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December 01, 2013
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Date:27MondayFebruary 2017Colloquia
"Molecular chaperones in action"
More information Time 11:00 - 12:15Location Gerhard M.J. Schmidt Lecture HallLecturer Prof. Charalampos (Babis) Kalodimos
Biochemistry, Molecular Biology & Biophysics, University of MinnesotaOrganizer Faculty of ChemistryContact -
Date:27MondayFebruary 2017Lecture
Lessons learned from membrane protein interactions
More information Time 11:15 - 11:15Location Ullmann Building of Life SciencesLecturer Dr. Oksana Shlyk
Lab of Prof. Avigdor Scherz, Dept. of Plant and Environmental SciencesOrganizer Department of Plant and Environmental SciencesContact -
Date:27MondayFebruary 2017Lecture
Magnetic Resonance Seminar
More information Time 15:00 - 15:00Title Engineering spin relaxation with cavitiesLocation Gerhard M.J. Schmidt Lecture HallLecturer Prof. John Morton
University College LondonOrganizer Department of Chemical and Biological PhysicsContact -
Date:28TuesdayFebruary 2017Lecture
G-INCPM-Special Seminar - Dr. Bruce Lefker, Medicinal Chemistry Specialist, Visiting Scientist, Pfizer - "Validation of Novel Biological Targets: A Medicinal Chemist's View
More information Time 11:00 - 12:15Location Nancy and Stephen Grand Israel National Center for Personalized MedicineLecturer Dr. Bruce Lefker Organizer Faculty of BiochemistryContact Abstract Show full text abstract about Validation of hypotheses is an essential part of the scienti...» Validation of hypotheses is an essential part of the scientific process. To validate novel biological targets, a range of powerful biological approaches have emerged and are being leveraged (eg CRISPR, siRNA, antisense, antibodies, etc). In addition to these biological approaches, small molecule “chemical probes” have proven to be an extremely valuable orthogonal approach for validation. Also, successful generation of a small molecule chemical probe increases the confidence that a target is druggable, and can enable demonstration of therapeutically useful effects in animal models and ultimately humans. Of note to this audience is that the majority of new biological targets that led to novel medicines were discovered in academia.
The G-INCPM at the Weizmann has established a drug discovery unit which can screen large collections of small molecules against novel biological targets or phenotypes in whole cells. A medicinal chemistry capability has recently been added to the Institute with the goal of increasing the value that will be derived from these ongoing screening efforts. The newly formed Medicinal Chemistry Unit is working closely with Biologists (at the Weizmann and other Institutes in Israel), and the High Throughput Screening Unit to interpret the output from screens, triage the output, and then optimize the most attractive hit matter. This lecture will present a definition of a “chemical probe” and our rationale for generating chemical probes. We will also discuss some of the common pitfalls in following up HTS hits, and the approaches being utilized to generate quality probes from screening campaigns.
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Date:28TuesdayFebruary 2017Lecture
Size asymmetric competition and plant communities along resource gradients
More information Time 11:15 - 11:15Location Ullmann Building of Life SciencesLecturer Niv Demalach
Department of Ecology, Evolution and Behavior, The Hebrew University of JerusalemOrganizer Department of Plant and Environmental SciencesContact Abstract Show full text abstract about My research focuses on the effects of interspecific competit...» My research focuses on the effects of interspecific competition on diversity and composition of herbaceous plant communities I developed a theoretical model that incorporates size-asymmetric competition into the classical resource competition model of Tilman (1982). The model shows that size-asymmetric light competition is a necessary and sufficient condition for explaining species loss under high levels of soil resources. The model’s predictions were tested in a Mediterranean annual community. For this purpose I developed a novel method for quantifying the size-asymmetry of light partitioning under field conditions. The experimental results were fully consistent with the predictions of the theoretical model. In addition I analyzed global scale data for testing the applicability of my models in various ecosystems. The results of the analysis provide further support for my theoretical and experimental findings. -
Date:28TuesdayFebruary 2017Lecture
"Systemic Ig Light-Chain Amyloidosis: Molecular Basis of Assembly."
