Pablo Armas has a degree in Biotechnology from Facultad de Ciencias Bioquímicas y Farmacéuticas (FCByF), Universidad Nacional de Rosario (UNR); he completed his PhD and Post-doc at Instituto de Biología Molecular y Celular de Rosario (IBR-CONICET-UNR), under the supervision of Dr. Nora Calcaterra. He is currently an Independent Researcher at CONICET and an Associate Researcher of the Biochemistry and Molecular Biology of Development group. He is Associate Professor of the Área Biología General, FCByF. In his research project, novel and little explored mechanisms of gene regulation are studied that depend on an unconventional structure of nucleic acids (DNA and RNA) known as guanine quadruplex or G4s. These mechanisms have been revealed in the last 20 years in all living organisms and even in DNA and RNA viruses. The project addresses the study of G4s in the control of genes related to animal development, using the zebrafish model. G4s are also studied as regulators of genes related to human pathologies, and the influence of genetic variations on G4s as causes for the predisposition or onset of those pathologies. In addition, the role of G4s in the biology and replication of the SARS-CoV-2 virus, which caused the COVID-19 pandemic, has recently been addressed.
Scopus Author ID: 6506870338 Orcid Google scholar Twitter: @PabloArmasF IG: pablo_armas
Directed Project:
Non-canonical structures of nucleic acids in the control of normal and pathological gene expression
We study the regulation of genes through novel and poorly explored mechanisms that depend on unconventional structures of nucleic acids (DNA and RNA), known as guanine quadruplexes or G4s. The regulation of genes by G4s has been revealed in the last 20 years for all living organisms, from animals and plants to microorganisms such as bacteria and even in viruses with DNA and RNA genetic material. The project addresses the study of G4s in the control of genes related to animal embryonic development, using zebrafish as a model. The function of G4s in the regulation of genes related to human pathologies is also studied, mainly for genes involved in cancer, and the influence of genetic variations in G4s as possible causes for the predisposition or onset of those pathologies. In addition, the project recently incorporated the study of the function of G4s in the biology and replication of the SARS-CoV-2 virus, which caused the COVID-19 pandemic.
Directed Human Resources:
Postdoctoral Fellows
PhD Students
Publicaciones:
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Bezzi, G., Piga, E. J., Binolfi, A., Armas, P. CNBP binds and unfolds in vitro G-quadruplexes formed in the SARS-CoV-2 positive and negative genome strands. 2021 International Journal of Molecular Sciences | Ver Publicación
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Armas, P., Calcaterra, N. B. G-quadruplex in animal development: Contribution to gene expression and genomic heterogeneity. 2018 Mechanisms of Development | Ver Publicación
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David, A.P.; Margarit, E.; Domizi, P.; Banchio, C. E.; Armas, P.* (Co-corresponding author); Calcaterra, N.B.* G-quadruplexes as novel cis-elements controlling transcription during embryonic development. 2016 Nucleic Acids Res. 2016 May 19;44(9):4163-73. doi: 10.1093/nar/gkw011. Epub 2016 Jan 14.
