Análise proteônica de venenos de Apis mellifera baseada em espectrometria de massas: abordagem quantitativa label-free e identificação de fosforilação / Mass Spectrometry-based proteomic analysis of honeybee venoms: label-free quantification and phosphorylation identification

Resende, Virginia Maria Ferreira

28 March 2013

Há muito tempo os venenos de abelhas se tornaram objeto de interesse de muitos cientistas, principalmente os venenos daquelas linhagens do gênero Apis, chamadas abelhas europeias e as conhecidas abelhas africanizadas. O foco no desenvolvimento de terapias eficazes que pudessem prevenir ou frear as reações desencadeadas pelas toxinas dos venenos desses insetos foi o principal estimulador do surgimento dessa grande área da pesquisa, uma vez que esses animais causam um grande número de acidentes em animais e seres humanos e os acidentes podem desencadear graves consequências, inclusive óbito. Sendo assim, desenvolvemos o presente trabalho baseado na caracterização da composição proteica dos venenos de abelhas europeias e africanizadas, na análise quantitativa diferencial entre os venenos e, na investigação de fosforilações e a possível relação das mesmas com as funções biológicas. Reunindo todos os elementos que estavam ao nosso alcance para compor o melhor conjunto de etapas para a realização do estudo proteômico de venenos de abelhas, nós atingimos todos os objetivos propostos. Utilizando uma abordagem baseada em espectrometria de massas, consistindo de análise shotgun seguida de LC-MS/MS realizada em um dos mais modernos espectrômetros de massas, nós fomos capazes de obter resultados extremamente confiáveis e interessantes. Comparando-se o efeito da extensão do gradiente de separação na cromatografia líquida, nós fomos capazes de atingir uma maior cobertura da amostra, uma vez que identificamos um maior número de proteínas após a utilização do gradiente mais longo. A identificação de fosforilações foi favorecida pela combinação de fragmentação por \"Colisão Induzida por Dissociação\" e medidas de massa de alta acurácia realizadas no instrumento LTQ-Orbitrap-Velos. Enquanto apenas 29 proteínas foram identificadas após 120 minutos de separação cromatográfica, um total de 51 proteínas foram identificadas aplicando-se gradiente mais longo. Dentre as 51 proteínas totais, 42 são comuns aos venenos das três abelhas. A comparação em pares mostrou que os venenos das abelhas europeias compartilham 44 proteínas e os venenos das abelhas africanizadas compartilham 43 proteínas tanto com o veneno de A. m. carnica quanto com o de A. m. ligustica. Além disso, nós revelamos que existem diferenças quantitativas entre algumas das proteínas dos venenos, sendo muitas dessas proteínas diferenciais toxinas com funções conhecidamente relevantes. A investigação de fosforilação mostrou que duas toxinas apresentam-se na forma fosforilada: melitina e icarapina. Melitina é considerada a principal toxina de venenos de abelhas, sendo bem conhecida por sua ação altamente tóxica e alergenicidade. Este peptídeo foi identificado com fosforilação ocorrendo no sítio Ser18 em todas as amostras de venenos, enquanto somente no veneno da abelha africanizada foi também identificado com sítio de fosforilação no resíduo de Thr10. Icarapina, também já descrita como um alérgeno do veneno, apresentou sítio de fosforilação no resíduo Ser205. Por fim, nós demonstramos o efeito da fosforilação presente em melitina (Ser18) realizando ensaios de atividade biológica do peptídeo fosforilado e nativo, como: hemólise, lise celular e desgranulação de mastócitos e atividade quimiotáctica. Foi observado que a toxicidade do peptídeo fosforilado é reduzida em comparação ao do peptídeo nativo. Sendo assim, nós podemos concluir que a combinação de metodologias eficientes e a utilização de moderna instrumentação nos levou a resultados surpreendentes, os quais se somam a todo o conhecimento já existente acerca de venenos de abelhas / Honeybee venom toxins disturb the activity of critical cellular processes, triggering immunological, physiological, and neurological responses within victims. Studies on venom toxins have provided invaluable knowledge towards elucidating the molecular and functional details of their biological targets, yet there has been no report of a full proteome/phosphoproteome profile of honeybee venom. In this study, we focused on Apis mellifera honeybee venom characterization, including proteins identification, label-free quantitative analysis and phosphorylation identification. Making use of a MS-based proteomic approach, consisting on in-solution digestion followed by LC-MS/MS analysis, we were able to compare the effect of the liquid chromatography gradient length on the sample coverage, consequently, to identify a higher number of proteins using longer separation gradient of the tryptic peptides. Favorable identification of phosphorylations was achieved by the application of a long separation gradient combined with CID fragmentation and high accuracy mass measurement using an LTQ Orbitrap Velos. Here we report on the comparative shotgun proteomics study of the venoms of two Apis mellifera subspecies, A. m. carnica and A. m. ligustica, and the hybrid known as Africanized honey bee (AHB). We identified 51 proteins in total, with 42 of them being common among the three venoms, including many previously unidentified entries. Performing label-free quantification, we observed that few proteins were found with different relative amounts. Additionally, we revealed the phosphorylation of two proteins in all the samples, with two of them being HBV toxins/allergens: melittin and icarapin. Icarapin was identified as phosphorylated at 205Ser. Melittin was identified as phosphorylated at the 18Ser and 10Thr positions in all venoms, as well. Given these novel findings, we then chose to compare the toxicity of the phosphorylated/unphosphorylated forms of the major venom toxin, melittin, considering the most prominent phosphorylation event, the phosphorylated 18Ser position. We showed that the toxicity is in fact decreased when the peptide is phosphorylated. Based on a combination of efficient methodology and state-of-the-art instrumentation, delineated by our Shotgun-NanoESI-Long Gradient-LTQ Orbitrap Velos analysis, we achieved proteomic coverage far surpassing any previous report. Together, these discoveries pave the way for future phosphovenomic studies

