Interaction of bepridil with the cardiac troponin C/troponin I complex

We have investigated the binding of bepridil to calcium-saturated cardiac troponin C in a cardiac troponin C/troponin I complex. Nuclear magnetic resonance spectroscopy and [(15)N,(2)H]cardiac troponin C permitted the mapping of bepridil-induced amide proton chemical shifts. A single bepridil-binding site in the regulatory domain was found with an affinity constant of approximately 140 microM(-1). In the presence of cardiac troponin I, bepridil binding to the C domain of cardiac troponin C was not detected. The pattern of bepridil-induced chemical shifts is consistent with stabilization of more open regulatory domain conformational states. A similar pattern of chemical shift perturbations was observed for interaction of the troponin I cardiac-specific amino-terminus with the cardiac troponin C regulatory domain. These results suggest that both bepridil and the cardiac-specific amino-terminus may mediate an increase in calcium affinity by interacting with and stabilizing open regulatory domain conformations. Chemical shift mapping suggests a possible role for inactive calcium-binding site I in the modulation of calcium affinity.

Modulation of cardiac troponin C-cardiac troponin I regulatory interactions by the amino-terminus of cardiac troponin I

Multidimensional heteronuclear magnetic resonance studies of the cardiac troponin C/troponin I(1-80)/troponin I(129-166) complex demonstrated that cardiac troponin I(129-166), corresponding to the adjacent inhibitory and regulatory regions, interacts with and induces an opening of the cardiac troponin C regulatory domain. Chemical shift perturbation mapping and (15)N transverse relaxation rates for intact cardiac troponin C bound to either cardiac troponin I(1-80)/troponin I(129-166) or troponin I(1-167) suggested that troponin I residues 81-128 do not interact strongly with troponin C but likely serve to modulate the interaction of troponin I(129-166) with the cardiac troponin C regulatory domain. Chemical shift perturbations due to troponin I(129-166) binding the cardiac troponin C/troponin I(1-80) complex correlate with partial opening of the cardiac troponin C regulatory domain previously demonstrated by distance measurements using fluorescence methodologies. Fluorescence emission from cardiac troponin C(F20W/N51C)(AEDANS) complexed to cardiac troponin I(1-80) was used to monitor binding of cardiac troponin I(129-166) to the regulatory domain of cardiac troponin C. The apparent K(d) for cardiac troponin I(129-166) binding to cardiac troponin C/troponin I(1-80) was 43.3 +/- 3.2 microM. After bisphosphorylation of cardiac troponin I(1-80) the apparent K(d) increased to 59.1 +/- 1.3 microM. Thus, phosphorylation of the cardiac-specific N-terminus of troponin I reduces the apparent binding affinity of the regulatory domain of cardiac troponin C for cardiac troponin I(129-166) and provides further evidence for beta-adrenergic modulation of troponin Ca(2+) sensitivity through a direct interaction between the cardiac-specific amino-terminus of troponin I and the cardiac troponin C regulatory domain.

Binding of levosimendan, a calcium sensitizer, to cardiac troponin C

Levosimendan is an inodilatory drug that mediates its cardiac effect by the calcium sensitization of contractile proteins. The target protein of levosimendan is cardiac troponin C (cTnC). In the current work, we have studied the interaction of levosimendan with Ca(2+)-saturated cTnC by heteronuclear NMR and small angle x-ray scattering. A specific interaction between levosimendan and the Ca(2+)-loaded regulatory domain of recombinant cTnC(C35S) was observed. The changes in the NMR spectra of the N-domain of full-length cTnC(C35S), due to the binding of levosimendan to the primary site, were indicative of a slow conformational exchange. In contrast, no binding of levosimendan to the regulatory domain of cTnC(A-Cys), where all the cysteine residues are mutated to serine, was detected. Moreover, it was shown that levosimendan was in fast exchange on the NMR time scale with a secondary binding site in the C-domain of both cTnC(C35S) and cTnC(A-Cys). The small angle x-ray scattering experiments confirm the binding of levosimendan to Ca(2+)-saturated cTnC but show no domain-domain closure. The experiments were run in the absence of the reducing agent dithiothreitol and the preservative sodium azide (NaN(3)), since we found that levosimendan reacts with these chemicals, commonly used for preparation of NMR protein samples.

Calculation of z-coordinates and orientational restraints using a metal binding tag

We introduce a new simple methodology allowing the measurement of (1)H-(15)N residual dipolar couplings, dipolar shifts, and unpaired electron-amide proton distances. This method utilizes a zinc finger tag fused at either the N- or the C-terminus of a protein. We have demonstrated this fusion strategy by incorporating the zinc finger of the retroviral gag protein onto the C-terminus of barnase, a ribonuclease produced by Bacillus amiloliquifaciance. We show that this tag can be substituted with cobalt and manganese. Binding of cobalt to the gag zinc finger-barnase fusion protein introduced sufficient anisotropic paramagnetic susceptibility for orientation of the molecule in the magnetic field. Partial alignment permitted measurement of (1)J(HN) scalar couplings along with dipolar couplings. Replacement of bound cobalt with diamagnetic zinc removes the paramagnetic-induced orientation of barnase, permitting the measurement of only (1)J(HN) scalar couplings. Dipolar couplings, ranging from -0.9 to 0.6 Hz, were easily measured from the difference in splitting frequencies in the presence of cobalt and zinc. The observed paramagnetic anisotropy induced by cobalt binding to the metal binding tag also permitted measurement of dipolar shifts. Substitution of manganese into the metal binding tag permitted the measurement of unpaired electron-amide proton distances using paramagnetic relaxation enhancement methodology. The availability of both amide proton dipolar shifts and unpaired electron to amide proton distances permitted the direct calculation of z-coordinates for individual amide protons. This approach is robust and will prove powerful for global fold determination of proteins identified in genome initiatives.

Magnesium-calcium exchange in cardiac troponin C bound to cardiac troponin I

Understanding the process of Ca(2+)/Mg(2+)exchange during muscle excitation and relaxation is fundamental to elucidating the mechanism of Ca(2+)-regulated muscle contraction. During the resting phase, the C-domain of cardiac troponin C may be occupied by either Ca(2+)or Mg(2+). Here, complexes of recombinant cardiac troponin C(81-161) and the N terminus of cardiac troponin I, representing residues 33-80, were generated in the presence of saturating Mg(2+). Heteronuclear multi-dimensional nuclear magnetic resonance experiments were used to obtain backbone assignments of the Mg(2+)-loaded complex. In the presence of cardiac troponin I, the affinity of site IV for Mg(2+)is increased. Comparison of Mg(2+)and Ca(2+)-loaded complexes reveals that chemical shift differences are primarily localized to metal-binding sites III and IV, defining positions within these sites that have distinct Ca(2+)/Mg(2+)conformations. The observed transition from the Mg(2+)-loaded to Ca(2+)-loaded form demonstrates that sites III and IV fill simultaneously with Ca(2+)displacing Mg(2+). However, even in the absence of excess Ca(2+), Mg(2+)does not readily displace Ca(2+)in the isolated binary complex. Thus, the Mg(2+)-loaded conformer may only represent a small fraction of the total cardiac troponin C found in the sarcomere.

