviolet difference spectroscopy in the pH range 3-9 at 0.2 M ionic strength and 25 degrees C. Similar experiments were also conducted with psi-carboxymethyl-glutamate-58 ribonuclease T1 at pH 5.0. At most pH values the characteristic difference spectrum and association constant were obtained. The binding constant for dGuo was approximately 550 M-1 and did not significantly vary in the pH range 3.5-9.0. The binding constant for Guo increased from pH 3.5 to 5.0, was constant between pH 5.0 and 7.0 (approximately 3200 M-1), and decreased at higher pH values. The binding of Guo and dGuo with ribonuclease T1 could also be distinguished in terms of the wavelength for maximal difference absorbance, lambdamax, between pH 5.0 and 7.0. At higher and lower pH values, lambdamax for Guo approached that found fr dGuo. On the other hand, the value of the binding constant (approximately6500 M-1) and the nature of the difference spectra for Guo and dGuo binding with lambdamax-carboxymethyl-glutamate-58-ribonuclease T1 at pH 5.0 were identical. These results suggest that the discrete interaction of the Guo 2'-hydroxyl group with ribonuclease T1 involves the lambda-carboxylate of glutamate-58 and an imidazolium group at the active site.     

Spectrophotometric analysis of the interaction between cytochrome b5 and cytochrome c

The interaction between cytochrome c and the tryptic fragment of cytochrome b5 has been found to produce a difference spectrum in the Soret region with a maximum absorbance at 416 nm. The intensity of this difference has been used to determine the stoichiometry of complex formation and the stability of the complex formed. At pH 7.0 [25 degrees C (phosphate), mu = 0.01 M], the two proteins were found to form a 1:1 complex with an association constant, KA, of 8(3) x 10(4) M-1. The stability of the complex was found to be strongly dependent on ionic strength with KA increasing to 4(3) x 10(6) M-1 at mu = 0.001 M [25 degrees C, pH 7.0 (phosphate)]. Analysis of the dependence of KA on pH from pH 6.5 to 8 demonstrated that this complex is maximally stable between pH 7 and 8 or about midway between the isoelectric points of the two proteins. Analysis of the temperature dependence of KA revealed that formation of the complex between the two proteins is largely entropic in origin with delta Ho = 1 +/- 3 kcal/mol and delta So = 33 +/- 11 eu [pH 7.0 (phosphate), mu = 0.001 M]. This result may be explained either by the model of Clothia and Janin [Clothia, C., & Janin, J. (1975) Nature (London) 256, 705] in terms of extensive solvent reorganization upon complexation or by the model of Ross and Subramanian [Ross, P. D., & Subramanian, S. (1981) Biochemistry 20, 3096] in which the negative enthalpic and entropic contributions of short-range protein-protein interactions are offset by proton release.     

Kinetic studies on the cleavage of oligouridylic acids and poly U by bovine pancreatic ribonuclease A

Kinetic parameters, Km and Vmax for the transesterification of oligouridylic acid, (Up)nU greater than p (n=0-4), by RNase A were measured spectrophotometrically at pH 7.0 and 25 degrees C. The kinetic parameters, pKm and log Vmax increased with increase in the chain length (n), and seemed to be almost constant with substrates having n greater than or equal to 2. The contribution of each subsite to the binding was estimated according to Hiromi's theory. The subsite affinities for (B1, R1, P1)+(B2, R2, P2) and (B3, R3, P3) are 8.03 kcal and 0.72 kcal/mol, respectively, and those for (B4, R4, P4) and (B5, R5, P5) are less than 0.5 kcal/mol. Therefore, we postulate that the size of the RNase A active site is about 3 nucleotides in length. Transesterification of poly U by RNase A was followed spectrophotometrically. The reaction is markedly influenced by ionic strength. At lower ionic strength, the v0-S curve of poly U cleavage was sigmoidal and cooperative, and it became less cooperative at higher ionic strength. Since the estimated Vmax value for poly U cleavage at ionic strength of 0.1 was more than 20 times larger than that of oligouridylic acids cleavage, we propose a non-specific interaction of poly U anion with cationic groups on the surface of the enzyme, modulating the conformation of active site, and thus increasing the activity at low ionic strength. The interaction decreases at higher ionic strength due to the interaction of counter anions with the non-specific sites.     