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Steeman, T. J., Weiner A. M. J., David, A. P., Binolfi, A., Calcaterra, N. B., Armas, P. G-quadruplexes regulate miRNA biogenesis in live zebrafish embryos. 2023 International Journal of Molecular Sciences | Ver Publicación
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Lorenzatti, A., Piga, E. J., Gismondi, M., Binolfi, A., Margarit, E., Calcaterra, N. B., Armas, P. Genetic variations in G-Quadruplex forming sequences affect the transcription of human disease-related genes. 2023 bioRxiv | Ver Publicación
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Armas, P, David, A.P, Calcaterra, N.B. Transcriptional control by G-quadruplexes: in vivo roles and perspectives for specific intervention. 2017 Transcription | Ver Publicación
Ana Arabolaza has a Master in Biotechnology from the Faculty of Biochemical and Pharmaceutical Sciences (FBIOyF) of the National University of Rosario (UNR). She completed her PhD in Biological Sciences (UNR) at the Institute of Molecular and Cellular Biology of Rosario (IBR), under the direction of Dr. Hugo Gramajo. During this period, she carried out research internships at the University of California – Irvine, United States and at Swansea University, Wales. Afterwards, she carried out a short-term research stay at SYNBIOCHEM (Manchester Synthetic Biology Research Centre for Fine and Speciality Chemicals) based in the Manchester Institute of Biotechnology (MIB)- University of Manchester – England, enjoying a scholarship from that University (Flexible Talent Mobility Account (FTMA2) MIB‐ SYNBIOCHEM). She is currently an Independent Researcher at CONICET, Teacher-Assistant in Charge of Assignments in the Microbiology area at FBIOyF and Project Director at IBR. Her research is focused on the study of the lipid metabolism of oleaginous bacteria and in Metabolic Engineering of model microorganisms for the production of novel oleochemicals.
ORCID 0000-0003-2347-8691
https://www.scopus.com/authid/detail.uri?authorId=6504363149
Dr. Cecilia Mansilla is a Biochemist graduated from the Faculty of Exact Sciences of the National University of La Plata (UNLP) and PhD from the Faculty of Biochemical and Pharmaceutical Sciences (FCByF) of the National University of Rosario, under the direction of Dr. Diego de Mendoza. She carried out research stays at the Scripps Institute, La Jolla (USA); Center for Biological Research, CSIC, Madrid (Spain); Charles University, Prague (Czech Republic); Pasteur Institute Structural Biology Unit, Paris (France) and Massachusetts General Hospital, Boston (USA). She is currently an Independent Researcher at CONICET and Project Director in the Microbial Physiology Group. She is an Associate Professor of Microbiology at the FCByF. Dr. Mansilla studies protein lipoylation and lipid synthesis as targets for new antibacterial and antiparasitic agents. For her doctoral thesis work she has received the “Dr. Enrique Herrero Ducloux” Award from the Argentine Chemical Association. Dr. Mansilla has received scholarships from the International Center for Genetic Engineering and Biotechnology; the Argentine-Brazilian Center for Biotechnology; the Howard Hughes Medical Institute; the ASM International Scholarship; the Fulbright -Ministry of Education of the Nation Scholarship, and has been a beneficiary of the Help Program for trips abroad “AVE” of the UNR.
orcid.org/0000-0002-1444-8661
Scopus Author ID: 6603112945
Tw @CeciliaMV67
Ig ceciliamansilla67
Lautaro Diacovich have a master in Biotechnology from the Facultad de Ciencias Bioquímicas y Farmacéuticas (FBIOyF) of the National University of Rosario (UNR). He finished his PhD. in the Instituto de Biología Molecular y Celular de Rosario (IBR), under the direction of Dr. Hugo Gramajo. During this period, he performed internships of investigation at the Universities of Stanford and Irvine, California, US. Then he completed a post-doctoral training at the Centre d’Immunologie de Marseille-Luminy, France. Actually, he is an Independent Research Investigator at CONICET, Teacher-Assistant in Charge of Assignments (JTP) in the Microbiology Department of FBIOyF, and Project Leader at IBR. His research is focused in the study of primary metabolism of pathogenic bacteria and in the interaction with the cell host, using different models, including Mycobacterium tuberculosis, Salmonella, Xanthomonas and Acinetobacter. He has received the EMBO post-doctoral fellowship.
