Investigating the role of the geminal dimethyl groups of coenzyme A: synthesis and studies of a didemethyl analogue

An analogue 2 of coenzyme A (CoA) has been prepared in which the geminal methyl groups are replaced with hydrogens. An NMR titration study was conducted and shifts in frequency of protons in the pantetheine portion of the molecule upon titration of the adenine base were observed as has been previously reported with CoA. These studies indicate that the geminal dimethyl groups are not essential for adoption of a partially folded conformation in solution. Based on 1H-1H coupling constants, the distribution of conformations about the carbon-carbon bonds in the region of the methyl deletion were estimated. The results suggest that the conformer distribution is similar to that of CoA, but with small increases in population of the anti conformers. A simple model compound containing the didemethyl pantoamide moiety was prepared and subjected to similar conformational analysis. The coupling constants and predicted conformer distribution were almost identical to that of the CoA analogue, indicating that the conformer distribution is controlled by local interactions and not influenced by interactions between distant parts of the CoA molecule. The acetyl derivative of 2 was a fairly good substrate for the acetyl-CoA utilizing enzymes carnitine acetyltransferase, chloramphenicol acetyltransferase, and citrate synthase, with 1.3- to 10-fold increased Km values and 2.5- to 11-fold decreases in Vmax. The combined results indicate that the geminal dimethyl groups of CoA have modest effects on function and minimal effects on conformation.     

Basic folded and low-populated locally disordered conformers of SUMO-2 characterized by NMR spectroscopy at varying pressures

SUMO proteins, a group of post-translational ubiquitin-like modifiers, have target enzymes (E1 and E2) like other ubiquitin-like modifiers, e.g., ubiquitin and NEDD8, but their physiological roles are quite different. In an effort to determine the characteristic molecular design of ubiquitin-like modifiers, we have investigated the structure of human SUMO-2 in solution not only in its basic folded state but also in its higher-energy state by utilizing standard and variable-pressure NMR spectroscopy, respectively. We have determined average coordinates of the basic folded conformer at ambient pressure, which gives a backbone structure almost identical with those of ubiquitin and NEDD8. We have further investigated conformational fluctuations in a wide conformational space using variable-pressure NMR spectroscopy in the range of 30-3 kbar, by which we find a low-populated ( approximately 2.5%) alternative conformer preferentially disordered in the enzyme-binding segment. The alternative conformer is structurally very close to but markedly different in equilibrium population from those for ubiquitin and NEDD8. These results support our notion that post-translational ubiquitin-like modifiers are evolutionarily designed for function both structurally and thermodynamically in their low-populated, high-energy conformers rather than in their basic folded conformers.     

Substrate-induced activation of a trapped IMC-mediated protein folding intermediate

While several unfolded proteins acquire native structures through distinct folding intermediates, the physiological relevance and importance of such states in the folding kinetics remain controversial. The intramolecular chaperone (IMC) of subtilisin was used to trap a partially folded, stable crosslinked intermediate conformer (CLIC) through a disulfide bond between mutated IMC and subtilisin. The trapped CLIC contains non-native interactions. Here we show that CLIC can be induced into a catalytically active form by incubating it with small peptide substrates. The structure and catalytic properties of the activated crosslinked intermediate conformer (A-CLIC) differ from those of the fully folded enzyme in that A-CLIC lacks any endopeptidase activity toward a large protein substrate. Our results show that a disulfide-linked partially folded protein can be induced to acquire catalytic activity with a substrate specificity that is different from completely folded subtilisin. These results also suggest that protein folding intermediates may also participate in catalytic reactions.     

Comparative fluorescence properties of bovine,goat, human and guinea pig α lactalbumin: Characterization of the environments of individual tryptophan residues in partially folded conformers

α Lactalbumin exists as a partially folded conformer (U form) at acid pH. A second partially folded conformer (H form) is formed above 60°. Comparison of the changes in tryptophan fluorescence which occur on forming U and H for the bovine, goat, human and guinea pig proteins, as well as analysis of fluorescence properties for the bovine protein and an N bromo succinimide derivative of this protein, have made it possible to determine which tryptophan residues give rise to such changes in fluorescence, and to draw a distinction between the molecular structure of the U and H forms of the protein. Trp 28 and 109 in the native state transfer their excitation energy to trp 63 whose fluorescence is quenched by a pair of vicinal disulfide bridges. This process persists in the U form of the protein, but is absent in the H conformer. Most of the change in fluorescence seen in the N ? U conversion is due to increase in yield of trp 28, while the changes in fluorescence occurring on formation of the H form are due to exposure of trp 63 and elimination of its quenching and/or excited state transfer from 28 to 109.     

