Characterization of the glutathione binding site of aldose reductase.

Despite extensive investigations, the physiological role of the polyol pathway enzyme-aldose reductase (AR) remains obscure. While the enzyme reduces glucose in vivo and in vitro, kinetic and structural studies indicate inefficient carbohydrate binding to the active site of the enzyme. The active site is lined by hydrophobic residues and appears more compatible with the binding of medium- to long-chain aliphatic aldehydes or hydrophobic aromatic aldehydes. In addition, our recent studies show that glutathione (GS) conjugates are also reduced efficiently by the enzyme. For instance, the GS conjugate of acrolein is reduced with a catalytic efficiency 1000-fold higher than the parent aldehyde, indicating specific recognition of glutathione by the active site residues of AR. An increase in the catalytic efficiency upon glutathiolation was also observed with trans-2-nonenal, trans-2-hexenal and trans, trans-2,4-decadienal, establishing that enhancement of catalytic efficiency was specifically due to the glutathione backbone and not specific to the aldehyde. Structure-activity relationships with substitution or deletion of amino acids of GSH indicated specific interactions of the active site with gamma-Glu1 and Cys of GSH. Molecular modeling revealed that the glutathione-propanal conjugate could bind in two distinct orientations. In orientation 1, gamma-Glu1 of the conjugate interacts with Trp20, Lys21 and Val47, and Gly3 interacts with Ser302 and Leu301, whereas in orientation 2, the molecule is inverted with gamma-Glu1 interacting with Ser302, and Leu301. Taken together, these data suggest that glutathiolation of aldehydes enhances their compatibility with the AR active site, which may be of physiological significance in detoxification of endogenous and xenobiotic aldehydes.

The herpesvirus encoded dUTPase as a potential chemotherapeutic target.

The human herpesviruses are a well characterized group of viruses that are responsible for a wide spectrum of human diseases. Included in this group of pathogens are the alphaherpesviruses (herpes simplex types 1 and 2 and varicella-zoster virus), the betaherpesviruses (cytomegalovirus, human herpesvirus types 6 and 7) and the gammaherpesviruses (Epstein-Barr virus and human herpesvirus 8). An important feature of these viruses is that they cause latent infections that can be reactivated to cause disease. The herpesviruses encode for a large number of structural and non-structural proteins, and several of the non-structural proteins, such as thymidine kinase, DNA polymerase, and ribonucleotide reductase, have been utilized as targets for the development of anti-herpesvirus agents. Another herpesvirus encoded enzyme that has received little attention as a potential target for the development of specific anti-herpesvirus agents is deoxyuridine triphosphate nucleotidohydrolase (dUTPase). Furthermore, little is known concerning the role of the herpesviruses' encoded dUTPases in virus replication and in modulating the chemotherapeutic efficiency of other anti-herpes agents. Because of recent advances in molecular virology and biochemistry, it is now possible to rationally develop "designer" drugs based upon the structural/functional interaction of the drug with a specific viral protein. The purpose of this review is to describe previous studies demonstrating the potential use of the herpesvirus encoded dUTPase as a drug target, to describe problems associated with using the dUTPase as a target and to discuss new approaches that can be used.

Selective recognition of glutathiolated aldehydes by aldose reductase.

In this study, the selectivity and specificity of aldose reductase (AR) for glutathionyl aldehydes was examined. Relative to free aldehydes, AR was a more efficient catalyst for the reduction of glutathiolated aldehydes. Reduction of glutathionyl propanal [gammaGlu-Cys(propanal)-Gly] was more efficient than that of Gly-Cys(propanal)-Gly and gamma-aminobutyric acid-Cys(propanal)-Gly suggesting a possible interaction between alpha-carboxyl of the conjugate and AR. Two active site residues, Trp20 or Ser302, were identified by molecular modeling as potential sites of this interaction. Mutations containing tryptophan-to-phenylalanine (W20F) and serine-to-alanine (S302A) substitutions did not significantly affect reduction of free aldehydes but decreased the catalytic efficiency of AR for glutathiolated aldehydes. Combined mutations indicate that both Trp20 and Ser302 are required for efficient catalysis of the conjugates. The decrease in efficiency due to W20F mutation with glutathionyl propanal was not observed with gamma-aminobutyric-Cys(propanal)-Gly or Gly-Cys-(propanal)-Gly, indicating that Trp20 is involved in binding the alpha-carboxyl of the conjugate. The effect of the S302A mutation was less severe when gammaGlu-Cys(propanal)-Glu rather than glutathionyl propanal was used as the substrate, consistent with an interaction between Ser302 and Gly-3 of the conjugate. These observations suggest that glutathiolation facilitates aldehyde reduction by AR and enhances the range of aldehydes available to the enzyme. Because the N-terminal carboxylate is unique to glutathione, binding of the conjugate with the alpha-carboxyl facing the bottom of the alpha/beta-barrel may assist in the exclusion of unrelated peptides and proteins.

