Milene C. Menezes

Hemorrhagic activity of HF3, a snake venom metalloproteinase: insights from the proteomic analysis of mouse skin and blood plasma.

Hemorrhage induced by snake venom metalloproteinases (SVMPs) is a complex phenomenon resulting in capillary disruption and blood extravasation. The mechanism of action of SVMPs has been investigated using various methodologies however the precise molecular events associated with microvessel disruption remains not fully understood. To gain insight into the hemorrhagic process, we analyzed the global effects of HF3, an extremely hemorrhagic SVMP from Bothrops jararaca, in the mouse skin and plasma. We report that in the HF3-treated skin there was evidence of degradation of extracellular matrix (collagens and proteoglycans), cytosolic, cytoskeleton, and plasma proteins. Furthermore, the data suggest that direct and indirect effects promoted by HF3 contributed to tissue injury as the activation of collagenases was detected in the HF3-treated skin. In the plasma analysis after depletion of the 20 most abundant proteins, fibronectin appeared as degraded by HF3. In contrast, some plasma proteinase inhibitors showed higher abundance compared to control skin and plasma. This is the first study to assess the complex in vivo effects of HF3 using high-throughput proteomic approaches, and the results underscore a scenario characterized by the interplay between the hydrolysis of intracellular, extracellular, and plasma proteins and the increase of plasma inhibitors in the hemorrhagic process.

Activation of leukocyte rolling by the cysteine‐rich domain and the hyper‐variable region of HF3, a snake venom hemorrhagic metalloproteinase

The functionality of the disintegrin‐like/cysteine‐rich domains of snake venom metalloproteinases (SVMPs) has been shown to reside in the cysteine‐rich region, which can interact with VWA‐containing proteins. Recently, the hyper‐variable region (HVR) of the cysteine‐rich domain was suggested to constitute a potential protein–protein adhesive interface. Here we show that recombinant proteins of HF3, a hemorrhagic P‐III SVMP, containing the cysteine‐rich domain (disintegrin‐like/cysteine‐rich and cysteine‐rich proteins) but not the disintegrin‐like protein were able to significantly increase leukocyte rolling in the microcirculation. Peptides from the HVR also promoted leukocyte rolling and this activity was inhibited by anti‐alphaM/beta2 antibodies. These results show, for the first time, that the cysteine‐rich domain and its HVR play a role in triggering pro‐inflammatory effects mediated by integrins.

Simplified procedures for the isolation of HF3, bothropasin, disintegrin-like/cysteine-rich protein and a novel P-I metalloproteinase from Bothrops jararaca venom.

HF3 and bothropasin are P-III hemorrhagic snake venom metalloproteinases (SVMPs) of Bothrops jararaca. The DC protein is composed of the disintegrin-like/cysteine-rich domains derived from the autolysis of P-III SVMPs. Here we describe simplified procedures for the isolation of HF3, bothropasin, the DC protein, and BJ-PI, a novel P-I SVMP. The isolated proteins were identified by mass spectrometry. BJ-PI is a potent caseinolytic enzyme devoid of hemorrhagic activity. HF3, bothropasin and BJ-PI show distinct fibrinogenolytic activities.

Proteomic identification of gender molecular markers in Bothrops jararaca venom.

UNLABELLED Variation in the snake venom proteome is a well-documented phenomenon; however, sex-based variation in the venom proteome/peptidome is poorly understood. Bothrops jararaca shows significant sexual size dimorphism and here we report a comparative proteomic/peptidomic analysis of venoms from male and female specimens and correlate it with the evaluation of important venom features. We demonstrate that adult male and female venoms have distinct profiles of proteolytic activity upon fibrinogen and gelatin. These differences were clearly reflected in their different profiles of SDS-PAGE, two-dimensional electrophoresis and glycosylated proteins. Identification of differential protein bands and spots between male or female venoms revealed gender-specific molecular markers. However, the proteome comparison by in-solution trypsin digestion and label-free quantification analysis showed that the overall profiles of male and female venoms are similar at the polypeptide chain level but show striking variation regarding their attached carbohydrate moieties. The analysis of the peptidomes of male and female venoms revealed different contents of peptides, while the bradykinin potentiating peptides (BPPs) showed rather similar profiles. Furthermore we confirmed the ubiquitous presence of four BPPs that lack the C-terminal Q-I-P-P sequence only in the female venom as gender molecular markers. As a result of these studies we demonstrate that the sexual size dimorphism is associated with differences in the venom proteome/peptidome in B. jararaca species. Moreover, gender-based variations contributed by different glycosylation levels in toxins impact venom complexity. BIOLOGICAL SIGNIFICANCE Bothrops jararaca is primarily a nocturnal and generalist snake species, however, it exhibits a notable ontogenetic shift in diet and in venom proteome upon neonate to adult transition. As is common in the Bothrops genus, B. jararaca shows significant sexual dimorphism in snout-vent length and weight, with females being larger than males. This sexual size dimorphism suggests the tendency for female specimens to feed on larger prey, and for male specimens to go on a diet similar to that of juveniles. Variation in the snake venom proteome is a ubiquitous phenomenon occurring at all taxonomic levels. At the intraspecific variation level, the individual contribution to the venom proteome is important but effects contributed by age and feeding habits may also affect the proteome phenotype. Whether sex-based factors play a role in venom variation of a species that shows sexual size dimorphism is poorly known. The use of proteomic strategies supported by transcriptomic data allows a more comprehensive assessment of venom proteomes uncovering components that are gender-specific.

