Lucilene Delazari dos Santos

Profiling the Proteome of the Venom from the Social Wasp Polybia paulista: A Clue to Understand the Envenoming Mechanism

The study reported here is a classical bottom-up proteomic approach where proteins from wasp venom were extracted and separated by 2-DE; the individual protein spots were proteolytically digested and subsequently identified by using tandem mass spectrometry and database query with the protein search engine MASCOT. Eighty-four venom proteins belonging to 12 different molecular functions were identified. These proteins were classified into three groups; the first is constituted of typical venom proteins: antigens-5, hyaluronidases, phospholipases, heat shock proteins, metalloproteinases, metalloproteinase-desintegrin like proteins, serine proteinases, proteinase inhibitors, vascular endothelial growth factor-related protein, arginine kinases, Sol i-II and -II like proteins, alpha-glucosidase, and superoxide dismutases. The second contained proteins structurally related to the muscles that involves the venom reservoir. The third group, associated with the housekeeping of cells from venom glands, was composed of enzymes, membrane proteins of different types, and transcriptional factors. The composition of P. paulista venom permits us to hypothesize about a general envenoming mechanism based on five actions: (i) diffusion of venom through the tissues and to the blood, (ii) tissue, (iii) hemolysis, (iv) inflammation, and (v) allergy-played by antigen-5, PLA1, hyaluronidase, HSP 60, HSP 90, and arginine kinases.

Proteomic analysis of kidney in rats chronically exposed to fluoride.

Two-dimensional gel electrophoresis (2-DE) was used to better understand alterations in renal metabolism induced by fluoride (F). Three groups of weanling male Wistar rats were treated with drinking water containing 0 (control), 5, or 50 ppm F for 60 days (n=6/group). Kidneys were collected for proteomic and histological (HE) analysis. After protein isolation, renal proteome profiles were examined using 2-DE and Colloidal Coomassie Blue staining. Protein spots with a 2-fold significant difference as detected by quantitative intensity analysis (Image Master Platinum software) and t-test (p<0.05) were excised and analyzed by MALDI-TOF MS (matrix assisted laser desorption ionization-time-of-flight mass spectrometry). The histological analysis revealed no damage in kidneys induced by F, except for a vascular congestion in the 50 ppm F group. Between control vs 50 ppm F, and control vs 5 ppm F groups, 12 and 6 differentially expressed proteins were detected, respectively. Six proteins, mainly related with metabolism, detoxification and housekeeping, were successfully identified. At the high F group, pyruvate carboxylase, a protein involved in the formation of oxaloacetate was found to be downregulated, while enoyl coenzyme A hydratase, involved in fatty acids oxidation, was found to be upregulated. Thus, proteomic analysis can provide new insights into the alterations in renal metabolism after F exposure, even in low doses.

A new scenario of bioprospecting of Hymenoptera venoms through proteomic approach

Venoms represent a huge and essentially unexplored reservoir of bioactive components that may cure diseases that do not respond to currently available therapies. This review select advances reported in the literature from 2000 to the present about the new scenario of Hymenoptera venom composition. On account of new technologies in the proteomic approach, which presents high resolution and sensitivity, the combination of developments in new instruments, fragmentation methods, strategic analysis, and mass spectrometry have become indispensable tools for interrogation of protein expression, molecule interaction, and post- translational modifications. Thus, the biochemical characterization of Hymenoptera venom has become a major subject of research in the area of allergy and immunology, in which proteomics has been an excellent alternative to assist the development of more specific extracts for diagnosis and treatment of hypersensitive patients to Hymenoptera venoms.

Brown Recluse Spider Venom: Proteomic Analysis and Proposal of a Putative Mechanism of Action

Loxosceles intermedia spider venom was subjected to proteomic analysis through a MudPIT shot-gun approach to identify the protein composition. Were identified 39 proteins which seem to responsible by the lesion of different types of tissues, to some physiopathological actions and by the prevention of structural damage to the toxin structures.

