In the present study, we report on the X-ray crystallographic structure of a GH32 invertase mutant, (i.e., the Arabidopsis thaliana cell-wall invertase 1-E203Q, AtcwINV1-mutant) in complex with sucrose. This structure was solved to reveal the features of sugar binding in the catalytic pocket. However, as demonstrated by the X-ray structure the sugar binding and the catalytic pocket arrangement is significantly altered as compared with what was expected based on previous X-ray structures on GH-J clan enzymes. We performed a series of docking and molecular dynamics simulations on various derivatives of AtcwINV1 to reveal the reasons behind this modified sugar binding. Our results demonstrate that the E203Q mutation introduced into the catalytic pocket triggers conformational changes that alter the wild type substrate binding. In addition, this study also reveals the putative productive sucrose binding modus in the wild type enzyme.
Summary. Background: Activated thrombin activatable fibrinolysis inhibitor (TAFIa) plays a pivotal role in fibrinolysis. TAFIa activity is regulated by a temperature-dependent instability. This instability has not only complicated the study of structure-function relationships of TAFIa but has also prevented the crystallization of TAFIa. Furthermore, the TAFIa instability has severely compromised the development of activity inhibiting monoclonal antibodies. Recently, we combined all known stabilizing mutations (i.e. S305C, T325I, T329I, H333Y and H335Q) resulting in a synergistic (one hundred and eightyfold) stabilization of TAFIa at 37°C. All these residues are located in an amino acid region (AA297-335) consisting of a-helix 9 and b-sheet 11. Objectives: To provide a comparative evaluation of the characteristics of a panel of stable TAFIa mutants and an energy-minimized model of the most stable TAFI variant. Results: The catalytic efficiency for activation of TAFI by thrombin/thrombomodulin was higher for all TAFI mutants compared with TAFI-wild type (wt). Except for TAFI variants carrying T325I-T329I, S305C-T325I or S305C-T325I-T329I mutations, the catalytic efficiency for Hip-Arg hydrolysis by TAFIa was similar for the TAFI mutants compared with the wild type. All TAFIa variants were equally well inhibited by potato tuber carboxypeptidase inhibitor (PTCI) and showed a significantly increased antifibrinolytic potential in accordance with their increased stability. Based on the intrinsic fluorescence decay of TAFIa, two independent structural transitions were found to be associated with the loss of functional activity. Conclusions: Using molecular dynamic calculations on both TAFI-wt and TAFI-S305C-T325I-T329I-H333Y-H335Q models, we were able to identify the molecular interactions that contribute to the increased stability of the mutants.
The fluorescence emission of the single tryptophan (W233) of the mutant protein DD-carboxypeptidase from streptomyces is characterized by a red-edge excitation shift (REES), i.e., the phenomenon that the wavelength of maximum emission depends on the excitation wavelength. This phenomenon is an indication for a strongly reduced dynamic environment of the single tryptophan, which has a very low accessibility to the solvent. The REES shows, however, an unusual temperature and time dependence. This, together with the fluorescence lifetime analysis, showing three resolvable lifetimes, can be explained by the presence of three rotameric states that can be identified using the Dead-End Elimination method. The three individual lifetimes increase with increasing emission wavelength, indicating the presence of restricted protein dynamics within the rotameric states. This is confirmed by time-resolved anisotropy measurements that show dynamics within the rotamers but not among the rotamers. The global picture is that of a protein with a single buried tryptophan showing strongly restricted dynamics within three distinct rotameric states with different emission spectra and an anisotropic environment.
The origin of the biexponential fluorescence decay of Trp in ribonuclease T1 under mildly destabilizing conditions, such as increased pH or temperature, or the presence of detergent, is still not understood. We have performed two extended replica-exchange molecular dynamics simulations to obtain a detailed representation of the native state at two protonation states corresponding to a high and low pH. At high pH, the appearance of partially unfolded states is evident. We found that this pH-induced destabilization originates from increased global repulsion as well as reduced local favorable electrostatic interactions and reduced H-bonding strength of His(27), His(40), and His(92). At high pH, alternative tryptophan rotamers appear and are linked to a distorted environment of the tryptophan, which also acts as a separate source of ground-state heterogeneity. The total population of these alternative conformations agrees well with the amplitude of the experimentally observed secondary fluorescence lifetime.
We observed an unusual glycine-to-glutamate substitution at protease (PR) residue position 48 (G48E) in an African patient infected with a subtype A1 HIV-1 strain failing a saquinavir-containing regimen. Phenotypic analysis of protease inhibitor (PI) susceptibility showed that the G48E site-directed mutant, when introduced into an NL4-3 HIV-1 PR backbone, was slightly resistant to SQV (2-fold when compared with the wild-type virus). In addition, the G48E and G48E/V82A site-directed mutants were associated with a decrease in fitness, whereas a reversion to the wild type at position 48 was observed in vitro. Growth competition experiments using a novel growth competition assay based on enhanced green fluorescent protein- or Discosoma spp. red fluorescent protein-expressing viruses showed that the replicative fitness of the G48E virus was reduced to 55% compared with the parental NL4-3 virus. Synthesizing all possible site-directed mutants found in the patient strain is too time-consuming; therefore, a molecular dynamics (MD) simulation approach was used to understand why this mutation survived despite its fitness cost. These simulations documented that the G48E mutant interacted with PI resistance mutations (M46I, I54V, Q58E, and L63P) and with natural polymorphisms specific to subtype A1 (E35D, M36I, and R57K) that were present in the patient's virus. We hypothesize that the polymorphisms contained in the PR flap regions of the patient's virus may compensate for the presence of G48E, possibly by restoring the flexibility of the PR flaps. In summary, our results demonstrate that the G48E substitution, when introduced in the context of an HIV-1 subtype B strain, is highly unstable and gives rise to viruses with a poor replicative fitness in vitro. We also showed that when confronted with too many mutations to evaluate in vitro, MD simulations are helpful to draft hypotheses on how polymorphisms can interact with resistance mutations to stabilize their potential fitness cost.
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