The active site, the substrate binding site, and the metal binding sites of the diisopropylfluorophosphatase (DFPase) from Loligo vulgaris have been modified by means of site-directed mutagenesis to improve our understanding of the reaction mechanism. Enzymatic characterization of mutants located in the major groove of the substrate binding pocket indicates that large hydrophobic side chains at these positions are favorable for substrate turnover. Moreover, the active site residue His287 proved to be beneficial, but not essential, for DFP hydrolysis. In most cases, hydrophobic side chains at position 287 led to significant catalytic activities although reduced relative to the wild-type enzyme. With respect to the Ca-1 binding site, where catalysis occurs, various mutants indicated that the net charge at this calcium-binding site as well as the relative positions of the charged calcium ligands is crucial for catalytic activity. The importance of the electrostatic potential at the active site was furthermore revealed by various mutations of residues lining the interior of the central water-filled tunnel, which traverses the entire protein structure. In this respect, the structural features of residue His181, which is located at the opposite end of the DFPase tunnel relative to the active site, were characterized extensively. It was concluded that a tunnel-spanning hydrogen bond network, which includes a large number of apparently slow exchanging water molecules, relays any modifications in the electrostatics of the system to the active site, thus affecting the catalytic reactivity of the enzyme.
Replacement of non-exchangeable protons by deuterons has become a standard tool in structural studies of proteins on the order of 30-40 kDa to overcome problems arising from rapid (1)H and (13)C transverse relaxation. However, (1)H nuclei are required at exchangeable sites to maintain the benefits of proton detection. Protein expression in D(2)O-based media containing deuterated carbon sources yields protein deuterated in all positions. Subsequent D/H-exchange is commonly used to reintroduce protons in labile positions. Since this strategy may fail for large proteins with strongly inhibited exchange we propose to express the protein in fully deuterated algal lysate medium in 100% H(2)O. As a side-effect partial C(alpha) protonation occurs in a residue-type dependent manner. Samples obtained by this protocol are suitable for complementary (1)H(N)- and (1)H(alpha)-based triple resonance experiments allowing complete backbone resonance assignments in cases where back-exchange of amide protons is very slow after expression in D(2)O and refolding of chemically denatured protein is not feasible. This approach is explored using a 35-kDa protein as a test case. The degree of C(alpha) protonation of individual amino acids is determined quantitatively and transverse relaxation properties of (1)H(N) and (15)N nuclei of the partially deuterated protein are investigated and compared to the fully protonated and perdeuterated species. Based on the deviations of assigned chemical shifts from random coil values its solution secondary structure can be established.
We demonstrate two novel approaches to enhance interactions of polymer-immobilized biomolecules with their substrates. In the first approach, diisopropylfluorophosphatase (DFPase) containing poly(urethane) (PU) coatings were made microporous by incorporating, then extracting, poly(ethylene glycol)-based diesters as porogens. Incorporation of 2% w/w porogen increased the effective diffusion coefficient of diisopropylfluorophosphate (DFP) through the coatings by 30% and increased the apparent turnover number of immobilized DFPase 3-fold. In the second approach, prior to immobilization, hydrophobic modification of DFPase was achieved through its conjugation with a dimer/trimer mixture of a uretdione based on 1,6-diisocyanatohexane. When the hydrophobically modified DFPase was immobilized in coatings, catalytic activity was 4-fold higher than that of the equivalent, immobilized, native DFPase. This activity enhancement was independent of the presence or absence of pores. Confocal microscopy images of coatings containing fluorescently labeled lysozyme show that the native enzyme is distributed uniformly over the entire thickness of the coatings. Hydrophobically modified and fluorescently labeled lysozyme is accumulated only in the upper 10 microm cross-sectional layer of a 100 microm-thick coating. Interactions of bioplastics with their substrates are tunable either by pore induction in a polymer or by directed migration of the hydrophobically modified biomolecule to the desired location. The latter approach has broad implications, including overcoming mass transfer limitations experienced by immobilized biocatalysts.
Methods are described to correlate aromatic 1H(delta)2/13C(delta)2 or 1H(epsilon)1/15N(epsilon)1 with aliphatic 13C(beta) chemical shifts of histidine and tryptophan residues, respectively. The pulse sequences exclusively rely on magnetization transfers via one-bond scalar couplings and employ [15N, 1H]- and/or [13C, 1H]-TROSY schemes to enhance sensitivity. In the case of histidine imidazole rings exhibiting slow HN-exchange with the solvent, connectivities of these proton resonances with beta-carbons can be established as well. In addition, their correlations to ring carbons can be detected in a simple [15N, 1H]-TROSY-H(N)Car experiment, revealing the tautomeric state of the neutral ring system. The novel methods are demonstrated with the 23-kDa protein xylanase and the 35-kDa protein diisopropyl-fluorophosphatase, providing nearly complete sequence-specific resonance assignments of their histidine delta-CH and tryptophan epsilon-NH groups.
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