• Picture of Prof. Mordechai Ben-Ari

    Prof. Mordechai Ben-Ari

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    Teaching and learning computer science
    Collaboration with:  Francesco Mondada, Ecole Polytechnique Federale de Lausanne
    Educational robotics
    Matriculation examinations in mathematics

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  • Picture of Dr. Haim Beidenkopf

    Dr. Haim Beidenkopf

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    Topological electronic phases
    Weyl/Dirac topological semimetals
    Strong/Weak/Crystalline/Higher-order topological insulators
    Topological superconductivity and Majorana modes
    Topological nano-devices
    Scanning tunneling microscopy and spectroscopy
    Molecular beam epitaxy

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  • Picture of Prof. Ed Bayer

    Prof. Ed Bayer

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    Structural and functional aspects of the multi-enzyme cellulosome complex from cellulose-degrading bacteria.
    Collaboration with:  Raphael Lamed, Tel Aviv University Yuval Shoham, Technion, Haifa Itzhak Mizrahi, Ben-Gurion University, Beer Sheva Oded Livnah, Hebrew University of Jerusalem Yitzhak Hadar, Hebrew University of Jerusalem Shi-You Ding, Michigan State University Nicole Koropatkin and Eric Martens, University of Michigan Rafael Bernardi, Auburn University Hermann Gaub, Ludwig Maximilian University Don C. Lamb, Ludwig Maximilian University Bryan White, University of Illinois Klaus Schulten, University of Illinois Bernard Henrissat, Marseille Mirjam Czjzek, Rostok, France Yingang Feng, Ya-Jun Liu and Qiu Cui, Qingdao, China Yannick Bomble, Martin Keller and Michael Himmel, NREL, Golden CO Victor De Lorenzo, Madrid Mariano Carrión-Vázquez, Spanish National Research Council Carlos Fonts, University of Lisbon Marek Cieplak, Polish Academy of Sciences Damien Thompson, University of Limerick Henri-Pierre Fierobe, CNRS, Marseille Harry Flint, University of Aberdeen Harry Gilbert, Newcastle University Gideon Davies, York University Dimitris Hatzinikolaou, University of Athens
    The cohesin-dockerin couple - Protein-protein interactions that mediate recognition and specificity in cellulosome assembly.
    Cellulose-binding domains as models for protein-sugar interactions.
    Bioinformatics of cellulases and cellulosome components
    Comparative genomics of cellulosome components.
    Structure determination of cellulosome components.
    Enzymology of cellulosomes for conversion of biomass to biofuels
    Designer cellulosomes - Selective engineering of chimaeric cellulosome constructs for nanotechnology.
    Avidin-biotin system - Mutated avidins and streptavidins

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  • Picture of Prof. Naama Barkai

    Prof. Naama Barkai

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    Systems Biology: gene circuits; epigenetics; biological specificity; protein intrinsic disorder.

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  • Picture of Prof. Roy Bar-Ziv

    Prof. Roy Bar-Ziv

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    Artificial biochemical circuits
    Cell-free gene expression on a chip
    Cell-free expression of protein nano-structures
    Autonomous interrogation of the state of a living cell
    The physics of microfluidic crystals

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  • Picture of Prof. Mario D. Bachi

    Prof. Mario D. Bachi

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    Organic synthesis through free radical reactions.
    Synthesis of Yingzhaosu A and related antimalarial drug candidates.
    Stereocontrol through Sulfur-Mediated Temporary Intramolecularization of Reactions.

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  • Picture of Dr. Avraham Roi

    Dr. Avraham Roi

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    The lab of host-pathogen genomics is interested in how individual encounters between host and pathogenic bacteria can ultimately define the outcome of infection. This is achieved by applying cross-disciplinary single-cell analysis platforms that collectively enable us to extensively profile and precisely monitor host-pathogen interactions within the context of in vivo infections.
    The work in the lab centers on salmonella infection of mouse macrophages as a tractable in vitro host-pathogen system. We use this model to develop state of the art high throughput genomic tools and interdisciplinary approaches, and then apply them to various in vivo infection models to address critical biological aspects of host-pathogen biology.
    Using comprehensive, quantitative, unbiased tools to analyse the molecular interactions that underlie distinct host-pathogen subpopulations and their impact on disease outcome.
    Using a powerful combination of cutting-edge single cell genetic and genomic approaches, we wish to address what forms the basis for successful immune clearance, from the level of individual infected cells to that of the whole organism, and why, in some cases, sterilization is incomplete?

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  • Picture of Dr. Ori Avinoam

    Dr. Ori Avinoam

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    Membrane remodeling during differentiation and fusion of vertebrate skeletal muscles
    Collaboration with: 
    Spatial and temporal organization of the molecular machines driving cell-to-cell fusion
    Maintenance of Membrane homeostasis during cell fusion
    Mechanisms of ER remodeling during cell fusion
    Exocytosis of Large Secretory Vesicles (LSVs)
    Collaboration with:  Prof. Benny Shilo
    Spatial and temporal organization of the molecular machines driving exocytosis of LSVs.
    The lipid and protein composition and function of the fusion pore
    Pre-organization of the vesicular membrane
    Maintenance of Membrane homeostasis during secretion
    The fusion mechanism of extracellular vesicles and viruses
    Collaboration with: 
    The fusion mechanism of extracellular vesicles
    Identification of Pan Coronavirus fusion inhibitors
    Development of correlative light and electron microcopy methods

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  • Picture of Prof. Ilya Averbukh

    Prof. Ilya Averbukh

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    Manipulation of atoms and molecules by laser fields
    Laser control of molecular alignment and orientation. Control of chiral molecules
    Echo phenomenon
    Atomic and molecular wave packets, ultra-fast optical phenomena.

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