Regulatory domain conformational exchange and linker region flexibility in cardiac troponin C bound to cardiac troponin I

Previously, we utilized (15)N transverse relaxation rates to demonstrate significant mobility in the linker region and conformational exchange in the regulatory domain of Ca(2+)-saturated cardiac troponin C bound to the isolated N-domain of cardiac troponin I (Gaponenko, V., Abusamhadneh, E., Abbott, M. B., Finley, N., Gasmi-Seabrook, G., Solaro, R.J., Rance, M., and Rosevear, P.R. (1999) J. Biol. Chem. 274, 16681-16684). Here we show a large decrease in cardiac troponin C linker flexibility, corresponding to residues 85-93, when bound to intact cardiac troponin I. The addition of 2 m urea to the intact cardiac troponin I-troponin C complex significantly increased linker flexibility. Conformational changes in the regulatory domain of cardiac troponin C were monitored in complexes with troponin I-(1-211), troponin I-(33-211), troponin I-(1-80) and bisphosphorylated troponin I-(1-80). The cardiac specific N terminus, residues 1-32, and the C-domain, residues 81-211, of troponin I are both capable of inducing conformational changes in the troponin C regulatory domain. Phosphorylation of the cardiac specific N terminus reversed its effects on the regulatory domain. These studies provide the first evidence that the cardiac specific N terminus can modulate the function of troponin C by altering the conformational equilibrium of the regulatory domain.

A set of HNCO-based experiments for measurement of residual dipolar couplings in 15N, 13C, (2H)-labeled proteins

Several HNCO-based three-dimensional experiments are described for the measurement of 13C'(i - 1)-13Calpha(i - 1), 5N(i)-13C'(i - 1), 15N(i)-13Calpha(i), 15N(i)-13Calpha(i - 1), 1H(N)(i)-13Calpha(i), 1H(N)(i)-13Calpha(i - 1), and 13Calpha(i - 1)-13Cbeta(i - 1) scalar and dipolar couplings in 15N, 13C, (2H)-labelled protein samples. These pulse sequences produce spin-state edited spectra superficially resembling an HNCO correlation spectrum, allowing accurate and simple measurement of couplings without introducing additional spectral crowding. Scalar and dipolar couplings are measured with good sensitivity from relatively large proteins, as demonstrated with three proteins: cardiac Troponin C, calerythrin and ubiquitin. Measurement of several dipolar couplings between spin-1/2 nuclei using spin-state selective 3D HNCO spectra provides a wealth of structural information.

Cardiac troponin I inhibitory peptide: location of interaction sites on troponin C

Cardiac troponin I(129-149) binds to the calcium saturated cardiac troponin C/troponin I(1-80) complex at two distinct sites. Binding of the first equivalent of troponin I(129-149) was found to primarily affect amide proton chemical shifts in the regulatory domain, while the second equivalent perturbed amide proton chemical shifts within the D/E linker region. Nitrogen-15 transverse relaxation rates showed that binding the first equivalent of inhibitory peptide to the regulatory domain decreased conformational exchange in defunct calcium binding site I and that addition of the second equivalent of inhibitory peptide decreased flexibility in the D/E linker region. No interactions between the inhibitory peptide and the C-domain of cardiac troponin C were detected by these methods demonstrating that the inhibitory peptide cannot displace cTnI(1-80) from the C-domain.

Protein global fold determination using site-directed spin and isotope labeling

We describe a simple experimental approach for the rapid determination of protein global folds. This strategy utilizes site-directed spin labeling (SDSL) in combination with isotope enrichment to determine long-range distance restraints between amide protons and the unpaired electron of a nitroxide spin label using the paramagnetic effect on relaxation rates. The precision and accuracy of calculating a protein global fold from only paramagnetic effects have been demonstrated on barnase, a well-characterized protein. Two monocysteine derivatives of barnase, (H102C) and (H102A/Q15C), were 15N enriched, and the paramagnetic nitroxide spin label, MTSSL, attached to the single Cys residue of each. Measurement of amide 1H longitudinal relaxation times, in both the oxidized and reduced states, allowed the determination of the paramagnetic contribution to the relaxation processes. Correlation times were obtained from the frequency dependence of these relaxation processes at 800, 600, and 500 MHz. Distances in the range of 8 to 35 A were calculated from the magnitude of the paramagnetic contribution to the relaxation processes and individual amide 1H correlation times. Distance restraints from the nitroxide spin to amide protons were used as restraints in structure calculations. Using nitroxide to amide 1H distances as long-range restraints and known secondary structure restraints, barnase global folds were calculated having backbone RMSDs <3 A from the crystal structure. This approach makes it possible to rapidly obtain the overall topology of a protein using a limited number of paramagnetic distance restraints.

Solution structures of the C-terminal domain of cardiac troponin C free and bound to the N-terminal domain of cardiac troponin I

The N-terminal domain of cardiac troponin I (cTnI) comprising residues 33-80 and lacking the cardiac-specific amino terminus forms a stable binary complex with the C-terminal domain of cardiac troponin C (cTnC) comprising residues 81-161. We have utilized heteronuclear multidimensional NMR to assign the backbone and side-chain resonances of Ca2+-saturated cTnC(81-161) both free and bound to cTnI(33-80). No significant differences were observed between secondary structural elements determined for free and cTnI(33-80)-bound cTnC(81-161). We have determined solution structures of Ca2+-saturated cTnC(81-161) free and bound to cTnI(33-80). While the tertiary structure of cTnC(81-161) is qualitatively similar to that observed free in solution, the binding of cTnI(33-80) results mainly in an opening of the structure and movement of the loop region between helices F and G. Together, these movements provide the binding site for the N-terminal domain of cTnI. The putative binding site for cTnI(33-80) was determined by mapping amide proton and nitrogen chemical shift changes, induced by the binding of cTnI(33-80), onto the C-terminal cTnC structure. The binding interface for cTnI(33-80), as suggested from chemical shift changes, involves predominantly hydrophobic interactions located in the expanded hydrophobic pocket. The largest chemical shift changes were observed in the loop region connecting helices F and G. Inspection of available TnC sequences reveals that these residues are highly conserved, suggesting a common binding motif for the Ca2+/Mg2+-dependent interaction site in the TnC/TnI complex.

NMR analysis of cardiac troponin C-troponin I complexes: effects of phosphorylation

Phosphorylation of the cardiac specific amino-terminus of troponin I has been demonstrated to reduce the Ca2+ affinity of the cardiac troponin C regulatory site. Recombinant N-terminal cardiac troponin I proteins, cardiac troponin I(33-80), cardiac troponin I(1-80), cardiac troponin I(1-80)DD and cardiac troponin I(1-80)pp, phosphorylated by protein kinase A, were used to form stable binary complexes with recombinant cardiac troponin C. Cardiac troponin I(1-80)DD, having phosphorylated Ser residues mutated to Asp, provided a stable mimetic of the phosphorylated state. In all complexes, the N-terminal domain of cardiac troponin I primarily makes contact with the C-terminal domain of cardiac troponin C. The nonphosphorylated cardiac specific amino-terminus, cardiac troponin I(1-80), was found to make additional interactions with the N-terminal domain of cardiac troponin C.

Effects of troponin I phosphorylation on conformational exchange in the regulatory domain of cardiac troponin C

Conformational exchange has been demonstrated within the regulatory domain of calcium-saturated cardiac troponin C when bound to the NH2-terminal domain of cardiac troponin I-(1-80), and cardiac troponin I-(1-80)DD, having serine residues 23 and 24 mutated to aspartate to mimic the phosphorylated form of the protein. Binding of cardiac troponin I-(1-80) decreases conformational exchange for residues 29, 32, and 34. Comparison of average transverse cross correlation rates show that both the NH2- and COOH-terminal domains of cardiac troponin C tumble with similar correlation times when bound to cardiac troponin I-(1-80). In contrast, the NH2- and COOH-terminal domains in free cardiac troponin C and cardiac troponin C bound cardiac troponin I-(1-80)DD tumble independently. These results suggest that the nonphosphorylated cardiac specific NH2 terminus of cardiac troponin I interacts with the NH2-terminal domain of cardiac troponin C.