Crystal structure and thermodynamic analysis of human brain fatty acid-binding protein.

Expression of brain fatty acid-binding protein (B-FABP) is spatially and temporally correlated with neuronal differentiation during brain development. Isothermal titration calorimetry demonstrates that recombinant human B-FABP clearly exhibits high affinity for the polyunsaturated n-3 fatty acids alpha-linolenic acid, eicosapentaenoic acid, docosahexaenoic acid, and for monounsaturated n-9 oleic acid (K(d) from 28 to 53 nm) over polyunsaturated n-6 fatty acids, linoleic acid, and arachidonic acid (K(d) from 115 to 206 nm). B-FABP has low binding affinity for saturated long chain fatty acids. The three-dimensional structure of recombinant human B-FABP in complex with oleic acid shows that the oleic acid hydrocarbon tail assumes a "U-shaped" conformation, whereas in the complex with docosahexaenoic acid the hydrocarbon tail adopts a helical conformation. A comparison of the three-dimensional structures and binding properties of human B-FABP with other homologous FABPs, indicates that the binding specificity is in part the result of nonconserved amino acid Phe(104), which interacts with double bonds present in the lipid hydrocarbon tail. In this context, analysis of the primary and tertiary structures of human B-FABP provides a rationale for its high affinity and specificity for polyunsaturated fatty acids. The expression of B-FABP in glial cells and its high affinity for docosahexaenoic acid, which is known to be an important component of neuronal membranes, points toward a role for B-FABP in supplying brain abundant fatty acids to the developing neuron.

Kinetic and structural characterization of the glutathione-binding site of aldose reductase.

Aldose reductase (AR), a member of the aldo-keto reductase superfamily, has been implicated in the etiology of secondary diabetic complications. However, the physiological functions of AR under euglycemic conditions remain unclear. We have recently demonstrated that, in intact heart, AR catalyzes the reduction of the glutathione conjugate of the lipid peroxidation product 4-hydroxy-trans-2-nonenal (Srivastava, S., Chandra, A., Wang, L., Seifert, W. E., Jr., DaGue, B. B., Ansari, N. H., Srivastava, S. K., and Bhatnagar, A. (1998) J. Biol. Chem. 273, 10893-10900), consistent with a possible role of AR in the metabolism of glutathione conjugates of aldehydes. Herein, we present several lines of evidence suggesting that the active site of AR forms a specific glutathione-binding domain. The catalytic efficiency of AR in the reduction of the glutathione conjugates of acrolein, trans-2-hexenal, trans-2-nonenal, and trans,trans-2,4-decadienal was 4-1000-fold higher than for the corresponding free alkanal. Alterations in the structure of glutathione diminished the catalytic efficiency in the reduction of the acrolein adduct, consistent with the presence of specific interactions between the amino acid residues of glutathione and the AR active site. In addition, non-aldehydic conjugates of glutathione or glutathione analogs displayed active-site inhibition. Molecular dynamics calculations suggest that the conjugate adopts a specific low energy configuration at the active site, indicating selective binding. These observations support an important role of AR in the metabolism of glutathione conjugates of endogenous and xenobiotic aldehydes and demonstrate, for the first time, efficient binding of glutathione conjugates to an aldo-keto reductase.

Definition and transfer of a serological epitope specific for peptide-empty forms of MHC class I.

Nascent class I molecules have been hypothesized to undergo a conformational change when they bind peptide based on the observation that most available antibodies only detect peptide-loaded class I. Furthermore recent evidence suggests that this peptide-facilitated conformational change induces the release of class I from association with transporter associated with antigen processing (TAP)/tapasin and other endoplasmic reticulum proteins facilitating class I assembly. To learn more about the structure of peptide-empty class I, we have studied mAb 64-3-7 that is specific for peptide-empty forms of L(d). We show here that mAb 64-3-7 detects a linear stretch of amino acids including principally residues 48Q and 50P. Furthermore, we demonstrate that the 64-3-7 epitope can be transferred to other class I molecules with limited mutagenesis. Interestingly, in the folded class I molecule residues 48 and 50 are on a loop connecting a beta strand (under the bound peptide) with the alpha(1) helix (rising above the ligand binding site). Thus it is attractive to propose that this loop is a hinge region. Importantly, the three-dimensional structure of this loop is strikingly conserved among class I molecules. Thus our findings suggest that all class I molecules undergo a similar conformational change in the loop around residues 48 and 50 when they associate with peptide.

An extensive region of an MHC class I alpha 2 domain loop influences interaction with the assembly complex.