Honeybee venom

Label-free quantification

LC-MS/MS fosforilação

LC-MS/MS phosphorylation

Melitina

Melittin

Proteoma

Veneno de abelha

Carbon nanotubes micro-arrays: characterization and application in biosensing of free proteins and label-free capture of breast cancer cells

Khosravi, Farhad

16 August 2016

"Circulating tumor cells (CTCs) are cells released into the bloodstream from primary tumors and are suspected to be one of the main causes behind metastatic spreading of cancer. The ability to capture and analyze circulating tumor cells in clinical samples is of great interest in prevailing patient prognosis and clinical management of cancer. Carbon nanotubes, individual rolled-up graphene sheets, have emerged as exciting materials for probing the biomolecular interactions. With diameter of about 1 nm, they can attach themselves to cell surface receptors through specific antibodies and hold a great potential for diagnostic cellular profiling. Carbon nanotubes can be either semiconducting or metallic, and the electronic properties of either type rivals the best known materials. Small size of nanotubes and the ability to functionalize their surface using 1-Pyrenebutanoic Acid, Succinimidyl Ester (PASE), enables a versatile probe for developing a platform for capture and analysis of cancer biomarkers and circulating tumor cells. Although nanotubes have previously been used to electrically detect a variety of molecules and proteins, here for the first time we demonstrate the label free capture of spiked breast cancer cells using ultra-thin carbon nanotube film micro-array devices in a drop of buffy coat and blood. A new statistical approach of using Dynamic Time Warping (DTW) was used to classify the electrical signatures with 90% sensitivity and 90% specificity in blood. These results suggest such label free devices could potentially be useful for clinical capture and further analysis of circulating tumor cells. This thesis will go in-depth the properties of carbon nanotubes, device fabrication and characterization methodologies, functionalization protocols, and experiments in buffy coats and in blood. Combination of nano and biological materials, functionalization protocols and advanced statistical classifiers can potentially enable clinical translation of such devices in the future. "

circulating tumor cells

cancer cells

biosensor

micro arrays

carbon nanotube

capture

sensing

field effect transistor

label free

Développements de méthodes de préparation d’échantillons pour l’analyse protéomique quantitative : application à la recherche de biomarqueurs de pathologies / Development of sample preparation methods for quantitative proteomics : application to diseases biomarkers research