Mutation of the carboxy terminal zinc finger of E. coli isoleucyl-tRNA synthetase alters zinc binding and aminoacylation activity

Escherichia coli isoleucyl-tRNA synthetase has been shown to contain two enzyme-bound zinc atoms per polypeptide chain. To investigate the structural and functional significance of the C-terminal enzyme-bound zinc, mutagenesis was used to alter Cys 922 to Ser [IleRS(C922S)] and to replace Cys 922 through Ala 939 with a 33 amino acid peptide unable to bind zinc (AIleRS). Both IleRS(C922S) and AIleRS were found to contain only a single enzyme-bound zinc per polypeptide chain. Substitution of Co2+ for Zn2+ in IleRS(C922S) gave a visible spectrum characteristic of that expected for a single tetrahedrally coordinated enzyme-bound Co2+ atom. Little or no effect on the Km values for ATP or Ile and only a 5 fold reduction of the (kcat/Km)Ile was observed for IleRS(C922S) and AIleRS in the isoleucine-dependent ATP-pyrophosphate exchange reaction. In the tRNA-dependent aminoacylation reaction, Km values for tRNA(Ile) were only slightly affected in the mutant proteins. However, kcat/Km values were decreased approximately 200 and 2500 fold for IleRS(C922S) and AIleRS, respectively. These results suggest that both the C-terminal enzyme-bound zinc and the C-terminal peptide play important roles in aminoacylation of tRNA(Ile).

Cardiac troponin I induced conformational changes in cardiac troponin C as monitored by NMR using site-directed spin and isotope labeling

Conformational changes in both free cardiac troponin C (cTnC) and in complex with a recombinant troponin I protein [cTnI(33-211), cTnI(33-80), or cTnI (86-211)] were observed by means of a combination of selective carbon-13 and spin labeling. The paramagnetic effect from the nitroxide spin label, MTSSL, attached to cTnC(C35S) at Cys 84 allowed measurement of the relative distances to the 13C-methyl groups of the 10 methionines of cTnC in the monomer or complex. All 10 1H-13C correlations in the heteronuclear single- and multiple-quantum coherence (HSMQC) spectrum of [13C-methyl] Met cTnC in the complex with cTnI(33-211) were previously assigned [Krudy, G. A., Kleerekoper, Q., Guo, X., Howarth, J. W., Solaro, R. J., & Rosevear, P. R. (1994) J. Biol. Chem. 269, 23731-23735]. In the presence of oxidized spin label, nine of the 10 Met methyl 1H-13C correlations of cTnC were significantly broadened in the cTnC(C35S) monomer. This suggests flexibility within the central helix, or interdomain D/E helical linker, bringing the N- and C-terminal domains in closer proximity than predicted from the crystallographic structure of TnC. In the spin-labeled cTnC(C35S). cTnI(33-211) complex only N-terminal Met methyl 1H-13C correlations of cTnC(C35S) were paramagnetically broadened beyond detection, whereas correlations for Met residues (103, 120, 137, and 157) in the C-terminal domain were not. Thus, complex formation with cTnI decreases interdomain flexibility and maintains cTnC in an extended conformation. This agrees with the recently published study suggesting that sTnC is extended when bound to sTnI [Olah, G. A., & Trewhella, J. (1994) Biochemistry 33, 12800-12806]. The recombinant N-terminal domain of cTnI, cTnI(33-80), gave similar results as observed with cTnI(33-211) when complexed with spin-labeled cTnC(C35S). However, complex formation with the C-terminal fragment, cTnI(86-211), which contains the inhibitory sequence, is insufficient to maintain cTnC extended to the amount observed with either cTnI(33-211) or cTnI(33-80); although compared to that observed in free cTnC, it does cause decreased flexibility in the interdomain linker. In the absence of the N-terminal domain of cTnI, there is a decrease in flexibility within the N-terminal domain of cTnC. Interestingly, the N-terminal domain of cTnC in the reduced spin-labeled complex with cTnI(86-211), in the presence of ascorbate, showed two distinct conformations which were not seen in the complex with cTnI(33-211).(ABSTRACT TRUNCATED AT 400 WORDS)

An NMR and spin label study of the effects of binding calcium and troponin I inhibitory peptide to cardiac troponin C

The paramagnetic relaxation reagent, 4-hydroxy-2,2,6,6-tetramethylpiperidinyl-1-oxy (HyTEMPO), was used to probe the surface exposure of methionine residues of recombinant cardiac troponin C (cTnC) in the absence and presence of Ca2+ at the regulatory site (site II), as well as in the presence of the troponin I inhibitory peptide (cTnIp). Methyl resonances of the 10 Met residues of cTnC were chosen as spectral probes because they are thought to play a role in both formation of the N-terminal hydrophobic pocket and in the binding of cTnIp. Proton longitudinal relaxation rates (R1's) of the [13C-methyl] groups in [13C-methyl]Met-labeled cTnC(C35S) were determined using a T1 two-dimensional heteronuclear single- and multiple-quantum coherence pulse sequence. Solvent-exposed Met residues exhibit increased relaxation rates from the paramagnetic effect of HyTEMPO. Relaxation rates in 2Ca(2+)-loaded and Ca(2+)-saturated cTnC, both in the presence and absence of HyTEMPO, permitted the topological mapping of the conformational changes induced by the binding of Ca2+ to site II, the site responsible for triggering muscle contraction. Calcium binding at site II resulted in an increased exposure of Met residues 45 and 81 to the soluble spin label HyTEMPO. This result is consistent with an opening of the hydrophobic pocket in the N-terminal domain of cTnC upon binding Ca2+ at site II. The binding of the inhibitory peptide cTnIp, corresponding to Asn 129 through Ile 149 of cTnI, to both 2Ca(2+)-loaded and Ca(2+)-saturated cTnC was shown to protect Met residues 120 and 157 from HyTEMPO as determined by a decrease in their measured R1 values. These results suggest that in both the 2Ca(2+)-loaded and Ca(2+)-saturated forms of cTnC, cTnIp binds primarily to the C-terminal domain of cTnC.

Assignment and calcium dependence of methionyl epsilon C and epsilon H resonances in cardiac troponin C

The 10 Met methyl groups in recombinant cardiac troponin (cTnC) were metabolically labeled with [13C-methyl]Met and detected as 10 individual cross-peaks using two-dimensional heteronuclear single- and multiple-quantum coherence (HSMQC) spectroscopy. The epsilon C and epsilon H chemical shifts for all 10 Met residues were sequence-specifically assigned using a combination of HSMQC and systematic conversion of the Met residues to Leu. The only negative functional consequence of these changes was seen when both Met 45 and 81 were mutated. Binding of Ca2+ to the high affinity C-terminal sites III and IV induced relatively large changes in the epsilon H and epsilon C chemical shifts of all Met residues in the C-terminal domain as well as small but significant changes in the chemical shifts of epsilon H Met 47 and Met 81 in the N-terminal half of cTnC. Binding of Ca2+ to the low affinity N-terminal site II induced large changes in the epsilon H and epsilon C chemical shifts of Met 45, Met 80, and Met 81. Binding of Ca2+ to site II had no effect on the chemical shifts of Met residues located in the C-terminal domain. The nature of the chemical shift changes of Met residues in the N- versus the C-terminal halves of cTnC were consistent with different Ca(2+)-induced conformational changes in these domains. Thus, the assigned methyl Met chemical shifts can serve as useful structural markers to study conformational transitional in free cTnC and potentially after association with small ligands, peptides, and other troponin subunits.

