Phosphorescence and optically detected magnetic resonance of HIV-1 nucleocapsid protein complexes with stem-loop sequences of the genomic Psi-recognition element

The binding of NCp7, the nucleocapsid protein of human immunodeficiency virus type 1, to oligonucleotide stem--loop (SL) sequences of the genomic Psi-recognition element has been studied using fluorescence, phosphorescence, and optically detected magnetic resonance (ODMR). RNA SL2, SL3, and SL4 constructs bind with higher affinity than the corresponding DNAs. G to I substitutions in the SL3 DNA loop sequence lead to reduced binding affinity and significant changes in the triplet state properties of Trp37 of NCp7, implicating these bases in contacts with aromatic amino acid residues of the zinc finger domains of NCp7, in agreement with the NMR structure of the 1:1 complex of NCp7 and SL3 RNA [DeGuzman, R. N., Wu, Z. R., Stalling, C. C., Pappaladro, L., Borer, P. N., and Summers, M. F. (1998) Science 279, 384-388]. The NCp7 to SL binding stoichiometry is 2:1 for intact SL sequences but is reduced to 1:1 for SL variants with an abasic or hydrocarbon loop. It is proposed that Delta D/Delta E(0,0), where Delta D is the change in the zero-field splitting D parameter and Delta E(0,0) is the shift of the tryptophan phosphorescence origin, provides a measure of aromatic stacking interactions with nucleic acid bases. Values on the order of 10(-5) indicate significant stacking interactions, while values closer to 10(-6) result from interactions not involving aromatic stacking. Binding of NCp7 to oligonucleotide substrates produces shortened Trp37 triplet state lifetimes by enhancement of k(x) and an increase of the relative value of P(x), the intersystem crossing rate to the T(x) sublevel. These effects are attributed to a reduction in the degree of electronic symmetry of Trp37 in the complexes. Guanine and adenine triplet states produced by optical pumping of SL3 DNA are characterized. We find, as with tryptophan, that D < 3E.     

Comparative phosphorescence and optically detected magnetic resonance studies of fatty acid binding to serum albumin

The binding of free fatty acid to bovine serum albumin (BSA) and human serum albumin (HSA) was studied by phosphorescence and optical detection of triplet-state magnetic resonance spectroscopy in zero applied magnetic field. We have found that oleic acid perturbs the excited triplet state of Trp-134 but not that of Trp-212 in BSA. The assignment is made by comparing the BSA results with those obtained from oleic acid binding to HSA. The phosphorescence 0,0 band as well as the zero-field splittings of Trp-134 undergoes significant changes upon binding of oleic acid to BSA. Shifts of the 0,0-band wavelength and of the zero-field splittings point to large changes in the Trp-134 local environment which accompany the complex formation. The shifts are progressive until 3-4 mol of oleic acid is added. The spectroscopic changes may be attributed to Stark effects caused by a protein conformational change near Trp-134 in the BSA-oleate complex. Oleic acid binding has a minimal effect on the triplet-state properties of the single Trp-214 of HSA. The binding specificity with regard to chain length and unsaturation is reflected by the differences in the Trp environment when BSA forms complexes with various fatty acids.     

Comparative phosphorescence and optically detected magnetic resonance studies of pig and yeast glyceraldehyde-3-phosphate dehydrogenase

A comparative optically detected magnetic resonance (ODMR) investigation has been made of the tryptophan (Trp) residues of glyceraldehyde-3-phosphate dehydrogenase (GAPD) from pig and yeast. We find that pig GAPD emits phosphorescence from only two of the three distinct Trp sites, while yeast GAPD exhibits resolved 0,0-bands from all three Trps. Heavy atom effects observed in the CH3Hg(II)-sulfhydryl complex of pig GAPD resemble closely those reported earlier for the analogous rabbit GAPD-CH3Hg(II) complex. Trp-310, with a 0,0-band at 416 nm, undergoes a selective heavy atom perturbation as a result of CH3Hg(II) binding to the nearby Cys-281. The 416-nm peak in yeast GAPD is assigned to Trp-310 on the basis of ODMR, but no heavy atom effect of CH3Hg(II)-sulfhydryl complexing is observed because of the absence of Cys-281 in yeast, thus supporting this assignment. The 406-nm 0,0-bands of pig and rabbit GAPD and the 409-nm band of yeast GAPD are assigned to Trp-193, located in a subunit contact region. This residue is solvent exposed in the yeast enzyme but appears to be buried in a polar environment in the mammalian GAPD. These differences may be related to variations in subunit co-operativity between species. Trp-84 appears to be quenched in pig and rabbit GAPD, most likely by His-108. In yeast GAPD, on the other hand, Trp-84 is not quenched, probably because His-108 is further removed. The Trp-84 0,0-band of the yeast enzyme peaks at 420 nm, making it the most red-shifted Trp origin reported thus far.(ABSTRACT TRUNCATED AT 250 WORDS)     

