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Date:09MondayDecember 2019Lecture
The temporal structure of the code of large neural populations
More information Time 10:30Location Nella and Leon Benoziyo Building for Brain ResearchLecturer Ehud Karpas (PhD Thesis Defense)
Elad Schneidman Lab, Dept of Neurobiology, WISOrganizer Department of NeurobiologyContact Details Show full text description of Students & Postdocs Seminar Benoziyo Brain Research ...» Students & Postdocs Seminar
Benoziyo Brain Research Building Room 113
For assistance with accessibility issues, please contact naomi.moses@weizmann.ac.il
Abstract Show full text abstract about Studying the neural code deals with trying to understand how...» Studying the neural code deals with trying to understand how information is stored and processed in the brain, searching for basic principles of this "language". The study of population codes aims to understand how neural populations collectively encode information, and to map interactions between neurons. Previous studies explored the firing rates of single cells and how they evolve with time. Other studies have shown that neural populations are correlated and explored spatial activity patterns of large groups. In this work we combine these approaches, and study population activity of large groups of neurons, and how they evolve with time.
We studied the fine temporal structure of spiking patterns of groups of up to 100 simultaneously recorded units in the prefrontal cortex of monkeys performing a visual discrimination task. We characterized the population activity using 10 ms time bins and found that population activity patterns (codebooks) were strongly shaped by spatial correlations. Further, using a novel extension of models which describe spatio-temporal population activity patterns, we show that temporal sequences of population activity patterns have strong history-dependence. Together, the large impact of spatial and temporal correlations makes the observed sequences of activity patterns many orders of magnitude more likely to appear than predicted by models that ignore these correlations and rely only on the population rates.
Surprisingly, despite these strong correlations, decoding behavior using models that were trained ignoring these correlations perform as well as decoders that were trained to capture these correlations. The difference in the role of correlations in population encoding and decoding suggests that one of the goals of the complex encoding scheme in the prefrontal cortex may be to create a code that can be read by simple downstream decoders that do not have to learn correlations.
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Date:09MondayDecember 2019Colloquia
Principles of Protein Assembly in Cells
More information Time 11:00 - 12:15Location Gerhard M.J. Schmidt Lecture HallLecturer Dr. Emmanuel Levy
Dept. of Structural Biology, WISOrganizer Faculty of ChemistryContact -
Date:09MondayDecember 2019Lecture
Computer Science Seminar
More information Time 11:15 - 13:00Title Clustering: How hard is it to classify data?Location Jacob Ziskind Building
Room 155Lecturer Karthik C.S
Tel Aviv UniversityOrganizer Faculty of Mathematics and Computer Science
SeminarContact Details Show full text description of Two popular objectives optimized in clustering algorithms ar...» Two popular objectives optimized in clustering algorithms are k-means and k-median. The k-means (resp. k-median) problem in the L_p-metric is specified by n points as input and the goal is to classify the input point-set into k clusters such that the k-means (resp. k-median) objective is minimized. The best-known inapproximability factor in literature for these NP-hard problems in L_p-metrics were well-below 1.01. In this talk, we take a significant step to improve the hardness of approximating these problems in various L_p-metrics.
