NMR studies of the AMP-binding site and mechanism of adenylate kinase

NMR has previously been used to determine the conformation of enzyme-bound MgATP and to locate the MgATP-binding site on adenylate kinase [Fry, D. C., Kuby, S. A., & Mildvan, A. S. (1985) Biochemistry 24, 4680-4694]. To determine the conformation and location of the other substrate, AMP, distances have been measured from Cr3+AMPPCP, a linear competitive inhibitor with respect to MgATP, to six protons and to the phosphorus atom of AMP on adenylate kinase, with the paramagnetic probe-T1 method. Time-dependent nuclear Overhauser effects (NOEs) have been used to measure five interproton distances on enzyme-bound AMP. These distances were used to determine the conformation of bound AMP in addition to its position with respect to metal-ATP. Enzyme-bound AMP exhibits a high anti-glycosyl torsional angle (chi = 110 +/- 10 degrees), a 3'-endo,2'-exo ribose pucker (delta = 105 +/- 10 degrees), and gauche-trans orientations about the C4'-C5' bond (gamma = 180 +/- 10 degrees) and the C5'-O5' bond (beta = 170 +/- 20 degrees). The distance from Cr3+ to the phosphorus of AMP is 5.9 +/- 0.3 A, indicating a reaction coordinate distance of approximately 3 A, which is consistent with an associative SN2 mechanism for the phosphoryl transfer. Ten intermolecular NOEs, from protons of the enzyme to those of AMP, were detected, indicating the proximity of at least three hydrophobic amino acids to bound AMP. These constraints, together with the conformation of AMP and the intersubstrate distances, were used to position AMP into the X-ray structure of adenylate kinase. The AMP binding site is found to be near (less than or equal to 4 A from) Leu-116, Arg-171, Val-173, Val-182, and Leu-190; all of these residues have been found to be invariant in muscle-type rabbit, calf, human, porcine [Kuby, S. A., Palmieri, R. H., Frischat, A., Fischer, A. H., Wu, L. H., Maland, L., & Manship, M. (1984) Biochemistry 23, 2393-2399], and chicken adenylate kinase [Kishi, F., Maruyama, M., Tanizawa, Y., & Nakazawa, A. (1986) J. Biol. Chem. 261, 2942-2945].     

Solution structure of the 45-residue MgATP-binding peptide of adenylate kinase as examined by 2-D NMR, FTIR, and CD spectroscopy

The structure of a synthetic peptide corresponding to residues 1-45 of rabbit muscle adenylate kinase has been studied in aqueous solution by two-dimensional NMR, FTIR, and CD spectroscopy. This peptide, which binds MgATP and is believed to represent most of the MgATP-binding site of the enzyme [Fry, D.C., Kuby, S.A., & Mildvan, A.S. (1985) Biochemistry 24, 4680-4694], appears to maintain a conformation similar to that of residues 1-45 in the X-ray structure of intact porcine adenylate kinase [Sachsenheimer, W., & Schulz, G.E. (1977) J. Mol. Biol. 114, 23-26], with 42% of the residues of the peptide showing NOEs indicative of phi and psi angles corresponding to those found in the protein. The NMR studies suggest that the peptide is composed of two helical regions of residues 4-7 and 23-29, and three stretches of beta-strand at residues 8-15, 30-32, and 35-40, yielding an overall secondary structure consisting of 24% alpha-helix, 38% beta-structure, and 38% aperiodic. Although the resolution-enhanced amide I band of the peptide FTIR spectrum is broad and rather featureless, possibly due to disorder, it can be fit by using methods developed on well-characterized globular proteins. On this basis, the peptide consists of 35 +/- 10% beta-structure, 60 +/- 12% turns and aperiodic structure, and not more than 10% alpha-helix. The CD spectrum is best fit by assuming the presence of at most 13% alpha-helix in the peptide, 24 +/- 2% beta-structure, and 66 +/- 4% aperiodic. The inability of the high-frequency FTIR and CD methods to detect helices in the amount found by NMR may result from the short helical lengths as well as from static and dynamic disorder in the peptide. Upon binding of MgATP, numerous conformational changes in the backbone of the peptide are detected by NMR, with smaller alterations in the overall secondary structure as assessed by CD. Detailed assignments of resonances in the peptide spectrum and intermolecular NOEs between protons of bound MgATP and those of the peptide, as well as chemical shifts of peptide resonances induced by the binding of MgATP, are consistent with the previously proposed binding site for MgATP on adenylate kinase.     

