Crystallization and preliminary X-ray investigation of non-specific complexes of a mutant ribonuclease T1 (Y45W) with 2'AMP and 2'UMP

We have succeeded in crystallizing complexes of a mutant ribonuclease T1 (Y45W) with the non-cognizable ribonucleotides 2'AMP and 2'UMP by macroscopic seeding of microcrystals of the mutant enzyme complexed with 2'GMP, which is the cognizable nucleotide inhibitor. The mutant enzyme has a tryptophan residue instead of Tyr45 of the wild-type enzyme and thus this mutation enhances the binding of ribonucleotides to the enzyme. The space group is P212121 with unit cell dimensions a = 49.40 A, b = 46.71 A, c = 41.02 A for the complex with 2'AMP and a = 48.97, b = 46.58 A, c = 40.97 A for the complex with 2'UMP, both of which are poorly isomorphous to the mother crystals. Diffraction data for the complexes with 2'AMP and 2'UMP were collected on a diffractometer at 1.7 A and 2.4 A resolution, respectively. The present studies show that crystallization of non-specific complexes of other protein-ligand systems with the dissociation constants around 10(-3) M, or even larger, could be feasible by application of the seeding technique. A comparison of the crystal structures of the complexes with that with 2'GMP may serve as a structural basis for the determination of differences between the specific and non-specific interactions of the enzyme.     

Calculation of the relative binding free energy of 2'GMP and 2'AMP to ribonuclease T1 using molecular dynamics/free energy perturbation approaches

We present a calculation of the relative changes in binding free energy between the complex of ribonuclease T1 (RNase Tr) with its inhibitor 2'-guanosine monophosphate (2'GMP) and that of RNase T1-2'-adenosine monophosphate (2'AMP) by means of a thermodynamic perturbation method implemented with molecular dynamics. Using the available crystal structure of the RNase T1-2'GMP complex, the structure of the RNase T1-2'AMP complex was obtained as a final structure of the perturbation calculation. The calculated difference in the free energy of binding (delta delta Gbind) was 2.76 kcal/mol. This compares well with the experimental value of 3.07 kcal/mol. The encouraging agreement in delta delta Gbind suggests that the interactions of inhibitors with the enzyme are reasonably represented. Energy component analyses of the two complexes reveal that the active site of RNase T1 electrostatically stabilizes the binding of 2'GMP more than that of 2'AMP by 44 kcal/mol, while the van der Waals' interactions are similar in the two complexes. The analyses suggest that the mutation from Glu46 to Gln may lead to a preference of RNase T1 for adenine in contrast to the guanine preference of the wild-type enzyme. Although the molecular dynamics equilibration moves the atoms of the RNase T1-2'GMP system about 0.9 A from their X-ray positions and the mutation of the G to A in the active site increases the deviation from the X-ray structure, the mutation of the A back to G reduces the deviation. This and the agreement found for delta delta Gbind suggest that the molecular dynamics/free energy perturbation method will be useful for both energetic and structural analysis of protein-ligand interactions.     

Three-dimensional structure of a mutant ribonuclease T1 (Y45W) complexed with non-cognizable ribonucleotide, 2'AMP, and its comparison with a specific complex with 2'GMP.

The crystal structure of a mutant ribonuclease T1 (Y45W) complexed with a non-cognizable ribonucleotide, 2'AMP, has been determined and refined to an R-factor of 0.159 using X-ray diffraction data at 1.7 A resolution. A specific complex of the enzyme with 2'GMP was also determined and refined to an R-factor of 0.173 at 1.9 A resolution. The adenine base of 2'AMP was found at a base-binding site that is far apart from the guanine recognition site, where the guanine base of 2'GMP binds. The binding of the adenine base is mediated by a single hydrogen bond and stacking interaction of the base with the imidazole ring of His92. The mode of stacking of the adenine base with His92 is similar to the stacking of the guanine base observed in complexes of ribonuclease T1 with guanylyl-2',5'-guanosine, reported by Koepke et al., and two guanosine bases, reported by Lenz et al., and in the complex of barnase with d(GpC), reported by Baudet & Janin. These observations suggest that the site is non-specific for base binding. The phosphate group of 2'AMP is tightly locked at the catalytic site with seven hydrogen bonds to the enzyme in a similar manner to that of 2'GMP. In addition, two hydrogen bonds are formed between the sugar moiety of 2'AMP and the enzyme. The 2'AMP molecule adopts the anti conformation of the glycosidic bond and C-3'-exo sugar pucker, whereas 2'GMP is in the syn conformation with C-3'-endo-C'-2'-exo pucker. The mutation enhances the binding of 2'GMP with conformational changes of the sugar ring and displacement of the phosphate group towards the interior of the catalytic site from the corresponding position in the wild-type enzyme complex. Comparison of two crystal structures obtained provides a solution to the problem that non-cognizable nucleotides exhibit unexpectedly strong binding to the enzyme, compared with high specificity in nucleolytic activity. The results indicate that the discrimination of the guanine base from the other nucleotide bases at the guanine recognition site is more effective than that estimated from nucleotide-binding experiments so far.     

