Convergent synthesis and properties of photoactivable NADPH mimics targeting nitric oxide synthases.

A new series of photoactivable NADPH mimics bearing one or two O-carboxymethyl groups on the adenosine moiety have been readily synthesized using click chemistry. These compounds display interesting one- or two-photon absorption properties. Their fluorescence emission wavelength and quantum yields (Φ) are dependent on the solvent polarity, with a red-shift in a more polar environment (λmax,em = 460-467 nm, Φ > 0.53 in DMSO, and λmax,em = 475-491 nm, Φ < 0.17 in Tris). These compounds show good binding affinity towards the constitutive nNOS and eNOS, confirming for the first time that the carboxymethyl group can be used as a surrogate of phosphate. Two-photon fluorescence imaging of nanotriggers in living cells showed that the presence of one carboxymethyl group (especially on the 3' position of the ribose) strongly favors the addressing of nanotriggers to eNOS in the cell context.

Differential behaviour of cationic triphenylamine derivatives in fixed and living cells: triggering and imaging cell death.

Triphenylamines are on/off fluorescent DNA minor groove binders, allowing nuclear staining of fixed cells. By contrast, they accumulate in the cytoplasm of living cells and efficiently trigger cell apoptosis upon prolonged visible light irradiation. This process occurs concomitantly with their subcellular re-localization to the nucleus, enabling fluorescence imaging of apoptosis.

New triarylamine-based far-red DNA stainers with high two-photon absorption properties.

A series of red emitting vinyl-triphenyamines (TP) have been synthesized and evaluated for their two photon absorption (2PA) properties. These compounds are virtually non fluorescent in the free state but exhibit a bright red fluorescence upon binding to double-stranded DNA, both in one- and two-photon absorption. This feature allows one- and two-photon confocal imaging in cells of nuclear DNA with an excellent contrast. Derivatizable analogues for covalent bioconjugation to oligonucleotides are described and variation on the structure is discussed.

Replacement of Asp-162 by Ala prevents the cooperative transition by the substrates while enhancing the effect of the allosteric activator ATP on E. coli aspartate transcarbamoylase.

The available crystal structures of Escherichia coli aspartate transcarbamoylase (ATCase) show that the conserved residue Asp-162 from the catalytic chain interacts with essentially the same residues in both the T- and R-states. To study the role of Asp-162 in the regulatory properties of the enzyme, this residue has been replaced by alanine. The mutant D162A shows a 7700-fold reduction in the maximal observed specific activity, a twofold decrease in the affinity for aspartate, a loss of homotropic cooperativity, and decreased activation by the nucleotide effector adenosine triphosphate (ATP) compared with the wild-type enzyme. Small-angle X-ray scattering (SAXS) measurements reveal that the unliganded mutant enzyme adopts the T-quaternary structure of the wild-type enzyme. Most strikingly, the bisubstrate analog N-phosphonacetyl-L-aspartate (PALA) is unable to induce the T to R quaternary structural transition, causing only a small alteration of the scattering pattern. In contrast, addition of the activator ATP in the presence of PALA causes a significant increase in the scattering amplitude, indicating a large quaternary structural change, although the mutant does not entirely convert to the wild-type R structure. Attempts at modeling this new conformation using rigid body movements of the catalytic trimers and regulatory dimers did not yield a satisfactory solution. This indicates that intra- and/or interchain rearrangements resulting from the mutation bring about domain movements not accounted for in the simple model. Therefore, Asp-162 appears to play a crucial role in the cooperative structural transition and the heterotropic regulatory properties of ATCase.

Behaviour of bovine phosphatidylethanolamine-binding protein with model membranes. Evidence of affinity for negatively charged membranes.

