Bothropstoxin-I (BthTx-I) is a Lys(49)-phospholipase A(2) from the venom of Bothrops jararacussu which demonstrates both myotoxic and Ca(2+)-independent membrane-damaging activities. The structural determinants of these activities are poorly defined, therefore site-directed mutagenesis has been used to substitute all cationic and aromatic residues between positions 115 and 129 in the C-terminal loop region of the protein. Substitution of lysine and arginine residues with alanine in the region 117-122 resulted in a significant reduction of myotoxic activity of the recombinant BthTx-I. With the exception of Lys(122), these same substitutions did not significantly alter the Ca(2+)-independent membrane-damaging activity. In contrast, substitution of the positively-charged residues at positions 115, 116 and 122 resulted in reduced Ca(2+)-independent membrane-damaging activity but, with the exception of Lys(122), had no effect on myotoxicity. These results indicate that the two activities are independent and are determined by discrete yet partially overlapping motifs in the C-terminal loop. Results from site-directed mutagenesis of the aromatic residues in the same part of the protein suggest that a region including residues 115-119 interacts superficially with the membrane interface and that the residues around position 125 partially insert into the lipid membrane. These results represent the first detailed mapping of a myotoxic site in a phospholipase A(2), and support a model of a Ca(2+)-independent membrane-damaging mechanism in which the C-terminal region of BthTx-I interacts with and contributes to the perturbation of the phospholipid bilayer.
BackgroundLeishmaniasis is a complex disease in which clinical outcome depends on factors such as parasite species, host genetics and immunity and vector species. In Brazil, Leishmania (Viannia) braziliensis is a major etiological agent of cutaneous (CL) and mucosal leishmaniasis (MCL), a disfiguring form of the disease, which occurs in ~10% of L. braziliensis-infected patients. Thus, clinical isolates from patients with CL and MCL may be a relevant source of information to uncover parasite factors contributing to pathogenesis. In this study, we investigated two pairs of L. (V.) braziliensis isolates from mucosal (LbrM) and cutaneous (LbrC) sites of the same patient to identify factors distinguishing parasites that migrate from those that remain at the primary site of infection.Methodology/Principal FindingsWe observed no major genomic divergences among the clinical isolates by molecular karyotype and genomic sequencing. RT-PCR revealed that the isolates lacked Leishmania RNA virus (LRV). However, the isolates exhibited distinct in vivo pathogenesis in BALB/c mice; the LbrC isolates were more virulent than the LbrM isolates. Metabolomic analysis revealed significantly increased levels of 14 metabolites in LbrC parasites and 31 metabolites in LbrM parasites that were mainly related to inflammation and chemotaxis. A proteome comparative analysis revealed the overexpression of LbrPGF2S (prostaglandin f2-alpha synthase) and HSP70 in both LbrC isolates. Overexpression of LbrPGF2S in LbrC and LbrM promastigotes led to an increase in infected macrophages and the number of amastigotes per cell at 24–48 h post-infection (p.i.).Conclusions/SignificanceDespite sharing high similarity at the genome structure and ploidy levels, the parasites exhibited divergent expressed genomes. The proteome and metabolome results indicated differential profiles between the cutaneous and mucosal isolates, primarily related to inflammation and chemotaxis. BALB/c infection revealed that the cutaneous isolates were more virulent than the mucosal parasites. Furthermore, our data suggest that the LbrPGF2S protein is a candidate to contribute to parasite virulence profiles in the mammalian host.
Bothropstoxin-I (BthTx-I) is a myotoxic phospholipase A(2) variant present in the venom of Bothrops jararacussu, in which the Asp(49) residue is replaced with a lysine, which damages artificial membranes by a Ca(2+)-independent mechanism. Wild-type BthTx-I and the mutants Lys(49)-->Asp, His(48)-->Gln and Lys(122)-->Ala were expressed in Escherichia coli BL21(DE3) cells, and the hydrolytic, myotoxic and membrane-damaging activities of the recombinant proteins were compared with native BthTx-I purified from whole venom. The Ca(2+)-independent membrane-damaging and myotoxic activities of the native and wild-type recombinant BthTx-I, His(48)Gln and Lys(49)Asp mutants were similar; however, the Lys(122)Ala mutant demonstrated reduced levels of both activities. Although a low hydrolytic activity against a mixed phospholipid substrate was observed with native BthTx-I, no substrate hydrolysis was detected with the wild-type recombinant enzyme or any of the mutants. In the case of the Lys(49)Asp mutant, this demonstrates that the absence of catalytic activity in Lys(49)-PLA(2) is not a consequence of the single Asp(49)-->Lys replacement. Furthermore, these results provide unambiguous evidence that the Ca(2+)-independent membrane-damaging and myotoxic activities are maintained in the absence of hydrolysis. The evidence favours a model for a hydrolysis-independent, membrane-damaging mechanism involving an interaction of the C-terminal region of BthTx-I with the target membrane.