Substrate and DNA binding to a 50-residue peptide fragment of DNA polymerase I. Comparison with the enzyme

The fluorescent nucleotide 2',3'-trinitrophenyl-ATP (TNP-ATP) binds at the triphosphate substrate binding site of the large (Klenow) fragment of DNA polymerase I (Pol I) as detected by direct binding studies measuring the increase in fluorescence of this ligand (n = 1.0, KD = 0.07 microM). The enzyme-TNP-ATP complex binds Mg2+ and Mn2+ tightly (KD = 0.05 microM) as measured by an increase in fluorescence on titrating with these metals. The substrate dGTP competitively displaces TNP-ATP from the enzyme (KD = 5.7 microM) de-enhancing the fluorescence. The polymerase reaction is half-maximally inhibited by 0.8 microM TNP-ATP in the presence of dATP (10 microM) as substrate. A region of the amino acid sequence of Pol I (peptide I) consisting of residues 728-777 has been synthesized and found to contain significant secondary structure by CD both in water and 50% methanol/water. In water at 3 degrees C, peptide I binds the substrate analog TNP-ATP (KD = 0.03 microM) with a stoichiometry of 0.2. In 50% methanol at 3 degrees C, peptide I binds TNP-ATP with a higher stoichiometry than in water, consistent with a 1:1 complex, but biphasically (16% of the peptide, KD = 0.09 microM; 84% of the peptide, KD = 5.0 microM), and competitively binds the Pol I substrates dATP, TTP, and dGTP (KD = 230-570 microM). Evidence from size exclusion high performance liquid chromatography suggests that these two forms of the peptide are monomer and dimer, respectively. Significantly, the peptide I-TNP-ATP complex binds duplex DNA, tightly (KD = 0.1-0.5 microM) and stoichiometrically, and single stranded DNA more weakly. The peptide I-duplex DNA complex binds both TNP-ATP (KD = 0.5-1.5 microM) and Pol I substrates (KD = 350-2100 microM) stoichiometrically. In a control experiment, a second peptide, peptide II, based on residues 840-888 of the Pol I sequence, retains secondary structure, as detected by CD, but displays no binding of TNP-ATP. The ability of peptide I, which represents only 8% of the large fragment of Pol I, to bind both substrates and duplex DNA indicates that residues 728-777 constitute a major portion of the substrate binding site of this enzyme.     

Synthesis and CD studies of an 88-residue peptide containing the main receptor binding site of HTLV-I SU-glycoprotein

Essential HTLV-I biological functions, like host-cell receptor recognition, depend on the structural motives on the surface glycoprotein gp46. We defined a peptide of 88 amino acids [Arg¹⁴⁷-Leu²³⁴] corresponding to the central part of the protein sequence, where major neutralizing epitopes are localized. After evaluating the feasibility of its chemical synthesis, the chosen sequence was realized using the stepwise solid-phase methodology. Multiple chromatographic purification steps were required to obtain a sample suitable for structural analysis. Correct folding was supported by strong binding of monooclonal antibodies, recognizing known exposed immunodominant regions. Circular dichroism studies confirmed a non-random conformation of at least 70–80% of the synthetic peptide. Investigation of the 3D-structure of the synthetic peptide will provide useful information for future vaccine and drug-design strategies. © 1997 European Peptide Society and John Wiley & Sons, Ltd. J. Pep. Sci.3: 347–353 No. of Figures: 5. No. of Tables: 0. No. of References: 23     

Two-dimensional NMR studies of the porcine muscle adenylate kinase

Porcine adenylate kinase was subjected to one- and two-dimensional proton NMR studies in order to identify amino acid spin systems and obtain sequence-specific resonance assignments. With a combination of results from a map of side-chain distances resulting from the refined X-ray crystallographic data and nuclear Overhauser effect spectroscopy (NOESY), assignments are suggested for all the aromatic spin systems.     

Quantitative 13C and 2H NMR relaxation studies of the 723-residue enzyme malate synthase G reveal a dynamic binding interface

A detailed understanding of molecular recognition is predicated not only on high-resolution static structures of the free and bound states but also on information about how these structures change with time, that is, molecular dynamics. Here we present a deuterium ((2)H) and carbon ((13)C) NMR relaxation study of methyl side chain dynamics in the 82 kDa enzyme malate synthase G (MSG) that is a promising target for the development of new antibiotic agents. It is shown that excellent agreement between (2)H- and (13)C-derived measures of dynamics is obtained, with correlation coefficients exceeding 0.95. The binding interface formed by MSG and its substrates is found to be highly dynamic in the ligand-free state of the enzyme with rigidification upon binding substrate. This study establishes that detailed, quantitative information about methyl side chain dynamics can be obtained by NMR on proteins with molecular masses on the order of 100 kDa and opens up the possibilities for studies of motion in a large number of important systems.     