NMR studies delineating spatial relationships within the cardiac troponin I-troponin C complex

NMR spectroscopy and selective isotope labeling of both recombinant cardiac troponin C (cTnC3) and a truncated cardiac troponin I (cTnI/NH2) lacking the N-terminal 32-amino acid cardiac-specific sequence have been used to probe protein-protein interactions central to muscle contraction. Using [methyl-13C]Met-labeled cTnC3, all 10 cTnC Met residues of Ca(2+)-saturated cTnC3 could be resolved in the two-dimensional heteronuclear single- and multiple-quantum coherence spectrum of the cTnI.cTnC complex. Based on the known Met assignments in cTnC3, the largest chemical shift changes were observed for Met81, Met120, Met137, and Met157. Methionines 120, 137, and 157 are all located in the C-terminal domain of cTnC. Methionine 81 is located at the N terminus of the central helix. Minimal chemical shift changes were observed for Met45, Met47, and Met103 of cTnC3 in the cTnI.cTnC complex. All 6 Met residues in [methyl13C]Met-labeled cTnI/NH2 could be resolved in the cTnI.cTnC complex, suggesting that both cTnI and cTnC form a stable homogeneous binary complex under the conditions of the NMR experiment. In the absence of added protease inhibitors in the cTnI.cTnC complex, cTnI/NH2 was found to undergo selective proteolysis to yield a 5.5-kDa N-terminal fragment corresponding to residues 33-80. Judging from the NMR spectra of [methyl13C]Met-labeled cTnC3, cTnI-(33-80) was sufficient for interaction with the C-terminal domain of cTnC in a manner identical to that observed for native cTnI/NH2. However, in the presence of the proteolytic fragment cTnI-(33-80), the chemical shift of Met81 was not perturbed from its position in free cTnC3. Thus, residues located C-terminal to Arg80 in cTnI appear to be responsible for interaction with the N-terminal half of cTnC. Taken together, these results provide strong evidence for an antiparallel arrangement for the two proteins in the troponin complex such that the N-terminal portion of cTnI interacts with the C-terminal domain of cTnC. This interaction likely plays a role in maintaining the stability of the TnI.TnC complex.

Synthetic macrophage activating peptides derived from the N-terminus of human MCF

Recently, we described the purification and N-terminal sequencing of a novel cytokine termed MCF (Monocyte Cytotoxicity Inducing Factor) (1,2). In order to study the interaction of this cytokine with monocytes, we synthesized a nona-peptide GAAVLEDSQ corresponding to the N-terminus of MCF: two truncated peptides, GAAVL and LEDSQ; and the substituted peptide, GAAVLENSQ. The authentic N-terminal peptide is biologically active in the nanomolar range, while substitution of asparagine for aspartic acid at position 7 diminishes biological activity. Biological activity was observed from the C-terminal fragment LEDSQ, but the N-terminal pentapeptide (GAAVL) was devoid of biological activity. Scatchard analysis revealed a single class of saturable high affinity sites. These studies indicate that the N-terminus of MCF is important in interacting with the binding site on monocytes and it may be possible to design synthetic activators and inhibitors of monocyte/macrophage cytotoxicity.

Probing the metal binding sites of Escherichia coli isoleucyl-tRNA synthetase

The metal binding properties of isoleucyl-tRNA synthetase (IleRS) from Escherichia coli were studied by in vivo substitution of the enzyme-bound metals. Purified E. coli IleRS was shown to have two tightly bound zinc atoms per active site. Cobalt- and cadmium-substituted IleRS were also found to contain two tightly bound Co2+ and Cd2+ atoms per polypeptide chain, respectively. The d-d transitions in the low energy absorption spectrum of Co(2+)-substituted IleRS were characteristic of that expected for two tetrahedrally coordinated Co2+ metals. Apo-IleRS was found to be inactive in both the aminoacylation of tRNA(Ile) and in the isoleucine-dependent ATP-pyrophosphate exchange reactions. Both Co(2+)- and Cd(2+)-substituted IleRS were found to have kcat/Km values in the isoleucine-dependent ATP-pyrophosphate exchange assay approximately 5-fold lower than the native Zn2+ enzyme. A single enzyme-bound Zn2+ or Co2+ atom per polypeptide chain could be removed by dialysis of Zn(2+)- or Co(2+)-substituted IleRS against 1,10-phenanthroline. Removal of one of the two enzyme-bound Zn2+ atoms per polypeptide chain with 1,10-phenanthroline was found to decrease (kcat/Km)Ile by approximately 130-fold. The dependence of the kinetic parameters on the identity and number of enzyme-bound metals in the isoleucine-dependent ATP-pyrophosphate exchange reaction suggests that at least one enzyme-bound metal is indirectly involved in aminoacyladenylate formation. Metal substitution or removal of one of the two enzyme-bound metals in IleRS was found to have little effect on the Km value for tRNA(Ile) or the kcat value for aminoacylation of tRNA(Ile).(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium plays distinctive structural roles in the N- and C-terminal domains of cardiac troponin C

One- and two-dimensional NMR techniques were used to compare the structural consequences of Ca2+ binding to both the low and high affinity Ca2+ binding sites in recombinant cardiac troponin C (cTnC3). In the absence of Ca2+, the short beta-sheet located between the high affinity Ca2+/Mg2+ binding sites in the C-terminal domain was found to be absent or loosely formed as judged by the inter-residue NOEs and chemical shifts of resonances in the Ca2+ binding loops. In contrast, the N-terminal domain beta-sheet located between site II and the naturally inactive site I was present even in the absence of bound Ca2+. Calcium-binding mutant proteins having either an inactive Ca2+ binding site III (CBM-III) or an inactive Ca2+ binding site IV (CBM-IV) (Negele, J. C., Dotson, D., Liu, W., Sweeney, H. L., and Putkey, J. A. (1992) J. Biol. Chem. 267, 825-831) were used to study the structural consequences of Ca2+ binding to each of the high affinity sites located in the C-terminal domain. Only a single active Ca2+ binding site was found necessary for formation of the short beta-sheet between Ca2+ binding sites III and IV. However, the absence of bound Ca2+ at site III was found to produce greater instability in the C-terminal domain as judged from the mobility of the C-terminal aromatic hydrophobic cluster. Thus, Ca2+ binding to the high affinity sites in the C-terminal domain results in an ordering of the aromatic hydrophobic cluster, as well as formation of a short beta-sheet between Ca2+ binding sites III and IV. These results demonstrate that Ca2+ binding plays distinctive structural roles in the N- and C-terminal domains of cTnC.

Identification of the metal ligands and characterization of a putative zinc finger in methionyl-tRNA synthetase

A truncated form of the methionyl-tRNA synthetase (delta MTS), which has been cloned, overproduced, and characterized, was used in an attempt to better understand the role of the enzyme-bound zinc in the amino-acylation process. Apo-, Zn(2+)-, Co(2+)-, and 113Cd(2+)-substituted delta MTS proteins were prepared in vivo and purified to homogeneity. Apo-delta MTS was devoid of enzymatic activity in the aminoacylation of tRNA(fMet) and in the methionine-dependent ATP-pyrophosphate exchange reactions. Kinetic constants in both the aminoacylation and ATP-pyrophosphate exchange reactions for the Co(2+)- and 113Cd(2+)-substituted delta MTS proteins were found to be identical with those of the native Zn2+ protein. The low energy absorption spectrum of Co(2+)-substituted delta MTS resembles the d-d transition bands characteristic of tetrahedrally coordinated Co(2+)-substituted proteins. A strong S-->Co2+ charge transfer absorption at 350 nm was clearly evident having a molar absorptivity consistent with four thiolate ligands. The environment of the metal center was further probed by measuring the 113Cd chemical shift of 113Cd(2+)-substituted delta MTS. A single resonance at 759.6 ppm was observed. This chemical shift is consistent with Cd2+ coordinated to four thiolate ligands. The Escherichia coli methionyl-tRNA synthetase contains a potential metal binding sequence Cys-X2-Cys-X9-Cys-X2-Cys in a connecting polypeptide within the nucleotide fold. Titration of a 21-amino acid peptide corresponding to this putative metal binding site, Cys145-Cys161, was shown to bind Co2+ with a Kd of 120 +/- 11 microM. These results demonstrate that the isolated zinc finger binding domain is capable of specifically forming a stoichiometric complex with the divalent cation. Taken together, our studies identify the 4 cysteine residues in the zinc finger-like domain as the metal binding ligands in the E. coli methionyl-tRNA synthetase. The role of the enzyme-bound metal appears to be structural and not directly involved in catalysis.