Rationalizing the solution properties of zwitterions by means of computational chemistry

This short review describes our computational studies of carnitine, acetylcarnitines, and betaines over the past two decades. Interspersed among the three computational studies--a molecular mechanics study of the conformer population of carnitine and acetylcarnitine, an AM1 study of the energetics of hydrolysis of acetylcarnitine, and an HF 6-31G* study of the solvation energies and structures of a homologous series of betaines--are brief overviews of our research in designing and testing new therapeutic agents for non-insulin dependent diabetes and for protection against sexually transmitted diseases. The three studies also show how computational chemistry has evolved during this time to enable an evaluation of the structure and energetics of zwitterions in aqueous solution.     

A folded (10 S) conformer of myosin from a striated muscle and its implications for regulation of ATPase activity.

Myosin from the striated adductor muscle of the scallop Pecten maximus is shown to fold into a compact 10 S conformer under relaxing conditions, as has been characterized for smooth and non-muscle myosins. The folding transition is accompanied by the trapping of nucleotide at the active site to give a species with a half-life of about an hour at 20 degrees C. Ca2+ binding to the specific, regulatory sites on a myosin head promotes unfolding to the extended 6 S conformer and activates product release by 60-fold. The unfolding transition, however, remains much slower than the contraction-relaxation cycle of scallop striated muscle and could not play a role in the regulation of these events. The dissociation of products from myosin heads in native thick filaments is Ca2(+)-regulated, but under relaxing conditions the nucleotide is released at least an order of magnitude faster than from the 10 S monomeric myosin, at a rate similar to that observed with heavy meromyosin. Thus, there is no evidence for any intermolecular interaction between neighbouring molecules in the filament analogous to the head-neck intramolecular interaction in the 10 S conformer. It is possible that the 10 S myosin state represents an inert form involved in the control of filament assembly during muscle growth and development. Removal of regulatory light chains or labelling the reactive heavy chain thiol of myosin prevents, or at least disfavours, formation of the folded 10 S conformer and allows separation of the modified protein from the native molecules.     

Two alternating structures of the HIV-1 leader RNA

In this study we demonstrate that the HIV-1 leader RNA exists in two alternative conformations, a branched structure consisting of several well-known hairpin motifs and a more stable structure that is formed by extensive long-distance base pairing. The latter conformation was first identified as a compactly folded RNA that migrates unusually fast in nondenaturing gels. The minimally required domains for formation of this conformer were determined by mutational analysis. The poly(A) and DIS regions of the leader are the major determinants of this RNA conformation. Further biochemical characterization of this conformer revealed that both hairpins are disrupted to allow extensive long-distance base pairing. As the DIS hairpin is known to be instrumental for formation of the HIV-1 RNA dimer, the interplay between formation of the conformer and dimerization was addressed. Formation of the conformer and the RNA dimer are mutually exclusive. Consequently, the conformer must rearrange into a branched structure that exposes the dimer initiation signal (DIS) hairpin, thus triggering formation of the RNA dimer. This structural rearrangement is facilitated by the viral nucleocapsid protein NC. We propose that this structural polymorphism of the HIV-1 leader RNA acts as a molecular switch in the viral replication cycle.     

A partially structured species of beta 2-microglobulin is significantly populated under physiological conditions and involved in fibrillogenesis

The folding of beta(2)-microglobulin (beta(2)-m), the protein forming amyloid deposits in dialysis-related amyloidosis, involves formation of a partially folded conformation named I(2), which slowly converts into the native fold, N. Here we show that the partially folded species I(2) can be separated from N by capillary electrophoresis. Data obtained with this technique and analysis of kinetic data obtained with intrinsic fluorescence indicate that the I(2) conformation is populated to approximately 14 +/- 8% at equilibrium under conditions of pH and temperature close to physiological. In the presence of fibrils extracted from patients, the I(2) conformer has a 5-fold higher propensity to aggregate than N, as indicated by the thioflavine T test and light scattering measurements. A mechanism of aggregation of beta(2)-m in vivo involving the association of the preformed fibrils with the fraction of I(2) existing at equilibrium is proposed from these results. The possibility of isolating and quantifying a partially folded conformer of beta(2)-m involved in the amyloidogenesis process provides new opportunities to monitor hemodialytic procedures aimed at the reduction of such species from the pool of circulating beta(2)-m but also to design new pharmaceutical approaches that consider such species as a putative molecular target.     