Role of phosphate chain mobility of MgATP in completing the 3-phosphoglycerate kinase catalytic site: binding, kinetic, and crystallographic studies with ATP and MgATP

The complexes of pig muscle 3-phosphoglycerate kinase with the substrate MgATP and with the nonsubstrate Mg(2+)-free ATP have been characterized by binding, kinetic, and crystallographic studies. Comparative experiments with ADP and MgADP have also been carried out. In contrast to the less specific and largely ionic binding of Mg(2+)-free ATP and ADP, specific occupation of the adenosine binding pocket by MgATP and MgADP has been revealed by displacement experiments with adenosine and anions, as well as supported by isothermal calorimetric titrations. The Mg(2+)-free nucleotides similarly stabilize the overall protein structure and restrict the conformational flexibility around the reactive thiol groups of helix 13, as observed by differential scanning microcalorimetry and thiol reactivity studies, respectively. The metal complexes, however, behave differently. MgADP, but not MgATP, further increases the conformational stability with respect to its Mg(2+)-free form, which indicates their different modes of binding to the enzyme. Crystal structures of the binary complexes of the enzyme with MgATP and with ATP (2.1 and 1.9 A resolution, respectively) have shown that the orientation and interaction of phosphates of MgATP largely differ not only from those of ATP but also from the previously determined ones of either MgADP [Davies, G. J., Gamblin, S. J., Littlechild, J. A., Dauter, Z., Wilson, K. S., and Watson, H. C. (1994) Acta Crystallogr. D50, 202-209] or the metal complexes of AMP-PNP [May, A., Vas, M., Harlos, K., and Blake, C. C. F. (1996) Proteins 24, 292-303; Auerbach, G., Huber, R., Grattinger, M., Zaiss, K., Schurig, H., Jaenicke, R., and Jacob, U. (1997) Structure 5, 1475-1483] and are more similar to the interactions formed with MgAMP-PCP [Kovári, Z., Flachner, B., Náray-Szabó, G., and Vas, M. (2002) Biochemistry 41, 8796-8806]. Mg(2+) is liganded to both beta- and gamma-phosphates of ATP, while beta-phosphate is linked to the conserved Asp218, i.e., to the N-terminus of helix 8, through a water molecule; the known interactions of either MgADP or the metal complexes of AMP-PNP with the N-terminus of helix 13 and with Asn336 of beta-strand J are absent in the case of MgATP. Fluctuation of MgATP phosphates between two alternative sites has been proposed to facilitate the correct positioning of the mobile side chain of Lys215, and the catalytically competent active site is thereby completed.     

Geometric isomers of a photoactivable general anesthetic delineate a binding site on adenylate kinase

General anesthetics are a class of drugs whose mode of action is poorly understood. Here, two photoactivable general anesthetics, n-octan-1-ol geometric isomers bearing a diazirine group on either the third or seventh carbon (3- and 7-azioctanol, respectively), were used to locate and delineate an anesthetic site on adenylate kinase. Each photoincorporated at a mole ratio of 1:1 as determined by mass spectrometry. The photolabeled kinase was subjected to tryptic digest, and the fragments were separated by chromatography and sequenced by mass spectrometry. 3-Azioctanol photolabeled His-36, whereas its isomer, 7-azioctanol, photolabeled Asp-41. Inspection of the known structure of adenylate kinase shows that the side chains of these residues are within approximately 5 A of each other. This distance matches the separation of the 3- and 7-positions of an extended aliphatic chain. The alkanol site so-defined spans two domains of adenylate kinase. His-36 is part of the CORE domain, and Asp-41 belongs to the nucleotide monophosphate binding domain. Upon ligand binding the nucleotide monophosphate binding domain rotates relative to the CORE domain, causing a conformational change that might be expected to affect alkanol binding. Indeed, the substrate-mimicking inhibitor adenosine-(5')-pentaphospho-(5')-adenosine (Ap5A) reduced the photoincorporation of 3-[(3)H]azioctanol by 75%.     