Muller, Leslie

21 December 2017

Les stratégies de protéomique quantitative sans marquage sont très attractives dans le domaine de la recherche de biomarqueurs de pathologies. Cependant, elles requièrent une pleine maîtrise du schéma analytique et de sa répétabilité. Plus particulièrement, la préparation d’échantillons nécessite d’être suffisamment répétable pour ne pas impacter la qualité et la fiabilité des résultats. Les objectifs de cette thèse étaient de développer et d’optimiser des méthodes analytiques pour la protéomique quantitative, en particulier pour l’étape de préparation d’échantillons. Ainsi, un protocole innovant, simple, rapide et permettant l’analyse quantitative sans marquage d’un grand nombre d’échantillons avec une haute répétabilité a été développé et optimisé : le « Tube-Gel ». Par ailleurs, des préparations d’échantillons adaptées à différentes matrices biologiques pour la recherche de biomarqueurs ont été élaborées. Les méthodes mises au point et leur application ont permis de proposer des candidats biomarqueurs pour plusieurs pathologies : le glioblastome, les lymphomes B diffus à grandes cellules, et les complications survenant sur les greffons rénaux. / Label-free quantitative proteomics strategies are very attractive for diseases biomarkers researches. These approaches require the full control and the repeatability of the analytical workflow. In particular, the sample preparation has to be repeatable enough to ensure the quality and reliability of the results. Objectives of this work were to optimize and develop analytical methods for quantitative proteomics, with a special focus on the sample preparation step. Thus, an innovative, easy and fast protocol allowing the analysis of high sample numbers with high repeatability was developed and further optimized: the “Tube-Gel” protocol. Besides,sample preparations adapted to a variety of biological matrices were developed for the search of biomarkers. The developed methods and their application allowed the identification of potential biomarkers for a variety of diseases: glioblastoma, diffuse large B-cell lymphomas and renal transplants failures.

Analyse protéomique

Spectrométrie de masse

Quantification sans marquage

Préparation d'échantillons

Proteomic analysis

Mass spectrometry

Label-free quantification

Sample preparation

543

Nouvelles technologies intégrées d'adressage et de détection des interactions moléculaires pour application de biopuces en diagnostic moléculaire in vitro / Novel integrated technologies of patterning and detection for the conception of microarrays dedicated to in vitro molecular diagnosis