The ability of phosphatidylethanolamine-binding protein (PEBP) to bind membranes was tested by using small and large unilamellar vesicles and monolayers composed of l-alpha-1,2-dimyristoylphosphatidylcholine, l-alpha-1,2-dimyristoylphosphatidylglycerol and l-alpha-1,2-dimyristoylphosphatidylethanolamine. PEBP only bound to model membranes containing l-alpha-1,2-dimyristoylphosphatidylglycerol; the interaction was primarily due to electrostatic forces between the basic protein and the acidic phospholipids. Further experiments indicated that the interaction was not dependent on the length and unsaturation of the phospholipid acyl chains and was not modified by the presence of cholesterol in the membrane. PEBP affinity for negatively charged membranes is puzzling considering the previous identification of the protein as a phosphatidylethanolamine-binding protein, and suggests that the association of PEBP with phospholipid membranes is driven by a mechanism other than its binding to solubilized phosphatidylethanolamine. An explanation was suggested by its three-dimensional structure: a small cavity at the protein surface has been reported to be the binding site of the polar head of phosphatidylethanolamine, while the N-terminal and C-terminal parts of PEBP, exposed at the protein surface, appear to be involved in the interaction with membranes. To test this hypothesis, we synthesized the two PEBP terminal regions and tested them with model membranes in parallel with the whole protein. Both peptides displayed the same behaviour as whole PEBP, indicating that they could participate in the binding of PEBP to membranes. Our results strongly suggest that PEBP directly interacts with negatively charged membrane microdomains in living cells.

DNA binding induces dissociation of the multimeric form of HIV-1 integrase: a time-resolved fluorescence anisotropy study.

Self-assembly of HIV-1 integrase (IN) in solution has been studied previously by time-resolved fluorescence, using tryptophan anisotropy decay. This approach provides information on the size of macromolecules via the determination of rotational correlation times (theta). We have shown that, at submicromolar concentration, IN is characterized by a long rotational correlation time (theta(20 degrees C) = 90-100 ns) corresponding to a high-order oligomeric form, likely a tetramer. In the present work, we investigated the self-assembly properties of the DNA-bound IN by using three independent fluorophores. Under enzymatic assay conditions (10(-7) M IN, 2 x 10(-8) M DNA), using either fluorescein-labeled or fluorescent guanosine analog-containing oligonucleotides that mimic a viral end long terminal repeat sequence, we found that the DNA-IN complex was characterized by shorter theta(20 degrees C) values of 15.5-19.5 and 23-27 ns, calculated from experiments performed at 25 degrees C and 37 degrees C, respectively. These results were confirmed by monitoring the Trp anisotropy decay as a function of the DNA substrate concentration: the theta of IN shifted from 90-100 ns to lower values (<30 ns) upon increasing the DNA concentration. Again, the normalized theta(20 degrees C) values were significantly higher when monitored at 37 degrees C as compared with 25 degrees C. These results indicate that upon binding the viral DNA end, the multimeric enzyme undergoes a dissociation, most likely into a homogeneous monomeric form at 25 degrees C and into a monomer-dimer equilibrium at 37 degrees C.

Tryptophan residues at subunit interfaces used as fluorescence probes to investigate homotropic and heterotropic regulation of aspartate transcarbamylase.

The homotropic and heterotropic interactions in Escherichia coli aspartate transcarbamylase (EC 2.1.3.2) are accompanied by various structure modifications. The large quaternary structure change associated with the T to R transition, promoted by substrate binding, is accompanied by different local conformational changes. These tertiary structure modifications can be monitored by fluorescence spectroscopy, after introduction of a tryptophan fluorescence probe at the site of investigation. To relate unambiguously the fluorescence signals to structure changes in a particular region, both naturally occurring Trp residues in positions 209c and 284c of the catalytic chains were previously substituted with Phe residues. The regions of interest were the so-called 240's loop at position Tyr240c, which undergoes a large conformational change upon substrate binding, and the interface between the catalytic and regulatory chains in positions Asn153r and Phe145r supposed to play a role in the different regulatory processes. Each of these tryptophan residues presents a complex fluorescence decay with three to four independent lifetimes, suggesting that the holoenzyme exists in slightly different conformational states. The bisubstrate analogue N-phosphonacetyl-L-aspartate affects mostly the environment of tryptophans at position 240c and 145r, and the fluorescence signals were related to ligand binding and the quaternary structure transition, respectively. The binding of the nucleotide activator ATP slightly affects the distribution of the conformational substates as probed by tryptophan residues at position 240c and 145r, whereas the inhibitor CTP modifies the position of the C-terminal residues as reflected by the fluorescence properties of Trp153r. These results are discussed in correlation with earlier mutagenesis studies and mechanisms of the enzyme allosteric regulation.