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Date:09MondayDecember 2019Lecture
Trapped on the ribosome: exploring the chemical biology of translational control
More information Time 14:00 - 15:00Location Gerhard M.J. Schmidt Lecture HallLecturer Prof. Jack Taunton
Dept. of Cellular and Molecular Pharmacology, University of California, San-FranciscoOrganizer Department of Structural BiologyContact -
Date:09MondayDecember 2019Lecture
A quantitative footprint of irreversibility in the absence of observable currents
More information Time 14:15Location Edna and K.B. Weissman Building of Physical Sciences
Room ALecturer Gili Bisker
TAUOrganizer Department of Physics of Complex Systems
Statistical Physics SeminarContact Abstract Show full text abstract about Time irreversibility is the hallmark of nonequilibrium dissi...» Time irreversibility is the hallmark of nonequilibrium dissipative processes. Detecting dissipation is essential for our basic understanding of the underlying physical mechanism, however, it remains a challenge in the absence of observable directed motion, flows, or fluxes. Additional difficulty arises in complex systems where many internal degrees of freedom are inaccessible to an external observer. In living systems, for example, the dissipation is directly related to the hydrolysis of fuel molecules such as adenosine triphosphate (ATP), whose consumption rate is difficult to directly measure in many experimental setups. In this talk, I will introduce a novel approach to detect time irreversibility and estimate the entropy production from time-series measurements, even in the absence of observable currents. This method can be implemented in scenarios where only partial information is available and thus provides a new tool for studying nonequilibrium phenomena.
1. G. Bisker et al. Inferring broken detailed balance in the absence of observable currents,
Nature Communications, 10(1), 1-10 (2019)
2. G. Bisker et al. Hierarchical Bounds on Entropy Production Inferred from Partial
Information, Journal of Statistical Mechanics: Theory and Experiment (9), 093210 (2017)
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Date:10TuesdayDecember 2019Lecture
Molecular errors and evolvability
More information Time 11:00 - 12:00Location Gerhard M.J. Schmidt Lecture HallLecturer Prof. Joanna Masel
Ecology and Evolutionary Biology, The University of Arizona, USAOrganizer Department of Structural BiologyContact -
Date:10TuesdayDecember 2019Lecture
Special Guest Seminar: Prof. Yair Reisner will lecture on "Hematopoietic and lung stem cell transplantation across major genetic barriers."
More information Time 11:00 - 12:00Location Wolfson Building for Biological Research
AuditoriumLecturer Prof. Yair Reisner
Head, Stem Cell Research; Dep. Stem Cell Transplantation & Cellular Therapy; MD Anderson Cancer Center; Houston, Texas.Organizer Department of ImmunologyContact -
Date:10TuesdayDecember 2019Lecture
Transposable elements as drivers of structural and functional variations in wheat genome
More information Time 11:30 - 12:30Location Nella and Leon Benoziyo Building for Biological Sciences
AuditoriumLecturer Prof. Khalil Kashkush
Dept. of Life Sciences, Faculty of Natural Sciences, Ben-Gurion University of the NegevOrganizer Department of Plant and Environmental SciencesHomepage Contact Details Show full text description of Hosts: Dr. Cathy Bessudo and Dr. Hadas Zehavi...» Hosts: Dr. Cathy Bessudo and Dr. Hadas Zehavi -
Date:10TuesdayDecember 2019Lecture
Tracking proteins' conformations inside cells with Gd(III) spin labels
More information Time 14:00 - 15:00Location Helen and Milton A. Kimmelman Building
Dov Elad RoomLecturer Prof. Daniella Goldfarb
Department of Chemical and Biological Physics, WISOrganizer Department of Structural BiologyContact -
Date:11WednesdayDecember 2019Lecture
Developmental Club Series 2019-20
More information Time 10:00Title Uncovering the basis of axonal guidance receptor multifunctionalityLocation Arthur and Rochelle Belfer Building for Biomedical Research
Botnar AuditoriumLecturer Prof. Avraham YaronOrganizer Department of Molecular Genetics
Developmental ClubContact -
Date:12ThursdayDecember 2019Lecture
In vivo multimodality imaging of immune-vascular interactions in cardiovascular disease
More information Time 10:00 - 11:00Location Perlman Chemical Sciences Building
Room 404Lecturer Prof. Katrien Vandoorne
Eindhoven University of Technology (The Netherlands), Department of Biomedical Engineering, Soft Tissue EngineeringOrganizer Department of Materials and Interfaces