Presentation of antigenic peptides to CTLs at the cell surface first requires assembly of MHC class I with peptide and beta 2-microglobulin in the endoplasmic reticulum. This process involves an assembly complex of several proteins, including TAP, tapasin, and calreticulin, all of which associate specifically with the beta 2-microglobulin-assembled, open form of the class I heavy chain. To better comprehend at a molecular level the regulation of class I assembly, we have assessed the influence of multiple individual amino acid substitutions in the MHC class I alpha 2 domain on interaction with TAP, tapasin, and calreticulin. In this report, we present evidence indicating that many residues surrounding position 134 in H-2Ld influence interaction with assembly complex components. Most mutations decreased association, but one (LdK131D) strongly increased it. The Ld mutants, with the exception of LdK131D, exhibited characteristics suggesting suboptimal intracellular peptide loading, similar to the phenotype of Ld expressed in a tapasin-deficient cell line. Notably, K131D was less peptide inducible than wild-type Ld, which is consistent with its unusually strong association with the endoplasmic reticulum assembly complex.

Alloreactive and syngeneic CTL are comparably dependent on interaction with MHC class I alpha-helical residues.

The molecular basis for the difference in the strength of T cell responses to self vs alloantigens is unknown, but may reflect how T cells are selected in the thymus. Because T cells with a high affinity for foreign as opposed to self MHC molecules are able to mature, it has been proposed that alloreactive T cells may be more strongly dependent upon interaction with MHC residues than are self-restricted T cells. This study was undertaken to rigorously address this hypothesis. Whereas other studies have compared self vs alloantigen recognition of different MHC alleles by a single T cell clone, we have compared self vs alloantigen recognition of a single MHC allele, H-2Ld, by a large panel of self-restricted and alloreactive T cell clones. Target cells expressing Ld molecules mutated at several different potential TCR contact residues were analyzed to determine which residues are important for recognition by self-restricted vs alloreactive T cells. We unequivocally demonstrate that self-restricted and alloreactive T cells do not differ, but rather are comparably dependent on interaction with MHC residues. Importantly, both self-restricted and alloreactive T cells are dependent upon the same MHC residues as primary contacts and, in addition, share a common recognition pattern of Ld. Furthermore, our analysis enables us to provide a model for allotype-specific T cell recognition of Ld vs Kb class I molecules.

Ternary complex structure of human HGPRTase, PRPP, Mg2+, and the inhibitor HPP reveals the involvement of the flexible loop in substrate binding.

Site-directed mutagenesis was used to replace Lys68 of the human hypoxanthine phosphoribosyltransferase (HGPRTase) with alanine to exploit this less reactive form of the enzyme to gain additional insights into the structure activity relationship of HGPRTase. Although this substitution resulted in only a minimal (one- to threefold) increase in the Km values for binding pyrophosphate or phosphoribosylpyrophosphate, the catalytic efficiencies (k(cat)/Km) of the forward and reverse reactions were more severely reduced (6- to 30-fold), and the mutant enzyme showed positive cooperativity in binding of alpha-D-5-phosphoribosyl-1-pyrophosphate (PRPP) and nucleotide. The K68A form of the human HGPRTase was cocrystallized with 7-hydroxy [4,3-d] pyrazolo pyrimidine (HPP) and Mg PRPP, and the refined structure reported. The PRPP molecule built into the [(Fo - Fc)phi(calc)] electron density shows atomic interactions between the Mg PRPP and enzyme residues in the pyrophosphate binding domain as well as in a long flexible loop (residues Leu101 to Gly111) that closes over the active site. Loop closure reveals the functional roles for the conserved SY dipeptide of the loop as well as the molecular basis for one form of gouty arthritis (S103R). In addition, the closed loop conformation provides structural information relevant to the mechanism of catalysis in human HGPRTase.

The three-dimensional structure of an H-2Ld-peptide complex explains the unique interaction of Ld with beta-2 microglobulin and peptide.

Solution at 2.5-A resolution of the three-dimensional structure of H-2Ld with a single nine-residue peptide provides a structural basis for understanding its unique interaction with beta-2 microglobulin (beta2m) and peptide. Consistent with the biological data that show an unusually weak association of Ld with beta2m, a novel orientation of the alpha1/alpha2 domains of Ld relative to beta2m results in a dearth of productive contacts compared with other class I proteins. Characteristics of the Ld antigen-binding cleft determine the unique motif of peptides that it binds. Ld has no central anchor residue due to the presence of several bulky side chains in its mid-cleft region. Also, its cleft is significantly more hydrophobic than that of the other class I molecules for which structures are known, resulting in many fewer H-bonds between peptide and cleft residues. The choice of Pro as a consensus anchor at peptide position 2 appears to be related to the hydrophobicity of the B pocket, and to the unique occurrence of Ile (which mirrors Pro in its inability to form H-bonds) at position 63 on the edge of this pocket. Thus, the paucity of stabilizing H-bonds combined with poor complementarity between peptide postion 2 Pro and the B pocket contribute to the weak association between Ld and its peptide antigen. The unique structural interactions of Ld with beta2m and peptide could make Ld more suited than other classical class I molecules to play a role in alternative pathways of antigen presentation.