ORCID 0000-0002-3339-0100
https://www.linkedin.com/in/lautaro-diacovich-6a29525/
https://www.scopus.com/authid/detail.uri?authorId=6507223397
María Inés Zanor is a biochemist, graduated from the Faculty of Biochemical and Pharmaceutical Sciences, National University of Rosario. She completed her postgraduate work at the Max Planck Institute for Molecular Plant Physiology in Golm-Postdam, Germany obtaining the Dr. title at the Faculty of Biochemical and Pharmaceutical Sciences, National University of Rosario. She continued in Germany where she also was engaged in two postdocs. She is an Independent Researcher at CONICET, and responsible for the Molecular Physiology of Crops line. The research of its line focuses on the characterization of proteins with unknown functions that participate in processes related to stress and growth, thus contributing to the identification of new strategies to increase stress tolerance and productivity of crops of agronomic interest. The line of work has identified a transcription factor that acts as a node in metabolic reprogramming, resulting in plants that are more tolerant to stress and have greater productivity. In the laboratory, direct and reverse genetic methods, biochemical and physiological studies are used and the behavior of plants is studied in optimal growth conditions and under environmental stress. Post-genomics techniques such as transcriptomics, proteomics and metabolomics are also used.
Directed Project:
Molecular physiology of crops
Achieving higher production goals to adequately feed the growing world population in quality and quantity is a challenge that involves expanding the region of arable areas and facing climate change. Furthermore, the urgent need to increase food production worldwide is associated with improving food quality. Plants, as sessile organisms, are continually challenged by multiple factors such as environmental stress that generates a negative impact on most relevant crops worldwide. It is estimated that the global economic losses associated with the reduction of growth and biomass production are in the order of billions of dollars, so the identification of the molecular mechanisms by which plants respond to environmental stress is essential to develop strategies of resistance. To increase productivity, it is important to correctly identify the molecular mechanisms that limit it in situations of environmental stress. Although in recent decades much progress has been made in the knowledge of numerous physiological, metabolic processes and molecular mechanisms related to responses to environmental stress in plants, there are still many unidentified components related to productivity and the response to stress, especially in agronomically important crops. The biochemical and physiological function of a large proportion of genes involved in responses to environmental stress is not yet determined. In this context, the study of proteins with unknown function is crucial to understand their participation in the gene activation chain in stress situations. Today, genomic and post-genomic tools are available to address these studies on a global scale and contribute to designing strategies to detect new key components related to the integration of environmental stress and plant growth programs.
Characterization of genes of unknown function related to plant productivity in unfavorable environments
It is estimated that between 20 and 40% of the genes present in sequenced eukaryotic organisms are proteins with no assigned function. The assignment of functions to a protein is based on the presence of detectable similarity between its sequence and that of functionally characterized proteins. However, even though a functional category can be assigned to a protein based on sequence homologies (for example: phosphatase, kinase, transcription factor), its biochemical and physiological function is partially or totally unknown. In the model organism Arabidopsis, about 5000 genes belong to this category and it is estimated that many of these proteins could be included in currently known metabolic pathways or gene networks. Consequently, since the role of many genes is not yet well established, it is of vital importance to characterize proteins with unknown functions in order to assign their location and roles in the gene activation chain in stress situations. Therefore, the project proposes to study the role in stress tolerance of a group of selected genes for which their functions are not yet established.
Comparative studies of gene expression after environmental stress in crops such as soybean, tomato and, Arabidopsis thaliana leaves demonstrated that although there are differences, many genes of both species are induced or repressed in a similar way. This suggests that these species have conserved response mechanisms. This observation allows us to think about transferring scientific results obtained using model plants to crops that can meet the growing demand for food.
Functional analysis of plant metabolism from a systems biology perspective
The main objective of this line of research is to understand the mechanisms of regulation of the metabolism of compounds that confer quality to species of horticultural interest using the tomato plant (Solanum lycopersicum) as a model. The tomatoes consumed in Argentina are of low organoleptic and nutritional quality, since they have been selected for other attributes such as size, shape and good post-harvest behavior for better marketing. However, consumers are increasingly demanding tomato fruits that have greater and better flavor and are high in vitamin compounds and antioxidants. This line of work aims to identify and evaluate the interaction of the metabolic constituents of a food such as tomatoes and human health to understand how the presence of bioactive compounds in a food is associated with diseases related to certain lifestyles. This type of study, whose approach is innovative and multidisciplinary, is key to the development of the nutraceutical products market, which has experienced maximum growth during the last decade and is estimated at 117 billion dollars worldwide.