The Helen and Martin Kimmel Institute for Magnetic ResonanceContact Abstract Show full text abstract about Cardiovascular disease is a result of genetic and environmen...» Cardiovascular disease is a result of genetic and environmental risk factors that together generate arterial and cardiac pathologies. Blood vessels connect multiple organ systems throughout the entire body allowing organs to interact via circulating messengers. Multimodality imaging achieves integration of these interfacing systems’ distinct processes, quantifying interactions that contribute to cardiovascular disease. Noninvasive multimodality imaging techniques are emerging tools that can further our understanding of this complex and dynamic interplay. Multichannel multimodality imaging including optics, CT, PET and MRI, are particularly promising because they can simultaneously sample multiple biomarkers. As the opportunities provided by imaging expand, mapping interconnected systems will help us decipher the complexity of cardiovascular disease and monitor novel therapeutic strategies. -
Date:12ThursdayDecember 2019Colloquia
Magic Angle Bilayer Graphene - Superconductors, Orbital Magnets, Correlated States and beyond
More information Time 11:15 - 12:30Location Edna and K.B. Weissman Building of Physical Sciences
AuditoriumLecturer Dmitri K. Efetov
ICFOOrganizer Faculty of PhysicsContact Details Show full text description of 11:00 Coffee, Tea and more ...» 11:00 Coffee, Tea and moreAbstract Show full text abstract about When twisted close to a magic relative orientation angle nea...» When twisted close to a magic relative orientation angle near 1 degree, bilayer graphene has flat moire superlattice minibands that have emerged as a rich and highly tunable source of strong correlation physics, notably the appearance of superconductivity close to interaction-induced insulating states. Here we report on the fabrication of bilayer graphene devices with exceptionally uniform twist angles. We show that the reduction in twist angle disorder reveals insulating states at all integer occupancies of the four-fold spin/valley degenerate flat conduction and valence bands, i.e. at moire band filling factors nu = 0, +(-) 1, +(-) 2, +(-) 3, and reveals new superconductivity regions below critical temperatures as high as 3 K close to - 2 filling. In addition we find novel orbital magnetic states with non-zero Chern numbers. Our study shows that symmetry-broken states, interaction driven insulators, and superconducting domes are common across the entire moire flat bands, including near charge neutrality. We further will discuss recent experiments including screened interactions, fragile topology and the first applications of this amazing new materials platform. -
Date:12ThursdayDecember 2019Lecture
Geometric Functional Analysis and Probability Seminar
More information Time 13:30 - 15:30Title Existence of persistence exponent for Gaussian stationary functionsLocation Jacob Ziskind Building
Room 155Lecturer Naomi Feldheim
BIUOrganizer Faculty of Mathematics and Computer Science
Faculty of Mathematical Sciences Seminar, Department of Computer Science and Applied Mathematics
Faculty of Mathematical Sciences Seminar, Department of Mathematics
Faculty of Mathematical Sciences SeminarContact Details Show full text description of Let Z(t) be a Gaussian stationary function on the real line,...» Let Z(t) be a Gaussian stationary function on the real line, and fix a level L -
Date:12ThursdayDecember 2019Lecture
TAM Tyrosine Kinase Receptor Signaling in Cancer: Unexpected Roles in the Tumor microenvironment
More information Time 14:00 - 15:00Location Max and Lillian Candiotty Building
AuditoriumLecturer Prof. Tal Burstyn-CohenOrganizer Department of Biological RegulationContact -
Date:15SundayDecember 201917TuesdayDecember 2019Lecture
1st Israeli ISAC Flow Cytometry workshop
More information Time All dayOrganizer Department of Life Sciences Core FacilitiesContact -
Date:15SundayDecember 201919ThursdayDecember 2019Conference
Selected Problems in Z-Pinch Physics
More information Time 08:00 - 08:00Location Edna and K.B. Weissman Building of Physical Sciences
Drory AuditoriumChairperson Tal QuellerContact -
Date:15SundayDecember 2019Conference
China-Weizmann Symposium on Scientific Cooperation
More information Time 09:00 - 18:00Location David Lopatie Conference Centre
President's AuditoriumChairperson Eli PollakContact -
Date:15SundayDecember 2019Lecture
Evaporation from the ocean: A new Lagrangian model and its application to observations
