Design and planning of a transdisciplinary investigation into farmland pollinators: rationale, co-design, and lessons learned

To provide a complete portrayal of the multiple factors negatively impacting insects in agricultural landscapes it is necessary to assess the concurrent incidence, magnitude, and interactions among multiple stressors over substantial biogeographical scales. Trans-national ecological field investigations with wide-ranging stakeholders typically encounter numerous challenges during the design planning stages, not least that the scientific soundness of a spatially replicated study design must account for the substantial geographic and climatic variation among distant sites. ‘PoshBee’ (Pan-European assessment, monitoring, and mitigation of Stressors on the Health of Bees) is a multi-partner transdisciplinary agroecological project established to investigate the suite of stressors typically encountered by pollinating insects in European agricultural landscapes. To do this, PoshBee established a network of 128 study sites across eight European countries and collected over 50 measurements and samples relating to the nutritional, toxicological, pathogenic, and landscape components of the bees’ environment. This paper describes the development process, rationale, and end-result of each aspect of the of the PoshBee field investigation. We describe the main issues and challenges encountered during the design stages and highlight a number of actions or processes that may benefit other multi-partner research consortia planning similar large-scale studies. It was soon identified that in a multi-component study design process, the development of interaction and communication networks involving all collaborators and stakeholders requires considerable time and resources. It was also necessary at each planning stage to be mindful of the needs and objectives of all stakeholders and partners, and further challenges inevitably arose when practical limitations, such as time restrictions and labour constraints, were superimposed upon prototype study designs. To promote clarity for all stakeholders, for each sub-component of the study, there should be a clear record of the rationale and reasoning that outlines how the final design transpired, what compromises were made, and how the requirements of different stakeholders were accomplished. Ultimately, multi-national agroecological field studies such as PoshBee benefit greatly from the involvement of diverse stakeholders and partners, ranging from field ecologists, project managers, policy legislators, mathematical modelers, and farmer organisations. While the execution of the study highlighted the advantages and benefits of large-scale transdisciplinary projects, the long planning period emphasized the need to formally describe a design framework that could facilitate the design process of future multi-partner collaborations

Etude de la biodistribution et de la toxicité des Nanoparticules de Fer chez le rat et sur une lignée de neuroblastome