Bothropstoxin-I (BthTx-I) is a myotoxic phospholipase A2 variant present in the venom of Bothrops jararacussu, in which the Asp49 residue is replaced with a lysine, which damages artificial membranes by a Ca2+-independent mechanism. Wild-type BthTx-I and the mutants Lys49 → Asp, His48 → Gln and Lys122 → Ala were expressed in Escherichia coli BL21(DE3) cells, and the hydrolytic, myotoxic and membrane-damaging activities of the recombinant proteins were compared with native BthTx-I purified from whole venom. The Ca2+-independent membrane-damaging and myotoxic activities of the native and wild-type recombinant BthTx-I, His48Gln and Lys49Asp mutants were similar; however, the Lys122Ala mutant demonstrated reduced levels of both activities. Although a low hydrolytic activity against a mixed phospholipid substrate was observed with native BthTx-I, no substrate hydrolysis was detected with the wild-type recombinant enzyme or any of the mutants. In the case of the Lys49Asp mutant, this demonstrates that the absence of catalytic activity in Lys49-PLA2 is not a consequence of the single Asp49 → Lys replacement. Furthermore, these results provide unambiguous evidence that the Ca2+-independent membrane-damaging and myotoxic activities are maintained in the absence of hydrolysis. The evidence favours a model for a hydrolysis-independent, membrane-damaging mechanism involving an interaction of the C-terminal region of BthTx-I with the target membrane.
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.
In this study, we detail the specificity of an aspartic peptidase from Rhizomucor miehei and evaluate the effects of this peptidase on clotting milk using the peptide sequence of k-casein (Abz-LSFMAIQ-EDDnp) and milk powder. Molecular mass of the peptidase was estimated at 37 kDa, and optimum activity was achieved at pH 5.5 and 55 °C. The peptidase was stable at pH values ranging from 3 to 5 and temperatures of up 45 °C for 60 min. Dramatic reductions in proteolytic activity were observed with exposure to sodium dodecyl sulfate, and aluminum and copper (II) chloride. Peptidase was inhibited by pepstatin A, and mass spectrometry analysis identified four peptide fragments (TWSISYGDGSSASGILAK, ASNGGGGEYIFGGYDSTK, GSLTTVPIDNSR, and GWWGITVDRA), similar to rhizopuspepsin. The analysis of catalytic specificity showed that the coagulant activity of the peptidase was higher than the proteolytic activity and that there was a preference for aromatic, basic, and nonpolar amino acids, particularly methionine, with specific cleavage of the peptide bond between phenylalanine and methionine. Thus, this peptidase may function as an important alternative enzyme in milk clotting during the preparation of cheese.
The hydrolysis of phospholipids by class II phospholipase A2 (PLA2) involves a Ca2+ ion cofactor bound to the Asp49 residue in the active site region. In the lysine 49 phospholipase A2 homologues (Lys49-PLA2), the Asp49 residue is substituted by Lys, and consequently the Lys49-PLA2s show no Ca2+ binding and no detectable phospholipid hydrolysis. Nevertheless, the Lys49-PLA2s demonstrate membrane damaging activity by an incompletely understood Ca2+-independent mechanism of action. Using a combination of steady-state and time-resolved fluorescence techniques, we have examined the effect of pH on the monomer-dimer equilibrium of bothropstoxin I (BthTX-I), a Lys49-PLA2 from the venom of Bothrops jararacussu which contains a single Trp77 residue located at the dimer interface. At pH 5.0, we observe a decreased quantum yield, a decreased rotational correlation time, and an increased bimolecular quenching rate constant with iodide. These results are consistent with a pH-induced dissociation of the BthTX-I dimer, with the consequent exposure of the Trp77 residue to aqueous solvent. In the presence of liposomes, membrane damaging activity is observed only under conditions in which the dimeric form of the BthTX-I is favored. These results demonstrate that the dimeric form of the protein is essential for the initiation of the Ca2+-independent membrane damaging activity.
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