Optically detected zero field magnetic resonance studies of proflavine-DNA and 3,4-benzpyrene-DNA complexes.

Optical detection of magnetic resonance has been used to observe the photoexcited triplet state zero-field transitions of proflavine in DNA and 3,4-benzpyrene in DNA at 2°K. The results suggest that optically detected magnetic resonance may be utilized for determining the local site distribution of small molecules bound to DNA.     

Optically detected triplet-state magnetic resonance studies of the DNA complexes of the bisquinoline analogue of echinomycin

The polymeric DNA and model duplex oligonucleotide complexes of the bisquinoline analogue of echinomycin (2QN) have been studied by optical detection of triplet-state magnetic resonance (ODMR) spectroscopy, with the quinoline chromophores of the drug used as intrinsic probes. Plots of ODMR transition frequencies versus monitored wavelength revealed heterogeneity in the phosphorescence emission of 2QN which was ascribed to the presence of a major and minor conformation of the drug in aqueous solutions (referred to as the red and blue forms of 2QN, respectively, in this report). ODMR results, in conjunction with findings from low-temperature phosphorescence investigations, indicate that the quinoline chromophores of the major (red) form of 2QN are involved in aromatic stacking interactions in complexes with the natural DNAs from Escherichia coli, Micrococcus lysodeikticus, Clostridium perfringens, and calf thymus as evidenced by red shifts in the phosphorescence 0,0-band of the drug, reductions in the phosphorescence lifetime and zero-field splitting (zfs) D and E parameters, and polarity reversals of the ODMR slow passage signals upon complex formation between the analogue and DNA. The polarity reversals, which reflect shifts in the triplet-state sublevel populations induced by complex formation, apparently result from changes in the triplet sublevel decay constants upon binding to the natural DNAs. The 2QN complexes of 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(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 self-complementary oligonucleotides d(ACGT)2, d(TCGA)2, and d(ACGTACGT)2 were also investigated. The extent of reduction of the zfs D parameter (delta D) for the major form of 2QN upon complex formation with the polymeric DNAs was found to scale linearly with the standard free energy of the drug-DNA interaction (delta G degrees) calculated from previously reported binding studies for these targets [Fox, K. R., et al. (1980) Biochem. J. 191, 729-740]. This relationship between spectroscopic and thermodynamic properties of the 2QN-polynucleotide complexes is a consequence of the effects of base stacking interactions on the electronic states of the intercalator, which were postulated to arise from second-order shifts of the ground-state and the triplet-state energies of the complex on the basis of a modification of the solvent effect theory of van Egmond et al. [(1975) Chem. Phys. Lett. 34, 423-426].     

Phosphorescence and optically detected magnetic resonance of 4',6-diamidino-2-phenylindole (DAPI) and its complexes with [d(CGACGTCG)]2 and [d(GGCCAATTGG)]2

Phosphorescence and optical detection of magnetic resonance (ODMR) is used to study the excited triplet state of 4',6-diamidino-2-phenyl indole (DAPI) and its complexes with the oligonucleotides [d(CGACGTCG)](2) and [d(GGCCAATTGG)](2), where binding occurs by intercalation between GC base pairs and by minor groove insertion, respectively. Weaker binding of DAPI to phosphate is also detected, and the triplet state of this complex is characterized. Intercalation with [d(CGACGTCG)](2) produces a phosphorescence redshift, while groove binding with [d(GGCCAATTGG)](2) leads to a blueshift. Both binding modes give rise to a small decrease in the zero-field splitting (zfs) of the DAPI triplet state. The largest redshift and zfs decrease are found for the phosphate complex. The phosphorescence lifetimes are shorter by an order of magnitude than that of indole or tryptophan as expected for the lower triplet state energy, E(00), of DAPI. The lifetimes agree well with a correlation with E(00) introduced by Siebrand [Siebrand, W. (1966) J. Chem. Phys. 44, 4055-4057] except for the [d(GGCCAATTGG)](2) minor groove complex with a lifetime that is about 20% too long. The longer lifetime is attributed to distortion of the amidino groups in this complex, resulting in less efficient intersystem crossing.     