Protein dissociation from DNA in model systems and chromatin.

Salt induced dissociation of protamine, poly(L-lysine) and poly(L-arginine) from DNA was measured by relative light scattering at theta = 90 degrees and/or centrifugation. Dissociation of histones from DNA was studied using relative light scattering and intrinsic tyrosine fluorescence. Protamine was dissociated from DNA at 0.15 M MgCl2 (ionic strength mu = 0.45) or 0.53 M NaCl (mu = 0.53) based on light scattering data and at approximately 0.2 M MgCl2 (mu = 0.6) or 0.6 M NaCl based on centrifugation data. NaCl induced dissociation of poly(Lys) or poly(Arg) from natural DNAs measured by light scattering did not depend on the guanine plus cytosine content. To dissociate poly(Arg) from DNA higher ionic strength using NaCl, MgCl2, or CaCl2, similar ionic strength using NaClo4, and lower ionic strength using Na2SO4 was needed then to dissociated poly(Lys). Both the decrease in light scattering and the enhancement of tyrosine fluorescence of chromatin occurred between 0.5 and 1.5 M NaCl when histones were dissociated.     

Expression, purification, and characterization of a recombinant ribonuclease H from Thermus thermophilus HB8.

Thermus thermophilus ribonuclease H was overexpressed and purified from Escherichia coli. The determination of the complete amino acid sequence allowed modification of that predicted from the DNA sequence, and the enzyme was shown to be composed of 166 amino acid residues with a molecular weight of 18,279. The isoelectric point of the enzyme was 10.5, and the specific absorption coefficient A0.1%(280) was 1.69. The enzymatic and physicochemical properties as well as the thermal and conformational stabilities of the enzyme were compared with those of E. coli RNase HI, which shows 52% amino acid sequence identity. Comparison of the far and near UV circular dichroism spectra suggests that the two enzymes are similar in the main chain folding but different in the spatial environments of tyrosine and tryptophan residues. The enzymatic activities of T. thermophilus RNase H at 37 and 70 degrees C for the hydrolysis of either an M13 DNA/RNA hybrid or a nonanucleotide duplex were approximately 5-fold lower and 3-fold higher, respectively, as compared with E. coli RNase HI at 37 degrees C. The melting temperature, Tm, of T. thermophilus RNase H was 82.1 degrees C in the presence of 1.2 M guanidine hydrochloride, which was 33.9 degrees C higher than that observed for E. coli RNase HI. The free energy changes of unfolding in the absence of denaturant, delta G[H2O], of T. thermophilus RNase H increased by 11.79 kcal/mol at 25 degrees C and 14.07 kcal/mol at 50 degrees C, as compared with E. coli RNase HI.     

The role of the salt concentration, proton, and phosphate binding on the thermal stability of wild and cloned DNA-binding protein Sso7d from Sulfolobus solfataricus

The acidic pH (1.5-7.0) and ionic strength (0.005-0.2M) dependence of thermodynamic functions of protein Sso7d from Sulfolobus solfataricus, cloned (c-Sso7d) and N-heptapeptide deleted [c-des(1-7)Sso7d] in glycine, and phosphate buffers was studied by means of adiabatic scanning calorimetry. The difference of proton binding was estimated from deltaHcal(pH), Td(pH), and (deltaTd/deltapH). It was found that a single group non-co-operative ionization with apparent pKa = 3.25 for both cloned and deleted proteins govern the thermal unfolding of two different (protonated and unprotonated) forms. deltaH degrees is found to be pH-independent and the changes in stability (deltaG degrees ) originate from changes in entropy terms. The apparent pKa measured at high salt concentrations decreases with 0.5 pH units from glycine to phosphate and the free energy of transfer at high ionic strength is 0.7 kcal/mol. The ionic strength dependence for the pH-dependent D-states is very different at pH 6.0 and 1.5. This is consistent with the property of denatured state to be more compacted or "closed" (Dc) at neutral or weak acidic pH and more random or "open" (Do) at acidic pH. From the Bjerrum's relation was found the number of screened charges important for the unfolding process. The main conclusions are: (1) the thermal stability of Sso7d has prominently entropic nature; (2) a single non-co-operative ionization controls the conformations in the D-state; and (3) pH-dependent conformational equilibrium could be functionally important in Sso7d-DNA recognition.     