Enhanced stability of cis Pro-Pro peptide bond in Pro-Pro-Phe sequence motif

Identification of sequence motifs that favor cis peptide bonds in proteins is important for understanding and designing proteins containing turns mediated by cis peptide conformations. From (1)H NMR solution studies on short peptides, we show that the Pro-Pro peptide bond in Pro-Pro-Phe almost equally populates the cis and trans isomers, with the cis isomer stabilized by a CHc...pi interaction involving the terminal Pro and Phe. We also show that Phe is over-represented at sequence positions immediately following cis Pro-Pro motifs in known protein structures. Our results demonstrate that the Pro-Pro cis conformer in Pro-Pro-Phe sequence motifs is as important as the trans conformer, both in short peptides as well as in natively folded proteins.     

Two folded conformers of ubiquitin revealed by high-pressure NMR.

High-pressure 15N/1H two-dimensional NMR spectroscopy has been utilized to study conformational fluctuation of a 76-residue protein ubiquitin at pH 4.5 at 20 degrees C. The on-line variable pressure cell technique is used in conjunction with a high-field NMR spectrometer operating at 750 MHz for 1H in the pressure range between 30 and 3500 bar. Large, continuous and reversible pressure-induced 1H and 15N chemical shifts were observed for 68 backbone amide groups, including the 7.52 ppm 15N shift of Val70 at 3500 bar, indicating a large-scale conformational change of ubiquitin with pressure. On the basis of the analysis of sigmoid-shaped pressure shifts, we conclude that ubiquitin exists as an equilibrium mixture of two major folded conformers mutually converting at a rate exceeding approximately 10(4) s(-1) at 20 degrees C at 2000 bar. The second conformer exists at a population of approximately 15% (DeltaG(0) = 4.2 kJ/mol) and is characterized with a significantly smaller partial molar volume (DeltaV(0) = -24 mL/mol) than that of the well-known basic native conformer. The analysis of 1H and 15N pressure shifts of individual amide groups indicates that the second conformer has a loosened core structure with weakened hydrogen bonds in the five-stranded beta-sheet. Furthermore, hydrogen bonds of residues 67-72 belonging to beta5 are substantially weakened or partially broken, giving increased freedom of motion for the C-terminal segment. The latter is confirmed by the significant decrease in 15N[1H] nuclear Overhauser effect for residues beyond 70 at high pressure. Since the C-terminal carboxyl group constitutes the reactive site for producing a multi-ubiquitin structure, the finding of the second folded conformer with a substantially altered conformation and mobility in the C-terminal region will shed new light on the reaction mechanism of ubiquitin.     

A study of the conformational state of the ATP gamma-p-azidoanilide-Mn2+ complex by NMR and atom-atomic potential methods

By means of H1 and P31 spin-lattice relaxation and atom-atomic potentials method it is shown that in aquous solution the ATP gamma-p-azidoanilide--Mn2+ complex occurs mainly as a mixture of two conformers in the ratio of 60:40. They both possess folded conformations with distances between aromatic rings 5-6 A, and adenine residue anti-oriented, the ribose and triphosphate chain conformations are 3E and gg, g'g', g'g', respectively, in the major conformer, and 2E and g'g', g'g', g'g' in the second conformer. Mn2+ ion forms 2-3 complexes with each conformer (the cation being differently coordinated) by substituting phosphoryl oxygens or N7 atoms of adenine for two water molecules in the hydration shell of the cation. Magnesium ion forms inner-sphere complexes with two out of four ion-coordination centres (P alpha, P beta, P gamma, N7(A] and outer-sphere complexes with two other centres.     

Equilibrium distribution of conformations for Met5-enkephalin predicted by energy calculation and related to experiment

Results of an extensive theoretical conformational analysis of the opiate pentapeptide Met⁵-enkephalin are compared to spectroscopic data. The comparison enables us to propose a consistent model for the conformational state of Met⁵-enkephalin in solution. The empirical energy calculations suggest that the molecule exists in aqueous solution in a small number of folded and extended families of conformers. The predominance of β_II′-turns at the level of the glycine residues at positions 2 and 3 is the most significant characteristic of folded conformers. A highly populated conformer of Met⁵-enkephalin is shown to possess structural features in common with the very potent narcotic etonitazene.     