Positions in human serum albumin which involve the indole binding site. Sequence of 107-residue fragment.

The first 107 residues of Fragment C of human serum albumin have been sequenced and two positions at which affinity labels block the indole site determined. Histidine 23 is the position of blockage by bromoacetyl-L-tryptophan and lysine 67 is the position of blockage by 5-dimethylaminonaphthalene-1-sulfonyl chloride and probably pyridoxal-5'-phosphate. The presence of an indole ligand at the binding site markedly reduces incorporation of the label into the above lysyl residue, and in the case of 5-dimethylaminonaphthalene-1-sulfonyl chloride, increases incorporation into three other positions, lysine residues 13, 39, and 84. It is concluded that binding of the indole ligand on the site brings about conformational changes in the albumin structure exposing new reactive positions for 5-dimethylaminonaphthalene-1-sulfonyl chloride. There is a large accumulation of basic and hydrophobic residues and no glycine, serine, threonine, valine, aspartate, or cysteine residues in the sequence 10 to 43. Lysine 71 has been identified by amino acid analyses and sequence studies as the position acetylated by acetylsalicylic acid (Hawkins, D. R., Pinckard, N., Crawford, C. P., and Farr, R. S. J. Clin. Invest. (1969) 48, 536), establishing the structural relationships of two major ligand binding sites on albumin. The lone tryptophan is at position 86. Evidence indicates that within residues 1 to 86 of Fragment C and within residues of the A-Phe fragment (Mr equals approximately 10,000), the latter known to be adjacent to Fragment C in the whole albumin structure, exists the major binding sites of all ligands for human serum albumin.     

A synthetic 13-residue peptide designed to resemble the primary binding site of the basic pancreatic trypsin inhibitor

A peptide, AC-Pro-Cys-Lys-Ala-Arg-Ile-DPhe-Pro-Tyr-Gly-Gly-Cys-Arg-NH2, which resembles the binding site of the basic pancreatic trypsin inhibitor, has been prepared by solid-phase peptide synthesis. A partially protected peptide was first obtained from the solid-phase product by removal of all side-chain protecting groups except the acetamidomethyl (Acm) groups on the cysteines. This di-Acm-peptide was deprotected, with concomitant formation of the cyclic product, by treatment with I2 in AcOH. The cyclic 13-residue peptide is a reversible, competitive inhibitor of trypsin with a Ki (app) of 2 . 10(-6) M, but loses its inhibitory activity upon incubation with trypsin. The di-Acm-peptide precursor has a Ki (app) of 5 . 10(-5) M and is deactivated more rapidly by trypsin. The effectiveness of the 13-residue peptides as inhibitors is in part attributed to the conformation induced by the beta-turn directing the -DPhe-Pro portion of the sequence.     

Design, NMR characterization and activity of a 21-residue peptide fragment of bacteriocin AS-48 containing its putative membrane interacting region.

Bacteriocin AS-48 is a 70-residue cyclic polypeptide from Enterococcus faecalis that shows a broad antimicrobial spectrum against both Gram-positive and Gram-negative bacteria. The structure of bacteriocin AS-48 consists of a globular arrangement of five helices with a high positive electrostatic potential in the region comprising helix 4, the turn linking helix 4 and 5, and the N-terminus of helix 5. This region has been considered to participate in its biological activity and in particular in membrane permeation. To understand the mechanism of the antibacterial activity of AS-48 and to discriminate the several mechanisms proposed, a simplified bacteriocin was designed consisting of 21 residues and containing the high positively charged region. A disulfide bridge was introduced at an appropriate position to stabilize the peptide and to conserve the helix-turn-helix arrangement in the parent molecule. According to (1)H and (13)C NMR data, the designed simplified bacteriocin fragment adopts a significant population of a native-like helical hairpin conformation in aqueous solution, which is further stabilized in 30% TFE. The designed peptide does not show any antibacterial activity, though it is shown to compete with the intact native bacteriocin AS-48. These results suggest that the mechanism of membrane disruption by bacteriocin is not as simple as being driven by a deposition of positively charged molecules on the plane of the bacterial membrane. Some other regions of the protein must be present such as, for instance, hydrophobic regions so as to enhance the accumulation of the peptide and favour membrane permeation.     