Directed Human Resources:
Postdoctoral Fellows
PhD Students
Gabriela Gago has a degree in Biotechnology from the Faculty of Biochemical and Pharmaceutical Sciences (FCByF) of the UNR, she completed her PhD in the Molecular Biology Area of the same Faculty under the supervision of Dr. Raquel Chan and Dr. Daniel Gonzalez. He carried out postdoctoral research at the IBR under the supervision of Hugo Gramajo and at the Global Health Institute in Lausanne (Switzerland) under the supervision of Stewart Cole. She is currently an Independent Researcher at CONICET and Associate Professor of Molecular Biology at FCByF. She works in the Physiology and Genetics of Actinomycetes group, where she leads studies related to the characterization of enzymes involved in lipid synthesis and their regulation in Mycobacterium tuberculosis, particularly those involved in the synthesis of phospholipids and triacylglycerides and in the communication of the two fatty acid synthase systems present in this pathogen.
Twitter: @GabrielaGago4 IG: @gabriela_gago
Orcid
Scopus
Directed Project:
Characterization of essential proteins for the coordination of Mycobacterium tuberculosis cell envelope synthesis during Infection
The aim of this research line is to provide information about the mechanisms that allow M. tuberculosis to adapt the expression of its cell envelope components in response to the environmental changes encountered in the host during infection. We aim to characterize the physiological role of FabH during infection, a key enzyme in the synthesis of mycolic acids. The synthesis pathways of phospholipids and TAGs are coordinated and share common enzymes and substrates, being phosphatidic acid (PA) a key intermediate. Enzymes involved in PA synthesis have not yet been characterized in mycobacteria, and therefore, we propose to elucidate these essential enzymatic steps for membrane biosynthesis. The analysis of the results will provide tools to understand how lipid synthesis is coordinated in M. tuberculosis and its role during infection, potentially offering new targets for the design of new antimycobacterial compounds.
Directed Human Resources:
PhD Students
Publicaciones:
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Crotta Asis A, et al Characterization of key enzymes involved in triacylglycerol biosynthesis in mycobacteria. 2021 Scientific Reports | Ver Publicación
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Mondino S, et al FasR Regulates Fatty Acid Biosynthesis and Is Essential for Virulence of Mycobacterium tuberculosis. 2020 Frontiers in Microbiology | Ver Publicación
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Gago G, Diacovich L, Gramajo H. Lipid metabolism and its implication in mycobacteria-host interaction.. 2017 "Curr Opin Microbiol. 2017 Nov 27;41:36-42. doi: 10.1016/j.mib.2017.11.020. [Epub ahead of print] Review.
PMID: 29190491"
| Ver Publicación
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Lara, J, et al Mycobacterium tuberculosis FasR senses long fatty acyl-CoA through a tunnel and a hydrophobic transmission spine. 2020 Nature Communications | Ver Publicación
Susana Checa has a Master in Science degree from the Faculty of Biochemical and Pharmaceutical Sciences (FCByF) of the National University of Rosario, Argentina; she completed her PhD at the PROMUBIE (Multidisciplinary Experimental Biology Program) of the same Faculty, under the direction of Dr. Alejandro Viale. She carried out three post-doctoral research stays in the different dependencies of the IBR (CONICET-UNR) and the Department of Microbiology of the FCByF. She is currently an Independent Researcher at CONICET, and a member of the Laboratory of Signal Transduction in Pathogenic Bacteria. She is also Professor of the Microbiology Department of the FCByF. She is director of the project: Design of bacterial biosensors of heavy metals and strategies for their bioremediation. Within the framework of this project, she studies at the molecular level metal stress signaling/response systems and their manipulation to generate efficient biotechnological tools to detect, quantify and/or bioremediate metals using bacteria. She also actively collaborates in the other projects carried out in her laboratory, particularly in the molecular and functional analysis of resistance to transition metals in Salmonella enterica and its role in pathogenesis.