Conformation of 2'GMP bound to a mutant ribonuclease T1 (Y45W) determined by X-ray diffraction and NMR methods.

The crystal structure of a mutant ribonuclease T1 (Y45W) complexed with a specific inhibitor, 2'GMP, has been determined by X-ray diffraction and refined at 1.9 A resolution to a conventional R-factor of 0.164. The mode of recognition of the guanine base by the enzyme is similar to that found for the wild-type ribonuclease T1 complexed with 2'GMP. The binding of the guanine base is clearly enhanced by maximum overlapping of the indole ring of Trp45 and the base. The glycosyl torsion angle of the inhibitor is in the syn conformation and the sugar exhibits a C3'-endo type pucker, which differs from that observed in the crystal of the complex between the wild-type ribonuclease T1 and 2'GMP. Analysis of 500-MHZ NMR spectra has also indicated that the 2'GMP molecule as bound to the mutant enzyme in solution exhibits a C3'-endo type pucker, similar to that bound to the wild-type enzyme in solution [Inagaki, Shimada, & Miyazawa (1985) Biochemistry 24, 1013-1020].     

Molecular dynamics simulations of ribonuclease T1: comparison of the free enzyme and the 2' GMP-enzyme complex

Molecular dynamics simulations were performed on free RNase T1 and the 2'GMP-RNase T1 complex in vacuum and with water in the active site along with crystallographically identified waters, allowing analysis of both active site and overall structural and dynamics changes due to the presence of 2'GMP. Differences in the active site include a closing in the presence of 2'GMP, which is accompanied by a decrease in mobility of active site residues. The functional relevance of the active site fluctuations is discussed. 2'GMP alters the motion of Tyr-45, suggesting a role for that residue in providing a hydrophobic environment for the protein-nucleic acid interactions responsible for the specificity of RNase T1. The presence of 2'GMP causes a structural change of the C-terminus of the alpha-helix, indicating the transmission of structural changes from the active site through the protein matrix. Overall fluctuations of both the free and 2'GMP enzyme forms are in good agreement with X-ray temperature factors. The motion of Trp-59 is influenced by 2'GMP, indicating differences in enzyme dynamics away from the active site, with the calculated changes following those previously seen in time-resolved fluorescence experiments.     

Contribution of single tryptophan residues to the fluorescence and stability of ribonuclease Sa

Ribonuclease Sa (RNase Sa) contains no tryptophan (Trp) residues. We have added single Trp residues to RNase Sa at sites where Trp is found in four other microbial ribonucleases, yielding the following variants of RNase Sa: Y52W, Y55W, T76W, and Y81W. We have determined crystal structures of T76W and Y81W at 1.1 and 1.0 A resolution, respectively. We have studied the fluorescence properties and stabilities of the four variants and compared them to wild-type RNase Sa and the other ribonucleases on which they were based. Our results should help others in selecting sites for adding Trp residues to proteins. The most interesting findings are: 1), Y52W is 2.9 kcal/mol less stable than RNase Sa and the fluorescence intensity emission maximum is blue-shifted to 309 nm. Only a Trp in azurin is blue-shifted to a greater extent (308 nm). This blue shift is considerably greater than observed for Trp71 in barnase, the Trp on which Y52W is based. 2), Y55W is 2.1 kcal/mol less stable than RNase Sa and the tryptophan fluorescence is almost completely quenched. In contrast, Trp59 in RNase T1, on which Y55W is based, has a 10-fold greater fluorescence emission intensity. 3), T76W is 0.7 kcal/mol more stable than RNase Sa, indicating that the Trp side chain has more favorable interactions with the protein than the threonine side chain. The fluorescence properties of folded Y76W are similar to those of the unfolded protein, showing that the tryptophan side chain in the folded protein is largely exposed to solvent. This is confirmed by the crystal structure of the T76W which shows that the side chain of the Trp is only approximately 7% buried. 4), Y81W is 0.4 kcal/mol less stable than RNase Sa. Based on the crystal structure of Y81W, the side chain of the Trp is 87% buried. Although all of the Trp side chains in the variants contribute to the unusual positive circular dichroism band observed near 235 nm for RNase Sa, the contribution is greatest for Y81W.     