Conformational changes in the metal-binding sites of cardiac troponin C induced by calcium binding

Isotope labeling of recombinant normal cardiac troponin C (cTnC3) with 15N-enriched amino acids and multidimensional NMR were used to assign the downfield-shifted amide protons of Gly residues at position 6 in Ca(2+)-binding loops II, III, and IV, as well as tightly hydrogen-bonded amides within the short antiparallel beta-sheets between pairs of Ca(2+)-binding loops. The amide protons of Gly70, Gly110, and Gly146 were found to be shifted significantly downfield from the remaining amide proton resonances in Ca(2+)-saturated cTnC3. No downfield-shifted Gly resonance was observed from the naturally inactive site I. Comparison of downfield-shifted amide protons in the Ca(2+)-saturated forms of cTnC3 and CBM-IIA, a mutant having Asp65 replaced by Ala, demonstrated that Gly70 is hydrogen bonded to the carboxylate side chain of Asp65. Thus, the hydrogen bond between Gly and Asp in positions 6 and 1, respectively, of the Ca(2+)-binding loop appears crucial for maintaining the integrity of the helix-loop-helix Ca(2+)-binding sites. In the apo- form of cTnC3, only Gly70 was found to be shifted significantly downfield with respect to the remaining amide proton resonances. Thus, even in the absence of Ca2+ at binding site II, the amide proton of Gly70 is strongly hydrogen bonded to the side-chain carboxylate of Asp65. The amide protons of Ile112 and Ile148 in the C-terminal domain and Ile36 in the N-terminal domain data-sheets exhibit chemical shifts consistent with hydrogen-bond formation between the pair of Ca(2+)-binding loops in each domain of Ca(2+)-saturated cTnC3.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparative NMR studies on cardiac troponin C and a mutant incapable of binding calcium at site II

One- and two-dimensional NMR techniques were used to study both the influence of mutations on the structure of recombinant normal cardiac troponin C (cTnC3) and the conformational changes induced by Ca2+ binding to site II, the site responsible for triggering muscle contraction. Spin systems of the nine Phe and three Tyr residues were elucidated from DQF-COSY and NOESY spectra. Comparison of the pattern of NOE connectivities obtained from a NOESY spectrum of cTnC3 with a model of cTnC based on the crystal structure of skeletal TnC permitted sequence-specific assignment of all three Tyr residues, as well as Phe-101 and Phe-153. NOESY spectra and calcium titrations of cTnC3 monitoring the aromatic region of the 1H NMR spectrum permitted localization of six of the nine Phe residues to either the N- or C-terminal domain of cTnC3. Analysis of the downfield-shifted C alpha H resonances permitted sequence-specific assignment of those residues involved in the beta-strand structures which are part of the Ca(2+)-binding loops in both the N- and C-terminal domains of cTnC3. The short beta-strands in the N-terminal domain of cTnC3 were found to be present and in close proximity even in the absence of Ca2+ bound at site II. Using these assignments, we have examined the effects of mutating Asp-65 to Ala, CBM-IIA, a functionally inactive mutant which is incapable of binding Ca2+ at site II [Putkey, J.A., Sweeney, H. L., & Campbell, S. T. (1989) J. Biol. Chem. 264, 12370]. Comparison of the apo, Mg(2+)-, and Ca(2+)-bound forms of cTnC3 and CBM-IIA demonstrates that the inability of CBM-IIA to trigger muscle contraction is not due to global structural changes in the mutant protein but is a consequence of the inability of CBM-IIA to bind Ca2+ at site II. The pattern of NOEs between aromatic residues in the C-terminal domain is nearly identical in cTnC3 and CBM-IIA. Similar interresidue NOEs were also observed between Phe residues assigned to the N-terminal domain in the Ca(2+)-saturated forms of both cTnC3 and CBM-IIA. However, chemical shift changes were observed for the N-terminal Phe residues in CBM-IIA. This suggests that binding of Ca2+ to site II alters the chemical environment of the residues in the N-terminal hydrophobic cluster without disrupting the spatial relationship between the Phe residues located in helices A and D.

A novel alpha-proton exchange reaction catalyzed by Escherichia coli methionyl-tRNA synthetase

The Escherichia coli truncated methionyl-tRNA synthetase (delta MTS) was shown to catalyze alpha-carbon hydrogen-deuterium exchange of L-selenomethionine, L-methionine, L-ethionine, and L-norleucine in the presence of deuterium oxide. The rate of alpha-proton exchange for L-methionine was shown to be linear with respect to delta MTS concentration. The exchange reaction showed saturation kinetics with apparent Km values of 21 and 4 mM in the absence and presence of saturating adenosine concentrations, respectively. As expected, delta MTS did not catalyze alpha-proton exchange of D-methionine since the enzyme has been shown to be specific for L-amino acids. In the absence of enzyme or in the presence of an equivalent concentration of Zn2+, no hydrogen-deuterium exchange was detected. The exchange reaction was not observed with L-methioninol, an analogue of L-methionine lacking the carboxylate group. These results suggest that the alpha-carboxylate group is a requirement for the delta MTS-catalyzed exchange reaction. The E. coli methionyl-tRNA synthetase (MTS) has previously been shown to be a zinc metalloprotein [Posorske, L. H., Cohn, M., Yanagisawa, N., & Auld, D. S. (1979) Biochim. Biophys. Acta 576, 128]. On the basis of the structural and mechanistic information available on MTS, we propose that the enzyme-bound zinc coordinates the carboxylate of the amino acid, while a base on the enzyme is responsible for exchange of the alpha-proton. The role of the enzyme-bound metal is to render the alpha-proton more acidic through coordination of the carboxylate group.(ABSTRACT TRUNCATED AT 250 WORDS)

Nuclear overhauser effect studies of the conformations of Mg(alpha, beta-methylene)ATP bound to E. coli isoleucyl-tRNA synthetase

Internuclear distances obtained from transferred nuclear Overhauser effects were used in combination with distance geometry calculations to define the E. coli isoleucyl-tRNA synthetase bound conformation of Mg(alpha, beta-methylene)ATP both in the absence and in the presence of the cognate and noncognate amino acids L-isoleucine and L-valine, respectively. A single nucleotide structure having an anti adenine-ribose glycosidic torsional angle of -114 degrees was found to satisfy the experimental distance constraints. The nearly identical anti glycosidic torsional angles observed in all three complexes demonstrate that the conformation of the adenosine moiety of the enzyme-bound nucleotide is not sensitive to the presence or to the nature of the amino acid bound at the aminoacyladenylate site. In addition, the acceptable range of Mg(alpha, beta-methylene)ATP conformations bound to the E. coli isoleucyl-tRNA synthetase was found to be nearly identical to that previously determined for the E. coli methionyl-tRNA synthetase (Williams and Rosevear (1991) J. Biol. Chem. 266, 2089-2098). Thus, the predicted structural homology between the isoleucyl- and methionyl-tRNA synthetases, both members of the same class of synthetases on the basis of common consensus sequences, is further supported by consensus enzyme-bound nucleotide conformations.