Iron Oxide Nanoparticles (IONPs) are used in several fields notably in Biomedicine as theranostic agents in Oncology and also as contrast agents in Magnetic Resonance Imaging. With the increase in the production and use of IONPs, there is a clear increase in human and environmental exposure to these NPs, which may pose a risk. The subject of my thesis is the study of the physiopathological impact and toxicity of iron oxide nanoparticles using a cell model of neuroblastoma and an animal study model, the Wistar rat. The aim of the research work of the in vitro part is to evaluate the cytotoxic and genotoxic effects as well as the effects on the expression of cellular proteins following the exposure of SH-SY5Y cells to increasing concentrations of iron NPs. We have shown that iron NPs induce cellular perturbations in a size and concentration dependent manner. Proteomic analysis followed by ontological gene annotation and signaling pathway analysis revealed the effects of IONPs on cytoskeleton, apoptosis and cancer development. The aims of our research carried out in vivo are to investigate the pathophysiological effects of iron NPs administered by three different routes, intravenous, intranasal and oral, also their impact on emotional and cognitive behavior as well as neurotransmitter and trace element homeostasis. The results showed that IONPs do not induce any changes in anxiety, locomotion, learning and memory in rats regardless of the administration route. However, these NPs cause a disruption of catecholamine and trace element levels in the brain. The most marked effects have been observed following intranasal instillation of NPs and are manifested by a decrease in serum iron levels, thrombocytosis and the presence of inflammatory foci in the liver. The comparative analysis of the three routes of administration showed that the intravenous route is the least toxic. Finally, the proteomic study of the proteomes of the brain, liver and lung has made it possible to evaluate the toxicity of the NPs of iron at the protein and molecular level. The obtained results provide an important support for the estimation and understanding of potentially adverse effects of these NPs, which have a certain toxicity that is not negligible from a molecular and physiopathological point of view. Thus, great care must be taken regarding their use in the biomedical field to minimize any risk related to IONP exposure in order to improve their biocompatibility and thus increase their benefits.Les nanoparticules d'oxyde de fer sont utilisées dans plusieurs domaines notamment en Biomédecine comme agents théranostiques en Cancérologie et aussi comme agents de contraste en Imagerie par Résonance Magnétique. Avec l'augmentation de la production et de l'utilisation de ces NPs de fer, il y a une évidente augmentation de l'exposition humaine et environnementale à ces NPs, et qui peut présenter un risque. Le sujet de ma thèse porte sur l'étude de l’impact physiopathologique et de la toxicité des nanoparticules de fer (NPs de fer) en utilisant un modèle cellulaire de neuroblastome et un modèle d'étude animal, le rat Wistar. L’objectif des travaux de recherche de la partie in vitro est d’évaluer les effets cytotoxiques et génotoxiques ainsi que les effets sur l’expression des protéines cellulaires suite à l’exposition des cellules SH-SY5Y à des concentrations croissantes des NPs de fer. Nous avons montré que les NPs de fer induisent des perturbations cellulaires d’une manière dépendante de la taille et de la concentration. L'analyse protéomique suivie par l'annotation des gènes avec l’ontologie et l'analyse des voies de signalisation a mis en évidence les effets des NPs de fer sur le cytosquelette, l'apoptose et le développement du cancer. Les objectifs de nos travaux de recherche réalisés in vivo consistent à étudier les effets physiopathologiques des NPs de fer administrées par trois voies différentes, intraveineuse, intranasale et orale, à savoir leur impact sur le comportement émotionnel et cognitif ainsi que sur l’homéostasie des neurotransmetteurs et des éléments traces. Les résultats ont montré que les NPs de fer n’induisent pas de modification concernant l’anxiété, la locomotion, l’apprentissage et la mémoire chez le rat quelle que soit la voie d’administration. Cependant, ces NPs provoquent une perturbation des niveaux des catécholamines et des éléments traces au niveau cérébral. Les effets les plus marqués ont été observés suite à l’instillation intranasale des NPs et se manifestent par une diminution de taux du fer sérique, la thrombocytose et la présence des foyers inflammatoires au niveau hépatique. L’analyse comparative des trois voies d’administration a montré que la voie intraveineuse est la moins toxique. Enfin, l’étude protéomique des protéomes du cerveau, du foie et du poumon a permis d’évaluer la toxicité des NPs de fer au niveau protéique et moléculaire. Les résultats obtenus présentent un support important pour l’estimation et la compréhension des effets potentiellement adverses de ces NPs qui présentent une certaine toxicité non négligeable de point de vue moléculaire et physiopathologique. Ainsi, leur utilisation dans le domaine biomédicale doit être prise avec beaucoup de précaution pour éviter au maximum tout risque lié à leur exposition afin d’améliorer leur biocompatibilité et ainsi augmenter leurs avantages

Biodistribution and toxicity study of Iron Nanoparticles in rats and on a neuroblastoma cell line