RNase T1 mutant Glu46Gln binds the inhibitors 2'GMP and 2'AMP at the 3' subsite.

On the basis of molecular dynamics and free-energy perturbation approaches, the Glu46Gln (E46Q) mutation in the guanine-specific ribonuclease T1 (RNase T1) was predicted to render the enzyme specific for adenine. The E46Q mutant was genetically engineered and characterized biochemically and crystallographically by investigating the structures of its two complexes with 2'AMP and 2'GMP. The ribonuclease E46Q mutant is nearly inactive towards dinucleoside phosphate substrates but shows 17% residual activity towards RNA. It binds 2'AMP and 2'GMP equally well with dissociation constants of 49 microM and 37 microM, in contrast to the wild-type enzyme, which strongly discriminates between these two nucleotides, yielding dissociation constants of 36 microM and 0.6 microM. These data suggest that the E46Q mutant binds the nucleotides not to the specific recognition site but to the subsite at His92. This was confirmed by the crystal structures, which also showed that the Gln46 amide is hydrogen bonded to the Phe100 N and O atoms, and tightly anchored in this position. This interaction may either have locked the guanine recognition site so that 2'AMP and 2'GMP are unable to insert, or the contribution to guanine recognition of Glu46 is so important that the E46Q mutant is unable to function in recognition of either guanine and adenine.     

Optical detection of triplet-state magnetic resonance studies on individual tryptophan residues of serum albumin: correlation between phosphorescence and zero-field splittings

Cyanogen bromide cleavage of bovine serum albumin (BSA) yields two fragments, N (1-183) and C (184-582), containing 183 and 399 amino acid residues, respectively. Each in each fragment are characterized in this study by phosphorescence and optically detected magnetic resonance spectroscopy, and the results are compared with those of the intact albumin. Trp-134 in fragment N is located in a hydrophobic environment in the interior of the protein, as reflected by its red-shifted phosphorescence and characteristic zero-field splittings. The spectral properties of Trp-212 in fragment C suggest its location in a partially buried, inhomogeneous environment. They show great similarity to those of human serum albumin, which contains a single Trp at position 214. The Trp phosphorescence 0,0-bands of fragments C and N are fitted with Gaussian functions by computer, and their relative contributions to the phosphoresence 0,0-band of BSA are adjusted to fit the observed BSA 0,0-band. The wavelength dependence of the [D[-[E[ transition frequencies of fragments N and C is then weighted by their 0,0-band intensity, taking into account differences in spin alignment, and summed to predict the peak frequency of the [D[-[E[ band profile as a function of phosphorescence wavelength for the intact BSA. Good agreement between predicted and observed behavior of [D[-[E[ vs. wavelength for the intact protein provides strong evidence for the additivity of the phosphorescence and ODMR spectra of the individual Trp sites in BSA. We find that Trp-134 and Trp-212 have wavelength-independent and wavelength-dependent zero-field splittings, respectively.     

Phosphorescence and ODMR study of the binding interactions of acetylcholine receptor alpha-subunit peptides with alpha-cobratoxin.