https://www.linkedin.com/in/susana-checa-353205116/
https://scholar.google.com.ar/citations?user=ivZ3makAAAAJ&hl=es&oi=ao
https://orcid.org/my-orcid?orcid=0000-0003-1629-2848
https://www.scopus.com/authid/detail.uri?authorId=6603353057
Twitter: @SusanaCheca1
IG: susana.checa.3
FB: Susana Checa
Directed Project:
DESIGN OF BACTERIAL BIOSENSORS FOR HEAVY METALS AND BIOTECHNOLOGICAL TOOLS FOR THEIR REMOVAL
Toxic metals such as mercury (Hg), lead (Pb) and cadmium (Cd) are disseminated in the environment as a result of human activities and improper waste disposal. These highly persistent pollutants cause severe pathologies and damage the ecosystem. Existing monitoring and removal methods are complex, expensive and/or unfriendly to the environment. Bacteria have mechanisms to detect and respond to these contaminants. My group studies these mechanisms and uses or modifies them on demand in order to develop simple and economical biotechnological detection/removal tools. Through genetic engineering and synthetic biology strategies we have obtained efficient and sensitive bacterial biosensors to detect and quantify the main metal contaminants. We are currently working on improving some of these tools and adding new capabilities such as removal or the detection of organometallic compounds.
Directed Human Resources:
PhD Students
Undergraduate Students
Publicaciones:
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Andrea A E Méndez, Julián I Mendoza, María Laura Echarren, Ignacio Terán , Susana K Checa, Fernando C Soncini
Evolution of Copper Homeostasis and Virulence in Salmonella. 2022 Frontiers in Microbiology
| Ver Publicación
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Andrea A. E. Méndez , José M. Argüello, Fernando C. Soncini & Susana K. Checa Scs system links copper and redox homeostasis in bacterial pathogens. 2024 Journal of Biological Chemistry | Ver Publicación
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Gonzalo Tulin, Nicolás R. Figueroa, Susana K. Checa, Fernando C. Soncini The multifarious MerR family of transcriptional regulators. 2023 Molecular Microbiology | Ver Publicación
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Julián I. Mendoza,Julián Lescano,Fernando C. Soncini,Susana K. Checa The protein scaffold calibrates metal specificity and activation in MerR sensors. 2022 Microbial Biotechnology | Ver Publicación
Víctor Blancato has a degree in Biotechnology from the Faculty of Biochemistry and Biological Sciences of the National University of Litoral; he completed his Ph.D. in Biological Sciences from the Faculty of Biochemical and Pharmaceutical Sciences (FBIOyF) of the National University of Rosario at the Institute of Cellular and Molecular Biology of Rosario under the direction of Dr. Christian Magni. He did research stays at the University of Groningen (The Netherlands), at the MICALIS laboratory (INRA-AgroParisTech, France), at the University of Florida (USA), and at the University of Caen Normandy (France). He is currently a teacher of Practical Works at FBIOyF and is independent researcher of CONICET, working as Project Director in the Laboratory of physiology and genetics of lactic acid bacteria (IBR). He participated in the development of lactic acid bacteria for the production of biopharmaceuticals and vaccines. He applies genomics and metagenomics techniques to evaluate the impact of using lactic acid bacteria producing recombinant enzymes as a technology to supplement or inoculate silage for livestock nutrition. In addition, through a bioinformatics approach, selects probable virulence factors of microorganisms present in food to: perform comparative virulence analysis using the insect Galleria mellonella as a model; and study the virulence and regulation mechanisms involved.