Conformation of NADP+ bound to a type II dihydrofolate reductase

Type II dihydrofolate reductases (DHFRs) encoded by the R67 and R388 plasmids are sequence and structurally different from known chromosomal DHFRs. These plasmid-derived DHFRs are responsible for confering trimethoprim resistance to the host strain. A derivative of R388 DHFR, RBG200, has been cloned and its physical properties have been characterized. This enzyme has been shown to transfer the pro-R hydrogen of NADPH to its substrate, dihydrofolate, making it a member of the A-stereospecific class of dehydrogenases [Brito, R. M. M., Reddick, R., Bennett, G. N., Rudolph, F. B., & Rosevear, P. R. (1990) Biochemistry 29,9825]. Two distinct binary RBG200.NADP+ complexes were detected. Addition of NADP+ to RBG200 DHFR results in formation of an initial binary complex, conformation I, which slowly interconverts to a second more stable binary complex, conformation II. The binding of NADP+ to RBG200 DHFR in the second binary complex was found to be weak, KD = 1.9 +/- 0.4 mM. Transferred NOEs were used to determine the conformation of NADP+ bound to RBG200 DHFR. The initial slope of the NOE buildup curves, measured from the intensity of the cross-peaks as a function of the mixing time in NOESY spectra, allowed interproton distances on enzyme-bound NADP+ to be estimated. The experimentally measured distances were used to define upper and lower bound distance constraints between proton pairs in distance geometry calculations. All NADP+ structures consistent with the experimental distance bounds were found to have a syn conformation about the nicotinamide-ribose (X = 94 +/- 26 degrees) and an anti conformation about the adenine-ribose (X = -92 +/- 32 degrees) glycosidic bonds.(ABSTRACT TRUNCATED AT 250 WORDS)

Nuclear Overhauser effect studies on the conformations of Mg(alpha,beta-methylene)ATP bound to Escherichia coli methionyl-tRNA synthetase

Internuclear distances obtained from nuclear Overhauser effects were used in combination with a distance geometry algorithm to determine the conformation of Mg(alpha,beta-methylene)ATP bound to the Escherichia coli truncated methionyl-tRNA synthetase (delta MTS) both in the absence and presence of cognate and noncognate amino acids. Mg(alpha,beta-methylene)ATP, a nonhydrolyzable analog of ATP, was used to prevent hydrolysis of the nucleotide in the presence of either cognate or noncognate amino acids. Kinetic analysis showed that Mg(alpha,beta-methylene)ATP was a linear competitive inhibitor with respect to ATP in the ATP-pyrophosphate exchange reaction with a Ki = 1.2 mM. The pattern of internuclear Overhauser effects on Mg(alpha,beta-methylene)ATP bound to delta MTS was qualitatively consistent only with an anti glycosidic torsional angle, suggesting that the adenosine portion of the nucleotide is uniquely oriented in the binary enzyme-nucleotide complex. Nearly identical patterns of nuclear Overhauser effects were also observed in ternary complexes containing either cognate L-methionine or noncognate L-homocysteine amino acids. Distance geometry calculations permitted the range and conformational space of the allowed adenine-ribose glycosidic torsional angles in each of the complexes to be better defined and compared. Average adenine-ribose glycosidic torsional angles for enzyme-bound Mg(alpha,beta-methylene)ATP of -106 +/- 9 degrees, -99 +/- 11 degrees, and -97 +/- 11 degrees were determined for the delta MTS.Mg(alpha,beta-methylene)ATP, delta MTS.Mg(alpha,beta-methylene)ATP.L-methionine, and delta MTS.Mg(alpha,beta-methylene)ATP.L-homocysteine complexes, respectively. Comparison of the three enzyme-bound conformations showed that a single nucleotide structure having an adenine-ribose glycosidic torsional angle of -98 degrees with a 3'-endo to O4'-exo ribose sugar pucker was, within error, consistent with the experimental internuclear distances obtained in all three complexes. The nearly identical anti glycosidic torsional angles observed in all three complexes demonstrates that the conformation of the adenosine moiety of the enzyme-bound nucleotide is not sensitive to the presence or the nature of the amino acid bound at the aminoacyladenylate site. Therefore, conformational changes known to occur in the methionyl-tRNA synthetase upon ligand binding appear not to alter the bound conformation of the nucleotide. Information on the conformation and arrangement of substrates bound at the aminoacyladenylate site of delta MTS is necessary for understanding the molecular mechanisms involved in amino acid activation and discrimination.

The low-affinity Ca2(+)-binding sites in cardiac/slow skeletal muscle troponin C perform distinct functions: site I alone cannot trigger contraction

Both troponin C (TnC) and calmodulin share a remarkably similar tertiary motif that may be common to other Ca2(+)-binding proteins with activator activity. TnC plays a critical role in regulating muscle contraction and is particularly well-suited for structural analysis by site-directed mutation. Fast-twitch skeletal muscle TnC has two low-affinity Ca2(+)-binding sites (sites I and II), while in cardiac and slow-twitch skeletal muscle TnC site I is inactive. Recently, using protein engineering, we directly demonstrated that binding of Ca2+ to the low-affinity site(s) initiates muscle contraction. In the present study, we use mutagenesis to determine whether either of the low-affinity sites in cardiac TnC can trigger contraction in slow-twitch skeletal muscle fibers. In one Ca2(+)-binding mutant, Ca2(+)-binding to the dormant low-affinity site I was restored (CBM+I). In a second mutant, site I was activated while site II was inactivated (CBM+I-IIA). Both proteins had the predicted CA2(+)-binding characteristics, and both were able to associate with troponin I and troponin T to form a troponin complex and integrate into permeabilized slow-twitch skeletal muscle fibers. A comparison of NMR spectra shows the aromatic regions in the two proteins to be qualitatively similar without divalent cations but markedly different with Ca2+. Mutant CBM+I supported force generation in skinned slow skeletal muscle fibers but had Sr2+ and Ca2+ sensitivities similar to fast skeletal TnC. Mutant CBM+I-IIA was unable to restore Ca2(+)-dependent contraction to TnC-depleted skinned slow muscle fibers. The data directly demonstrate that low-affinity sites I and II have distinct functions and that only site II in cardiac TnC can trigger muscle contraction in slow-twitch skeletal muscle fibers. This principle of distinct, modular activities for Ca2(+)-binding sites in the same protein may apply to other members of the TnC/calmodulin family.