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)     

alpha-Bungarotoxin binding to two acetylcholine receptor alpha-peptides and their methylmercury-modified analogs: intrinsic phosphorescence and optically detected magnetic resonance studies.

Phosphorescence and optically detected magnetic resonance (ODMR) have been used to characterize two synthetic peptides, alpha 181-198 and alpha 185-196, of the major binding determinant of the alpha-acetylcholine receptor (AChR) of Torpedo californica and its interaction with alpha-bungarotoxin (BgTX) using Trp as an intrinsic probe. BgTX conformational changes are suggested upon complexation with the peptides. Methylmercury-modified peptides show conformational heterogeneity which brings some of the modified Cys residues into proximity of peptide Trp(s). These modified peptides, when bound to BgTX, undergo structural changes which remove the tagged Cys from its close contact with the Trp residue(s) of the peptide.     

Triplet state of tryptophan in proteins: the nature of the optically detected magnetic resonance lines

Optical detection of magnetic resonance (ODMR) has been employed to examine the homogeneity of the tryptophan environment, both of the isolated residue in solvent, and of tryptophan in glucagon and lysozyme and azurin B (Pseudomonas aeruginosa). From the shifts in the zero-field splittings, we can safely conclude that tryptophan in lysozyme, azurin B, or glucagon does not have the same type of solvent interaction as the free residue. However, by "burning holes" in the OSMR lines, it is evident that the lines in these cases are inhomogeneously broadened. From the relative line widths and hole widths, it appears that ODMR can be used to examine the relative diversity of interactions for a luminescent amino acid in a protein. We have followed the ODMR line characteristics in a progression from free N-acetyl-L-tryptophanamide, to tryptophan in lysozyme, to "denatured" lysozyme, and present evidence that the line widths narrow as the tryptophan residues become less solvent accessible.     

Manganese substrate complexes of phosphofructokinase studies by pulsed magnetic resonance

The formation of binary, ternary, and quaternary complexes between phosphofructokinase, manganese, and substrates has been demonstrated by use of pulsed nuclear magnetic resonance techniques. A Scatchard plot of the interaction of manganese with phosphofructokinase as determined by electron paramagnetic resonance shows two types of manganese binding sites. Phosphofructokinase seems to contain one or two of the metal binding sites with K_d = 20 μm and ?_b ≦ 4, and perhaps, as many as 14 binding sites with K_d ~ 0.8 mm and ?_b ≦ 12 ± 2 per enzyme. Addition of ATP or ADP results in a further enhancement of the relaxation rate indicating ternary complex formation. The concentration of ATP and ADP which results in half maximal change of enhancement is 30–100 μm and 80 μm, respectively. No change in the water proton relaxation rate was detected upon addition of fructose-6-P or fructose-1,6-bisphosphate. A quaternary complex was detected by proton relaxation measurements upon addition of fructose-6-P to a reaction mixture containing β, γ-methylene ATP, manganese, and enzyme with 50 μm fructose-6-P required to obtain the half maximal observed effect. This evidence for a quaternary complex is consistent with a sequential reaction mechanism for phosphofructokinase.     

Study of the triplet state properties of tyrosines and tryptophan in azuring using optically detected magnetic resonance.

Optically detected magnetic resonance (ODMR) signals and phosphorescence spectra were seen of tyrosine in the P. aeruginosa and tryptophanless P. fluorescens azurins and of tryptophan in the former. This confirmed a conclusion from other experiments that the tryptophan of P. aeruginosa cannot effectively quench the singlet energy of both tyrosines. The ODMR signals were all very narrow, additional evidence that the chromophores are buried in the interior of the protein. Accurate values of the zero-field coupling constants D and E lead to a tentative correlation of D values with the red shift of the 0 leads to 0 peak of the phosphorescence spectrum. The environment of tryptophan in P. aeruginosa is the most hydrocarbon like of any tryptophan so far observed. The experiments raise a number of unanswered questions concerning rate processes. The intensities of the 2E transition of tyrosine and the phosphorescence of both tyrosine and tryptophan are substantially reduced when the copper is oxidized. Nevertheless the phsphorescence lifetimes are unaffected. A hole cannot be burned in the ODMR resonances. The homogeneously broadened lines may conceivably be a result of low-temperature proton tunnelling.     