Optical detection of magnetic resonance (ODMR) and phosphorescence spectroscopy have been applied to synthetic peptides derived from the alpha-subunit of the nicotinic acetylcholine receptor of Torpedo californica and their complexes with alpha-cobratoxin (CBTX). The CBTX Trp phosphorescence is strongly quenched by the proximal disulfide linkage, while the emission wavelengths and ODMR frequencies of the 18-mer alpha 181-198 indicate a more hydrophobic Trp environment than in the 12-mer alpha 185-196. Binding to CBTX produces a subtle increase in the hydrophobicity of the Trp environment for the peptides, in qualitative agreement with a recently proposed binding model, in which a receptor Trp residue interacts strongly with a hydrophobic cleft of the toxin.     

Effect of nucleic acid binding on the triplet state properties of tetrapeptides containing tryptophan and 6-methyltryptophan: a study by phosphorescence and ODMR spectroscopy

Complexes of four peptides [KWGK, KGWK, K(6MeW)GK, KG(6MeW)K] with the nucleic acids [poly(A), poly(C), poly(U), poly(I), and rG(8)] have been investigated by phosphorescence and optically detected magnetic resonance (ODMR) spectroscopy. The intrinsic spectroscopic probes used in these studies are tryptophan (W) and 6-methyltryptophan (6MeW). Binding to the nucleic acids results in a red-shift of the phosphorescence 0,0-band (delta E(0,0)) of the aromatic residue as well as a reduction of its zero-field splitting parameter (delta D). Results are compared with earlier studies of the HIV-1 nucleocapsid protein, NCp7, that contains a single tryptophan residue (Trp37) within a retroviral zinc finger sequence. Binding of poly(A) or poly(U) to the tetrapeptides induces larger delta E(0,0) and delta D than when bound to NCp7, indicating stronger stacking interactions. Poly(I), on the other hand, produces larger shifts in Trp37 of NCp7. Binding of rG(8) produces sequence-dependent effects in the peptides. When bound to NCp7, but in contrast with tetrapeptide binding, nucleic acids produce large changes in triplet state kinetics consistent with enhanced spin-orbit coupling. These results are discussed in terms of three limiting types of tryptophan-base interaction: intercalation, aromatic stacking, and edge-on interaction. These should have differing effects on the properties of the triplet state.     

Binding modes of inhibitors of ribonuclease T1 as elucidated by analysis of two-dimensional NMR

Aromatic proton and high field shifted methyl proton resonances of RNase T1 complexed with Guo, 2'GMP, 3'GMP, or 5'GMP were assigned to specific amino acid residues by analyses of the two-dimensional NMR spectra in comparison with the crystal structure of the RNase T1-2'GMP complex. These assignments were subsequently correlated to those of free RNase T1 [Hoffmann & Rüterjans (1988) Eur. J. Biochem. 177, 539-560]. The spatial proximities of amino acid residues as elucidated by NOESY spectra were found to be quite similar among free RNase T1 and the inhibitor complexes, showing that large conformational changes did not occur upon complex formation. However, small but appreciable conformational changes were induced, which were reflected by the systematic chemical shift changes of some amino acid residues in the active site. Furthermore, we confirmed that RNase T1 contains two specific binding sites, one for the guanine base and the other for the phosphate moiety. The inhibitors are forced to adapt their conformations to fit the guanine base and the phosphate moiety to each binding site on the enzyme. This is consistent with our previous studies that 2'GMP and 3'GMP take the syn form as a bound conformation, while 5'GMP takes the anti conformation around glycosidic bonds [Inagaki et al. (1985) Biochemistry 24, 1013-1020]. The slow-exchange process between free and bound forms involving Tyr42 and Tyr45 was found to be specific to the recognition of the guanine base.     

Binding modes of inhibitors to ribonuclease T1 as elucidated by the analysis of two-dimensional NMR

Aromatic proton and high field shifted methyl proton resonances of RNase T1 complexed with Guo, 2'GMP, 3'GMP or 5'GMP were assigned to specific amino acid residues by 2D-NMR spectra in comparison with the crystal structure of RNase T1-2'GMP complex. The spatial proximities of amino acid residues as elucidated by NOESY spectra were found to be quite similar among free RNase T1 and the inhibitor complexes, showing that large conformational changes did not occur upon complex formation. However, small but appreciable conformational changes were induced which were reflected by the systematic chemical shift changes of some amino acid residues in the active site. Furthermore, we confirmed that RNase T1 contains two specific binding sites, one for the guanine base and the other for the phosphate moiety. The inhibitors are forced to adapt their conformations to fit the guanine base and the phosphate moiety to each binding site on the enzyme. This is consistent with our previous studies that 2'GMP and 3'GMP take syn form as a bound conformation, while 5'GMP takes anti conformation around glycosidic bonds.     