Model studies of DNA-protein interaction. I. Effect of aminocarboxylic and amide groups of amino acids on DNA thermostability and conformation

To elucidate interactions of amino-carboxylate dipole and amide group of amino acids with DNA, glycine and glutamine, concentration dependences of the melting curves and CD spectra of calf thymus DNA at low ionic strength (10(-4) M) Na-citrate have been studied. A considerable increase of the melting temperature delta t1/2 and a decrease of the temperature interval of melting delta t with the rise of glycine concentration were observed without changes in the CD spectrum. A comparison was made between the influence of dipolar glycine ion and isolated amino and carboxylate ions of ammonium acetate. The data obtained indicated the predominance of electrostatic interaction of glycine with DNA phosphates until the ligand concentration was approximately 0.6 M and, apparently, specific interactions of carboxylate ion with guanine at higher glycine concentrations. Destabilizing effect of glutamine on DNA at a concentration of 5.10(-3) M was observed, whereas at higher concentrations two-phase increase of delta t1/2 was shown. Small changes in DNA CD spectrum under the action of glutamine were registered. The comparison data for glutamine and acrylamide showed that DNA destabilizing effect was due to the amide group. The destabilizing effect of amide group can be explained by its interaction with the bases in single-stranded regions of DNA with the formation of two H-bonds. It is possible that the increase of DNA delta t1/2 is the result of the interaction of phosphates both with aminocarboxylate and amide groups of glutamine.     

Physiochemical studies on interactions between DNA and RNA polymerase. Ultraviolet absorption measurements.

The interaction between Escherichia coli RNA polymerase and a restriction fragment of coliphage T7 DNA containing four promoter sites for the coli enzyme has been studied by difference uv absorption spectroscopy in a low ionic strength buffer containing 10 mm MgCl2 and 50 mM KCl. The binding of the enzyme to the DNA is accompanied by a hyperchromic shift which shows a maximum around 260 nm, and increases with increasing temperature in the temperature range studied (4-40 degrees C). Measurements were also carried out with whole T7 DNA and a restriction fragment containing no promoter site. A comparison of the results obtained with the various DNAs suggests that the binding of an RNA polymerase to a promoter site in the low ionic strength medium causes the disruption of a short segment of the DNA helix, of the order of ten pairs; the binding of an enzyme molecule to a promotor site appears to have a cooperative effect on the binding of the enzyme molecules to adjacent non-promoter sites with concomitant disruption of DNA base pairs.     

4-nitroimidazole binding to horse metmyoglobin: evidence for preferential anion binding

The ionization of 4-nitroimidazole to 4-nitroimidazolate was investigated as a function of ionic strength. The apparent pKa varies from 8.99 to 9.50 between 0.001 and 1.0 M ionic strength, respectively, at 25 degrees C. The ionic strength dependence of this ionization is anomalous. The binding of 4-nitroimidazole by horse metmyoglobin was studied between pH 5.0 and 11.5 and as a function of ionic strength between 0.01 and 1.0 M. The association rate constant is pH-dependent, varying from 24 M(-1)s(-1) at pH 5 to a maximum value of 280 M(-1)s(-1) at pH 9.5 and then decreasing to 10 M(-1)s(-1) at pH 11.5 in 0.1 M ionic strength buffers. The dissociation rate constant has a much smaller pH dependence, varying from 0.082 s(-1) at low pH to 0.035 s(-1) at high pH, with an apparent pKa of 6.5. The binding affinity of 4-nitroimidazole to horse metmyoglobin is about 2.5 orders of magnitude stronger than that for imidazole and this increased affinity is attributed to the much slower dissociation rate for 4-nitroimidazole compared to that of imidazole. Although the ionic strength dependence of the binding rate is small and secondary kinetic salt effects can account for the ionic strength dependence of the association rate constant, the pH dependence of the rate constants and microscopic reversibility arguments indicate that the anionic form of the ligand binds more rapidly to all forms of metmyoglobin than does the neutral form of the ligand. However, the spectrum of the complex is similar to model complexes involving neutral imidazole and not imidazolate. The latter observation suggests that the initial metmyoglobin/4-nitroimidazolate complex rapidly binds a proton and the neutral form of the bound ligand is stabilized, probably through hydrogen binding with the distal histidine.     