Foncy, Julie

12 December 2013

Le marché du diagnostic connait un essor considérable depuis l’avènement de labiologie moléculaire. Plus précis et souvent plus rapide, le diagnostic moléculaire in vitro(DIV) est de plus en plus utilisé dans les laboratoires d’analyses médicales. L’ensemble destests dédiés au marché du DIV répond à des contraintes socio-économiques très précisescomme : la fiabilité du résultat, le délai de réponse court, le faible coût et la facilitéd’utilisation. Les indicateurs socio-économiques montrent que la technologie des biopuces estun potentiel bon candidat pour répondre aux attentes du marché. En effet, cet outil permetl’analyse simultanée de plusieurs dizaines voire centaines de séquences nucléiques et doncl’identification d’autant d’organismes en une seule analyse. Cette technologie s’inscrit encomplément de la PCR en apportant l’avantage de l’analyse multiplexée à moyen débit. Deplus, elle permet de donner une réponse globale de la multiplicité des espèces présentes dansl’échantillon sans avoir besoin de passer par une étape de culture. Néanmoins, cettetechnologie n’est pas optimisée pour le marché du DIV. En effet, son usage est complexe, peurobuste et trop cher pour concurrencer les méthodes actuelles (microbiologie pasteurienne,PCR, Elisa, etc..). Dans le but de réduire le coût de fabrication des biopuces à ADN, il estdonc nécessaire de développer des méthodes alternatives. Dans un premier temps, l’objectif de cette thèse Cifre a été de mettre au point unprototype nouveau de dépôt de biomolécules basé sur la lithographie douce, permettant dedéposer les oligonucléotides sondes de façon multiplexée et selon des motifs micrométriques.Cette nouvelle technologie a été évaluée par rapport aux technologies de références. Puis,nous avons développé un procédé innovant de double fonctionnalisation de surface. Ceprocédé simple et rapide a pour avantages de fonctionnaliser la biopuce avec la chimie desurface et les sondes en une seule étape et d’augmenter les signaux d’hybridation. La secondepartie de la thèse a été de coupler cette nouvelle technologie à la détection des événementsd’hybridation sans marquage en utilisant la diffraction de la lumière. La principale différenceavec la méthode de détection par fluorescence repose sur l’adressage des sondes. En effet, ledépôt doit être réalisé sous forme de réseaux de lignes nanométriques diffractants de façon àce que l'interaction entre les molécules déposées et les cibles qui interagissent soit trèssensible. Cette seconde phase du projet a été très ambitieuse et innovante. La faisabilité decette méthode de détection, démontrée par des simulations théoriques, a fait l’objet d’untravail d’optimisation très important et les résultats obtenus montrent que cette technologiesans marquage est possible. / The diagnosis market increased since the advent of molecular biology. More precise and often faster, the in vitro molecular diagnosis (DIV) is more and more used in medical analyses laboratories. DNA chips technology seems to be a good candidate to answer the market expectations. Indeed, this tool allows making several hundreds of analyses simultaneously. Furthermore, it allows giving a global answer of all the present species in the sample without the need of a culture step. Nevertheless, this technology is not optimized for the market of the DIV. Indeed, its use is complex and too expensive in comparison with the current methods (Pasteur microbiology, PCR, Elisa, etc.). So it is necessary to develop an alternative method to reduce the manufacturing cost and simplify the use of DNA chips. First, the goal of this industrial PhD Cifre supported by the Dendris Company was to complete a new prototype of biomolecules deposition based on soft lithography, allowing multiplexing the deposition of oligonucleotides probes along micro and nanometric patterns.This new technology was compared with the reference technologies. Then, we developed an innovative process of surface co-functionalization. This simple and fast process permits to functionalize the DNA chips with both surface chemistry and probes in a single step and to increase the hybridization signals. The second part of this PhD thesis was to couple this new technology with label-free detection using light diffraction. The main difference with fluorescence-based detection was about probes patterning. Indeed, we needed to generate molecular gratings of nanometric lines to diffract efficiently light from a laser beam. We showed that the absolute diffraction intensity increase with the gratings thickness, which is directly correlated with, probes and targets interactions. The second phase of the project was very ambitious and innovative because we demonstrated the feasibility of this label-free detection. And now we can think that this technology will appear as an alternative method for the diagnosis

Biopuce

Oligonucléotides

Détection sans marquage

Diagnostic

DNA chips

Oligonucleotides

Structured surface functionalization

Label-free detection

Diagnosis

660.6

Label Free Methods for the Quantification of Molecular Interaction with Membrane Protein on Cell Surface