More information Time 11:00Location Sussman Family Building for Environmental Sciences
M. Magaritz Seminar RoomLecturer Natan Paldor
The Hebrew University of JerusalemOrganizer Department of Earth and Planetary SciencesContact -
Date:15SundayDecember 2019Lecture
Topological defects in the actin cytoskeleton as organizing centers of Hydra morphogenesis
More information Time 11:00 - 12:00Location Perlman Chemical Sciences Building
Room 404Lecturer Prof. Kinneret Keren
Physics Department, TechnionOrganizer Department of Materials and Interfaces
Soft Matter and BiomaterialsContact Abstract Show full text abstract about Morphogenesis is one of the most remarkable examples of biol...» Morphogenesis is one of the most remarkable examples of biological self-organization. Despite substantial progress, we still do not understand the organizational principles underlying the convergence of this process, across scales, to form viable organisms. We focus on the mechanical aspects of morphogenesis using Hydra, a small multicellular fresh-water animal, as a model system. Hydra has a simple body plan and is famous for its ability to regenerate its whole body from small tissue segments. I will show that the nematic order of the supra-cellular actin fibers in regenerating Hydra defines a coarse-grained field, whose dynamics provide an effective description of the morphogenesis process, with the topological defects in the nematic order acting as effective organizing centers. I will further describe our attempts to directly probe the influence of mechanics on morphogenesis, by applying various external mechanical constraints on regenerating Hydra. -
Date:15SundayDecember 2019Lecture
Faculty Seminar
More information Time 11:15 - 13:00Title Representation, inference and design of multicellular systemsLocation Jacob Ziskind Building
Room 155Lecturer Mor Nitzan
Harvard UniversityOrganizer Faculty of Mathematics and Computer Science
Faculty of Mathematical Sciences Seminar, Department of Computer Science and Applied Mathematics
Faculty of Mathematical Sciences Seminar, Department of Mathematics
Faculty of Mathematical Sciences SeminarContact Details Show full text description of The past decade has witnessed the emergence of single-cell t...» The past decade has witnessed the emergence of single-cell technologies that measure the expression level of genes at a single-cell resolution. These developments have revolutionized our understanding of the rich heterogeneity, structure, and dynamics of cellular populations, by probing the states of millions of cells, and their change under different conditions or over time. However, in standard experiments, information about the spatial context of cells, along with additional layers of information they encode about their location along dynamic processes (e.g. cell cycle or differentiation trajectories), is either lost or not explicitly accessible. This poses a fundamental problem for elucidating collective tissue function and mechanisms of cell-to-cell communication.
In this talk I will present computational approaches for addressing these challenges, by learning interpretable representations of structure, context and design principles for multicellular systems from single-cell information. I will first describe how the locations of cells in their tissue of origin and the resulting spatial gene expression can be probabilistically inferred from single-cell information by a generalized optimal-transport optimization framework, that can flexibly incorporate prior biological assumptions or knowledge derived from experiments. Inference in this case is based on an organization principle for spatial gene expression, namely a structural correspondence between distances of cells in expression and physical space, which we hypothesized and supported for different tissues. We used this framework to spatially reconstruct diverse tissues and organisms, including the fly embryo, mammalian intestinal epithelium and cerebellum, and further inferred spatially informative genes. Since cells encode multiple layers of information, in addition to their spatial context, I will also discuss several approaches for the disentanglement of single-cell gene expression into distinct biological processes, based on ideas rooted in random matrix theory and manifold learning. I will finally discuss how these results can be generalized to reveal principles underlying self-organization of cells into multicellular structures, setting the foundation for the computationally-directed design of cell-to-cell interactions optimized for specific tissue structure or function.