RNase A effects on sedimentation and DNA binding properties of dexamethasone-receptor complexes from HeLa cell cytosol

Dexamethasone-receptor complexes from HeLa cell cytosol sediment at 7.4S in low salt sucrose gradients, and at 3.8S in high salt gradients. If cytosol is heated at 25 degrees C, receptor complexes sediment at 6.9S in low salt, and at 3.6S in high salt gradients. RNase A treatment at 25 degrees C, instead, results in receptor complexes which sediment in low salt gradients as two major forms at 6.5 and 4.8S. Receptor complexes from RNase A-treated cytosols sediment as their counterparts from untreated cytosols in high salt gradients. Although the shift in sedimentation properties of receptor complexes at 2 degrees C is induced by RNase A, and not by other low molecular weight basic proteins or RNase T1, the effect can be also obtained by inactive RNase A. The catalytically active enzyme, however, is required to observe 6.5 and 4.8S complexes after cytosol incubations at 25 degrees C. Placental ribonuclease inhibitor prevents the appearance of RNase A-induced receptor forms at 25 degrees C, but not at 2 degrees C. Moreover, this inhibitor can prevent the 7.4 to 6.9S shift in sedimentation coefficient of receptor complexes caused by cytosol heating. Dexamethasone-receptor complexes from HeLa cell cytosol show low levels of binding to DNA-cellulose, and heating at 25 degrees C is required to observe a six-fold increase in DNA binding levels. RNase A treatment of cytosols at 2 degrees C does not result in significant enhancement in receptor complex binding to DNA. If RNase A treatment is carried out at 25 degrees C, however, DNA binding levels of receptor complexes increased by 25% over the values observed with control heated cytosol. This effect cannot be observed if RNase T1 substitutes for RNase A. Placental ribonuclease inhibitor can prevent the temperature-dependent increase in DNA binding properties of dexamethasone-receptor complexes either in the presence or absence of exogenous RNase A. These findings indicate that exogenous RNases can perturb the structure of dexamethasone-receptor complexes without being involved in the transformation process.     

Spectroscopic analysis of the interaction of Escherichia coli DNA-dependent RNA polymerase with T7 DNA and synthetic polynucleotides.

We have studied the circular dichroism and ultraviolet difference spectra of T7 bacteriophage DNA and various synthetic polynucleotides upon addition of Escherichia coli RNA polymerase. When RNA polymerase binds nonspecifically to T7 DNA, the CD spectrum shows a decrease in the maximum at 272 but no detectable changes in other regions of the spectrum. This CD change can be compared with those associated with known conformational changes in DNA. Nonspecific binding to RNA polymerase leads to an increase in the winding angle, theta, in T7 DNA. The CD and UV difference spectra for poly[d(A-T)] at 4 degrees C show similar effects. At 25 degrees C, binding of RNA polymerase to poly[d(A-T)] leads to hyperchromicity at 263 nm and to significant changes in CD. These effects are consistent with an opening of the double helix, i.e. melting of a short region of the DNA. The hyperchromicity observed at 263 nm for poly[d(A-T)] is used to determine the number of base pairs disrupted in the binding of RNA polymerase holoenzyme. The melting effect involves about 10 base pairs/RNA polymerase molecule. Changes in the CD of poly(dT) and poly(dA) on binding to RNA polymerase suggest an unstacking of the bases with a change in the backbone conformation. This is further confirmed by the UV difference spectra. We also show direct evidence for differences in the template binding site between holo- and core enzyme, presumably induced by the sigma subunit. By titration of the enzyme with poly(dT) the physical site size of RNA polymerase on single-stranded DNA is approximately equal to 30 bases for both holo- and core enzyme. Titration of poly[d(A-T)] with polymerase places the figure at approximately equal to 28 base pairs for double-stranded DNA.     