January 2018

abstract: Measuring molecular interaction with membrane proteins is critical for understanding cellular functions, validating biomarkers and screening drugs. Despite the importance, developing such a capability has been a difficult challenge, especially for small molecules binding to membrane proteins in their native cellular environment. The current mainstream practice is to isolate membrane proteins from the cell membranes, which is difficult and often lead to the loss of their native structures and functions. In this thesis, novel detection methods for in situ quantification of molecular interactions with membrane proteins are described. First, a label-free surface plasmon resonance imaging (SPRi) platform is developed for the in situ detection of the molecular interactions between membrane protein drug target and its specific antibody drug molecule on cell surface. With this method, the binding kinetics of the drug-target interaction is quantified for drug evaluation and the receptor density on the cell surface is also determined. Second, a label-free mechanically amplification detection method coupled with a microfluidic device is developed for the detection of both large and small molecules on single cells. Using this method, four major types of transmembrane proteins, including glycoproteins, ion channels, G-protein coupled receptors (GPCRs) and tyrosine kinase receptors on single whole cells are studied with their specific drug molecules. The basic principle of this method is established by developing a thermodynamic model to express the binding-induced nanometer-scale cellular deformation in terms of membrane protein density and cellular mechanical properties. Experiments are carried out to validate the model. Last, by tracking the cell membrane edge deformation, molecular binding induced downstream event – granule exocytosis is measured with a dual-optical imaging system. Using this method, the single granule exocytosis events in single cells are monitored and the temporal-spatial distribution of the granule fusion-induced cell membrane deformation are mapped. Different patterns of granule release are resolved, including multiple release events occurring close in time and position. The label-free cell membrane deformation tracking method was validated with the simultaneous fluorescence recording. And the simultaneous cell membrane deformation detection and fluorescence recording allow the study of the propagation of the granule release-induced membrane deformation along cell surfaces. / Dissertation/Thesis / Doctoral Dissertation Electrical Engineering 2018

Electrical engineering

Biochemistry

Biomedical engineering

Label-free

Membrane protein

Molecular interaction

Optical imaging

Single cell

Vesicle release

Integrated Optical Slot-Waveguide Ring Resonator Sensor Arrays for Lab-on-Chip Applications

Gylfason, Kristinn Björgvin

January 2010

This thesis treats the development of an integrated optical sensor array. The sensors are slot-waveguide ring resonators, integrated with on-chip surface grating couplers and light splitters, for alignment tolerant, real-time, refractive index sensing, and label-free biosensing. The work includes: the design of components and system layouts, the development of fabrication methods, the fabrication of sensor chips, the characterization of the chips, and the development of physical system models for accurate extraction of resonance wavelengths in measured spectra. The main scientific achievements include: The evaluation of a novel type of nano-structured optical waveguide for biochemical sensing. The realization of an array of such slot-waveguide sensors, integrated with microfluidic sample handling, for multiplex assays. The first study of the thermal behavior of slot-waveguide sensors and the discovery of unique temperature compensation capabilities. From an application perspective, the use of alignment tolerant surface gratings to couple light into the optical chip enables quick replacement of cartridges in the read-out instrument. Furthermore, the fabrication sequence avoids polishing of individual chips, and thus ensures that the cost benefits of silicon batch micro-fabrication can be leveraged in mass production. The high sensitivity of the slot waveguide resonators, combined with on-chip referencing and physical modeling, yields low limits of detection. The obtained volume refractive index detection limit of 5 × 10−6 refractive index units (RIU), and the surface mass density detection limit of 0.9 pg/mm2, shows that performance comparable to that of commercial non-integrated surface plasmon resonance sensors, made from bulk optical components, canbe achieved in a compact cartridge. / Qc20100715 / SABIO