Oligomeric states of the HIV-1 integrase as measured by time-resolved fluorescence anisotropy.

Self-assembly properties of HIV-1 integrase were investigated by time-resolved fluorescence anisotropy using tryptophanyl residues as a probe. From simulation analyses, we show that suitable photon counting leads to an accurate determination of long rotational correlation times in the range of 20-80 ns, permitting the distinction of the monomer, dimer, and tetramer from higher oligomeric forms of integrase. The accuracy of correlation times higher than 100 ns is too low to distinguish the octamer from other larger species. The oligomeric states of the widely used detergent-solubilized integrase were then studied in solution under varying parameters known to influence the activity. In the micromolar range, integrase exists as high-order multimers such as an octamer and/or aggregates and a well-defined tetramer, at 25 and 35 degrees C, respectively. However, integrase is monomeric at catalytically active concentrations (in the sub-micromolar range). Detergents (NP-40 and CHAPS) and divalent cation cofactors (Mg(2+) and Mn(2+)) have a clear dissociative effect on the high multimeric forms of integrase. In addition, we observed that Mg(2+) and Mn(2+) have different effects on both the oligomeric state and the conformation of the monomer. This could explain in part why these two metal cations are not equivalent in terms of catalytic activity in vitro. In contrast, addition of Zn(2+) stimulates dimerization. Interestingly, this role of Zn(2+) in the multimerization process was evident only in the presence of Mg(2+) which by itself does not induce oligomerization. Finally, it is highly suggested that the presence of detergent during the purification procedure plays a negative role in the proper self-assembly of integrase. Accordingly, the accompanying paper [Leh, H., et al. (2000) Biochemistry 39, 9285-9294] shows that a detergent-free integrase preparation has self-assembly and catalytic properties different from those of the detergent-solubilized enzyme.

Determinants of Mg2+-dependent activities of recombinant human immunodeficiency virus type 1 integrase.

The relationship between Mg(2+)-dependent activity and the self-assembly state of HIV-1 integrase was investigated using different protein preparations. The first preparations, IN(CHAPS) and IN(dial), were purified in the presence of detergent, but in the case of IN(dial), the detergent was removed during a final dialysis. The third preparation, IN(zn), was purified without any detergent. The three preparations displayed comparable Mn(2+)-dependent activities. In contrast, the Mg(2+)-dependent activity that reflects a more realistic view of the physiological activity strongly depended on the preparation. IN(CHAPS) was not capable of using Mg(2+) as a cofactor, whereas IN(zn) was highly active under the same conditions. In the accompanying paper [Deprez, E., et al. (2000) Biochemistry 39, 9275-9284], we used time-resolved fluorescence anisotropy to demonstrate that IN(CHAPS) was monomeric at the concentration of enzymatic assays. Here, we show that IN(zn) was homogeneously tetrameric under similar conditions. Moreover, IN(dial) that exhibited an intermediary Mg(2+)-dependent activity existed in a monomer-multimer equilibrium. The level of Mg(2+)- but not Mn(2+)-dependent activity of IN(dial) was altered by addition of detergent which plays a detrimental role in the maintenance of the oligomeric organization. Our results indicate that the ability of integrase to use Mg(2+) as a cofactor is related to its self-assembly state in solution, whereas Mn(2+)-dependent activity is not. Finally, the oligomeric IN(zn) was capable of binding efficiently to DNA regardless of the cationic cofactor, whereas the monomeric IN(CHAPS) strictly required Mn(2+). Thus, we propose that a specific conformation of integrase is a prerequisite for its binding to DNA in the presence of Mg(2+).

