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.     

NMR structure of the complex between the zinc finger protein NCp10 of Moloney murine leukemia virus and the single-stranded pentanucleotide d(ACGCC): comparison with HIV-NCp7 complexes.

The structure of the 56 amino acid nucleocapsid protein NCp10 of retrovirus MoMuLV, which contains a single CX(2)CX(4)HX(4)C-type zinc finger, has been determined previously by NMR. The important role of NCp10 (or NCp7 for HIV-1) in the retroviral life cycle seems mainly related to their preferential binding to single-stranded nucleic acids. We report here the structure of the complex formed between the biologically active (14-53)NCp10 and the oligonucleotide d(ACGCC) in aqueous solution determined by 2D (1)H NMR based methods. The aromatic residue Trp(35) of NCp10 directs nucleic acid complexation as shown by its complete fluorescence quenching upon addition of d(ACGCC). (1)H and (31)P NMR studies support the insertion of Trp(35) between the G(3) and C(4) bases. A total of 577 NOE distance restraints, of which 40 were intermolecular, were used for the structure determination. The zinc finger provides a well-defined surface for the binding of d(ACGCC) through hydrophobic interactions and tryptophan stacking on the guanine. This latter interaction was also observed in the NMR-derived structures of the complexes between NCp7, which contains two successive zinc fingers, and single-stranded DNA and RNA, supporting the proposal for a major role played by aromatic residues of NCp proteins in nucleic acid recognition. Upon binding to the nucleotide a new loop in NCp10 that participates in the intermolecular interaction is formed. Additional interactions provided by positively charged residues surrounding the zinc finger appear necessary for tight binding. The structure of the complex NCp10-d(ACGCC) gives a structural explanation for the loss of virus infectivity following point mutations in the finger domain.     

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.     

Time-resolved fluorescence investigation of the human immunodeficiency virus type 1 nucleocapsid protein: influence of the binding of nucleic acids

Depending on the HIV-1 isolate, MN or BH10, the nucleocapsid protein, NCp7, corresponds to a 55- or 71-amino acid length product, respectively. The MN NCp7 contains a single Trp residue at position 37 in the distal zinc finger motif, and the BH10 NCp7 contains an additional Trp, at position 61 in the C-terminal chain. The time-resolved intensity decay parameters of the zinc-saturated BH10 NCp7 were determined and compared to those of single-Trp-containing derivatives. The fluorescence decay of BH10 NCp7 could be clearly represented as a linear combination (with respect to both lifetimes and fractional intensities) of the individual emitting Trp residues. This suggested the absence of interactions between the two Trp residues, a feature that was confirmed by molecular modeling and fluorescence energy transfer studies. In the presence of tRNAPhe, taken as a RNA model, the same conclusions hold true despite the large fluorescence decrease induced by the binding of tRNAPhe. Indeed, the fluorescence of Trp37 appears almost fully quenched, in keeping with a stacking of this residue with the bases of tRNAPhe. Despite the multiple binding sites in tRNAPhe, the large prevalence of ultrashort lifetimes, associated with the stacking of Trp37, suggests that this stacking constitutes a major feature in the binding process of NCp7 to nucleic acids. In contrast, Trp61 only stacked to a small extent with tRNAPhe. The behavior of this residue in the tRNAPhe-NCp7 complexes appeared to be rather heterogeneous, suggesting that it does not constitute a major determinant in the binding process. Finally, our data suggested that the binding of NCp7 proteins from the two HIV-1 strains to nonspecific nucleic acid sequences was largely similar.     

Triplet state properties of tryptophan residues in complexes of mutated Escherichia coli single-stranded DNA binding proteins with single-stranded polynucleotides.