Conformational changes at the active site of adenylate kinase detected using a fluorescent probe and monoclonal antibody binding

A fluorescent probe, IAEDANS, was introduced into the active site of adenylate kinase (AK) by specifically modifying Cys-25. During modification, enzyme activity was greatly diminished. This probe allowed observation of conformational changes at the active site during denaturation that could not be detected directly in previous studies. The binding ability of modified AK with its monoclonal antibody (McAb3D3) was identical to that of native AK and the fluorescence of modified AK was quenched by interaction with McAb3D3. The relative fluorescence changes during the binding of modified AK with McAb3D3 in different concentrations of guanidine hydrochloride were monitored. The combination of this active site modification with the use of a conformation specific monoclonal antibody has potential for use in the study of the kinetics of folding of AK and in the detection of folding intermediates.     

NMR of a synthetic peptide spanning the triphosphate binding site of adenosine 5'-triphosphate in actin

The amino acid residues 114-118 in actin were found to be implicated strongly in the binding of nucleotide, and as would be expected for such an important binding site, they are located in a completely conserved region of the actin sequence. A 19-residue peptide with the actin sequence 106-124 was synthesized in order to span the putative triphosphate binding site. Proton NMR spectra of the actin peptide 114-118 in the presence and absence of ATP indicated that Arg-116 and Lys-118 are particularly involved in binding ATP. A strong binding of ATP to the peptide 106-124 also was measured. Tripolyphosphate bound to the peptide 106-124 somewhat more weakly than ATP. Binding involved residues 115-118 and 121-124, indicating the presence of a reverse turn between these segments. Proton resonances were assigned by using two-dimensional double quantum correlated spectroscopy, one-dimensional spin decoupling techniques, one-dimensional nuclear Overhauser enhancement difference spectroscopy, and pH titration. The alpha CH resonances of Ala-3 and Asn-6 are markedly shifted downfield with respect to values in small unstructured peptides due to their close proximity to the side chains of Pro-4 and Pro-7, respectively. Several other resonances display chemical shifts which are indicative of a structured environment. Assignment of the amide proton resonances in H2O and measurements of the coupling constant 3JHNCH and the chemical shifts of the amide protons reveal that much of the synthetic peptide, particularly the backbone, exhibits a highly structured environment and represents a good model for the triphosphate binding site in actin.     

In vitro mutagenesis studies at the arginine residues of adenylate kinase. A revised binding site for AMP in the X-ray-deduced model

Although X-ray crystallographic and NMR studies have been made on the adenylate kinases, the substrate-binding sites are not unequivocally established. In an attempt to shed light on the binding sites for MgATP2- and for AMP2- in human cytosolic adenylate kinase (EC 2.7.4.3, hAK1), we have investigated the enzymic effects of replacement of the arginine residues (R44, R132, R138, and R149), which had been assumed by Pai et al. [Pai, E. F., Sachsenheimer, W., Schirmer, R. H., & Schulz, G. E. (1977) J. Mol. Biol. 114, 37-45] to interact with the phosphoryl groups of AMP2- and MgATP2-. With use of the site-directed mutagenesis method, point mutations were made in the artificial gene for hAK1 [Kim, H. J., Nishikawa, S., Tanaka, T., Uesugi, S., Takenaka, H., Hamada, M., & Kuby, S. A. (1989) Protein Eng. 2, 379-386] to replace these arginine residues with alanyl residues and yield the mutants R44A hAK1, R132A hAK1, R138A hAK1, and R149A hAK1. The resulting large increases in the Km,app values for AMP2- of the mutant enzymes, the relatively small increases in the Km,app values for MgATP2-, and the fact that the R132A, R138A, and R149A mutant enzymes proved to be very poor catalysts are consistent with the idea that the assigned substrate binding sites of Pai et al. (1977) have been reversed and that their ATP-binding site may be assigned as the AMP site.     

Protein folding and function: the N-terminal fragment in adenylate kinase

Three-dimensional protein folds range from simple to highly complex architectures. In complex folds, some building block fragments are more important for correct protein folding than others. Such fragments are typically buried in the protein core and mediate interactions between other fragments. Here we present an automated, surface area-based algorithm that is able to indicate which, among all local elements of the structure, is critical for the formation of the native fold, and apply it to structurally well-characterized proteins. In particular, we focus on adenylate kinase. The fragment containing the phosphate binding, P-loop (the "giant anion hole") flanked by a beta-strand and an alpha-helix near the N-terminus, is identified as a critical building block. This building block shows a high degree of sequence and structural conservation in all adenylate kinases. The results of our molecular dynamics simulations are consistent with this identification. In its absence, the protein flips to a stable, non-native state. In this misfolded conformation, the other local elements of the structure are in their native-like conformations; however, their association is non-native. Furthermore, this element is critically important for the function of the enzyme, coupling folding, and function.     