Orcid
Scopus
Twitter: @VictorBlancato
Instagram: @victorsb14
Directed Project:
Applications of recombinant lactic acid bacteria in industrial processes. Development of technologies for animal nutrition
The general objective of this research line is to develop new biotechnological strategies to improve animal nutrition. The knowledge generated will facilitate the optimization of feed production processes and increase the efficiency of their utilization, leading to sustainable and environmentally friendly production. To achieve this, molecular biology, biochemistry, and high-throughput sequencing techniques are used to study the impact of enzymes produced by lactic acid bacteria (LAB) or recombinant LAB as technologies for supplementing or inoculating silage. LAB are commonly consumed by humans and used worldwide in producing and preserving fermented foods. In this context, we propose to explore the use of recombinant LAB to enhance the nutritional value of silage; and to assess the effects on the composition of the microbiota and its metabolic profile, as well as chemical changes occurring within the silage.
Directed Human Resources:
Dr. Binolfi got his PhD in Biological Sciences in 2010 at the Institute of Molecular and Cellular Biology of Rosario, Argentina. Immediately after, he moved to Berlin as a postdoctoral research associate at the Leibniz Institute of Molecular Pharmacology where he contributed to develop and implement high resolution NMR methodologies in live cells (In-cell NMR). After returning to Argentina, he earned a group leader position and formed an independent group at IBR-CONICET. There he applied innovative In-cell NMR techniques to answer biologically relevant questions, such as how the intracellular environment and changes therein, for instance those elicited by oxidative stress, impact the structure and function of proteins and other biomolecules. Dr. Binolfi is now actively pushing the frontiers in the field so as to develop new NMR methodologies in live animals and to steer structural biology studies towards genuine in vivo conditions. Dr. Binolfi contributions were published in high impact journals and have been recognized as milestones by experts in the field and by international news services. He has been invited to present his work in many countries around the world. He an Independent researcher of CONICET, Director of the Cellular-Structural Biology Lab at IBR-CONICET, a member of the Argentinian Platform of Structural Biology and Metabolomics (PLABEM) and vice-president of the Foundation of the Institute of Molecular and Cellular Biology of Rosario (Fundación IBR).
Scopus Author ID: 8727274100
ORCID: https://orcid.org/0000-0003-2374-0864
Google Scholar: https://scholar.google.com/citations?user=-IEaIw8AAAAJ&hl=en
Twitter: @Abinolfi
Daniela Gardiol is a Biochemist from the School of Biochemical and Pharmaceutical Sciences (FCByF) of the National University of Rosario. She obtained her PhD at the the Department of Microbiology under the supervision of Dr. Diego de Mendoza. She performed her postdoctoral studies at the Tumor Virology Laboratory of the International Center of Genetic Engineering and Biotechnology in Trieste, Italy. During this period, she specialized in molecular virology and fundamentally in viral oncogenesis. Currently she is Professor of the Virology Area of the FCByF and Researcher from CONICET and the Research Council of the UNR. She is the group leader of the Oncogenic Virus lab, which has been interested in viral carcinogenesis mechanisms related to cell polarity disruption. Currently, the studies have been extrapolated to other viruses of regional interest such as Flaviviruses, investigating different cytopathogenic mechanisms and virus-host cell interactions.
Link a Google Scholar https://scholar.google.com.ar/citations?hl=es&user=gFOejdcAAAAJ
Adriana Giri is a Biochemist graduated at the School of Biochemical and Pharmaceutical Sciences (FCByF) of the National University of Rosario (NUR). She carried out a Ph.D on Microbiological Sciences at the Human Retrovirus Lab of the Institute of Microbiology of the University of Genoa (Italy) under the direction of Dr. Oliviero Varnier. She performed post-doctoral stages at the National Institutes of Health (Bethesda, USA) and at the Center for Advanced Biotechnology (Genoa, Italy). She is currently an Independent Researcher at CONICET and Head of the Human Virology Group. She is an Associate Professor of Virology at the FCByF (NUR). She is co-founder of the technology-based company DETx MOL S.A. (https://www.detxmol.com.ar/) focused on the design and development of molecular kits for the diagnosis of human infectious diseases. She participates in the Argentine Interinstitutional SARS-CoV-2 Genomics Project (http://pais.qb.fcen.uba.ar/) as coordinator of Southern Santa Fe province. Her group studies the molecular epidemiology of viral infections in human and animal hosts according to the One Health initiative and develops technologies for the identification and diagnosis of novel DNA and RNA viruses that are of interest for health that include conventional molecular methods and metagenomic approaches.