Effect of single mutations on the structural dynamics of a DNA repair enzyme, the Escherichia coli formamidopyrimidine-DNA glycosylase--a fluorescence study using tryptophan residues as reporter groups.

The effects on the structure dynamics of the Escherichia coli wild-type formamidopyrimidine-DNA glycosylase (Fpg) protein of the single mutations Lys57-->Gly (FpgK57G), Pro2-->Gly (FpgP2G) and Pro2-->Glu (FpgP2E) were studied by fluorescence techniques, namely: lifetime measurements and acrylamide quenching of the fluorescence of Trp residues. The fluorescence decays of Fpg and its mutant forms were analysed by the maximum-entropy method and lifetime distributions in the range 200 ps to 9 ns were obtained. The lifetime distribution profiles of FpgK57G, FpgP2G and FpgP2E are different from that of wild-type Fpg. Both dynamic and static quenching by acrylamide were observed for all the proteins. At 20 degrees C, the bimolecular collisional quenching rate constant of the FpgP2E fluorescence by acrylamide was only 0.8 M(-1) s(-1) as compared to about 1.4 M(-1) s(-1) for the three other proteins. At 6 degrees C, all the spectroscopic properties of these four proteins are about the same. The analysis of experimental data demonstrates that all three mutations induce a structural reorganization of the Fpg protein. However, only the P2E mutation lead to a reduced accessibility of some Trp residues to acrylamide quenching. It is concluded that the single P2E replacement induces a conformational change leading to a more rigid globular structure as opposed to the wild type and K57G and P2G mutations. The influence of the single mutations on the enzyme activities of the Fpg protein is discussed.

Structural investigations of basic amphipathic model peptides in the presence of lipid vesicles studied by circular dichroism, fluorescence, monolayer and modeling.

A cationic amphiphilic peptide made of 10 leucine and 10 lysine residues, and four of its fluorescent derivatives in which leucines were substituted by Trp residues at different locations on the primary sequence have been synthesized. The interactions of these five peptides with neutral anionic or cationic vesicles were investigated using circular dichroism, steady state and time-resolved fluorescence with a combination of Trp quenching by brominated lipid probes, monolayers, modeling with minimization and simulated annealing procedures. We show that all the five peptides interact with neutral and anionic DMPC, DMPG, DOPC or egg yolk PC vesicles. The binding takes place whatever the peptide conformation in solution is. In the case of DMPC bilayers the binding free energy DeltaG is estimated at -8 kcal mole-1 and the number of phospholipid molecules involved is about 20-25 per peptide molecule. Peptides are bound as single-stranded alpha helices orientated parallel to the bilayer surface. In the anchoring of phospholipid head groups around the peptides, the lipid molecules are not smeared out in a plane parallel to the membrane surface but are organized around the hydrophilic face of the alpha helices like 'wheat grains around an ear' and protrude outside the bilayer towards the solvent. We suggest that such a lipid arrangement generates transient structural defects responsible for the membrane permeability enhancement. When an electrical potential is applied, the axis of the peptide helices remains parallel to the membrane surface and does not reorient to give rise to a bundle of helix monomers that forms transmembrane channels via a 'barrel stave' mechanism. The penetration depth of alpha helices in relation to the position of phosphorus atoms in the unperturbed lipid leaflet is estimated at 3.2 A.

Solvent effects on horse apomyoglobin dynamics.