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.     

A comparative investigation of snake venom neurotoxins and their triplet-state tryptophan-disulfide interactions using phosphorescence and optically detected magnetic resonance.

We have investigated the luminescence and optically detected magnetic resonance (ODMR) of the highly homologous snake venom neurotoxins alpha-bungarotoxin (BgTX), alpha-cobratoxin (CbTX), and cobrotoxin (CoTX) in frozen aqueous glasses. The phosphorescence intensity and lifetime of the single invariant tryptophan, Trp29, are found to be diminished in BgTX and CbTx relative to CoTX both at 77 K and at 4.2 K. Selective reduction of the Cys30-Cys34 disulfide proximal to Trp29 in BgTX and CbTX, that is absent in CoTX, results in the enhancement of the phosphorescence to fluorescence intensity ratio of Trp29 and identifies this disulfide as the source of the triplet-state quenching. Variations of the phosphorescence parameters are observed for differently frozen BgTX and CbTX samples. We argue that this observation is consistent with conformational flexibility in the region of Trp29. For BgTX and CbTX, changing the wavelength of excitation from 285 to 300 nm results in a small bathochromic phosphorescence shift of 0.4 nm, an average decrease in the lifetime, and a change in the polarity of the normally positive D-E ODMR signal. From the small excitation-dependent emission shift, we infer that Trp29 is in a relatively hydrophobic environment. The excitation-dependent changes in lifetime and ODMR signal parameters arise from subtle heterogeneity in the disposition of Trp29 with respect to Cys30-Cys34. We discuss the mechanism of disulfide-induced quenching of the Trp29 triplet state in BgTX and CbTX and argue that it most probably is due to electron transfer.     

Phosphorus nuclear magnetic resonance studies of phosphoglucomutase and its metal ion complexes.

The ³¹P nuclear magnetic resonance of the covalently bound phosphate group at the active site of phosphoglucomutase has been examined by means of Fourier transform nuclear magnetic resonance spectroscopy. At a pD of 7.9, the chemical shift of the ³¹P nucleus is 3.8 ± 0.1 ppm downfield from 85% H₃PO₄; this shift is close to that of phosphoserine (dianionic form). Proton decoupling experiments suggest that the phosphorus of the enzymic phosphate group is coupled to protons with chemical shifts similar to those of phosphoserine. In D₂O, with proton decoupling, the ratio of the longitudinal and transverse diamagnetic relaxation times in solutions of 1.6 mm phosphoenzyme yields an approximate correlation time of 10^?7s for the ³¹P nucleus of the enzyme. This is within the range of values expected for tumbling of the entire protein molecule and suggests that the covalently attached phosphate group is immobilized or “frozen” at the active site of the enzyme by means of noncovalent interactions with adjacent groups. Consistent with this, the pK_a of the enzymic phosphate is significantly lower than that of phosphoserine. Binding of the diamagnetic activator, Mg²⁺, causes little or no change in the chemical shift of the resonance of the enzymic phosphorus from pD = 5.3 to 7.6, a downfield shift (?0.5 ± 0.1 ppm) at pD = 8.6, but an upfield shift (0.8 ±0.1 ppm) for that of phosphoserine, suggesting that bound Mg²⁺ is not coordinated to the enzymic phosphate. Independent evidence against direct coordination is provided by the paramagnetic effects of Ni²⁺ bound at the active site on the relaxation rates of the enzymic phosphorus. By assessing the paramagnetic effect of bound Ni²⁺ on both the longitudinal and transverse relaxation rates of the observed resonance, and by using correlation times determined for water proton relaxation induced by the Ni²⁺ complex, a range of Ni²⁺ to phosphorus distances of 4 to 6 Å is calculated. These distances suggest a second sphere interaction between the enzyme-bound metal and the enzymic phosphate group. Bound Ni²⁺ also markedly decreases the integrated intensity of the ³¹P resonance. Although the reason for this intensity decrease is incompletely explained, the present data establish the close proximity of the bound metal ion and the active site phosphoserine on phosphoglucomutase.