https://www.scopus.com/authid/detail.uri?authorId=7102961247
@VirologyIBR
Rodolfo Rasia has a degree in Biotechnology and a PhD in Biological Sciences from the School of Biochemistry and Pharmacy of the National University of Rosario (FCByF-UNR). He obtained his Ph.D under the direction of Alejandro J. Vila. Later he did postdoctoral stays at the Max Planck Institute for Biophysical Chemistry (MPI-BPC) in Göttingen Germany, with Thomas Jovin, and at the Institute of Structural Biology (IBS) of Grenoble in France, with Jerôme Boisbouvier, specializing in NMR spectroscopy of biological macromolecules. Back in Argentina, he joined the Institute of Molecular and Cellular Biology of Rosario (IBR) as a researcher and the FCByF-UNR as professor of Biophysics. He currently leads the group of Biophysics of Molecular Recognition at the IBR. His scientific career was always centered around the physicochemical study of proteins and the application of different spectroscopic methods to understand their structure and function. His current work focuses on protein-mediated molecular recognition, both of different molecules (nucleic acids, small substrates) and of other proteins, and the order-disorder transitions that happen in these systems (induced folding, conformational stability).
https://scholar.google.com/citations?hl=en&user=TVbw0gMAAAAJ
https://orcid.org/0000-0003-3940-067X
https://www.scopus.com/authid/detail.uri?authorId=26028451300
Twitter: @FitoDeRosario; @bmr_ibr
Leticia I. Llarrull has a degree in Biotechnology from the School of Biochemical and Pharmaceutical Sciences (FCByF) of the National University of Rosario (UNR). She completed her doctorate in Biological Sciences in 2007 at the Institute of Molecular and Cell Biology of Rosario (IBR-CONICET-UNR), under the direction of Dr. Alejandro Vila. She received the Best Thesis Award 2008 by the Argentine Society of Biophysics. She carried out a postdoctoral stay (2007-2011) in the laboratory of Prof. Mobashery at the University of Notre Dame, Indiana, United States. In 2008, she was named a PEW Latinamerican Fellow in Biomedical Sciences. In 2013 she received the JCI TOYP Santa Fe Award, Category “Scientific and Technological Development” (Junior Chamber International, Santa Fe, Argentina) and in 2014 she received recognition from the Senate of the Argentine Nation for the discovery of a new class of antibiotic to combat resistant bacteria. She was a member of the Hygiene and Safety Committee (2012-2020), and of the IBR Board of Directors (2018-2021). She is currently an Independent Researcher at CONICET and directs the Laboratory of Bacterial Sensors at IBR. She is also Director of the Doctoral Program in Biological Sciences at the FCByF (UNR) and Associate Professor in the Biophysics Area of the FCByF (UNR). Since 2018 she is a member of the Argentine Regional Committee of the PEW Fellows Program, The PEW Charitable Trusts.
https://orcid.org/0000-0002-5679-4343
linkedin.com/in/leticia-llarrull-aa8451115
Anabella Lodeyro has a degree in Biotechnology from the Faculty of Biochemical and Pharmaceutical Sciences (FCByF) of the National University of Rosario; she have obtained her PhD degree in the Biophysics Area of the same Faculty under the direction of Dr. Oscar Roveri. She conducted research courses at national and international universities. She completed her Post-Doctoral studies at the Institute of Molecular and Cellular Biology of Rosario (IBR-CONICET-UNR), under the direction of Dr. Néstor Carrillo. She is currently an Independent Researcher from CONICET and works in the Group of Biochemistry of stress in plants. She is a professor of the Biophysics Area from the FCByF. Her group studies how the redox state in plants regulates biological processes like foliar development and responses to abiotic (especially salinity, drought and oxidants) and biotic (pathogens) stress.