The effects of the solvent conditions (buffer pH 9, 8, or 7 or buffer pH 6.5 alone or mixed with 3.2% ethanol or 6.2% formamide) on the protein dynamics of horse apomyoglobin were investigated through tryptophan fluorescence quenching, spectra, and decay properties. Raising the pH (which induces discontinuous protein conformation changes) increases the structural fluctuations inside the hydrophobic A, G, and H helix core. Mixed solutions containing either 3.2% ethanol or 6.2% formamide (which redistribute water molecules on the protein surface) produce protein dynamics changes in the vicinity of the two Trp residues, without inducing particular constraints on these very residues. Formamide increases, in the same way, the polarity and the protein flexibility while ethanol reduces both. The present fluorescence work also shows that, whatever the outside solvent, the two Trp residues W7 and W14, embedded in the A, G, and H helix core, are equally and statistically reached by small molecules diffusing inside the protein matrix. Hydrogen-tritium exchange measurements on the protein in mixed solvents reveal that the dynamics of the A, G, and H helix cluster and of the B and E helixes are greatly influenced by the nature of the outside medium. A small amount of formamide in the buffer increases the protein fluctuations while an ethanol-water mixture reduces them. We suggest that the hydratation state of the protein surface could be the relevant parameter of the protein dynamics.

Pressure effects on the lateral distribution of cholesterol in lipid bilayers: a time-resolved spectroscopy study.

The effects of hydrostatic pressure and temperature on the phase behavior and physical properties of the binary mixture palmitoyloleoylphosphatidylcholine/cholesterol, over the 0-40 molar % range of cholesterol compositions, were determined from the changes in the fluorescence lifetime distribution and anisotropy decay parameters of the natural lipid trans-parinaric acid (t-PnA). Pressurized samples were excited with a Ti-sapphire subpicosecond laser, and fluorescence decays were analyzed by the quantified maximum entropy method. Above the transition temperature (T(T) = -5 degrees C), at atmospheric pressure, two liquid-crystalline phases, alpha and beta, are formed in this system. At each temperature and cholesterol concentration below the transition pressure, the fluorescence lifetime distribution pattern of t-PnA was clearly modulated by the pressure changes. Pressure increased the fraction of the liquid-ordered beta-phase and its order parameter, but it decreased the amount of cholesterol in this phase. Palmitoyloleoylphosphatidylcholine/cholesterol phase diagrams were also determined as a function of temperature and hydrostatic pressure.

Dynamic and structural properties of glucose oxidase enzyme.

The catalytic oxidation of beta-D-glucose by the enzyme glucose oxidase involves a redox change of the flavin coenzyme. The structure and the dynamics of the two extreme glucose oxidase forms were studied by using infrared absorption spectroscopy of the amide I'band, tryptophan fluorescence quenching and hydrogen isotopic exchange. The conversion of FAD to FADH2 does not change the amount of alpha-helix present in the protein outer shell, but reorganizes a fraction of random coil to beta-sheet structure. The dynamics of the protein interior vary with the redox states of the flavin without affecting the motions of the structural elements near the protein surface. From the structure of glucose oxidase given by X-ray crystallography, these results suggest that the dynamics of the interface between the two monomers are involved in the catalytic mechanism.

X-ray scattering titration of the quaternary structure transition of aspartate transcarbamylase with a bisubstrate analogue: influence of nucleotide effectors.

The regulation of aspartate transcarbamylase (ATCase) involves various conformational changes, including a large quaternary structure rearrangement. This is directly related to a major change in its solution X-ray scattering curve upon binding the bisubstrate analogue N-(phosphonacetyl)-L-aspartate (PALA), allowing us to monitor directly the amount of the different quaternary structures present in solution. Data were analysed by singular vector decomposition without any prior assumption as to the number of quaternary structure states. Scattering curves in the presence of variable concentrations of PALA, alone or with saturating CTP or ATP, can be accounted for with only two states. Consequently the method gives the fraction of molecules in either state. Whereas CTP slightly decreases the proportion of molecules in the R state, ATP has no detectable effect, whatever the amount of PALA ligated to ATCase. The requirement for only two quaternary structures, suggesting a concerted transition, promoted us to test the ability of the classical model, proposed by Monod, Wyman and Changeux, to account for our data. By and large, it is satisfactory as regards the homotropic effect of PALA and the observed effect of CTP, although it remains incompatible with some other observations, which support the involvement of more indirect mechanisms in the inhibitory properties of CTP. But ATP does not directly influence the T to R transition and consequently must act by a totally different mechanism.