Les nanoparticules d'oxyde de fer sont utilisées dans plusieurs domaines notamment en Biomédecine comme agents théranostiques en Cancérologie et aussi comme agents de contraste en Imagerie par Résonance Magnétique. Avec l'augmentation de la production et de l'utilisation de ces NPs de fer, il y a une évidente augmentation de l'exposition humaine et environnementale à ces NPs, et qui peut présenter un risque. Le sujet de ma thèse porte sur l'étude de l’impact physiopathologique et de la toxicité des nanoparticules de fer (NPs de fer) en utilisant un modèle cellulaire de neuroblastome et un modèle d'étude animal, le rat Wistar. L’objectif des travaux de recherche de la partie in vitro est d’évaluer les effets cytotoxiques et génotoxiques ainsi que les effets sur l’expression des protéines cellulaires suite à l’exposition des cellules SH-SY5Y à des concentrations croissantes des NPs de fer. Nous avons montré que les NPs de fer induisent des perturbations cellulaires d’une manière dépendante de la taille et de la concentration. L'analyse protéomique suivie par l'annotation des gènes avec l’ontologie et l'analyse des voies de signalisation a mis en évidence les effets des NPs de fer sur le cytosquelette, l'apoptose et le développement du cancer. Les objectifs de nos travaux de recherche réalisés in vivo consistent à étudier les effets physiopathologiques des NPs de fer administrées par trois voies différentes, intraveineuse, intranasale et orale, à savoir leur impact sur le comportement émotionnel et cognitif ainsi que sur l’homéostasie des neurotransmetteurs et des éléments traces. Les résultats ont montré que les NPs de fer n’induisent pas de modification concernant l’anxiété, la locomotion, l’apprentissage et la mémoire chez le rat quelle que soit la voie d’administration. Cependant, ces NPs provoquent une perturbation des niveaux des catécholamines et des éléments traces au niveau cérébral. Les effets les plus marqués ont été observés suite à l’instillation intranasale des NPs et se manifestent par une diminution de taux du fer sérique, la thrombocytose et la présence des foyers inflammatoires au niveau hépatique. L’analyse comparative des trois voies d’administration a montré que la voie intraveineuse est la moins toxique. Enfin, l’étude protéomique des protéomes du cerveau, du foie et du poumon a permis d’évaluer la toxicité des NPs de fer au niveau protéique et moléculaire. Les résultats obtenus présentent un support important pour l’estimation et la compréhension des effets potentiellement adverses de ces NPs qui présentent une certaine toxicité non négligeable de point de vue moléculaire et physiopathologique. Ainsi, leur utilisation dans le domaine biomédicale doit être prise avec beaucoup de précaution pour éviter au maximum tout risque lié à leur exposition afin d’améliorer leur biocompatibilité et ainsi augmenter leurs avantages.Iron Oxide Nanoparticles (IONPs) are used in several fields notably in Biomedicine as theranostic agents in Oncology and also as contrast agents in Magnetic Resonance Imaging. With the increase in the production and use of IONPs, there is a clear increase in human and environmental exposure to these NPs, which may pose a risk. The subject of my thesis is the study of the physiopathological impact and toxicity of iron oxide nanoparticles using a cell model of neuroblastoma and an animal study model, the Wistar rat. The aim of the research work of the in vitro part is to evaluate the cytotoxic and genotoxic effects as well as the effects on the expression of cellular proteins following the exposure of SH-SY5Y cells to increasing concentrations of iron NPs. We have shown that iron NPs induce cellular perturbations in a size and concentration dependent manner. Proteomic analysis followed by ontological gene annotation and signaling pathway analysis revealed the effects of IONPs on cytoskeleton, apoptosis and cancer development. The aims of our research carried out in vivo are to investigate the pathophysiological effects of iron NPs administered by three different routes, intravenous, intranasal and oral, also their impact on emotional and cognitive behavior as well as neurotransmitter and trace element homeostasis. The results showed that IONPs do not induce any changes in anxiety, locomotion, learning and memory in rats regardless of the administration route. However, these NPs cause a disruption of catecholamine and trace element levels in the brain. The most marked effects have been observed following intranasal instillation of NPs and are manifested by a decrease in serum iron levels, thrombocytosis and the presence of inflammatory foci in the liver. The comparative analysis of the three routes of administration showed that the intravenous route is the least toxic. Finally, the proteomic study of the proteomes of the brain, liver and lung has made it possible to evaluate the toxicity of the NPs of iron at the protein and molecular level. The obtained results provide an important support for the estimation and understanding of potentially adverse effects of these NPs, which have a certain toxicity that is not negligible from a molecular and physiopathological point of view. Thus, great care must be taken regarding their use in the biomedical field to minimize any risk related to IONP exposure in order to improve their biocompatibility and thus increase their benefits

Unraveling the Bombus terrestris Hemolymph, an Indicator of the Immune Response to Microbial Infections, through Complementary Mass Spectrometry Approaches