Interaction of the antineoplastic agent mitoxantrone with double-stranded nucleic acids

The binding of mitoxantrone with double-helical nucleic acids was investigated by the methods of isothermal microcalorimetry, circular dichroism and absorption at the ionic strength mu = 0.11 and 0.011 M NaCl at temperature region of 30 divided by 60 degrees C. The investigation shows, that at mu = 0.11 M NaCl mitoxantrone interacts with double-helical nucleic acids in one way only. For such conditions using spectrophotometric titration data Scatchard plots for the binding of mitoxantrone with double-helical nucleic acids were constructed. The calculations show that the saturation stoichiometry is one mitoxantrone molecule per 2 divided by 3 base pairs DNA and 6 divided by 8 base pairs RNA. The dependence of binding constant from GC-content is observed. It is shown that the binding enthalpy of mitoxantrone with DNA and RNA increases linearly and reaches -(3.0 +/- 0.5) kkal per 1 mol mitoxantrone. It is shown that a binding mitoxantrone with double-helical nucleic acids, besides the intercalation of rings, a determinate contribution in the binding is given also by electrostatic interaction of side chains mitoxantrone with nucleic acids.     

Conformational stability of ribonuclease T1. I. Thermal denaturation and effects of salts.

The thermal transition of RNase T1 was studied by two different methods; tryptophan residue fluorescence and circular dichroism. The fluorescence measurements provide information about the environment of the indole group and CD measurements on the gross conformation of the polypeptide chain. Both measurements at pH 5 gave the same transition temperature of 56 degrees C and the same thermodynamic quantities, delta Htr (= 120 kcal/mol) and delta Str (= 360 eu/mol), for the transition from the native state to the thermally denatured state, indicating simultaneous melting of the whole molecule including the hydrophobic region where the tryptophan residue is buried. Stabilization by salts was observed in the pH range from 2 to 10, since the presence of 0.5 m NaCL caused an increase of about 5 degrees C to 10 degrees C in the transition temperature, depending on the pH. The fluorescence measurements on the RNase T1 complexed with 2'-GMP showed a transition with delta Htr =167 kcal/mol and delta Str =497 eu/mol at a transition temperature about 6 degrees C higher than that for the free enzyme. The large value of delta Htr for RNase T1 indicates the highly cooperative nature of the thermal transition; this value is much higher than those of other globular proteins. Analysis of the CD spectrum of thermally denatured RNase T1 suggests that the denatured state is not completely random but retains some ordered structures.     

Thermodynamic and spectral study of DNA-prospidin complex

By the methods of heat denaturation and luminescence the interaction between an antitumor drug prospidine and DNA in aqueous solutions at two ionic strengths (0.1 and 0.001 M NaCl) and at various prospidine concentrations was studied. For the first time it has been demonstrated that the interaction occurs at 0.1 M NaCl and therapeutic prospidine concentrations. In the framework of Frank-Kamenetsky's theory of melting of a polymer with stabilizing ligands the size of the binding site and binding constants (K) with the decrease of ionic strength, the lack of alterations in the DNA UV absorption spectrum on complex formation and the data on the competitive binding of ethydium bromide suggest that at the first stage of the reaction an external complex is formed due to electrostatic interactions between quaternary nitrogen atoms of prospidine and DNA phosphate groups. Incubation of the complex at 37 0 C leads to a decrease of the DNA melting temperature and hyperchromic effect. Presumably this is due to the relatively slow formation of chemical bonds between alkylating groups of prospidine and nucleophilic groups of DNA bases, which results in the destabilization and denaturation of DNA. It is concluded that the interaction between prospidine and DNA must be taken into consideration when studying the molecular mechanism of prospidine antitumour activity.     

Spermine stabilization of folded ribonuclease T1

The interaction of ribonuclease T1 with tetraprotonated spermine (SPM4+), Mg2+, phosphate and other ionic ligands at pH 6.0 was investigated in binding experiments at 25 degrees C and/or by their effects on the midpoint temperature for thermal unfolding of the enzyme. SPM4+ binding with the native protein at 25 degrees C was characterized by an association constant of approximately 2 x 10(4) M-1. This ligand also binds to the unfolded protein but with a approximately 35-fold lower affinity. Phosphate binds at the active site whereas Mg2+ and SPM4+ cations compete for binding at a polyanionic locus that probably involves residues Glu-28, Asp-29, and Glu-31 at the C-terminal end of the alpha-helix. Steady-state kinetic studies using minimal RNA substrates demonstrated that SPM4+ binding with the enzyme does not affect its catalytic activity. SPM4+ also preferentially binds with the folded form of the disulfide-reduced enzyme which has the same or slightly enhanced catalytic properties compared with native ribonuclease T1. The unfolding rate for the native protein in 8 M urea was approximately 8-fold lower in the presence of 0.05 M SPM4+. SPM4+ appears to increase the amplitude of an unobserved fast phase(s) for refolding of the native enzyme. A single kinetic phase characterized refolding of the reduced enzyme which was slightly faster than the slowest refolding phase for the native form.     