biosensor

label-free biosensing

ring resonator

optical waveguide

lab-on-a-chip

Elektronisk mät- och apparatteknik

Photonics

Fotonik

Photonic Crystal Nanobeam Cavities for Biomedical Sensing

Quan, Qimin

21 June 2013

Manipulation of light at the nanoscale has the promise to enable numerous technological advances in biomedical sensing, optical communications, nano-mechanics and quantum optics. As photons have vanishingly small interaction cross sections, their interactions have to be mitigated by matters (i.e. quantum emitters, molecules, electrons etc.). Waveguides and cavities are the fundamental building blocks of the optical circuits, which control or confine light to specific matters of interest. The first half of the thesis (Chapters 2 & 3) focuses on how to design various photonic nanostructures to manipulate light on nano- to micro- scale, especially to modify the light-matter interaction properties. Chapter 2 discusses how nano-slot waveguides and photonic crystal nanobeam waveguides are able to modify the emission of quantum emitters, in a different way that normal ridge waveguides are not able to. Chapter 3 focuses on a more complicated and powerful structure: the photonic crystal nanobeam cavity. The design, fabrication and characterization of the photonic crystal nanobeam cavities are described and demonstrated in detail, which lays out the foundation of the biomedical sensing applications in the second half of the thesis. The second half of the thesis (Chapters 4 & 5) focuses on the application of photonic crystal nanobeam cavities in the label-free sensing of biomedical substances. Chapter 4 demonstrates detection of solutions with different refractive index (aceton, methanol, IPA etc.), glucose concentration, single polystyrene nanoparticles and single streptavidin bio-molecules. Chapter 4 proposes a novel nonlinear optical method to further enhance the sensitivity. Chapter 4 also demonstrates high quality nanobeam cavities fabricated in polymers, that open up a new route to decrease the cost, as well as to achieve novel applications with functional polymers. The broader impact of this technology lies in its potential of commercialization of a new generation of biosensors with high sensitivity and high integration. Chapter 5 discusses progresses towards instrumentation of the nanobeam cavity sensing technology for research & development apparatus, as well as point-of-care diagnostic tools. / Engineering and Applied Sciences

optics

nanoscience

biomedical engineering

label-free bio-sensing

nanostructure

photonic crystal

quantum information

resonators

silicon photonics chips

Label-Free Optical Imaging of Chromophores and Genome Analysis at the Single Cell Level

Lu, Sijia

06 October 2014

Since the emergence of biology as a quantitative science in the past century, a lot of biological discoveries have been driven by milestone technical advances such as X-ray crystallography, fluorescence microscopy and high-throughput sequencing. Fluorescence microscopy is widely used to explore the nanoscale cellular world because of its superb sensitivity and spatial resolution. However, many species (e.g. lipids, small proteins) are non-fluorescent and are difficult to label without disturbing their native functions. In the first part of the dissertation, we explore using three different contrast mechanisms for label-free imaging of these species – absorption and stimulated emission (Chapter 2), heat generation and diffusion (Chapter 3) and nonlinear scattering (Chapter 4). We demonstrate label-free imaging of blood vessels, cytochromes, drugs for photodynamic therapy, and muscle and brain tissues with three dimensional optical sectioning capability. With the rapid development of high throughput genotyping techniques, genome analysis is currently routinely done genome-wide with single nucleotide resolution. However, a large amount of starting materials are often required for whole genome analysis. The dynamic changes in DNA molecules generate intra-sample heterogeneity. Even with the same genome content, different cells often have very different transcriptome profiles in a functional organism. Such intra-sample heterogeneities in the genome and transcriptome are often masked by ensemble analysis. In this second part of the dissertation, we first introduce a whole genome amplification method with high coverage in sequencing single human cells (Chapter 6). We then use the technique to study meiotic recombinations in sperm cells from an individual (Chapter 7). We further develop a technique that enables digital counting of genome fragments and whole genome haplotyping in single cells (Chapter 8). And we introduce our ongoing efforts on single cell transcriptome analysis (Chapter 9). In the end, we introduce our initial effort in exploring the genome accessibility at the single cell level (Chapter 9). Through the development of techniques probing the single cell genome, transcriptome and possibly epigenome, we hope to provide a toolbox for studying biological processes with genome-wide and single cell resolution. / Chemistry and Chemical Biology