Complexes of point-mutated E. coli single-stranded DNA-binding protein (Eco SSB) with homopolynucleotides have been investigated by optical detection of magnetic resonance (ODMR) of the triplet state of tryptophan (Trp) residues. Investigation of the individual sublevel kinetics of the lowest triplet state of Trp residues 40 and 54 in the poly (dT) complex of Eco SSB-W88F,W135F (a mutant protein whose Trp residues at positions 88 and 135 have been substituted by Phe) shows that Trp 54 is the most affected residue upon stacking with thymine bases, confirming previous results based on SSB mutants having single Trp----Phe substitutions. (Zang, L. H., A. H. Maki, J. B. Murphy, and J. W. Chase. 1987. Biophys. J. 52:867-872). The Tx sublevel of Trp 54 shows a fourfold increase in the decay rate constant, as well as an increase in its populating rate constant by selective spin-orbit coupling. The two nonradiative sublevels show no change in lifetime, relative to unstacked Trp. For Trp 40, a weaker perturbation of Tx by thymine results in a sublevel lifetime about one-half that of normal Trp. Trp54 displays a 2[E]transition of negative polarity in the double mutant SSB complex with Poly (dT), but gives a vanishingly weak [D] - [E] signal, thus implying that the steady-state sublevel populations of Tx and Tz are nearly equal in this residue. Poly (5-BrU) induces the largest red-shift of the Eco SSB-W88F,W135F Trp phosphorescence 0,0-band of all polynucleotides investigated. Its phosphorescence decay fits well to two exponential components of 1.02 and 0.12 s, with no contribution from long-lived Trp residues. This behavior provides convincing evidence that both Trp 40 and 54 are perturbed by stacking with brominated uridine. The observed decrease in the Trp [D] values further confirms the stacking of the Trp residues with 5-BrU. Wave-length-selected ODMR experiments conducted on the [D[ + [E] transition of Eco SSB-W88F,W135F complexed with poly(5HgU) indicate the presence of multiple heavy atom-perturbed sites. Measurements made on poly (5-HgU) which each of its 4 Trp residues has been replaced in turn by Phe demonstrate that Trp 40 and 54 are the only Trp residues undergoing stacking with nucleotide bases, as previously proposed.     

Phosphorescence properties and protein structure surrounding tryptophan residues in yeast, pig, and rabbit glyceraldehyde-3-phosphate dehydrogenase

An investigation of the phosphorescence emission properties of tryptophan (Trp) was carried out in glyceraldehyde-3-phosphate dehydrogenase from yeast and from pig and rabbit muscle. Aided by the external heavy-atom effect of iodide, the dependence on excitation wavelength, and thermal quenching profiles, it was established that the 0,0 vibronic band peaked at 406 nm in the pig and rabbit proteins is made up of overlapping contributions from two Trp residues. In contrast to a previous report [Davis, J.M., & Maki, A.H. (1984) Biochemistry 23, 6249-6256], this implies that even in the muscle enzymes all three aromatic side chains are phosphorescent. Further, when the nature of the local environment of each residue is compared to the crystallographic structure of lobster GPDH, it leads to a complete new assignment of the individual phosphorescence spectra. With each protein, a single Trp, identified as Trp-310, was found to display long-lived phosphorescence at room temperature. The decay of this emission gives evidence of conformational homogeneity among the subunits of the tetrameric molecule.     

Structural and dynamic characterization of the aromatic amino acids of the human immunodeficiency virus type I nucleocapsid protein zinc fingers and their involvement in heterologous tRNA(Phe) binding: a steady-state and time-resolved fluorescence study.

The steady-state and time-resolved fluorescence properties of two zinc-saturated 18-residue synthetic peptides with the amino acid sequence of the NH2-terminal (NCp7 13-30 F16W, where the naturally occurring Phe was replaced by a Trp residue) and the COOH-terminal (NCp7 34-51) zinc finger domains of human immunodeficiency virus type I nucleocapsid protein were investigated. Fluorescence intensity decay of both Trp 16 and Trp 37 residues suggested the existence of two fully solvent-exposed ground-state classes governed by a C = 2.2 equilibrium constant. The lifetimes of Trp 16 classes differed from those of Trp 37 essentially because of differences in nonradiative rate constants. Arrhenius plots of the temperature-dependent nonradiative rate constants suggested that the fluorescence quenchers involved in both classes and in both peptides were different and the collisional rate of these quenchers with the indole ring was very low, probably because of the highly constrained peptide chain conformation. The nature of the ground-state classes was discussed in relation to 1H nuclear magnetic resonance data. Using Trp fluorescence to monitor the interaction of both peptides with tRNA(Phe) we found that a stacking between the indole ring of both Trp residues and the bases of tRNA(Phe) occurred. This stacking constituted the main driving force of the interaction and modified the tRNA(Phe) conformation. Moreover, the binding of both fingers to tRNA(Phe) was noncooperative with similar site size (3 nucleotide residues/peptide), but the affinity of the NH2-terminal finger domain (K = 1.3 (+/- 0.2) 10(5) M-1) in low ionic strength buffer was one order of magnitude larger than the COOH-terminal one due to additional electrostatic interactions involving Lys 14 and/or Arg 29 residues.     