International audiencePollinators, including Bombus terrestris, are crucial for maintaining biodiversity in ecosystems and for agriculture. Deciphering their immune response under stress conditions is a key issue for protecting these populations. To assess this metric, we analyzed the B. terrestris hemolymph as an indicator of their immune status. Hemolymph analysis was carried out using mass spectrometry, MALDI molecular mass fingerprinting was used for its effectiveness in assessing the immune status, and high-resolution mass spectrometry was used to measure the impact of experimental bacterial infections on the “hemoproteome”. By infecting with three different types of bacteria, we observed that B. terrestris reacts in a specific way to bacterial attacks. Indeed, bacteria impact survival and stimulate an immune response in infected individuals, visible through changes in the molecular composition of their hemolymph. The characterization and label-free quantification of proteins involved in specific signaling pathways in bumble bees by bottom-up proteomics revealed differences in protein expression between the non-experimentally infected and the infected bees. Our results highlight the alteration of pathways involved in immune and defense reactions, stress, and energetic metabolism. Lastly, we developed molecular signatures reflecting the health status of B. terrestris to pave the way for diagnosis/prognosis tools in response to environmental stress

Parasite and Pesticide Impacts on the Bumblebee (Bombus terrestris) Haemolymph Proteome

International audiencePesticides pose a potential threat to bee health, especially in combination with other stressors, such as parasites. However, pesticide risk assessment tests pesticides in isolation from other stresses, i.e., on otherwise healthy bees. Through molecular analysis, the specific impacts of a pesticide or its interaction with another stressor can be elucidated. Molecular mass profiling by MALDI BeeTyping ® was used on bee haemolymph to explore the signature of pesticidal and parasitic stressor impacts. This approach was complemented by bottom-up proteomics to investigate the modulation of the haemoproteome. We tested acute oral doses of three pesticides-glyphosate, Amistar and sulfoxaflor-on the bumblebee Bombus terrestris, alongside the gut parasite Crithidia bombi. We found no impact of any pesticide on parasite intensity and no impact of sulfoxaflor or glyphosate on survival or weight change. Amistar caused weight loss and 19-41% mortality. Haemoproteome analysis showed various protein dysregulations. The major pathways dysregulated were those involved in insect defences and immune responses, with Amistar having the strongest impact on these dysregulated pathways. Our results show that even when no response can be seen at a whole organism level, MALDI BeeTyping ® can detect effects. Mass spectrometry analysis of bee haemolymph provides a pertinent tool to evaluate stressor impacts on bee health, even at the level of individuals

Sub-acute intravenous exposure to Fe2O3 nanoparticles does not alter cognitive performances and catecholamine levels, but slightly disrupts plasma iron level and brain iron content in rats

International audienceEngineered nanomaterials are used in various applications due to their particular properties. Among them, Iron Oxide Nanoparticles (Fe2O3-NPs) are used in Biomedicine as theranostic agents i.e. contrast agents in Magnetic Resonance Imaging and cancer treatment. With the increasing production and use of these Fe2O3-NPs, there is an evident raise of Fe2O3-NPs exposure and subsequently a higher risk of adverse outcomes for the environment and Human. In the present paper, we investigated the effects of an intravenous daily Fe2O3-NPs exposure on Wistar rat for one week. As results, we showed that several hematological parameters and transaminase (ALT and AST) levels as well as organ histology remained unchanged in treated rats. Neither the catecholamine levels nor the emotional behavior and learning / memory capacities of rats were impacted by the sub-acute intravenous exposure to Fe2O3-NPs. However, iron level in plasma and iron content homeostasis in brain were disrupted after this exposure. Thus, our results demonstrated that Fe2O3-NPs could have transient effects on rat but the intravenous route is still safer that others which is encouraging for their use in medical and/or biological applications

Effects of Iron Oxide Nanoparticles (γ-Fe2O3) on Liver, Lung and Brain Proteomes following Sub-Acute Intranasal Exposure: A New Toxicological Assessment in Rat Model Using iTRAQ-Based Quantitative Proteomics