Glu-50 in the catalytic chain of Escherichia coli aspartate transcarbamoylase plays a crucial role in the stability of the R quaternary structure.

Glu-50 of aspartate transcarbamoylase from Escherichia coli forms a set of interdomain bridging interactions between the 2 domains of the catalytic chain; these interactions are critical for stabilization of the high-activity high-affinity form of the enzyme. The mutant enzyme with an alanine substituted for Glu-50 (Glu-50-->Ala) exhibits significantly reduced activity, little cooperativity, and altered regulatory behavior (Newton CJ, Kantrowitz ER, 1990, Biochemistry 29:1444-1451). A study of the structural consequences of replacing Glu-50 by alanine using solution X-ray scattering is reported here. Correspondingly, in the absence of substrates, the mutant enzyme is in the same, so-called T quaternary conformation as is the wild-type enzyme. In the presence of a saturating concentration of the bisubstrate analog N-phosphonacetyl-L-aspartate (PALA), the mutant enzyme is in the same, so-called R quaternary conformation as the wild-type enzyme. However, the Glu-50-->Ala enzyme differs from the wild-type enzyme, in that its scattering pattern is hardly altered by a combination of carbamoyl phosphate and succinate. Addition of ATP under these conditions does result in a slight shift toward the R structure. Steady-state kinetic studies indicate that, in contrast to the wild-type enzyme, the Glu-50-->Ala enzyme is activated by PALA at saturating concentrations of carbamoyl phosphate and aspartate, and that PALA increases the affinity of the mutant enzyme for aspartate. These data suggest that the enzyme does not undergo the normal T to R transition upon binding of the physiological substrates and verifies the previous suggestion that the interdomain bridging interactions involving Glu-50 are critical for the creation of the high-activity, high-affinity R state of the enzyme.

Apparent cooperativity for carbamoylphosphate in Escherichia coli aspartate transcarbamoylase only reflects cooperativity for aspartate.

The reaction catalyzed by Escherichia coli aspartate transcarbamoylase (ATCase) proceeds through an ordered mechanism, in which carbamoylphosphate binds first, followed by aspartate; upon binding of this second substrate, the enzyme undergoes a concerted transition from a low-affinity T state to a high-affinity R state. In various studies, conflicting results were obtained concerning the existence of positive cooperativity for the first substrate, carbamoylphosphate. It is shown here that cooperativity for this substrate is only apparent. Indeed, saturation curves for carbamoylphosphate display sigmoidicity only if the aspartate concentration used is high enough to shift ATCase into the R state. Furthermore, it is shown that succinate, an unreactive aspartate analogue which is able to promote the T-->R conformational transition, also induces the appearance of cooperativity for carbamoylphosphate. Similar results were obtained in the course of continuous-flow-dialysis experiments, which show that the binding of carbamoylphosphate is apparently cooperative only in the presence of a concentration of succinate high enough to shift the enzyme into the R state. Taken together, these data show that the apparent cooperativity for carbamoylphosphate is not an intrinsic property of ATCase, as it only reflects the cooperativity for the second substrate, aspartate, as a consequence of the process of ordered substrate binding.

Pressure effects on the physical properties of lipid bilayers detected by trans-parinaric acid fluorescence decay.