NMR study of a 34-residue N-terminal fragment of the parathyroid-hormone-related protein secreted during humoral hypercalcemia of malignancy

The proton resonances of the biologically active peptide parathyroid-hormone-related protein (residues 1-34) were assigned using one-dimensional spin-decoupling techniques, two-dimensional correlated spectroscopy and by comparing the spectra of the peptides 1-20, 1-25, 1-29, 7-34 and 15-34. The conformation of 1-34 was determined using one- and two-dimensional nuclear Overhauser enhancement spectroscopy in the rotating frame. Amide proton temperature coefficients, vicinal coupling constants and circular dichroic spectra helped reveal a surprisingly compact structure with residues 3-9 forming alpha-helix, type-I beta-turns between residues 10-13 and 16-19 and several interactions between the N-terminal residues and the C-terminal residues. Of these latter, the strongest appeared to be between Asp-10 and Phe-22. One peptide surface in the deduced model presents multiple positive charges, while the opposite surface has a hydrophobic character possibly functioning to exclude water from the binding interface and enhancing the binding constant.     

Solution conformation of a peptide fragment representing a proposed RNA-binding site of a viral coat protein studied by two-dimensional NMR

The first 25 amino acids of the coat protein of cowpea chlorotic mottle virus are essential for binding the encapsidated RNA. Although an alpha-helical conformation has been predicted for this highly positively charged N-terminal region [Argos, P. (1981) Virology 110, 55-62; Vriend, G., Verduin, B. J. M., & Hemminga, M. A. (1986) J. Mol. Biol. 191, 453-460], no experimental evidence for this conformation has been presented so far. In this study, two-dimensional proton NMR experiments were performed on a chemically synthesized pentacosapeptide containing the first 25 amino acids of this coat protein [Ten Kortenaar, P. B. W., Krüse, J., Hemminga, M. A., & Tesser, G. I. (1986) Int. J. Pept. Protein Res. 27, 401-413]. All resonances could be assigned by a combined use of two-dimensional correlated spectroscopy and nuclear Overhauser enhancement spectroscopy carried out at four different temperatures. Various NMR parameters indicate the presence of a conformational ensemble consisting of helical structures rapidly converting into more extended states. Differences in chemical shifts and nuclear Overhauser effects indicate that lowering the temperature induces a shift of the dynamic equilibrium toward more helical structures. At 10 degrees C, a perceptible fraction of the conformational ensemble consists of structures with an alpha-helical conformation between residues 9 and 17, likely starting with a turnlike structure around Thr9 and Arg10. Both the conformation and the position of this helical region agree well with the secondary structure predictions mentioned above.     

31P NMR studies of the structure of cation-nucleotide complexes bound to porcine muscle adenylate kinase

The paramagnetic effects on the spin-relaxation rates of 31P nuclei in complexes of porcine muscle adenylate kinase with ATP, GTP, GDP, and AMP were measured in the presence of two dissimilar activating paramagnetic cations, Mn(II) and Co(II), to examine the structures of the enzyme-bound complexes. Experiments were performed exclusively on enzyme-bound complexes to limit contributions to observed relaxation rates to two exchanging complexes (with and without cation). Measurements were made at three frequencies, 81, 121.5, and 190.2 MHz, and as a function of temperature in the range 5-30 degrees C to determine the effect of exchange on the observed relaxation rates. Relaxation rates in the E.MnATP, E.MnGTP, and E.MnGDP complexes were shown to be exchange-limited and therefore without structural information. Relaxation rates for the complexes E.CoATP, E.CoGTP, and E.CoGDP were shown to depend on Co(II)-31P distances. Inability to precisely estimate spectral densities arising from electronic relaxation of Co(II) restricts calculations of Co(II)-31P distances in these complexes to upper and lower limits. At the center of these limits, the Co(II)-31P distances of beta-P and gamma-P in E.CoATP and E.CoGTP, and of beta-P (E.CoGDP), are in the range 3.1-3.5 A appropriate for the first coordination sphere. For all these complexes, the corresponding distance for alpha-P is appreciably larger in the range 3.9-4.5 A.(ABSTRACT TRUNCATED AT 250 WORDS)