Characterization and stereochemistry of cofactor oxidation by a type II dihydrofolate reductase

Type II dihydrofolate reductases (DHFRs) encoded by the R67 and R388 plasmids are different both in sequence and in structure from known chromosomal DHFRs. These plasmid-derived DHFRs are responsible for conferring trimethoprim resistance to the host strain. A derivative of R388 DHFR, RBG200, has been cloned and overproduced [Vermersch, P. S., Klass, M. R., & Bennett, G. N. (1986) Gene 41, 289]. With this cloned and overproduced protein, a rapid purification procedure has been developed that yields milligram quantities of apparently homogeneous RBG200 DHFR with a specific activity 1.5-fold greater than that previously reported for the purified R388 protein [Amyes, S. G. B., & Smith, J. T. (1976) Eur. J. Biochem. 61, 597]. The pH versus activity profile and the native molecular weight of RBG200 DHFR were found to be similar to those previously reported for other type II DHFRs but different from those of the known chromosomal DHFRs. Stereospecifically labeled [4(S)-2H,4(R)-1H]NADPH was synthesized and used to determine the stereospecificity of NADPH oxidation by RBG200 DHFR. RBG200 DHFR was found to specifically transfer the pro-R hydrogen of NADPH to dihydrofolate, making it a member of the A-stereospecific class of dehydrogenases. Thus, although RBG200 DHFR is different both in sequence and in structure from known chromosomal enzymes, both enzymes catalyze identical hydrogen-transfer reactions. Two distinct binary RBG200 DHFR-NADP+ complexes were detected by monitoring the 1H NMR chemical shifts and line widths of the coenzyme in the presence of RBG200 DHFR.(ABSTRACT TRUNCATED AT 250 WORDS)

The processing of N-linked glycans in yeast. Mutually exclusive steps in the processing of a Man6 derivative by yeast membrane preparations

When a derivatized oligosaccharide isolated from ovalbumin and containing 6 mannose residues was incubated with yeast membranes and GDP-mannose, two sets of products were obtained, a high molecular weight one containing about 25 mannose residues and a low molecular weight one consisting of compounds with 7, 8, and 9 mannose residues, respectively. When the low molecular weight products were reincubated with the yeast membranes and GDP-mannose, no further mannose incorporation was observed, showing that these compounds must be of the wrong structure as substrates for yeast glycan processing enzymes. The structures were investigated by 1H NMR spectroscopy. The high molecular weight products contained an outer chain of an average length of 18 1----6-linked mannose residues attached to a core structure made up of the original 6 mannose residues with one additional 1----2-linked mannose added. The low molecular weight product with 8 mannose residues was deduced to contain a terminal 1----6-linked mannose (on the 1----6 arm) substituted by mannose at the 2-position, and the ones with 7 and 9 mannose residues were identified as having an additional 1----3-linked mannose on the starting Man6 substrate and on the Man8 product, respectively. The results lend further support to the picture that the processing steps must occur in proper sequence for specific products to form.

Protein matrix effects on glycan processing by mannosidase II and sialyl transferase from rat liver

The effect of the protein environment on the reaction sequence and the relative rates of two two-step reactions involved in the biosynthesis of complex glycans in glycoproteins has been explored by comparing the processing of biotinylated substrates either free or bound to avidin. By use of biotinyl and biotinamidohexanoyl derivatives, the display of the glycan in a proximal and distal association with the avidin surface could also be assessed. Mannosidase II removes two Man residues from the substrate GlcNAcMan5GlcNAc2-R to yield GlcNAcMAn3GlcNAc2-R. The NMR spectra of the substrate, intermediate, and product showed that the first Man is removed from the 6-arm of the substrate. The rate constants for the first and second step (estimated by direct analysis of the reactants by anion-exchange chromatography with a pulsed amperometric detector) were determined to be about 0.05 and 0.08 min-1, respectively, for the free substrates. In the proximal complex k1 was reduced 80-fold, and the k2 step could not be observed under the same conditions. In the distal complex both k1 and k2 were reduced about 8-fold. Sialyl transferases transfer Sia from CMP-Sia to the biantennary substrate Gal2GlcNAc2-Man3GlcNA2-R to yield the product Sia2Gal2-GlcNAc2Man3GlcNAc2-R with the Sia linked either 2-3 or 2-6 to the Gal residues. The NMR spectra showed that the first step involved the Gal on the 3-arm of the substrate and that both Sia residues were added 2-6.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and NMR studies of [methyl-13C]methionine-labeled truncated methionyl-tRNA synthetase

A procedure for the rapid purification of a truncated form of the Escherichia coli methionyl-tRNA synthetase has been developed. With this procedure, final yields of approximately 3 mg of truncated methionyl-tRNA synthetase per gram of cells, carrying the plasmid encoding the gene for the truncated synthetase [Barker, D.G., Ebel, J.-P., Jakes, R., & Bruton, C.J. (1982) Eur. J. Biochem. 127, 449], can be obtained. The catalytic properties of the purified truncated synthetase were found to be identical with those of the native dimeric and trypsin-modified methionyl-tRNA synthetases. A rapid procedure for obtaining milligram quantities of the enzyme is necessary before the efficient incorporation of stable isotopes into the synthetase becomes practical for physical studies. With this procedure, truncated methionyl-tRNA synthetase labeled with [methyl-13C]methionine was purified from an Escherichia coli strain auxotrophic for methionine and containing the plasmid encoding the gene for the truncated methionyl-tRNA synthetase. Both carbon-13 and proton observe-heteronuclear detect NMR experiments were used to observe the 13C-enriched methyl resonances of the 17 methionine residues in the truncated synthetase. In the absence of ligands, 13 of the 17 methionine residues could be resolved by carbon-13 NMR. Titration of the synthetase, monitoring the chemical shifts of resonances B and M (Figure 3), with a number of amino acid ligands and ATP yielded dissociation constants consistent with those derived from binding and kinetic data, indicating active site binding of the ligands under the conditions of the NMR experiment.(ABSTRACT TRUNCATED AT 250 WORDS)

Nuclear overhauser effect studies on the conformation of magnesium adenosine 5'-triphosphate bound to rabbit muscle creatine kinase

Nuclear Overhauser effects were used to determine interproton distances on MgATP bound to rabbit muscle creatine kinase. The internuclear distances were used in a distance geometry program that objectively determines both the conformation of the bound MgATP and its uniqueness. Two classes of structures were found that satisfied the measured interproton distances. Both classes had the same anti glycosidic torsional angle (chi = 78 +/- 10 degrees) but differed in their ribose ring puckers (O1'-endo or C4'-exo). The uniqueness of the glycosidic torsional angle is consistent with the preference of creatine kinase for adenine nucleotides. One of these conformations of MgATP bound to creatine kinase is indistinguishable from the conformation found for Co(NH3)4ATP bound to the catalytic subunit of protein kinase, which also has a high specificity for adenine nucleotides [chi = 78 +/- 10 degrees, O1'-endo; Rosevear, P.R., Bramson, H.N., O'Brian, C., Kaiser, E.T., & Mildvan, A.S. (1983) Biochemistry 22, 3439]. Distance geometry calculations also suggest that upper limit distances, when low enough (less than or equal to 3.4 A), can be used instead of measured distances to define, within experimental error, the glycosidic torsional angle of bound nucleotides. However, this approach does not permit an evaluation of the ribose ring pucker.

Nuclear Overhauser effect studies of the conformations of MgATP bound to the active and secondary sites of muscle pyruvate kinase

MgATP binds both at the active site (site 1) and at a secondary site (site 2) on each monomer of muscle pyruvate kinase as previously found by binding studies and by X-ray analysis. Interproton distances on MgATP bound at each site have been measured by the time-dependent nuclear Overhauser effect in the absence and presence of phosphoenolpyruvate (P-enolpyruvate), which blocks ATP binding at site 1. Interproton distances at site 2 are consistent with a single conformation of bound ATP with a high antiglycosidic torsional angle (chi = 68 +/- 10 degrees) and a C3'-endo ribose pucker (delta = 90 +/- 10 degrees). Interproton distances at site 1, determined in the absence of P-enolpyruvate by assuming the averaging of distances at both sites, cannot be fit by a single adenine-ribose conformation but require the contribution of at least three low-energy structures: 62 +/- 10% low anti (chi = 30 degrees), C3'-endo; 20 +/- 8% high anti (chi = 55 degrees), O1'-endo; and 18 +/- 8% syn (chi = 217 degrees), C2'-endo. Although a different set of ATP conformations might also have fit the interproton distances, the mixture of conformations used also fits previously determined distances from Mn2+ to the protons of ATP bound at site 1 [Sloan, D. L., & Mildvan, A. S. (1976) J. Biol. Chem. 251, 2412] and is similar to the adenine-ribose portion of free Co(NH3)4ATP, which consists of 35% low anti, 51% high anti, and 14% syn [Rosevear, P. R., Bramson, H. N., O'Brian, C., Kaiser, E. T., & Mildvan, A. S. (1983) Biochemistry 22, 3439].(ABSTRACT TRUNCATED AT 250 WORDS)