More information Time 14:00 - 15:00Location Helen and Milton A. Kimmelman BuildingLecturer Dr. Boris Brumshtein
Dept. Chemistry and Biochemistry UCLAOrganizer Department of Chemical and Structural BiologyContact -
Date:01WednesdayMarch 2017Lecture
AMO Special Seminar
More information Time 13:15 - 14:15Title Attosecond charge transport in atoms and condensed matterLocation Edna and K.B. Weissman Building of Physical SciencesLecturer Prof. Ursula Keller
ETHOrganizer Department of Physics of Complex SystemsContact Abstract Show full text abstract about The basic motivation for our work is to understand how charg...» The basic motivation for our work is to understand how charge is transported on an atomic spatial and attosecond time scale. Strong-field ionization in the dipole approximation (i.e. tunnel ionization) is much faster than the group delay of the electron wavepacket (i.e. Wigner delay), whereas photoemission from atoms can typically be described by the Wigner delay - but not in all cases. For example autoionization resonances in the continuum can change the ionization delay. Moving to condensed matter we have investigated the escape time of photoemitted electrons from metal surfaces such as Ag, Au and Cu. We want to address the question about the correct escape velocity of the electons and their ability to “feel” the periodic crystal potential on a attosecond time and an atomic length scale. Our most recent experiment can confirm an upper limit of around 300 attosecond over a distance less than 2 atomic layers during which an electron can assume its effective mass. Furthermore femtosecond charge transport modulation driven by a transient electric field in the petahertz regime have been observed in diamond and can be explained by the dynamical Kranz Keldysh effect (DFKE). State-of-the-art numerical calculations reveal that only a small number of transitions give rise to the observed effects and that the more classical intra-band transitions dominate the response over inter-band transitions. -
Date:02ThursdayMarch 2017Lecture
The Impact of Ploidy on Adaptation
More information Time 10:00 - 10:00Location Arthur and Rochelle Belfer Building for Biomedical ResearchLecturer Dr. Anna Selmecki
Assistant Professor Department of Medical Microbiology and Immunology Creighton University Medical SchoolOrganizer Department of Molecular GeneticsContact -
Date:02ThursdayMarch 2017Colloquia
Nonlinear phononics: coherent control of the crystal lattice and of the collective properties of solids
More information Time 11:15 - 12:30Location Edna and K.B. Weissman Building of Physical SciencesLecturer Andrea Cavaliery
Max Planck GesellschaftOrganizer Faculty of PhysicsContact Abstract Show full text abstract about In this talk, I will discuss how coherent electromagnetic ra...» In this talk, I will discuss how coherent electromagnetic radiation at infrared and TeraHerz frequencies can be used to coherently rearrange atoms within the crystal lattice of a solid. The motion of atoms is large, and energy flows between different modes of the crystal. Such nonlinear phononics allows for the control of metal insulator transitions, magnetic phenomena, superconductivity and ferroelectricity.
I will also discuss how femtosecond x-ray beams from free electron lasers are integral to these studies, and are used to image structures during these non-equilibrium processes.
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Date:02ThursdayMarch 2017Lecture
Neuronal ensembles: emergent motifs of cortical function?