Triplet state of tryptophan in proteins. 2. Differentiation between tryptophan residues 62 and 108 in lysozyme.

We have used optically detected magnetic resonance (ODMR) to characterize the degree of solvent availability of the tryptophan residues in lysozyme that are likely to be responsible for the observed phosphorescence. From the phosphorescence spectra, ODMR zero-field splittings (zfs), and ODMR line widths, we concur with the X-ray structure [Blake, C. C., Mair, G. A., North, A. C. T., Phillips, D. C., & Sarma, V. R. (1967) Proc. R. Soc. London, ser. B 167, 365-377] that Trp-62 behaves as an exposed residue and Trp-108 is buried. In addition, we present evidence that ODMR can be used in conjunction with conventional phosphorescence to evaluate the degree of order in the microenvironments of tryptophan in a protein containing several tryptophans. By the specific modification of residues Trp-62 and Trp-108, we have identified those portions of the ODMR lines in the native enzyme that are due to those specific residues. Barring major enzyme conformational changes in the vicinity of unmodified tryptophan residues when Trp-62 or Trp-108 are selectively modified, we find that Trp-108 dominates both the phosphorescence and the ODMR signals in native lysozyme. The results are discussed in view of previous fluorescence findings.     

Characterization of the tryptophan residues of Escherechia coli alkaline phosphatase by phosphorescence and optically detected magnetic resonance spectroscopy.

The phosphorescence and zero field optically detected magnetic resonance (ODMR) of the tryptophan (Trp) residues of alkaline phosphatase from Escherechia coli are examined. Each Trp is resolved optically and identified with the aid of the W220Y mutant and the terbium complex of the apoenzyme. Trp(109), known from earlier work to be the source of room-temperature phosphorescence (RTP), emits a highly resolved low-temperature phosphorescence (LTP) spectrum and has the narrowest ODMR bands observed thus far from any protein site, revealing a uniquely homogeneous local environment. The decay kinetics of Trp(109) at 1.2 K reveals that the major triplet population (70%) undergoes inefficient crystallike spin-lattice relaxation by direct interaction with lattice phonons, the remainder being relaxed efficiently by local disorder modes. The latter population is smaller than is typical for protein sites, suggesting an unusual degree of local rigidity and order consistent with the long-lived RTP. Trp(220) emits a broader LTP spectrum originating to the blue of Trp(109). It has typically broad ODMR bands consistent with local heterogeneity. The LTP of Trp(268) has an ill-defined origin blue shifted relative to Trp(220) and ODMR frequencies consistent with a greater degree of solvent exposure. Trp(268) has noticeable dispersion of its decay kinetics, consistent with quenching at the triplet level by a nearby disulfide residue.     

Spectroscopic studies of arsenic(III) binding to Escherichia coli RI methyltransferase and to two mutants, C223S and W183F.

The interactions of an arsenic (III) reagent, (CH3)2AsSCH2CONH2, with two Escherichia coli RI methyltransferase mutants, W183F and C223S, have been studied by phosphorescence, optically detected magnetic resonance, and fluorescence spectroscopy. The phosphorescence spectrum of the W183F mutant containing only one tryptophan at position 225 reveals a single 0,0-band that is red-shifted by 9.8 nm upon binding of As(III). Fluorescence titration of W183F with (CH3)2AsSCH2CONH2 produces a large tryptophan fluorescence quenching. Analysis of the quenching data points to a single high-affinity As(III) binding site that is associated with the fluorescence quenching. Triplet-state kinetic measurements performed on the perturbed tryptophan show large reductions in the lifetimes of the triplet sublevels, especially that of the T chi sublevel. As(III) binding to the enzyme at a site very close to the Trp225 residue induces an external heavy-atom effect, showing that the perturber atom is in van der Waals contact with the indole chromophore. In the case of the C223S mutant, a single tryptophan 0,0-band also is observed in the phosphorescence spectrum, but no change occurs upon addition of the As(III) reagent. Fluorescence titration of C223S with As(III) shows essentially no quenching of tryptophan fluorescence, in contrast with W183F. These results, along with previous triplet-state and biochemical studies on the wild-type enzyme [Tsao, D. H.H., & Maki, A. H. (1991) Biochemistry 30, 4565-4572], show that As(III) binds with high affinity to the Cys223 residue and that the Trp225 side chain is located close enough to that of Cys223 to produce a heavy-atom perturbation when As(III) is bound.     