NMR and computer modeling studies of the conformations of glutathione derivatives at the active site of glyoxalase I

The conformations of four derivatives of glutathione bound at the active site of the metalloenzyme glyoxalase I have been determined by NMR measurements and by computer model building using a distance geometry approach. Paramagnetic effects of Mn2+-glyoxalase I on the longitudinal relaxation rates of the carbon-bound protons of the substrate analog S-(acetonyl)-glutathione at three frequencies, the hydrophobic competitive inhibitor S-(propyl)glutathione at four frequencies, and the charged competitive inhibitor S-(carboxymethyl)glutathione at a single frequency were used to calculate Mn2+ to proton distances in each complex. These and previously determined distances from Mn2+ to the protons and 13C-enriched carbon atoms of the product S-(D-lactoyl)glutathione were used in a distance geometry program to compute the conformations of each enzyme-bound derivative which best fit the measured distances and other known constraints such as bond lengths, van der Waals radii, planar and trans-peptide bonds, and thioester linkages. The distance geometry program also provided a measure of the uniqueness of the conformations consistent with the experimental data. Extended Y-shaped conformations were detected for each of the bound glutathione derivatives, similar to the x-ray structure and the theoretically calculated conformation of glutathione itself, suggesting this to be a low energy form. Acceptable conformations of each enzyme-bound derivative fell into two classes with the metal either above or below the mean plane through the glutathione compound. The conformational uncertainty within each class was relatively small, ranging from deviations of 0.9-1.9 A in the average positions of each of the atoms. A small but significant difference in the conformation of the substrate analog as compared to the product was detected in the position of the reaction center carbon directly bonded to the glutathione sulfur atom. Unlike the second-sphere metal complexes formed by the bound substrate analog, the product, or the hydrophobic competitive inhibitor, the charged competitive inhibitor S-(carboxymethyl)glutathione binds farther from the metal, in the third coordination sphere.

NMR studies of the mechanism of cyclic AMP-dependent protein kinase

NMR has been used to study the role of the divalent cation, the conformations, arrangement, and exchange rates of the enzyme-bound metal-ATP and peptide substrates, the mechanism of the phosphoryl transfer, and the structure and role of the regulatory subunit on type II cyclic AMP (cAMP)-dependent protein kinase from bovine heart. The active complex consists of an enzyme-ATP-metal bridge in which the metal is beta, gamma coordinated, with delta chirality at P beta, and a torsional angle at the adenine-ribose bond in the high-anti range (x approximately 80 degrees). The bound heptapeptide substrate Leu-Arg-Arg-Ala-Ser-Leu-Gly is extended in conformation, forming either a coil or, less likely, a beta turn but not an alpha helix or beta sheet. The distance from the gamma-P of bound ATP analogs to the Ser-OH of the bound peptide (5.3 +/- 0.7 A) would permit a metaphosphate or an elongated phosphorane intermediate or transition state. The regulatory subunit (R2) blocks the peptide- or protein-binding site of the catalytic subunit. The 31P chemical shift of cAMP is not greatly altered on binding to R2, but the resonance is broadened to approximately 32 Hz, which indicates no chemical change but marked immobilization of bound cAMP. A narrower (approximately 7 Hz) 31P resonance at 4.44 ppm is assigned to P-serine-95 of R2 because it disappears with catalytic subunit, Mg2+, and an ADP-generating system.

NMR studies of the backbone protons and secondary structure of pentapeptide and heptapeptide substrates bound to bovine heart protein kinase

The conformations of enzyme-bound pentapeptide (Arg-Arg-Ala-Ser-Leu) and heptapeptide (Leu-Arg-Arg-Ala-Ser-Leu-Gly) substrates of protein kinase have been studied by NMR in quaternary complexes of the type (Formula: see text). Paramagnetic effects of Mn2+ bound at the inhibitory site of the catalytic subunit on the longitudinal relaxation rates of backbone Ca protons, as well as on side-chain protons of the bound pentapeptide and heptapeptide substrates, have been used to determine Mn2+ to proton distances which range from 8.2 to 12.4 A. A combination of the paramagnetic probe-T1 method with the Redfield 2-1-4-1-2 pulse sequence for suppression of the water signal has been used to measure distances from Mn2+ to all of the backbone amide (NH) protons of the bound pentapeptide and heptapeptide substrates, which range from 6.8 to 11.1 A. Paramagnetic effects on the transverse relaxation rates yield rate constants for peptide exchange, indicating that the complexes studied by NMR dissociate rapidly enough to participate in catalysis. Model-building studies based on the Mn2+-proton distances, as well as on previously determined distances from Cr3+-AMPPCP to side-chain protons [Granot, J., Mildvan, A.S., Bramson, H. N., & Kaiser, E. T. (1981) Biochemistry 20, 602], rule out alpha-helical, beta-sheet, beta-bulge, and all possible beta-turn conformations within the bound pentapeptide and heptapeptide substrates. The distances are fit only by extended coil conformations for the bound peptide substrates with a minor difference between the pentapeptides and heptapeptides in the phi torsional angle at Arg3C alpha and in psi at Arg2C alpha. An extended coil conformation, which minimizes the number of interactions within the substrate, would facilitate enzyme-substrate interaction and could thereby contribute to the specificity of protein kinase.

13C NMR studies of the product complex of glyoxalase I

The paramagnetic effects of Mn2+ . glyoxalase I on the 13C relaxation rates of the reaction product, S-(D-lactoyl)glutathione, separately enriched in the lactoyl carbonyl (C-1) and hydroxymethylene (C-2) carbons, have been measured at 62.8 MHz. The 1/fT1p values of C-1 (1100 +/- 120 s-1) and C-2 (712 +/- 290 s-1) and the previously determined tau c (0.74 ns) yield Mn2+ to carbon distances of 5.7 +/- 0.3 and 6.1 +/- 0.5 A, respectively. These distances, together with previously determined Mn2+-proton distances (Sellin, S., Rosevear, P.R., Mannervik, B., and Mildvan, A.S. (1982) J. Biol. Chem. 257, 10023-10029) constrain the thioester carbonyl group of the product to point toward the metal, with the oxygen positioned to accept a hydrogen bond from a water ligand, in a kinetically competent, second sphere complex. Model-building studies indicate that any averaging of multiple second sphere complexes would require as a major contributor at least one conformation with the lactoyl carbonyl oxygen within hydrogen-bonding distance of an intervening water ligand. Such a structure would facilitate polarization of the carbonyl group in the reverse glyoxalase reaction.

Identification of carbohydrate-binding proteins from mouse and human fibroblasts

Three carbohydrate-binding proteins (Mr 35 000, 16 000 and 13 500) were isolated from extracts of mouse 3T3 fibroblasts by affinity chromatography on polyacrylamide beads to which was covalently bound the ligand 6-aminohexyl 4-beta-D-galactosyl-2-acetamido-2-deoxy-beta-D-glucopyranoside. None of these proteins bind to polyacrylamide beads coupled with either 6-aminohexanol or 6-aminohexyl beta-D-galactopyranoside. Therefore they appear to be carbohydrate-binding proteins specific for galactose-terminated glycoconjugates. A carbohydrate-binding protein was also purified from extracts of human foreskin fibroblasts. This protein (Mr 35000) may represent the human counterpart of the mouse protein of similar Mr and binding properties.