Project description:Both single cell and bulk RNA sequencing was performed on expanding or differentiating snake venom gland organoids (from Aspidelaps Lubricus Cowlesi and Naja Nivea), or tissue (Aspidelaps Lubricus Cowlesi). Bulk RNA sequencing from the snake venom gland, liver and pancreas was performed to construct a de novo transcriptome using Trinity.

Project description:proteomic analysis of venom gland peptides from the scorpion Centruroides vittatus

Project description:Combined Proteomic and Transcriptomic Interrogation of the Venom Gland of Conus geographus Uncovers Novel Components and Functional Compartmentalization

Project description:While cellular transcripts encode rich information that provide key features to understand the molecular basis of snake venom variation, their presence/ abundance does not necessary imply/correlate in the translation of a functional (protein) product. In this study we carried out an analysis of the venom gland proteome of Bothrops jararaca taking into account two distinct phases of its ontogenetic development (i.e. newborn and adult specimens) and the marked sexual dimorphism recently reported on its venom proteome. Proteomic data analysis showed wider dynamic range for toxins when comparing to non-toxins and a dynamic proteome rearrangement in cellular proteins upon B. jararaca development. Differentially expressed proteins covered a number of biological pathways related to protein synthesis, including proteins related to transcription and translation, which were found to be significantly higher expressed in the newborn venom gland. Our results showed that the variation in the expression levels of cellular proteins gives rise to an even higher variation in the dynamic range of the expressed toxins. Upon ageing, the molecular constraints related to protein synthesis together with ecological traits would likely have an impact on the toxin repertoire, which, in the case of B. jararaca species, would enable the species to deal with different prey types during its lifespan.

Project description:Snake venom-gland transcriptomics

Project description:Venoms are important evolutionary keys and innovation for several animal taxons., including snakes. Their use is specially related to feed, predation and defense. Snake venoms are composed mainly by free secreted proteins, about 98%, and stored in the lumen of the venom gland, where they are processed through poorly understood mechanisms. In the perspective of protein-diversity, venoms undergo evolutionary pressure which generate a rapid evolutionary response, causing a great diversity in their toxin-components. We know now that extracellular vesicles exist in snake venom, although their biological role are still unknown. We believe that understanding EV-mediated effects could change our way of seeing envenoming, especially long-term sequelae. From what we know about EVs and snake venoms, there is a lot of potential of cross-organism communication occurrence between snakes and human victims. To advance in the comprehension of venom EVs function, we used fresh B. jararaca venom as our model. Fresh venom was fractionated by sequential centrifugation, resulting in two populations of vesicles (Bj-EVs). Purified Bj-EVs were analyzed by electron microscopy, NTA and proteomics. The interaction of Bj-EVs with mammalian cells was accessed by fluorescence and electron microscopy.

Project description:Protein expression is a major link in the genotype-phenotype relationship, and processes affecting protein abundances, such as rates of transcription and translation, could contribute to phenotypic evolution if they generate heritable variation. Recent work has suggested that mRNA abundances do not accurately predict final protein abundances, which would imply that post-transcriptional regulatory processes contribute significantly to phenotypes. Post-transcriptional processes also appear to buffer changes in transcriptional patterns as species diverge, suggesting that the transcriptional changes have little or no effect on the phenotypes under study. We tested for concordance between mRNA and protein expression levels in snake venoms by means of mRNA-seq and quantitative mass spectrometry for 11 snakes representing 10 species, six genera, and three families. In contrast to most previous work, we found high correlations between venom-gland transcriptomes and venom proteomes for ten of our 11 comparisons. We tested for protein-level buffering of transcriptional changes during species divergence by comparing the difference between transcript abundance and protein abundance for three pairs of species and one intraspecific pair. We found no evidence for buffering during divergence of our three species pairs but did find evidence for protein-level buffering for our single intraspecific comparison, suggesting that buffering, if present, was a transient phenomenon in venom divergence. Our results demonstrated that post-transcriptional mechanisms did not contribute significantly to phenotypic evolution in venoms and suggest a more prominent and direct role for cis-regulatory evolution in phenotypic variation, particularly for snake venoms.