Affinities of packaging domain loops in HIV-1 RNA for the nucleocapsid protein

To design anti-nucleocapsid drugs, it is useful to know the affinities the protein has for its natural substrates under physiological conditions. Dissociation equilibrium constants are reported for seven RNA stem-loops bound to the mature HIV-1 nucleocapsid protein, NCp7. The loops include SL1, SL2, SL3, and SL4 from the major packaging domain of genomic RNA. The binding assay is based on quenching the fluorescence of tryptophan-37 in the protein by G residues in the single-stranded loops. Tightly bound RNA molecules quench nearly all the fluorescence of freshly purified NCp7 in 0.2 M NaCl. In contrast, when the GGAG-tetraloop of tight-binding SL3 is replaced with UUCG or GAUA, quenching is almost nil, indicating very low affinity. Interpreting fluorescence titrations in terms of a rapidly equilibrating 1:1 complex explains nearly all of the experimental variance for the loops. Analyzed in this way, the highest affinities are for 20mer SL3 and 19mer SL2 hairpin constructs (K(d) = 28 +/- 3 and 23 +/- 2 nM, respectively). The 20mer stem-UUCG-loop and GAUA-loop constructs have <0.5% of the affinity for NCp7 relative to SL3. Affinities relative to SL3 for the other stem-loops are the following: 10% for a 16mer construct to model SL4, 30% for a 27mer model of the 9-residue apical loop of SL1, and 20% for a 23mer model of a 1 x 3 asymmetric internal loop in SL1. A 154mer construct that includes all four stem-loops binds tightly to NCp7, with the equivalent of three NCp7 molecules bound with high affinity per RNA; it is also possible that two strong sites and several weaker ones combine to give the appearance of three strong sites.     

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)     

Phosphorescence and optically detected magnetic resonance studies of echinomycin-DNA complexes

Echinomycin complexes with polymeric DNAs and model duplex oligonucleotides have been studied by low-temperature phosphorescence and optical detection of triplet-state magnetic resonance (ODMR) spectroscopy, with the quinoxaline chromophores of the drug used as intrinsic probes. Although not optically resolved, plots of ODMR transition frequencies versus monitored wavelength revealed heterogeneity in the phosphorescence emission of echinomycin, which was ascribed to the presence of two distinct quinoxaline triplet-state environments (referred to as the blue and red triplet states of echinomycin in this report). We think that a likely origin of the two triplet states of echinomycin is the occurrence of two or more distinct conformations of the drug in aqueous solutions. Spectroscopically observed perturbations of the triplet-state properties of echinomycin such as the phosphorescence emission spectrum, phosphorescence lifetime, ODMR spectrum, and zero-field splitting (zfs) energies were investigated upon drug binding to the double-stranded alternating copolymers poly(dG-dC).poly(dG-dC) [abbreviated as poly[d(G-C)2]] and poly(dA-dT).poly(dA-dT) [abbreviated as poly[d(A-T)2]], the homopolymer duplexes poly(dG).poly(dC) [abbreviated as poly(dG.dC)] and poly(dA).poly(dT) [abbreviated as poly(dA.dT)], and the natural DNAs from Escherichia coli, Micrococcus lysodeikticus, and calf thymus. Echinomycin bisintercalation complexes with the self-complementary oligonucleotides d(ACGT), d(CGTACG), and d(ACGTACGT), which are thought to model drug binding sites, were also investigated. Phosphorescence and ODMR spectroscopic results indicate that the quinoxaline chromophores of the drug are involved in aromatic stacking interactions in complexes with the natural DNAs as evidenced by red shifts in the phosphorescence 0,0 band of the drug, a small but significant reduction in the phosphorescence lifetime of the red triplet state, and reduction of the zfs D-value of both the blue and red triplet states upon drug complexation. These changes in the triplet-state properties of echinomycin are consistent with stacking interactions that increase the polarizability of the quinoxaline environment. The extent of the reduction of the D parameter for the red triplet state upon complexation with the polymeric DNAs was found to correlate with the binding affinities measured for these targets [Wakelin, L. P. G., & Waring, M. J. (1976) Biochem. J. 157, 721-740], with the single exception of the drug-poly[d(G-C)2] complex, for which an increase in the D-value was noted. In addition, upon drug binding to the natural DNAs, there is a reversal of signal polarity in the ODMR spectra of the red triplet state. Among the synthetic DNA polymers investigated, a reversal of ODMR signal polarity was found only with the echinomycin-poly[d(A-T)2] complex.(ABSTRACT TRUNCATED AT 400 WORDS)     

Phosphorescence and optically detected magnetic resonance measurements of the 2'AMP and 2'GMP complexes of a mutant ribonuclease T1 (Y45W) in solution: correlation with X-ray crystal structures.