A delicate interplay of structure, dynamics, and thermodynamics for function: a high pressure NMR study of outer surface protein A

Outer surface protein A (OspA) is a crucial protein in the infection of Borrelia burgdorferi causing Lyme disease. We studied conformational fluctuations of OspA with high-pressure ¹⁵N/¹H two-dimensional NMR along with high-pressure fluorescence spectroscopy. We found evidence within folded, native OspA for rapid local fluctuations of the polypeptide backbone in the nonglobular single layer β-sheet connecting the N- and C-terminal domains with τ << ms, which may give the two domains certain independence in mobility and thermodynamic stability. Furthermore, we found that folded, native OspA is in equilibrium (τ >> ms) with a minor conformer I, which is almost fully disordered and hydrated for the entire C-terminal part of the polypeptide chain from β8 to the C-terminus. Conformer I is characterized with ΔG⁰ = 32 ± 9 kJ/mol and ΔV⁰ = −140 ± 40 mL/mol, populating only ∼0.001% at 40°C at 0.1 MPa, pH 5.9. Because in the folded conformer the receptor binding epitope of OspA is buried in the C-terminal domain, its transition into conformer I under in vivo conditions may be critical for the infection of B. burgdorferi. The formation and stability of the peculiar conformer I are apparently supported by a large packing defect or cavity located in the C-terminal domain.     

Minor folding defects trigger local modification of glycoproteins by the ER folding sensor GT

UDP-glucose:glycoprotein glucosyltransferase (GT) is a key component of the glycoprotein-specific folding and quality control system in the endoplasmic reticulum. By exclusively reglucosylating incompletely folded and assembled glycoproteins, it serves as a folding sensor that prolongs the association of newly synthesized glycoproteins with the chaperone-like lectins calnexin and calreticulin. Here, we address the mechanism by which GT recognizes and labels its substrates. Using an improved inhibitor assay based on soluble conformers of pancreatic ribonuclease in its glycosylated (RNase B) and unglycosylated (RNase A) forms, we found that the protein moiety of a misfolded conformer alone is sufficient for specific recognition by GT in vitro. To investigate the relationship between recognition and glucosylation, we tested a variety of glycosylation mutants of RNase S-Protein and an RNase mutant with a local folding defect [RNase C65S, C72S], as well as a series of loop insertion mutants. The results indicated that local folding defects in an otherwise correctly folded domain could be recognized by GT. Only glycans attached to the polypeptide within the misfolded sites were glucosylated.     

Kinetics of folding of Escherichia coli OmpA from narrow to large pore conformation in a planar bilayer

The outer membrane protein of Escherichia coli, OmpA, is currently alleged to adopt two native conformations: a major two-domain conformer in which 171 N-terminal residues form a narrow eight beta-barrel pore and 154 C-terminal residues are in the periplasm and a minor one-domain conformer in which all 325 residues create a large pore. However, recent studies in planar bilayers indicate the conformation of OmpA is temperature-sensitive and that increasing temperature converts narrow pores to large pores. Here we examine the reversibility and kinetics of this transition for single OmpA molecules in planar bilayers of diphytanoylphosphatidylcholine (DPhPC). We find that the transition is irreversible. When temperatures are decreased, large pores close down, and when temperatures are stabilized they reopen in the large pore conformation, with gradually increasing open time. Large pores are converted to narrow pores only by denaturing agents. The transition from narrow to large pores requires temperatures >or= 26 degrees C and is a biphasic process with rates that rise steeply with temperature. The first phase, a flickering stepwise transition from a low-conductance to a high-conductance state requires approximately 7 h at 26 degrees C but only approximately 13 min at 42 degrees C, signifying an activation energy of 139 +/- 12 kJ/mol. This is followed by a gradual increase in conductance and open probability, interpreted as optimization of the large pore structure. The results indicate that the two-domain structure is a partially folded intermediate that is kinetically stable at lower temperatures and that mature fully folded OmpA is a large pore.     

Global structure of four-way RNA junctions studied using fluorescence resonance energy transfer.