The effects of hydrostatic pressure on the physical properties of large unilamellar vesicles of single lipids dipalmitoyl phosphatidylcholine (DPPC) and dimyristoyl phosphatidylcholine (DMPC) and lipid mixtures of DMPC/DPPC have been studied from time-resolved fluorescence of trans-parinaric acid. Additional experiments were carried out using diphenylhexatriene to compare the results extracted from both probes. Fluorescence decays were analyzed by the maximum entropy method. Pressure does not influence the fluorescence lifetime distribution of trans-parinaric acid in isotropic solvents. However, in pressurized lipid bilayers an abrupt change was observed in the lifetime distribution which was associated with the isothermal pressure-induced phase transition. The pressure to temperature equivalence values, dT/dP, determined from the midpoint of the phase transitions, were 24 and 14.5 degrees C kbar-1 for DMPC and POPC, respectively. Relatively moderate pressures of about 500 bar shifted the DMPC/DPPC phase diagram 11.5 degrees C to higher temperatures. The effects of pressure on the structural properties of these lipid vesicles were investigated from the anisotropy decays of both probes. Order parameters for all systems increased with pressure. In the gel phase of POPC the order parameter was smaller than that obtained in the same phase of saturated phospholipids, suggesting that an efficient packing of the POPC hydrocarbon chains is hindered.

The tryptophan residues of aspartate transcarbamylase: site-directed mutagenesis and time-resolved fluorescence spectroscopy.

Aspartate transcarbamylase (EC 2.1.3.2) contains two tryptophan residues in position 209 and 284 of the catalytic chains (c) and no such chromophore in the regulatory chains (r). Thus, as a dodecamer [(c3)2(r2)3] the native enzyme molecule contains 12 tryptophan residues. The present study of the regulatory conformational changes in this enzyme is based on the fluorescence properties of these intrinsic probes. Site-directed mutagenesis was used in order to differentiate the respective contributions of the two tryptophans to the fluorescence properties of the enzyme and to identify the mobility of their environment in the course of the different regulatory processes. Each of these tryptophan residues gives two independent fluorescence decays, suggesting that the catalytic subunit exists in two slightly different conformational states. The binding of the substrate analog N-phosphonacetyl-L-aspartate promotes the same fluorescence signal whether or not the catalytic subunits are associated with the regulatory subunits, suggesting that the substrate-induced conformational change of the catalytic subunit is the essential trigger for the quaternary structure transition involved in cooperativity. The binding of the substrate analog affects mostly the environment of tryptophan 284, while the binding of the activator ATP affects mostly the environment of tryptophan 209, confirming that this activator acts through a mechanism different from that involved in homotropic cooperativity.

Structural consequences of the replacement of Glu239 by Gln in the catalytic chain of Escherichia coli aspartate transcarbamylase.

Low-angle X-ray scattering in solution has been used to probe the quaternary structure of a mutant version of Escherichia coli aspartate transcarbamylase in which Glu239 of the catalytic chain was replaced by glutamine by site-directed mutagenesis. X-ray crystallographic studies of the wild-type enzyme have shown that one set of intersubunit interactions involving Glu239 are lost, and are replaced by another set of intrachain interactions when the enzyme undergoes the allosteric transition from the T to the R state. Functional analysis of the mutant enzyme with glutamine in place of Glu239 indicates that homotropic co-operativity is lost without altering the maximal specific activity. The radius of gyration of the unligated mutant enzyme is larger than the unligated wild-type, indicating an alteration in quaternary structure of the mutant. However, the radius of gyration of the mutant enzyme in the presence of N-(phosphonoacetyl)-L-aspartate (PALA) is identical with the value for the wild-type enzyme in the presence of PALA. X-ray scattering at larger angles indicates that the mutant enzyme is in a new structural state different from the wild-type T and R structures. The scattering pattern in the presence of saturating concentrations of PALA is identical with that of the wild-type R structure. Saturating concentrations of carbamyl phosphate alone are sufficient to convert most of the mutant enzyme to the R structure, in the absence of aspartate. CTP shifts the scattering pattern of the mutant enzyme in the presence of saturating carbamyl phosphate towards the scattering curve of the unligated enzyme, but CTP has no effect on the scattering curve in the absence of carbamyl phosphate or in the presence of subsaturating PALA. However, in the presence of subsaturating PALA, ATP causes a strong shift towards the R structure. Neither ATP nor CTP has any effect on the activity of the mutant enzyme. These data suggest that the replacement of Glu239 by glutamine results in a new quaternary structure. These data also explain, on a structural basis, why co-operativity is lost in this mutant enzyme.