Physical studies of tyrosine and tryptophan residues in mammalian A1 heterogeneous nuclear ribonucleoprotein. Support for a segmented structure.

The mammalian heterogeneous ribonucleoprotein (hnRNP) A1 and its constituent N-terminal domain, termed UP1, have been studied by steady-state and dynamic fluorimetry, as well as phosphorescence and optically detected magnetic resonance (ODMR) spectroscopy at cryogenic temperatures. The results of these diverse techniques coincide in assigning the site of the single tryptophan residue of A1, located in the UP1 domain, to a partially solvent-exposed site distal to the protein's nucleic acid binding surface. In contrast, tyrosine fluorescence is significantly perturbed when either protein associates with single-stranded polynucleotides. Tyr to Trp energy transfer at the singlet level is found for both UP1 and A1 proteins. Single-stranded polynucleotide binding induces a quenching of their intrinsic fluorescence emission, which can be attributed to a significant reduction (greater than 50%) of the Tyr contribution, while Trp emission is only quenched by approximately 15%. Tyrosine quenching effects of similar magnitude are seen upon polynucleotide binding by either UP1 (1 Trp, 4 Tyr) or A1 (1 Trp, 12 Tyr), strongly suggesting that Tyr residues in both the N-terminal and C-terminal domain of A1 are involved in the binding process. Tyr phosphorescence emission was strongly quenched in the complexes of UP1 with various polynucleotides, and was attributed to triplet state energy transfer to nucleic acid bases located in the close vicinity of the fluorophore. These results are consistent with stacking of the tyrosine residues with the nucleic acid bases. While the UP1 Tyr phosphorescence lifetime is drastically shortened in the polynucleotide complex, no change of phosphorescence emission maximum, phosphorescence decay lifetime or ODMR transition frequencies were observed for the single Trp residue. The results of dynamic anisotropy measurements of the Trp fluorescence have been interpreted as indicative of significant internal flexibility in both UP1 and A1, suggesting a flexible linkage connecting the two sub-domains in UP1. Theoretical calculations based on amino acid sequence for chain flexibility and other secondary structural parameters are consistent with this observation, and suggest that flexible linkages between sub-domains may exist in other RNA binding proteins. While the dynamic anisotropy data are consistent with simultaneous binding of both the C-terminal and the N-terminal domains to the nucleic acid lattice, no evidence for simultaneous binding of both UP1 sub-domains was found.     

Crystallographic characterization of wild-type and mutant ribonuclease T1 complexes with several ribonucleotides

Ribonuclease T1 and the mutant enzymes were cocrystallized with several ribonucleotides, including non-hydrolyzable substrate analogs of di- and triribonucleotides, which have a novel guanylate in which the 2'-hydroxyl group of the ribose is replaced by a fluorine atom. One of the mutant enzymes has a tryptophan residue, instead of Tyr45 of the wild-type enzyme, to enhance the binding of ribonucleotides to the enzyme and the other mutant enzyme has histidine and aspartate residues, instead of Asn43 and Asn44, respectively, to reproduce the natural substitutions found in ribonuclease Ms. Polymorphism of the crystals was observed for wild-type and mutant enzymes. However, orthorhombic crystals, which are virtually all isomorphous to each other, were successfully obtained from wild-type and mutant (Y45W) enzymes by the macroscopic seeding technique using mother crystals of the wild-type ribonuclease T1 complexed with 2'GMP or 3'GMP. The diffraction patterns of these crystals extend beyond 2.5 A resolution and the diffraction data were collected from some of the crystals on a diffractometer up to a range of 2.5 to 1.8 A resolution.     