DNA amplification

imaging

label-free

single cell analysis

single cell sequencing

whole genome amplification

chemistry

genetics

biomedical engineering

The genome of Euglena gracilis : annotation, function and expression

Ebenezer, ThankGod Echezona

January 2018

Euglena gracilis is a species of unicellular photosynthetic flagellate that inhibits aquatic ecosystems. E. gracilis belongs to the supergroup Excavata, and are an important component of the global biosphere, have biotechnological potential and is useful biological model due to their evolutionary history and complex biology. Whilst the evolutionary position of E. gracilis is now clear, their relationship with other protists such as Naegleria, Giardia, and Kinetoplastids, remains to be investigated in detail. Investigating and understanding the biology of this complex organism is a promising way to approach many evolutionary puzzles, including secondary endosymbiotic events and the evolution of parasitism, due to their relationship with Kinetoplastids. Here, I report a draft genome for E. gracilis, together with a high quality transcriptome and proteomic analysis. The estimated genome size is ~ 2 Gbp, with a GC content of ~ 50 % and a protein coding potential predicted at 36,526 Open Reading Frames (ORFs). Less than 25% of the genome is single copy sequence, indicating extensive repeat structure. There are evidences for large number of paralogs amongst specific gene families, indicating expansions and possible polyploidy as well as extensive sharing of genes with other non photosynthetic and photosynthetic eukaryotes: red and green algael genes, together with trypanosomes and other members of the excavates. Functional resolution into several of the biological systems indicates multiple similarities with the trypanosomatids in terms of orthology, paralogy, relatedness and complexity. Several biological systems such as nuclear architecture (e.g. chromosome segregation, nuclear pore complex, nuclear lamins), protein trafficking, translation, surface, consist of conserved and divergent components. For instance, several gene families likely associated with the cell surface and signal transduction possess very large numbers of lineage-specific paralogs, suggesting great flexibility in environmental monitoring and, together with divergent mechanisms for metabolic control, novel solutions to adaptation to extreme environments. I also demonstrate that the majority of control of protein expression levels is post-transcriptional and absence of transcriptional regulation, despite the presence of conventional introns. These data are a major advance in the understanding of the nuclear genome of Euglenids and provide a platform for investigation of the contributions of E. gracilis and relatives to the biosphere.

Análise proteônica de venenos de Apis mellifera baseada em espectrometria de massas: abordagem quantitativa label-free e identificação de fosforilação / Mass Spectrometry-based proteomic analysis of honeybee venoms: label-free quantification and phosphorylation identification