Disintegrin-like/cysteine-rich domains of the reprolysin HF3: Site-directed mutagenesis reveals essential role of specific residues.

Little is known about the biochemical properties of the non-catalytic domains of snake venom metalloproteinases (SVMPs). The ECD sequence of the disintegrin-like domain (D-domain) has been assigned as the disintegrin motif and, recently, the hyper-variable region (HVR) of the cysteine-rich domain (C-domain) was suggested to constitute a potential protein-protein adhesive interface. Here we show that the recombinant C-domain of HF3, a hemorrhagic SVMP from Bothrops jararaca, as well as three peptides resembling its HVR, inhibit collagen-induced platelet aggregation, which indicates a role for the C-domain and its HVR in targeting HF3 to platelets. Site-directed mutagenesis was used for the first time to identify charged residues essential for the functionality of the disintegrin-like/cysteine-rich domains (DC-domains). Residues of the disintegrin loop (E467 and D469), and of the HVR (K568, K569 and K575) of HF3 were individually mutated to Ala. Interestingly, only the mutant D469A was obtained in soluble form in Escherichia coli and this single mutation caused loss of two functional activities of the DC-domains: inhibition of platelet aggregation and increase of leukocyte rolling in the microcirculation. In summary we demonstrate that the C-domain and its HVR are critical for HF3 to affect platelets and leukocytes, however, the disintegrin loop may be important for the functionality of the D-domain in the context of the C-domain.

Trends in the Evolution of Snake Toxins Underscored by an Integrative Omics Approach to Profile the Venom of the Colubrid Phalotris mertensi

Only few studies on snake venoms were dedicated to deeply characterize the toxin secretion of animals from the Colubridae family, despite the fact that they represent the majority of snake diversity. As a consequence, some evolutionary trends observed in venom proteins that underpinned the evolutionary histories of snake toxins were based on data from a minor parcel of the clade. Here, we investigated the proteins of the totally unknown venom from Phalotris mertensi (Dipsadinae subfamily), in order to obtain a detailed profile of its toxins and to appreciate evolutionary tendencies occurring in colubrid venoms. By means of integrated omics and functional approaches, including RNAseq, Sanger sequencing, high-resolution proteomics, recombinant protein production, and enzymatic tests, we verified an active toxic secretion containing up to 21 types of proteins. A high content of Kunitz-type proteins and C-type lectins were observed, although several enzymatic components such as metalloproteinases and an L-amino acid oxidase were also present in the venom. Interestingly, an arguable venom component of other species was demonstrated as a true venom protein and named svLIPA (snake venom acid lipase). This finding indicates the importance of checking the actual protein occurrence across species before rejecting genes suggested to code for toxins, which are relevant for the discussion about the early evolution of reptile venoms. Moreover, trends in the evolution of some toxin classes, such as simplification of metalloproteinases and rearrangements of Kunitz and Wap domains, parallel similar phenomena observed in other venomous snake families and provide a broader picture of toxin evolution.

Interaction of Bothrops jararaca venom metalloproteinases with protein inhibitors.