Using Proteomic Strategies for Sequencing and Post-Translational Modifications Assignment of Antigen-5, a Major Allergen from the Venom of the Social Wasp Polybia paulista

Antigen-5 is one of the major allergens identified in wasp venoms, and despite the fact that its biological function is still unknown, many studies have demonstrated its allergenicity. In this study, the biochemical and structural characterization of antigen-5 from the venom of the social wasp Polybia paulista are reported. A gel-based mass spectrometry strategy with CID fragmentation methods and classical protocols of protein chemistry, which included N- and C-terminal sequencing, were used to assign the complete sequence and determine the presence/location of the post-translational modifications (PTMs) of this protein. Six different isoforms of antigen-5 were identified in the crude venom of P. paulista ; the most abundant, which corresponds to the intact form of this protein, was recognized by the pool of human specific-IgE. This protein was extensively sequenced through CID mass spectrometry, and a series of PTMs were observed such as hydroxylation, phosphorylation, and glycosylation. Sequence data revealed that this protein has 59.3-93.7% identity with antigen-5 proteins from other known vespid venoms. The molecular model of P. paulista antigen-5 shows that this protein has three α-helices, one 310 helix, and four β-sheets covering 28 and 17.9% of the sequence, respectively. The identification and characterization of allergenic compounds is essential for the development of advanced component-resolved allergy diagnostics and treatment.

Heterologous fibrin sealant derived from snake venom: from bench to bedside – an overview

Hemostatic and adhesive agents date back to World War II, when homologous fibrin sealant came onto scene. Considering that infectious diseases can be transmitted via human blood, a new heterologous fibrin sealant was standardized in the 1990s. Its components were a serine protease (a thrombin-like enzyme) extracted from the venom of Crotalus durissus terrificus snakes and a fibrinogen-rich cryoprecipitate extracted from the blood of Bubalus bubalis buffaloes. This new bioproduct has been used as a coagulant, sealant, adhesive and recently as a candidate scaffold for mesenchymal stem cells and bone and cartilage repair. This review discusses the composition of a new heterologous fibrin sealant, and cites published articles related to its preclinical applications aiming at repairing nervous system traumas and regenerating bone marrow. Finally, we present an innovative safety trial I/II that found the product to be a safe and clinically promising candidate for treating chronic venous ulcers. A multicenter clinical trial, phase II/III, with a larger number of participants will be performed to prove the efficacy of an innovative biopharmaceutical product derived from animal venom.

Individual venom profiling of Crotalus durissus terrificus specimens from a geographically limited region: Crotamine assessment and captivity evaluation on the biological activities

Crotalus durissus terrificus (Cdt) venom major components comprise crotoxin, crotamine, gyroxin and convulxin. Crotamine exerts a myotoxic action, among others, but its expression varies even amid snakes from the same region. Biochemical, enzymatic and pharmacological variations of venoms may be associated with the geography, climate, gender, age, and diet, as well as captivity time and venom extraction intervals. The present study aimed to characterize the Cdt venom from the Botucatu region, (SP, Brazil), by assessing its biochemical, pharmacological and enzymatic properties. Venoms from newly captured snakes and already-captured animals were characterized comparatively to verify the sexual, environmental (length of captivity) and ontogenetic variations that could influence the venom composition. Protein concentration, SDS-PAGE and RP-HPLC were performed and the coagulant, toxic (LD50) and crotamine activities were assayed. Individual SDS-PAGE analyses (315 samples) were performed and the biological activities of the venom of 60 adults (captive and newly captured males and females) and 18 newborns were compared with the Brazilian Reference Venom. Crotamine was found in 39.7% (125/315) of the samples, as determined by SDS-PAGE and RP-HPLC. Protein concentration differed significantly between adults (75%) and newborns (60%). RP-HPLC and SDS-PAGE analyses showed highly variable protein concentration and copious crotoxin isoforms; however, the LD50 values decreased during the captivity time. Cdt venom biological activities were similar among adult groups, but diminished during the captivity period. The current findings demonstrate that venoms vary significantly in terms activity and protein concentration, despite originating from the same specie and region.

Proteomic analysis of urine in rats chronically exposed to fluoride

Urine is an ideal source of materials to search for potential disease‐related biomarkers as it is produced by the affected tissues and can be easily obtained by noninvasive methods. 2‐DE‐based proteomic approach was used to better understand the molecular mechanisms of injury induced by fluoride (F−) and define potential biomarkers of dental fluorosis. Three groups of weanling male Wistar rats were treated with drinking water containing 0 (control), 5, or 50 ppm F− for 60 days (n = 15/group). During the experimental period, the animals were kept individually in metabolic cages, to analyze the water and food consumption, as well as fecal and urinary F− excretion. Urinary proteome profiles were examined using 2‐DE and Colloidal Coomassie Brilliant Blue staining. A dose‐response regarding F− intake and excretion was detected. Quantitative intensity analysis revealed 8, 11, and 8 significantly altered proteins between control vs. 5 ppm F−, control vs. 50 ppm F− and 5 ppm F− vs. 50 ppm F− groups, respectively. Two proteins regulated by androgens (androgen‐regulated 20‐KDa protein and α‐2μ‐globulin) and one related to detoxification (aflatoxin‐B1‐aldehyde‐reductase) were identified by MALDI‐TOF‐TOF MS/MS. Thus, proteomic analysis can help to better understand the mechanisms underlying F− toxicity, even in low doses.

