Formation of stable class II MHC/peptide complex involves conformational changes and proceeds via an intermediate. Although this intermediate complex forms and dissociates in minutes, its conversion ...to a stable complex is a very slow process, taking up to a few days to reach completion. Here, we investigate the different steps of this binding and demonstrate that the conformational changes necessary to generate a receptive molecule is the rate-determining slow step in the process, while formation of the stable MHC/peptide complex is very rapid. With HLA-DR1 as our model class II molecule, we first used low affinity variants of hemagglutinin peptide (HA306-318), which lack the principal anchor, to shape the conformation of the MHC and then studied the kinetics of stable binding of HA306-318 to such an induced conformation. We found that the apparent association rate of HA306-318 is equivalent to the dissociation rate of the low affinity peptide. A 4- to 18-fold enhancement in the binding rates of HA306-318 was observed depending on the dissociation rates of the low affinity peptides. These results establish that 1) formation of stable MHC/peptide complexes is very rapid and 2) prior binding of low affinity peptide induces a receptive conformation in MHC for efficient stable peptide binding. Furthermore, in the absence of any free peptide, this receptive molecule rapidly reverts to slow binding behavior toward the subsequently offered peptide. These results have important implications for the roles of low affinity MHC/peptide complexes in Ag presentation.
Certain class II MHC-peptide complexes are resistant to SDS-induced dissociation. This property, which has been used as an in vivo as well as an in vitro peptide binding assay, is not understood at ...the molecular level. Here we have investigated the mechanistic basis of SDS stability of HLA-DR1 complexes by using a biosensor-based assay and SDS-PAGE with a combination of wild-type and mutant HLA-DR1 and variants of hemagglutinin peptide HA306-318. Experiments with wild-type DR1 along with previously published results establish that the SDS-stable complexes are formed only when the hydrophobic pocket 1 (P1) is occupied by a bulky aromatic (Trp, Phe, Tyr) or an aliphatic residue (Met, Ile, Val, Leu). To further explore whether the SDS sensitivity is primarily due to the exposed hydrophobic regions, we mutated residue beta Gly86 at the bottom of P1 to tyrosine, presumably reducing the depth of the pocket and the exposure of hydrophobic residues and increasing the contacts between subunits. In direct contrast to wild-type DR1, the peptide-free mutant DR1 exists as an alpha/beta heterodimer in SDS. Moreover, the presence of a smaller hydrophobic residue, such as alanine, as P1 anchor with no contribution from any other anchor is sufficient to enhance the SDS stability of the mutant complexes, demonstrating that the basis of SDS resistance may be localized to P1 interactions. The good correlation between SDS sensitivity and the exposure of hydrophobic residues provides a biochemical rationale for the use of this assay to investigate the maturation of class II molecules and the longevity of the complexes.
The human class II major histocompatibility complex protein HLA-DR1 has been shown previously to undergo a distinct conformational change from an open to a compact form upon binding peptide. To ...investigate the role of peptide in triggering the conformational change, the minimal requirements for inducing the compact conformation were determined. Peptides as short as two and four residues, which occupy only a small fraction of the peptide-binding cleft, were able to induce the conformational change. A mutant HLA-DR1 protein with a substitution in the β subunit designed to fill the P1 pocket from within the protein (Gly86 to Tyr) adopted to a large extent the compact, peptide-bound conformation. Interactions important in stabilizing the compact conformation are shown to be distinct from those responsible for high affinity binding or for stabilization of the complex against thermal denaturation. The results suggest that occupancy of the P1 pocket is responsible for partial conversion to the compact form but that both side chain and main chain interactions contribute to the full conformational change. The implications of the conformational change to intracellular antigen loading and presentation are discussed.
A subsite model as proposed by Hiromi Hiromi, K. (1970) Biochem. Biophys. Res. Commun. 40, 1-6 has been applied to various hydrolases including glucoamylase (GA). The model assumes a single enzyme ...complex, a hydrolytic rate constant which is independent of substrate length, and a ratelimiting hydrolytic step. Recent kinetic studies with GA contradict these assumptions. Here we reevaluate the substrate binding of GA studying the pre-steady-state kinetics with glucose, which is reported here for the first time, and maltose. The association equilibrium constants for glucose and maltose interactions with wild-type and Trp120-->Phe GA from Aspergillus awamori in H2O and D2O buffers were obtained. Kinetic results indicate that a single glucose molecule binds to GA weakly by a single-step mechanism, E + G1<-->EG1, under the conditions studied. Similar fluorescence intensities of the GA-glucose and GA-maltose complexes, the high tryptophan concentration around subsite 1, crystal structures of various inhibitor complexes, pre-steady-state and steady-state modeling, feasibility of condensation reactions, and other evidence strongly suggest that glucose binds at subsite 1. These results conflict with the high subsite 2 and low subsite 1 affinities obtained using Hiromi's model. Using the substrate association constants for glucose and maltose obtained by pre-steady-state kinetics, the affinity of alpha-glucose for subsite 1 is shown to be substantially higher than the apparent affinity of glucose for subsite 2. We propose a GA catalytic mechanism whereby substrate binding is initiated by subsite 1 interactions with the nonreducing end of the oligosaccharide substrate, minimizing nonproductive substrate binding. Through conformational changes, entropic contributions, and increased local concentration, subsite 2 subsequently has enhanced affinity for the second covalently linked glucosyl residue.
Intermediates in the catalytic mechanism of Aspergillus awamori glucoamylase (GA) were identified by studying pre-steady-state and steady-state kinetics of the wild-type GA/maltose and Trp120 -->Phe ...GA/maltotriose reactions in H2O and D2O. Pre-steady-state fluorescence signal analysis was carried out to ascertain the relative intrinsic fluorescence of the enzyme intermediates. A three-step minimal pathway for oligosaccharide hydrolysis represented by E + Gx (k1) reversible (k-1) EGX (k2)reversible(k-2) EP (kcat)--> E + P is proposed. The first step, represented by the association constant K1 (k1/k-1), depicts the fast formation of enzyme-substrate complex and is the primary factor in fluorescence quenching. A 2.7-fold increase in K1 with D2O as solvent is observed with both enzymes due to the cumulative effect of deuterium on complex hydrogen bonding at the active site. The second step further quenches the enzyme fluorescence and is identified as the hydrolytic step, forming an enzyme-product complex. Both k2 and k-2 values show similar 2-fold decreases in D2O for both enzymes, consistent with the microscopic reversibility of the hydrolytic reaction. The solvent isotopic effect on the hydrolytic step is likely due to either abstraction of an exchangeable proton from the general acid Glu179 or directed addition of water to the oxocarbonium ion intermediate by the general base Glu400. No significant isotope effect was observed on the steady-state kcat value for wild-type GA with maltose, indicating a ronhydrolytic step as rate-limiting. The third step, a posthydrolytic rate-determining step, is the product release as evident from steady-state kinetics with wild-type and Trp120-->Phe GAs using alpha-D-glucosyl fluoride.