Project description:Acanthoscurria juruenicola is an Amazonian tarantula spider described for the first time a century ago. Specimens of both genders are similar in size and in most morphological aspects, but ecological behavior and their venom composition remained unknown to date. Here we present the peptidomics characterization of the spider venom by a combination of mass spectrometric analysis of both native and digested peptides, venom gland transcriptomics and bioinformatics. A total of 367 native features were observed in the venom peptidome. Seventeen cysteine-rich peptides were simultaneously observed in the transcriptome and in the mass spectrometric experiments, from which fourteen were completely sequenced in the mature forms. The mature peptides have 3-5 disulfide bonds and cover the 3.7-8.6 kDa mass range. Moreover, in vivo paralytic activities of the whole venom were observed in crickets. In silico analysis indicated that all mature peptides are potentially antimicrobial and two may be potential anticancer agents. The antimicrobial activity was experimentally confirmed for the peptide Ap1a against Micrococcus luteus, Pseudomonas aeruginosa and Candida albicans.

Project description:Spider venoms are a unique source of bioactive peptides displaying remarkable structural stability and potent neuroactivity. Phoneutria nigriventer, often referred to as Brazilian wandering spider, banana spider or “armed” spider, is endemic from South America and amongst the most dangerous venomous spiders in the world. Envenomation accidents with P. nigriventer often occur in Brazil with approximately 4,000 cases per year and which symptoms include priapism, hypertension, blurred vision, sweating, and vomiting, amongst others. Besides its clinical relevance, P. nigriventer venom comprises promising peptide drug leads providing therapeutic effects in a range of disease models. In this study, we further explored the neuroactivity and molecular diversity of the venom from P. nigriventer using fractionation-guided high-throughput cellular assays coupled to proteomics analysis and multi-pharmacology activity to broaden the knowledge and therapeutic potential of this venom, as well as a proof-of-concept for an investigative pipeline to study spider-venom derived neuroactive peptides. We applied ion channel assays in a neuroblastoma cell line to investigate modulation of voltage-gated sodium and calcium channels, and nicotinic acetylcholine α7 receptor. We then investigated the venom components using mass spectrometry to identify peptide masses and sequences associated to the observed neuromodulations. Our findings showed this venom is highly complex compared to other neurotoxin-rich venoms and comprises potent modulators of voltage-gated sodium and calcium channels which were classified into 4 families of neuroactive peptides based on their activities and structures. In addition to the reported P. nigriventer neuroactive peptides, we identified at least 27 novel cysteine-rich venom peptides in which neuroactivities are still to be elucidated in voltage-gated ion channels and other potential targets. Our findings provide a new basis for studying non-explored bioactivities of known and novel neuroactive components in P. nigriventer venom, and further supports the successful application of our discovery pipeline for identifying ion channel-targeting venom peptides with potential to become drug leads with diverse exploratory and therapeutic applications.

Project description:Predatory bugs capture prey by injecting venom from their salivary glands using specialized stylets. Understanding venom function has been impeded by a scarcity of knowledge of their venom composition. We therefore examined the proteinaceous components of the salivary venom of the predatory stink bug Arma chinensis (Hemiptera: Pentatomidae). Using gland extracts and venoms from 5th-instar nymphs or adult females, we performed shotgun proteomics combined with venom gland transcriptomics. We found that the venom of A. chinensis comprised a complex suite of over a hundred individual proteins, including oxidoreductases, transferases, hydrolases, ligases, protease inhibitors, and recognition, transport and binding proteins. Besides the uncharacterized proteins, hydrolases such as venom serine proteases, cathepsins, phospholipase A2, phosphatases, nucleases, alpha-amylases, and chitinases constitute the most abundant protein families. However, salivary proteins shared by and unique to other predatory heteropterans were not detected in A. chinensis venom. Injection of the proteinaceous (> 3 kDa) venom fraction of A. chinensis gland extracts or venom into its prey, the larvae of the Oriental armyworm Mythimna separata (Walker, 1865), revealed insecticidal activity against lepidopterans. Our data expands the knowledge of heteropteran salivary proteins and suggests predatory asopine bugs as a novel source for bioinsecticides.