Ouvrages publiés en collaboration (1)
  1. 1. Larsen, M., Bousbata, S., & Roepstorff, P. (2006). Proteome specific sample preparation methods for matrix assisted laser desorption/ionization mass spectrometry.
    2.   Articles dans des revues avec comité de lecture (29)
  2. 1. Ouali, R., & Bousbata, S. (2025). Rhodnius prolixus (kissing bug). Trends in parasitology. doi:10.1016/j.pt.2025.06.014
  3. 2. Ouali, R., & Bousbata, S. (2025). Refining the annotation of Rhodnius prolixus aspartic proteases A1 family genes through proteogenomics. Current research in parasitology and vector-borne diseases, 7, 100253. doi:10.1016/j.crpvbd.2025.100253
  4. 3. Ouali, R., Vieira, L. R., Salmon, D., & Bousbata, S. (2024). Trypanosoma cruzi reprograms mitochondrial metabolism within the anterior midgut of its vector Rhodnius prolixus during the early stages of infection. Parasites & Vectors, 17(1), 381. doi:10.1186/s13071-024-06415-1
  5. 4. Ouali, R., & Bousbata, S. (2024). Unveiling the Peptidase Network Orchestrating Hemoglobin Catabolism in Rhodnius prolixus. Molecular & cellular proteomics.
  6. 5. Ouali, R., Vieira, L. R., Salmon, D., & Bousbata, S. (2022). Rhodnius prolixus Hemolymph Immuno-Physiology: Deciphering the Systemic Immune Response Triggered by Trypanosoma cruzi Establishment in the Vector Using Quantitative Proteomics. Cells, 11(9), 1449. doi:10.3390/cells11091449
  7. 6. Ouali, R., Vieira, L. R., Salmon, D., & Bousbata, S. (2021). Early post-prandial regulation of protein expression in the midgut of chagas disease vector rhodnius prolixus highlights new potential targets for vector control strategy. Microorganisms, 9(4), 804. doi:10.3390/microorganisms9040804
  8. 7. Ouali, R., De Brito, K. C. V., Salmon, D. S., & Bousbata, S. (2020). High-Throughput Identification of the Rhodnius prolixus Midgut Proteome Unravels a Sophisticated Hematophagic Machinery. Proteomes, 8(16), 1-13.
  9. 8. Mendes, A., Juhlen, R. G., Bousbata, S., & Fahrenkrog, B. (2020). Disclosing the Interactome of Leukemogenic NUP98-HOXA9 and SET-NUP214 Fusion Proteins Using a Proteomic Approach. Cells, 9(7). doi:10.3390/cells9071666
  10. 9. Bettonville, M., D'Aria, S., Weatherly, K., Porporato, P. E., Zhang, J., Bousbata, S., Sonveaux, P., & Braun, M. Y. (2018). Long-term antigen exposure irreversibly modifies metabolic requirements for T cell function. eLife, 7. doi:10.7554/eLife.30938
  11. 10. Brosson, S., Bottu, G., Pays, E., Bousbata, S., & Salmon, D. (2017). Identification and preliminary characterization of a putative C-type lectin receptor-like protein in the T. cruzi tomato lectin endocytic-enriched proteome. Microbiological research, 205, 73-79. doi:10.1016/j.micres.2017.07.001
  12. 11. Zeghir-Bouteldja, R., Polome, A., Bousbata, S., & Touil-Boukoffa, C. (2017). Comparative proteome profiling of hydatid fluid from Algerian patients reveals cyst location-related variation in Echinococcus granulosus. Acta Tropica, 171, 199-206. doi:10.1016/j.actatropica.2017.03.034
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