Virginia Maria Ferreira Resende

28 March 2013

Há muito tempo os venenos de abelhas se tornaram objeto de interesse de muitos cientistas, principalmente os venenos daquelas linhagens do gênero Apis, chamadas abelhas europeias e as conhecidas abelhas africanizadas. O foco no desenvolvimento de terapias eficazes que pudessem prevenir ou frear as reações desencadeadas pelas toxinas dos venenos desses insetos foi o principal estimulador do surgimento dessa grande área da pesquisa, uma vez que esses animais causam um grande número de acidentes em animais e seres humanos e os acidentes podem desencadear graves consequências, inclusive óbito. Sendo assim, desenvolvemos o presente trabalho baseado na caracterização da composição proteica dos venenos de abelhas europeias e africanizadas, na análise quantitativa diferencial entre os venenos e, na investigação de fosforilações e a possível relação das mesmas com as funções biológicas. Reunindo todos os elementos que estavam ao nosso alcance para compor o melhor conjunto de etapas para a realização do estudo proteômico de venenos de abelhas, nós atingimos todos os objetivos propostos. Utilizando uma abordagem baseada em espectrometria de massas, consistindo de análise shotgun seguida de LC-MS/MS realizada em um dos mais modernos espectrômetros de massas, nós fomos capazes de obter resultados extremamente confiáveis e interessantes. Comparando-se o efeito da extensão do gradiente de separação na cromatografia líquida, nós fomos capazes de atingir uma maior cobertura da amostra, uma vez que identificamos um maior número de proteínas após a utilização do gradiente mais longo. A identificação de fosforilações foi favorecida pela combinação de fragmentação por \"Colisão Induzida por Dissociação\" e medidas de massa de alta acurácia realizadas no instrumento LTQ-Orbitrap-Velos. Enquanto apenas 29 proteínas foram identificadas após 120 minutos de separação cromatográfica, um total de 51 proteínas foram identificadas aplicando-se gradiente mais longo. Dentre as 51 proteínas totais, 42 são comuns aos venenos das três abelhas. A comparação em pares mostrou que os venenos das abelhas europeias compartilham 44 proteínas e os venenos das abelhas africanizadas compartilham 43 proteínas tanto com o veneno de A. m. carnica quanto com o de A. m. ligustica. Além disso, nós revelamos que existem diferenças quantitativas entre algumas das proteínas dos venenos, sendo muitas dessas proteínas diferenciais toxinas com funções conhecidamente relevantes. A investigação de fosforilação mostrou que duas toxinas apresentam-se na forma fosforilada: melitina e icarapina. Melitina é considerada a principal toxina de venenos de abelhas, sendo bem conhecida por sua ação altamente tóxica e alergenicidade. Este peptídeo foi identificado com fosforilação ocorrendo no sítio Ser18 em todas as amostras de venenos, enquanto somente no veneno da abelha africanizada foi também identificado com sítio de fosforilação no resíduo de Thr10. Icarapina, também já descrita como um alérgeno do veneno, apresentou sítio de fosforilação no resíduo Ser205. Por fim, nós demonstramos o efeito da fosforilação presente em melitina (Ser18) realizando ensaios de atividade biológica do peptídeo fosforilado e nativo, como: hemólise, lise celular e desgranulação de mastócitos e atividade quimiotáctica. Foi observado que a toxicidade do peptídeo fosforilado é reduzida em comparação ao do peptídeo nativo. Sendo assim, nós podemos concluir que a combinação de metodologias eficientes e a utilização de moderna instrumentação nos levou a resultados surpreendentes, os quais se somam a todo o conhecimento já existente acerca de venenos de abelhas / Honeybee venom toxins disturb the activity of critical cellular processes, triggering immunological, physiological, and neurological responses within victims. Studies on venom toxins have provided invaluable knowledge towards elucidating the molecular and functional details of their biological targets, yet there has been no report of a full proteome/phosphoproteome profile of honeybee venom. In this study, we focused on Apis mellifera honeybee venom characterization, including proteins identification, label-free quantitative analysis and phosphorylation identification. Making use of a MS-based proteomic approach, consisting on in-solution digestion followed by LC-MS/MS analysis, we were able to compare the effect of the liquid chromatography gradient length on the sample coverage, consequently, to identify a higher number of proteins using longer separation gradient of the tryptic peptides. Favorable identification of phosphorylations was achieved by the application of a long separation gradient combined with CID fragmentation and high accuracy mass measurement using an LTQ Orbitrap Velos. Here we report on the comparative shotgun proteomics study of the venoms of two Apis mellifera subspecies, A. m. carnica and A. m. ligustica, and the hybrid known as Africanized honey bee (AHB). We identified 51 proteins in total, with 42 of them being common among the three venoms, including many previously unidentified entries. Performing label-free quantification, we observed that few proteins were found with different relative amounts. Additionally, we revealed the phosphorylation of two proteins in all the samples, with two of them being HBV toxins/allergens: melittin and icarapin. Icarapin was identified as phosphorylated at 205Ser. Melittin was identified as phosphorylated at the 18Ser and 10Thr positions in all venoms, as well. Given these novel findings, we then chose to compare the toxicity of the phosphorylated/unphosphorylated forms of the major venom toxin, melittin, considering the most prominent phosphorylation event, the phosphorylated 18Ser position. We showed that the toxicity is in fact decreased when the peptide is phosphorylated. Based on a combination of efficient methodology and state-of-the-art instrumentation, delineated by our Shotgun-NanoESI-Long Gradient-LTQ Orbitrap Velos analysis, we achieved proteomic coverage far surpassing any previous report. Together, these discoveries pave the way for future phosphovenomic studies

LC-MS/MS fosforilação

Melitina

Proteoma

Veneno de abelha

Honeybee venom

Label-free quantification

LC-MS/MS phosphorylation

Melittin