Phosphorescence and ODMR measurements have been made on ribonuclease T1 (RNase T1), the mutated enzyme RNase T1 (Y45W), and their complexes with 2'GMP and 2'AMP. It is not possible to observe the phosphorescence of Trp45 in RNase T1 (Y45W). Only that of the naturally occurring Trp59 is seen. The binding of 2'GMP to wild-type RNase T1 produces only a minor red shift in the phosphorescence and no change in the ODMR spectrum of Trp59. However, a new tryptophan 0,0-band is found 8.2 nm to the red of the Trp59 0,0-band in the 2'GMP complex of the mutated RNase T1 (Y45W). Wavelength-selected ODMR measurements reveal that the red-shifted emission induced by 2'GMP binding, assigned to Trp45, occurs from a residue with significantly different zero-field splittings than those of Trp59, a buried residue subject to local polar interactions. The phosphorescence red shift and the zero-field splitting parameters demonstrate that Trp45 is located in a polarizable environment in the 2'GMP complex. In contrast with 2'GMP, binding of 2'AMP to RNase T1 (Y45W) induces no observable phosphorescence emission from Trp45, but leads only to a minor red shift in the phosphorescence origin of Trp59 in both the mutated and wild-type enzyme. The lack of resolved phosphorescence emission from Trp45 in RNase T1 (Y45W) implies that the emission of this residue is quenched in the uncomplexed enzyme. We conclude that local conformational changes that occur upon binding 2'GMP remove quenching residues from the vicinity of Trp45, restoring its luminescence.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stacking interactions of tryptophan residues and nucleotide bases in complexes formed between Escherichia coli single-stranded DNA binding protein and heavy atom-modified poly(uridylic) acid. A study by optically detected magnetic resonance spectroscopy

The complexes formed between Escherichia coli single-stranded DNA binding protein (SSBP) and the heavy atom-modified single-stranded polynucleotides poly(5-BrU) and poly(5-HgU) are investigated using optically detected magnetic resonance (ODMR) methods. In these complexes the triplet state properties of the tryptophan residues are subjected to the external heavy atom effect generated by bromine and mercury atoms and are characterized by a shortened triplet state lifetime and the appearance of the otherwise dark [D] + [E] slow passage ODMR signal. These features provide direct evidence for close range interactions between tryptophan residue(s) and the nucleotide bases in the complexes. The extent of the triplet state lifetime reduction in the case of the SSBP-poly(5-HgU) complex together with steric considerations of the complex structure is consistent only with a van der Waals contact between the perturbed molecule and the heavy atom perturber by means of a stacking interaction. Fast passage ODMR measurements show a lifetime for a sublevel of the perturbed tryptophan chromophore(s) in this complex on the order of 1 ms. The amplitude-modulated phosphorescence microwave double resonance technique captures selectively the broadened and red-shifted phosphorescence spectrum of the heavy atom-perturbed tryptophan residue(s). This work supports a model for the binding of SSBP to single-stranded polynucleotides in which the bases are inserted into hydrophobic regions of the protein, where they are likely to undergo stacking interactions with the indole moiety of buried tryptophan residues.     

Nucleic acid binding properties of the simian immunodeficiency virus nucleocapsid protein NCp8

The nucleocapsid protein of simian immunodeficiency virus (SIV) NCp8 has two copies of conserved sequences (termed zinc fingers, ZF) of 14 amino acids with 4 invariant residues (CCHC) that coordinate Zn(II). Each of its two ZFs has a Trp residue. A significant quenching of NCp8 Trp fluorescence was seen in nucleic acid complexes, suggesting stacking of the indole ring with nucleobases and the simultaneous involvement of both ZFs in the binding process. Both ZFs contribute to the nucleic acid binding free energy of NCp8, albeit in a not additive manner. NCp8 exhibited a base preference analogous to that of NCp7: G approximately I > T > U > C > A. Alternating base sequences that bind HIV-1 NCp7 in a sequence-specific manner were also bound selectively by NCp8. Specific sequence recognition required at least five bases and the presence of bound Zn(II). The two ZFs account for the net displacement of 3 out of 4 sodium ions upon binding (2 by the first and one by the second finger), and for most (85%) of the hydrophobic stabilization in complex formation. Based on the sequence and functional similarity of SIV NCp8 and HIV-1 NCp7, and using available structural information for free and oligonucleotide bound NCp7, we propose a structural model for NCp8-oligonucleotide complexes.     

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.     

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.     

Temperature dependence of the phosphorescence quantum yield of various alpha-lactalbumins and of hen egg-white lysozyme.