More information Time 11:30 - 11:30Location Gerhard M.J. Schmidt Lecture HallLecturer Prof. Rafael Yuste
Dept of Biological Sciences, Columbia University, NYOrganizer Department of Brain SciencesContact -
Date:02ThursdayMarch 2017Lecture
Cortical spike multiplexing using gamma frequency latencies
More information Time 12:45 - 12:45Location Gerhard M.J. Schmidt Lecture HallLecturer Prof. Dana H. Ballard
Dept of Computer Sciences, University of Texas at AustinOrganizer Department of Brain SciencesContact -
Date:02ThursdayMarch 2017Lecture
AMO Special Seminar
More information Time 14:00 - 15:30Location Edna and K.B. Weissman Building of Physical SciencesLecturer Dr. Tracy Northup
Universtität InnsbruckOrganizer Department of Physics of Complex SystemsContact -
Date:05SundayMarch 2017Lecture
Science and Clinical Orthopedics
More information Time 08:30 - 12:00Location Arthur and Rochelle Belfer Building for Biomedical ResearchLecturer Prof. Benjamin Alman, Keynote speaker
Duke UniversityOrganizer Department of Molecular GeneticsContact -
Date:05SundayMarch 2017Lecture
Sandbox- a Playground for Genomic Research and Science Innovation
More information Time 09:00 - 10:00Location Gerhard M.J. Schmidt Lecture HallLecturer Dr. Hadas Keren-Shaul
Life Science Core FacilitiesOrganizer Department of Life Sciences Core FacilitiesContact -
Date:05SundayMarch 2017Lecture
Chemical Physics Department Guest Seminar
More information Time 11:00 - 11:00Title TEERs for DEERs - advanced spectroscopy of correlated spins in molecules using a single spin sensorLocation Gerhard M.J. Schmidt Lecture HallLecturer Dr. Amit Finkler
University of StuttgartOrganizer Department of Chemical and Biological PhysicsContact Abstract Show full text abstract about Defects in the solid state are potentially suitable candidat...» Defects in the solid state are potentially suitable candidates for nanoscale sensing and imaging. Among these, the nitrogen-vacancy (NV) center in diamond has gained wide publicity due to its long coherence time, stability and wide temperature and frequency ranges of operation. With recent reports on the sensing of electron and nuclear spins from single proteins, we attempt to go one step further to the realm of correlated spins. I will present measurements of electron spins in spin-labeled molecules both at room temperature and at low temperature. I will show that it is possible to detect the dipolar coupling between two spin labels in a doubly-labeled peptide using a scheme we call "triple electron-electron resonance". This is a necessary step towards sensing of spins in correlated-electrons
systems. Together with quantum-assisted schemes and improvements in signal readout, I will offer methods with which we can tackle challenges in chemical physics, laying out a potential platform for a spin network.
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Date:05SundayMarch 2017Lecture
Seeing methanogens through computer simulations
More information Time 11:00 - 11:00Location Sussman Family Building for Environmental SciencesLecturer Qusheng Jin
Department of Earth Sciences University of OregonOrganizer Department of Earth and Planetary SciencesContact -
Date:05SundayMarch 2017Lecture
Personalized medicine for type 2 diabetes: Are we there?
More information Time 15:00 - 16:00Location Arthur and Rochelle Belfer Building for Biomedical ResearchLecturer Prof. Hilla Knobler
Institute of Diabetes, Endocrinology & Metabolism, Kaplan Medical Centre, Hebrew University School of MedicineContact -
Date:05SundayMarch 2017Lecture
Molecular Neuroscience Forum Seminar
More information Time 15:00 - 16:00Title Neurotrophic factor signaling in cerebellar developmentLocation Wolfson Building for Biological ResearchLecturer Carlos Ibanez
Weston Visiting Professor, Weizmann Institute of Science Department of Neuroscience Karolinska Institute Stockholm, SwedenOrganizer Department of Biomolecular SciencesHomepage Contact -
Date:06MondayMarch 2017Colloquia
"Surface studies and matter wave optics experiments with neutral helium beams"
More information Time 11:00 - 12:15Location Gerhard M.J. Schmidt Lecture HallLecturer Prof. Bodil Holst
University of BergenOrganizer Faculty of ChemistryContact -
Date:06MondayMarch 2017Lecture
Metabolic regulation of normal and leukaemia stem cells: the role of reactive oxygen species, mitochondria transfer and nitric oxide
More information Time 14:00 - 15:00Title Cancer Research ClubLocation Max and Lillian Candiotty BuildingLecturer Prof. Tsvee Lapidot
Dept. of Immunology, Weizmann InstituteOrganizer Department of Immunology and Regenerative BiologyContact Abstract Show full text abstract about Bone marrow (BM) retained blood forming stem cells are prote...» Bone marrow (BM) retained blood forming stem cells are protected from DNA damaging agents including chemotherapy to prevent lethal infections and hematology failure. Stem cell chemotherapy resistance, requires dynamic interactions with BM stromal and endothelial cells and involves metabolic regulation of ROS, mitochondria transfer, and inhibition of NO. Leukemic stem cells initiate and maintain the disease and are the major target for clinical chemotherapy treatment. These malignant stem cells also reside in the BM and their chemotherapy resistance can lead to lethal leukemia relapse. Metabolic regulation of normal and leukemic stem cells in the bone marrow will be discussed.