Increase in nucleolytic activity of ribonuclease T1 by substitution of tryptophan 45 for tyrosine 45

The preparation and analysis of a mutant ribonuclease (RNase) T1 which possesses higher nucleolytic activity than the wild-type enzyme are described. The gene for the mutant RNase T1 (Tyr45----Trp45), in which a single amino acid at the binding site of the guanine base has been changed, was constructed by the cassette mutangenesis method using a chemically synthesized gene [Ikehara, M. et al. (1986) Proc. Natl Acad. Sci. USA 83, 4695-4699]. In order to reduce the nucleolytic activity of the enzyme in vivo, this gene was expressed in Escherichia coli as a fused protein connected through methionine residues to other proteins at both the N- and C-termini. After liberation from the fused protein by cleavage with cyanogen bromide at the methionine junctions, the mutant RNase T1 was purified by column chromatography. The nucleolytic activity toward pGpC increased to 120% of that of wild-type RNase T1. The kinetic parameters of the mutant enzyme demonstrate that this higher nucleolytic activity is due to a higher affinity for the substrate, probably because of an increased stacking effect in the binding pocket for the guanine base. This mutant enzyme also possessed a higher nucleolytic activity against pApC than wild-type RNase T1.     

Specific modification of DNA at E. coli RNA-polymerase binding sites

Specific modification of promoter regions of DNA has been studied. Plasmid pK56B1 DNA has been used as a model to test RNA-polymerase binding with DNA under various conditions. RNA-polymerase is shown to form specific complexes with DNA which are stable in solutions with a moderate ionic strength (0.1-0.2 M NaCl), under pH 5-8 in the presence of 0.5 M O-methylhydroxylamine of O-delta-aminooxybutylhydroxylamine. Escherichia coli JM103 cells have been transfected with DNAs treated with 0.5 M O-methylhydroxylamine at 37 degrees C, pH 5.2. The inactivation effects of the mutagen on single-stranded DNA of bacteriophage M13 m p1, double-stranded form of this bacteriophage (replicative form-RF) and on the complex of RNA-polymerase with RF DNA have been compared. The obtained data confirmed the specificity of reagent action with DNA sites binding with the enzyme. Selectivity of promoters modification has been confirmed also by the analysis of M13 m p1 DNA mutations induced in lacZ' gene by delta-aminooxybutylhydroxylamine effect on the DNA complex with DNA-polymerase.     

The binding of porphyrin cytochrome c to yeast cytochrome c peroxidase. A fluorescence study of the number of sites and their sensitivity to salt

Porphyrin c, the iron-free derivative of cytochrome c, is a reasonably good model for cytochrome c binding to cytochrome c peroxidase (CcP). It binds with the same stoichiometry but only one-quarter as tightly as cytochrome c. CcP (resting, FeIII) and CcP X CN can both bind up to two molecules of porphyrin c. The binding of the first porphyrin c is tight (kd = 1 X 10(-9) M, pH 6, ionic strength mu = 0, 4 degrees C) and results in quenching of the porphyrin c fluorescence. The binding is sensitive to ionic strength. The binding of the second porphyrin c is looser (Kd unknown) and does not result in quenching of the porphyrin fluorescence. The binding of porphyrin c to the cyano form and the resting forms of CcP cannot be distinguished by our methods. ES is the first acceptor of electrons from c(II) and can bind at least two molecules of porphyrin c. The binding of the first porphyrin c is extremely tight, results in substantial quenching and is insensitive to ionic strength. The binding of porphyrin c to the loose site (Kd = 2 X 10(-9) M, pH 6, 4 degrees C, mu = 0) results, unlike the resting and cyano forms, in quenching of fluorescence of the second porphyrin c. The binding of the second porphyrin c to ES is sensitive to ionic strength. The calculated distances between porphyrin c and the hemes of CcP(FeIII) and ES are approximately 2.5 nm.