Crotalus durissus terrificus crotapotin naturally displays preferred positions for amino acid substitutions

BackgroundClassically, Crotalus durissus terrificus (Cdt) venom can be described, according to chromatographic criteria, as a simple venom, composed of four major toxins, namely: gyroxin, crotamine, crotoxin and convulxin. Crotoxin is a non-covalent heterodimeric neurotoxin constituted of two subunits: an active phospholipase A2 and a chaperone protein, termed crotapotin. This molecule is composed of three peptide chains connected by seven disulfide bridges. Naturally occurring variants/isoforms of either crotoxin or crotapotin itself have already been reported.MethodsThe crude Cdt venom was separated by using RP-HPLC and the toxins were identified by mass spectrometry (MS). Crotapotin was purified, reduced and alkylated in order to separate the peptide chains that were further analyzed by mass spectrometry and de novo peptide sequencing.ResultsThe RP-HPLC profile of the isolated crotapotin chains already indicated that the α chain would present isoforms, which was corroborated by the MS and tandem mass spectrometry analyses.ConclusionIt was possible to observe that the Cdt crotapotin displays a preferred amino acid substitution pattern present in the α chain, at positions 31 and 40. Moreover, substitutions could also be observed in β and γ chains (one for each). The combinations of these four different peptides, with the already described chains, would produce ten different crotapotins, which is compatible to our previous observations for the Cdt venom.

Crotoxin: a novel allergen to occupational anaphylaxis

Anaphylaxis is an immediate, serious, and potentially fatal systemic other type of allergy. In her family history, the patient indicated hypersensitivity reaction.1 The signs and symptoms result from the release of chemical mediators from mast cells and basophils, the mechanism of which may or may not be mediated by the immune system. The initial manifestation of anaphylaxis includes symptoms such as urticaria, angioedema, acute rhinoconjunctivitis, bronchospasm, hypotension, sneezing, itching and hyperemia of the nose, and conjunctival mucosa. Severe cases may evolve into shock, respiratory failure, and even death.2 Anaphylaxis can be triggered by multiple causes, including animal toxins.3,4 Various purified extracts are commercially available for diagnosis and immunotherapy.5,6 Allergic reactions caused by snake venoms are rare and poorly studied, but there are not only clinical case reports of patients with occupational allergies to snakes but also studies that provide evidence of immunoreactive allergens that originate from these venoms.7-9 Proteome analysis of Crotalus durissus terrificus rattlesnake venom identified 7 protein families in which phospholipase A2 (PLA2) and serine proteases were the predominant components of this venom.10 The aim of this studywas to isolate and identify a new allergen from this snake venom capable of inducing occupational allergies in susceptible individuals. The patient was a 23-year-old, white, female graduate student in the Tropical Diseases Program of Botucatu Medical School, Universidade Estadual Paulista (UNESP), São Paulo, Brazil. She has worked with snake venom for 4 years at Center for the Studies of Venom and Animal Venomous (CEVAP) research laboratory. Despite the equipment for individual safety (personal protective equipment) routinely used, her exposure occurred during procedures in the Laboratory of Venom Animals. Diverse activities that require handling of snake venoms, such as milking, dilution, filtration, centrifugation, freeze drying, andweighing to aliquot and storing it, are performed in this laboratory. She began presenting with allergic reactions characterized by sneezing, itchy skin, and nasoconjunctival hyperemia soon after manipulating lyophilized rattlesnake venom used in research at CEVAP/UNESP. These reactions intensified, and before finally stopping her activities, the patient presented with the above symptoms, in addition to eyelid edema, wheezing, dyspnea, cough, hoarseness, and dysphagia, displaying a clinical picture of anaphylaxis. These symptoms resolved spontaneously 10 to 15 minutes after the patient would leave the laboratory. The patient also reported having a childhood history of asthma and rhinitis, although these symptoms were being controlled without the use of drugs. She was not aware of any