Four-way helical junctions are found widely in natural RNA species. In this study, we have studied the conformation of two junctions by fluorescence resonance energy transfer. We show that the junctions are folded by pairwise coaxial helical stacking, forming one predominant stacking conformer in both examples studied. At low magnesium ion concentrations, the helical axes of both junctions are approximately perpendicular. One junction undergoes a rotation into a distorted antiparallel structure induced by the binding of a single magnesium ion. By contrast, the axes of the four-way junction of the U1 snRNA remain approximately perpendicular under all conditions examined, and we have determined the stacking conformer adopted.     

Folding protein alpha-carbon chains into compact forms by Monte Carlo methods.

A method is presented for generating folded chains of specific amino acid sequences on a simple cubic lattice. Monte Carlo simulations are used to transform extended geometries of simplified alpha-carbon chains for eight small monomeric globular proteins into folded states. Permitted chain transitions are limited to a few types of moves, all restricted to occur on the lattice. Crude residue-residue potentials derived from statistical structure data are used to describe the energies for each conformer. The low resolution structures obtained by this procedure contain many of the correct gross features of the native folded architectures with respect to average residue energy per nonbonded contact, segment density, and location of surface loops and disulfide pairs. Rms deviations between these and the native X-ray structures and percentage of native long-range contacts found in these final folded structures are 7.6 +/- 0.7 A and 48 +/- 3%, respectively. This procedure can be useful for predicting approximate tertiary interactions from amino acid sequence.     

Synthesis and anthelmintic activity of substituted (R)-phenyllactic acid containing cyclohexadepsipeptides

The substituted (R)-phenyllactic acid containing cyclohexadepsipeptides (CHDPs) represent novel enniatin derivatives with strong in vivo activities against the parasitic nematode Haemonchus contortus Rudolphi in sheep. 2D NMR spectroscopic analysis revealed for the substituted (R)-phenyllactic acid containing CHDPs one major conformer with an unsymmetrically folded conformation lacking a cis-amide bond. A correlation between the substitution pattern and its anthelmintic activity was found. Here we report on a simple total synthetic pathway of the precursor for this particular type of CHDPs and an efficient modification of the benzylic side chain (R-PhLac(2)).     

Temperature-jump NMR study of protein folding: Ribonuclease A at low pH

Summary The kinetic process of folding of bovine pancreatic ribonuclease A in a²H₂O environment at pH 1.2 was examined by a recently developed temperature-jump NMR method (Akasaka et al., (1990) Rev. Sci. Instrum.61, 66–68). Upon temperature-jump down from 45°C to 29°C, which was attained within 6 s, the proton NMR spectral changes were followed consecutively in time intervals of seconds. There was a rapid spectral change, which was finished within the jump period, followed by a much slower process which lasted for a minute or longer. Rates of the slower process were measured at different positions of the polypeptide chain as intensity changes of individual His and Tyr proton signals of the folded conformer and as intensity changes of aliphatic and His protons of the unfolded conformer. Most of these rates coincided with each other within experimental error with an average value of 2.8×10^–2s^–1. The result gave clear experimental evidence that the slow folding of RNase A at low pH is a cooperative process involving most regions of the molecule, not only thermodynamically, but kinetically as well.     

Anesthetic stabilization of protein intermediates: myoglobin and halothane

Halothane, an inhaled anesthetic, destabilizes the folded structure of myoglobin. To determine whether this is due to preferential interactions with less stable folded conformers of myoglobin versus the completely unfolded state, we used photoaffinity labeling, hydrogen exchange, fluorescence spectroscopy, and circular dichroism spectroscopy. Apomyoglobin was used as a model of a less stable conformer of myoglobin. Halothane destabilizes myoglobin and binds with low affinity and stoichiometry but stabilizes and binds with higher affinity to apomyoglobin. The same halothane concentration has no effect on cytochrome c stability. The apomyoglobin/halothane complex is favored at pH 6.5 as compared to pH 4.5 or pH 2.5. Halothane photoincorporates into several sites in apomyoglobin, some allosteric to the heme pocket. Guanidinium unfolding of myoglobin, monitored by CD spectroscopy, shows destabilization at less than 1.3 M Gdm but stabilization at greater than 1.3 M Gdm, consistent with the hypothesis that less stable conformers of myoglobin bind halothane preferentially. We suggest the structural feature underlying preferential binding to less stable conformers is an enlarged cavity volume distribution, since myoglobin has several intermediate-sized cavities, while cytochrome c is more well packed and has no cavities detected by GRASP. Specific binding to less stable intermediates may underlie anesthetic potentiation of protein activity.