The radiative quantum yield, phi op, of the triplet state of human alpha-lactalbumin (HLA) has been measured in the temperature range between 6 K and the softening point of the aqueous glass (approximately 150 K). phi op has little temperature dependence below approximately 30 K, but above this it decreases sharply with increasing temperature. The unusual temperature dependence is fitted by a phenomenological two-state model in which the phosphorescence originates primarily from a donor, tryptophan (Trp) 104, and an acceptor, Trp 60, the populations of which are coupled by a thermally activated triplet-triplet energy transfer process. The model assumes that the acceptor (Trp 60) triplet state undergoes radiationless deactivation by a proximal disulfide residue, while the donor (Trp 104) has no such extrinsic quencher. The decrease of phi op with increasing temperature is accounted for by the thermally activated triplet-triplet energy transfer process. The disulfide quenching rate constant itself is assumed to be temperature independent, in accord with recent measurements of simple disulfide quenching in long chain snake venom neurotoxins (Schlyer, B. D., E. Lau, and A. H. Maki. 1992. Biochemistry. 31:4375-4383; Li, Z., A. Bruce, and W. C. Galley. 1992. Biophys. J. 61:1364-1371). We find that the phosphorescence quenching in HLA occurs with an activation energy of 97 cm-1, which we associate with a barrier to the energy transfer process. The data are fit well by the model if we assume a value for the temperature-independent disulfide quenching constant of kQ > 3 s-1 that is consistent with recent measurements on indole-disulfide model systems (Li, Z., A. Bruce, and W. C. Galley. 1992. Biophys. J. 61:1364-1371). Similar results are reported for bovine alpha-lactalbumin (BLA) and for hen egg-white lysozyme (HEWL) that contains the structural equivalents of Trp 104 and Trp 60 of HLA. HLA provides the best agreement with calculations since it is the simplest, lacking Trp 26, a residue not considered in the model, that probably contributes significantly to the phosphorescence of BLA, guinea pig alpha-lactalbumin (GPLA), and HEWL. GPLA, which contains Trp 104 but lacks Trp 60, shows qualitatively less thermally induced phosphorescence quenching than HLA, BLA, and HEWL, thus supporting the postulated quenching model.     

Time resolved fluorescence and phosphorescence properties of the individual tryptophan residues of barnase: evidence for protein-protein interactions.

Steady-state and time-resolved fluorescence, as well as phosphorescence measurements, were used to resolve the luminescence properties of the three individual tryptophan residues of barnase. Assignment of the fluorescence properties was performed using single-tryptophan-containing mutants and the results were compared with the information available from the study of wild-type and two-tryptophan-containing mutants (Willaert, Lowenthal, Sancho, Froeyen, Fersht, Engelborghs, Biochemistry 1992;31:711-716). The fluorescence and the phosphorescence emission of wild-type barnase is dominated by Trp35, although Trp71 has the strongest intrinsic fluorescence when present alone. Fluorescence emission of these two tryptophan residues is blue-shifted and pH-independent. The fluorescence decay parameters of Trp94 are pH-dependent, and an intramolecular collision frequency of 2 to 5 x 10(9) s(-1) between Trp94 and His18 is calculated. Fluorescence emission of Trp94 is red-shifted. Fluorescence anisotropy decay reveals the local mobility of the individual tryptophan residues and this result correlates well with their phosphorescence properties. Trp35 and Trp71 display a single phosphorescence lifetime, which reflects the rigidity of their environment. Surface Trp94 does not exhibit detectable phosphorescence emission. The existence of energy transfer between Trp71 and Trp94, as previously detected by fluorescence measurements, is also observed in the phosphorescence emission of barnase. Dynamic quenching causes the phosphorescence intensity to be protein-concentration dependent. In addition, fluorescence anisotropy shows concentration dependency, and this can be described by the formation of trimers in solution.     

Optically detected magnetic resonance study of tyrosine residues in point-mutated bacteriophage T4 lysozyme

Two spectroscopically distinct types of tyrosine (Tyr) residues in triply point mutated bacteriophage T4 lysozyme, which contains no tryptophan (Trp), have been detected by optical detection of triplet-state magnetic resonance (ODMR) spectroscopy. Their triplet states are characterized by similar E but different D values. The Tyr site which exhibits the lower D value and has the red-shifted phosphorescence origin is quenched by energy transfer to Trp and has D and E values comparable to previously studied Tyr residues. The blue-shifted Tyr site, which is not quenched by Trp, exhibits a larger D value that has been found previously. Calculation of energy-transfer efficiencies of Tyr-Trp pairs based on the crystal structure of the native enzyme provides a possible assignment of Tyr sites to the two different spectral types.