Iron Oxide Nanoparticles (IONPs) present unique properties making them one of the most used NPs in the biomedical field. Nevertheless, for many years, growing production and use of IONPs are associated with risks that can affect human and the environment. Thus, it is essential to study the effects of these nanoparticles to better understand their mechanism of action and the molecular perturbations induced in the organism. In the present study, we investigated the toxicological effects of IONPs (γ-Fe2O3) on liver, lung and brain proteomes in Wistar rats. Exposed rats received IONP solution during 7 consecutive days by intranasal instillation at a dose of 10 mg/kg body weight. An iTRAQ-based quantitative proteomics was used to study proteomic variations at the level of the three organs. Using this proteomic approach, we identified 1565; 1135 and 1161 proteins respectively in the brain, liver and lung. Amon them, we quantified 1541; 1125 and 1128 proteins respectively in the brain, liver and lung. Several proteins were dysregulated comparing treated samples to controls, particularly, proteins involved in cytoskeleton remodeling, cellular metabolism, immune system stimulation, inflammation process, response to oxidative stress, angiogenesis, and neurodegenerative diseases

Intranasal instillation of iron oxide nanoparticles induces inflammation and perturbation of trace elements and neurotransmitters, but not behavioral impairment in rats

International audienceOver the last decades, engineered nanomaterials have been widely used in various applications due to their interesting properties. Among them, iron oxide nanoparticles (IONPs) are used as theranostic agents for cancer, and also as contrast agents in magnetic resonance imaging. With the increasing production and use of these IONPs, there is an evident raise of IONP exposure and subsequently a higher risk of adverse outcome for humans and the environment. In this work, we aimed to investigate the effects of sub-acute IONP exposure on Wistar rat, particularly (i) on the emotional and learning/memory behavior, (ii) on the hematological and biochemical parameters, (iii) on the neurotransmitter content, and (vi) on the trace element homeostasis. Rats were treated during seven consecutive days by intranasal instillations at a dose of 10 mg/kg body weight. The mean body weight increased significantly in IONP-exposed rats. Moreover, several hematological parameters were normal in treated rats except the platelet count which was increased. The biochemical study revealed that phosphatase alkaline level decreased in IONP-exposed rats, but no changes were observed for the other hepatic enzymes (ALT and AST) levels. The trace element homeostasis was slightly modulated by IONP exposure. Sub-acute intranasal exposure to IONPs increased dopamine and norepinephrine levels in rat brain; however, it did not affect the emotional behavior, the anxiety index, and the learning/memory capacities of rats

Investigating the toxic effects induced by iron oxide nanoparticles on neuroblastoma cell line: an integrative study combining cytotoxic, genotoxic and proteomic tools

International audienceNanomaterials have gained much attention for their use and benefit in several fields. Iron Oxide Nanoparticles (IONPs) have been used in Biomedicine as contrast agents for imaging cancer cells. However, several studies reported the potential toxicity of those nanoparticles in different models, especially in cells. Therefore, in our present study, we investigated the effects of IONPs on the SH-SY5Y neuroblastoma cell line. We carried out cytotoxic and genotoxic studies to evaluate the phenotypic effects, and proteomic investigation to evaluate the molecular effects and the mechanisms by which this kind of NPs could induce toxicity. Our results showed that the use of three different sizes of IONPs (14, 22 and 30 nm) induced cell detachment, cell morphological changes, size, and concentration-dependent IONP internalization and cell mortality. IONPs induced slight genotoxic damage assayed by modified comet assay without affecting cell cycle, mitochondrial function, membrane integrity, intracellular calcium level, and without inducing ROS generation. All the studies were performed to compare also the effects of IONPs to the ferric iron by incubating cells with equivalent concentration of FeCl3. In all tests, the NPs exhibited more toxicity than the ferric iron. The proteomic analysis followed by gene ontology and pathway analysis evidenced the effects of IONPs on cytoskeleton, cell apoptosis, and cancer development. Our findings provided more information about IONP effects on human cells and especially on cancer cell line