Snake venom metalloproteinases (SVMPs) play important roles in the local and systemic hemorrhage observed upon envenomation. In a previous study on the structural elements important for the activities of HF3 (highly hemorrhagic, P-III-SVMP), bothropasin (hemorrhagic, P-III-SVMP) and BJ-PI (non-hemorrhagic, P-I-SVMP), from Bothrops jararaca, it was demonstrated that they differ in their proteolysis profile of plasma and extracellular matrix proteins. In this study, we evaluated the ability of proteins DM43 and α2-macroglobulin to interfere with the proteolytic activity of these SVMPs on fibrinogen and collagen VI and with their ability to induce hemorrhage. DM43 inhibited the proteolytic activity of bothropasin and BJ-PI but not that of HF3, and was not cleaved the three proteinases. On the other hand, α2-macroglobulin did not inhibit any of the proteinases and was rather cleaved by them. In agreement with these findings, binding analysis showed interaction of bothropasin and BJ-PI but not HF3 to DM43 while none of the proteinases bound to α2-macroglobulin. Moreover, DM43 promoted partial inhibition of the hemorrhagic activity of bothropasin but not that of HF3. Our results demonstrate that metalloproteinases of B. jararaca venom showing different domain composition, glycosylation level and hemorrhagic potency show variable susceptibilities to protein inhibitors.

The proteinase-rich proteome of Bothrops jararaca venom

Abstract By catalyzing limited proteolysis or extensive degradation, proteolytic enzymes determine the fate of most proteins in an organism. In the evolutionary process of snake venoms, genes encoding proteinases were tailored to generate potent toxins to target key physiological proteins and thereby play a critical role in prey capture, immobilization and defense against predators. In Bothrops jararaca, metalloproteinases and serine proteinases are among the most abundant toxins both in newborn and adult venoms. In this review, we examine the proteinase-rich venom proteome of B. jararaca and how the proteinases act in a complex and heterogeneous fashion to exert their deleterious local and systemic effects.

Proteoforms of the platelet-aggregating enzyme PA-BJ, a serine proteinase from Bothrops jararaca venom

Snake venoms contain serine proteinases that are functionally similar to thrombin and specifically cleave fibrinogen to convert it into fibrin or activate platelets to aggregation. PA-BJ is a serine proteinase from Bothrops jararaca venom that promotes platelet aggregation and this effect is mediated by the G-coupled protein receptors PAR1 and PAR4. In this study we describe an improved procedure to obtain PA-BJ from B. jararaca venom that uses less chromatographic steps, and, interestingly, results in the isolation of eight proteoforms showing slightly different pIs and molecular masses due to variations in their glycosylation levels. The identity of the isolated PA-BJ forms (1-8) was confirmed by mass spectrometry, and they showed similar platelet-activating activity on washed platelet suspensions. N- and O-deglycosylation of PA-BJ 1-8 under denaturing conditions generated variable electrophoretic profiles and showed that some forms were resistant to complete deglycosylation. Furthermore, N- and O-deglycosylation under non-denaturing conditions also showed different electrophoretic profiles between the PA-BJ forms and caused partial loss of their ability to cleave a recombinant exodomain of PAR1 receptor. In parallel, three cDNAs encoding PA-BJ-like enzymes were identified by pyrosequencing of a B. jararaca venom gland library constructed with RNA from a single specimen. Taken together, our results suggest that PA-BJ occurs in the B. jararaca venom in multiple proteoforms displaying similar properties upon platelets regardless of their variable isoelectric points, molecular masses, carbohydrate moieties and susceptibility to the activity of glycosidases, and highlight that variability of specific venom components contributes to venom proteome complexity.

Replication Protein A-1 Has a Preference for the Telomeric G-rich Sequence in Trypanosoma cruzi

Replication protein A (RPA), the major eukaryotic single‐stranded binding protein, is a heterotrimeric complex formed by RPA‐1, RPA‐2, and RPA‐3. RPA is a fundamental player in replication, repair, recombination, and checkpoint signaling. In addition, increasing evidences have been adding functions to RPA in telomere maintenance, such as interaction with telomerase to facilitate its activity and also involvement in telomere capping in some conditions. Trypanosoma cruzi, the etiological agent of Chagas disease is a protozoa parasite that appears early in the evolution of eukaryotes. Recently, we have showed that T. cruziRPA presents canonical functions being involved with DNA replication and DNA damage response. Here, we found by FISH/IF assays that T. cruziRPA localizes at telomeres even outside replication (S) phase. In vitro analysis showed that one telomeric repeat is sufficient to bind RPA‐1. Telomeric DNA induces different secondary structural modifications on RPA‐1 in comparison with other types of DNA. In addition, RPA‐1 presents a higher affinity for telomeric sequence compared to randomic sequence, suggesting that RPA may play specific roles in T. cruzi telomeric region.