Biophysical Characterization of the Nucleoside Diphosphate Kinase of Leishmania major and Effect of the P95S Mutation.

Nucleoside diphosphate kinases (NDK; EC 2.7.4.6) are enzymes required for maintaining intracellular levels of nucleosides triphosphates (NTP) through transfer the γ-phosphoryl group from a NTP to a NDP. The enzyme is associated with several biological functions including prevention of host ATP-mediated cytolysis during pathogenic infections. Here we present the biophysical characterization of NDK from Leishmania major and the effect of a mutation on the protein structure in solution. The structural stability was analyzed since this secreted protein may act in different microenvironments at various stages of the parasite life cycle. LmNDK and P95S mutant were subjected to denaturation with pH and guanidine. Structural transitions were monitored by circular dichroism and intrinsic fluorescence tryptophan emission. Our results showed that the LmNDK is more structurally stable than other described NDKs and that the catalytically active P95S mutant in the Kpn loop presented a decrease in protein stability, indicating the importance of this proline for maintenance of the LmNDK structure.

Determination of Specificity and Biochemical Characteristics of Neutral Protease Isolated from Myceliophthora thermophila.

Proteases hydrolyze polypeptides to release peptides and/or amino acids. This subclass of enzymes is among those with the most sales worldwide, particularly those produced by microorganisms. Proteases may be applied in the several industries, including the food industry, leather, detergents, and bioremediation. Myceliophthora thermophila protease was produced by a submerged bioprocess and then purified 185-fold by anion exchange and hydrophobic chromatography with a 37% yield. The molecular mass was estimated at 36.2 kDa, and mass spectrometry identified two sequences: GVVANMSLGGSYSASINNAAAALVR and STGNAAITGVPSGTTNR. The isolated protein was characterized biochemically, showed an optimum pH of 6.5 and optimum temperature of 45 °C, and stability at wide range of pH and temperatures and in the presence of reducing agents and some surfactants. Kinetic assays for this enzyme showed a greater catalytic efficiency when the substrate had alanine at position P'2. The protease presented characteristics that may be of interest to many industrial areas.

Molecular adaptability of nucleoside diphosphate kinase b from trypanosomatid parasites: stability, oligomerization and structural determinants of nucleotide binding.

Nucleoside diphosphate kinases play a crucial role in the purine-salvage pathway of trypanosomatid protozoa and have been found in the secretome of Leishmania sp., suggesting a function related to host-cell integrity for the benefit of the parasite. Due to their importance for housekeeping functions in the parasite and by prolonging the life of host cells in infection, they become an attractive target for drug discovery and design. In this work, we describe the first structural characterization of nucleoside diphosphate kinases b from trypanosomatid parasites (tNDKbs) providing insights into their oligomerization, stability and structural determinants for nucleotide binding. Crystallographic studies of LmNDKb when complexed with phosphate, AMP and ADP showed that the crucial hydrogen-bonding residues involved in the nucleotide interaction are fully conserved in tNDKbs. Depending on the nature of the ligand, the nucleotide-binding pocket undergoes conformational changes, which leads to different cavity volumes. SAXS experiments showed that tNDKbs, like other eukaryotic NDKs, form a hexamer in solution and their oligomeric state does not rely on the presence of nucleotides or mimetics. Fluorescence-based thermal-shift assays demonstrated slightly higher stability of tNDKbs compared to human NDKb (HsNDKb), which is in agreement with the fact that tNDKbs are secreted and subjected to variations of temperature in the host cells during infection and disease development. Moreover, tNDKbs were stabilized upon nucleotide binding, whereas HsNDKb was not influenced. Contrasts on the surface electrostatic potential around the nucleotide-binding pocket might be a determinant for nucleotide affinity and protein stability differentiation. All these together demonstrated the molecular adaptation of parasite NDKbs in order to exert their biological functions intra-parasite and when secreted by regulating ATP levels of host cells.