She is director of the project “Redox biochemistry of chloroplast in foliar development”
Scopus Author ID: 8520605000, https://orcid.org/0000-0001-9208-2194
@ana_lodeyro
Claudia Banchio is a Biochemist graduated from the Faculty of Biochemical and Pharmaceutical Sciences (FCByF) of the National University of Rosario. She completed her phD at the Institute of Molecular and Cellular Biology of Rosario (IBR) of the same Faculty, under the direction of Dr. Hugo Gramajo. She did a post-doctoral research stay at the University of Alberta, Edmonton, Canada under the direction of Dr. Dennis Vance. She is currently an Independent Researcher at CONICET, and head of the Molecular and Cellular Biology of Lipids Group. She is a Professor of Biology at the FCByF. Her group studies the role of lipids in regulation, signaling and cellular repair processes of the nervous system in different physiological and pathological scenarios.
ORCID 0000-0002-5234-7212
Julia A. Cricco has a degree in Biotechnology from the Facultad de Ciencias Bioquímicas y Farmacéuticas (FCByF) of the Universidad Nacional de Rosario (UNR); She completed her Ph.D. at the same faculty, under the advisoring of professor Alejandro J. Vila. She carried out postdoctoral research stays at the University of Utah (USA) and at the University of São Paulo (Brazil). She is currently an Independent Researcher at CONICET and is a professor of Biophysics at the FCByF. She is the director of the laboratory that studies heme and copper transport mechanisms and homeostasis in Trypanosoma cruzi.
https://www.researchgate.net/profile/Julia-Cricco
https://scholar.google.com/citations?user=sFnNN58AAAAJ&hl=en
twitter: @Juli_Cricco
IG: juliacricco
FC: Julia Cricco
Daniela Albanesi received a Ph. D. in Biological Sciences in March 2006 from the National University of Rosario, Argentina. She got training in crystallogenesis and X-ray protein crystallography during two consecutive short-term visits (2004 and 2005) and a postdoctorate (2006-2008) at the Unit of Structural Biochemistry (nowadays, the Unit of Structural Microbiology) of the Pasteur Institute, Paris, France (2006-2008). Since 2009, she is a Career Investigator from the Research Council of Argentina (CONICET) where she holds the Independent Researcher category since 2016. She is the head at the Molecular Microbiology Laboratory at the IBR in Rosario, Argentina and she is also permanent staff of the Platform of Structural Biology and Metabolomics of Argentina (PLABEM). At present, her projects focus on the study of the mechanisms underlying the control of membrane homeostasis and cell envelope biogenesis in Gram-positive bacteria. Since 2001, she is a teaching assistant at the National University of Rosario, Argentina.
https://orcid.org/0000-0003-4380-9152
https://www.scopus.com/authid/detail.uri?authorId=6506924553
IG: @daniela_albanesi
TW @AlbanesiDaniela
Gabriela Coux has a degree in Biotechnology from the Faculty of Biochemical and Pharmaceutical Sciences (FCByF) of the National University of Rosario (UNR). She completed her PhD at the Institute of Experimental Physiology (IFISE) of the same Faculty, under the direction of Dr. María Mónica Elías. She did her postdoctoral studies at the IBR under the direction of Dr. Marcelo Cabada, and post-doctoral research stays at the University of Massachusetts, USA. She is an Associate Professor of Biophysics at FCByF-UNR. She is currently an Independent Researcher at CONICET, and Director of the project Regulation of genes controlling craniofacial morphogenesis. Her group studies the molecular mechanisms of embryonic craniofacial development, both under physiological and pathological circumstances.
Bioinformatics, biophysics, biochemistry, microscopy & molecular biology are the group’s favorite tools. And the zebrafish is the protagonist of these studies.
https://www.conicet.gov.ar/new_scp/detalle.php?id=31158&keywords=coux&datos_academicos=yes
https://www.researchgate.net/profile/Gabriela-Coux
Twitter: @gcoux