Optically detected magnetic resonance of tryptophan residues in complexes formed between a bacterial single-stranded DNA binding protein and heavy atom modified poly(uridylic acid)

Optically detected magnetic resonance (ODMR) methods were employed to study three single-stranded DNA binding (SSB) proteins encoded by plasmids of enteric bacteria: pIP71a, R64, and F. Equilibrium binding isotherms obtained by fluorescence titrations reveal that the complexes of the plasmid SSB proteins with heavy atom modified polynucleotides are readily disrupted by salt. Since all the plasmid SSB proteins show limited solubility at low ionic strength (pIP71a greater than R64 greater than F), we were able to bind only the pIP71a protein to mercurated poly(uridylic acid) [poly(5-HgU)] and brominated poly(uridylic acid) [poly(5-BrU)]. ODMR results reveal the existence of at least one heavy atom perturbed, red-shifted, stacked Trp residue in these complexes. Amplitude-modulated phosphorescence microwave double resonance spectra display selectively the phosphorescence associated with Hg-perturbed Trp residue(s) in the pIP71a SSB protein-poly(5-HgU) complex, which has a broad, red-shifted 0,0-band. Our results suggest that Trp-135 in Escherichia coli SSB, which is absent in the plasmid-encoded SSB proteins, is located in a polar environment and is not involved in stacking interactions with the nucleotide bases. Phosphorescence spectra and lifetime measurements of the pIP71a SSB protein-poly (5-BrU) complex show that at least one Trp residue in the complex does not undergo stacking. This sets a higher limit of two stacking interactions of Trp residues with nucleotide bases in complexes of pIP71a SSB with single-stranded polynucleotides.     

Investigation of complexes formed between gene 32 protein from bacteriophage T4 and heavy-atom-modified single-stranded polynucleotides using optical detection of magnetic resonance

Optical detection of triplet-state magnetic resonance (ODMR) is employed to study the complexes formed between gene 32 protein (GP32), a single-stranded DNA-binding protein from bacteriophage T4, and the heavy-atom-derivatized polynucleotides poly(5-HgU) and poly(5-BrU). The triplet-state properties of some of the tryptophan (Trp) residues in the complexes are dramatically different from those in the free protein, in that they are subject to an external heavy-atom effect. Direct evidence for the presence of a heavy-atom effect, and hence a close-range interaction between mercurated or brominated nucleotide bases and Trp residues in the complex, is provided by the observation of the zero-field (D) + (E) ODMR transition of Trp, which is not normally observed in the absence of a heavy-atom perturbation. The amplitude-modulated phosphorescence-microwave double-resonance (AM-PMDR) technique is employed to selectively capture the phosphorescence spectrum originating from the heavy-atom-perturbed Trp residue(s) in the GP32-poly(5-HgU) complex. Arguments based on our experimental results lead to the conclusion that the heavy-atom perturbation arises from aromatic stacking interactions between Trp and mercurated bases. Wavelength-selected ODMR measurements reveal the existence of two environmentally distinct and spectrally different types of Trp in GP32. One of these types is perturbed selectively by the heavy atom and hence undergoes stacking interactions with the heavy-atom-derivatized bases of the polynucleotide while the second type of Trp residue is unaffected.(ABSTRACT TRUNCATED AT 250 WORDS)     

The properties of the interaction between bovine pancreatic ribonuclease a and mononucleotides supports the existence of several binding sub-sites in the enzyme

The binding of 5'AMP, 5'GMP, 5'CMP, 3'CMP and Cl6RMP to RNAase A was studied by means of the gel filtration technique. It was found that only one molecule of 3'CMP binds strongly to the enzyme although a very unspecific binding is also present. The interaction of 5'AMP and 5'GMP with the enzyme shows one strong binding site and several weak binding sites, whereas two molecules of 5'CMP bind to RNAase A with equal strength. Cl6RMP shows an anomalous behaviour as both split peaks and troughs are found in the chromatogram. The Ka values for 3'CMP and the strong binding site of 5'AMP and 5'GMP are very similar whereas that for the two binding sites of 5'CMP is smaller (about 2.2 X 10(-4)M-1 and 0.5 X 10(-4)M-1, respectively at pH 5.5, I = 0.01 and 25 degrees C). The results are in general agreement with the known multiplicity of ligand-binding subsites in RNAase A.