All events, 2016

Sex differences in the brain: a whole body perspective

Lecture
Date:
Tuesday, November 8, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Greet de Vries
|
Neuroscience Institute, Georgia State University

The hundreds of sex differences found in the brain beg the question as to how they develop and what is their function. Factors that cause sex differences in the brain are sex chromosomal gene expression, gonadal hormones, and environmental interactions. Parsimony dictates that these factors act directly on the brain. In fact, available literature on sexual differentiation of the mammalian brain by and large considers just two organs: the gonads and the brain. This perspective, which leaves out all other body parts, misleads us in several ways. First, there is accumulating evidence that all organs are sexually differentiated, and that sex differences in peripheral organs affect the brain. For example, there are sex differences in muscles, adipose tissue, the liver, immune system, gut, kidneys, bladder, and placenta that directly affect the nervous system and behavior. Sex differences may therefore develop in part because brains reside in fundamentally different bodies. This has consequences for brain function as well. Brains may generate different output autonomously, but if they are wired up to different bodies, similar output will have different consequences. To generate similar behaviors, the nervous system may have to compensate by giving different commands. This interaction between body and brain has to be taken into account for a full understanding of the development as well as function of sex differences in the brain. Considering the consequences of this interaction also provides possible explanations for the often remarkable sex differences in neurological and behavioral disorders. These principles will be demonstrated by discussing the development and function of sex differences in vasopressin signaling in brain and body.

Visual perception as retrospective decoding in working memory

Lecture
Date:
Tuesday, November 1, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Misha Tsodyks
|
Neurobiology Department, WIS In collaboration with Ning Qian, Stephanie Ding and Chris Cueva

When faced with complex visual scene, observers inspect different parts of a scene sequentially, storing corresponding features in working memory for subsequent integration into a holistic perception. Yet models of perception rarely consider working memory explicitly. We probed processing hierarchy by comparing absolute judgements of single orientations and relative/ordinal judgements between two sequentially presented orientations. We found that lower-level, absolute judgements failed to account for higher-level, relative/ordinal judgements. However, when ordinal judgement was used to retrospectively decode memory representations of absolute orientations, striking aspects of absolute judgements, including their correlation and forward/backward aftereffects, were explained. We suggest that the brain prioritizes decoding of more useful, higher-level features, which are more invariant and categorical and thus easier to specify and maintain in noisy working memory, and that more-reliable higher-level decoding.

Neurodevelopmental disorders from basic science to novel therapeutic approaches

Lecture
Date:
Sunday, October 9, 2016
Hour: 10:00
Location:
Gerhard M.J. Schmidt Lecture Hall
Dr. Yehezkel (Hezi) Sztainberg
|
Dept of Molecular and Human Genetics, Baylor College of Medicine and The Jan and Dan Duncan Neurological Research Institute, Texas Children’s Hospital, Houston TX

Neurodevelopmental disorders encompass a wide range of childhood-onset medical conditions caused by different genetic mutations and interaction with environmental factors, affect ~2% of the population, and are a leading cause of intellectual disability and autism spectrum disorder. Evidence is accumulating that either loss or gain in dosage of proteins involved in cognitive and behavioural processes can be deleterious to the nervous system by causing a failure in the ability to maintain neuronal homeostasis. My studies are focused on the MECP2 duplication syndrome, one of the most common genomic rearrangements in males, characterized by autism, intellectual disability, motor dysfunction, anxiety, epilepsy, recurrent respiratory tract infections and early death. To determine whether the phenotypes of MECP2 duplication are reversible upon normalization of MeCP2 levels, I first generated and characterized a new mouse model that over-expresses a conditional allele of Mecp2 that could be deleted in the adult animal (Nature 2015). Upon normalization of MeCP2 in adult symptomatic mice, several phenotypes were rescued at the behavioral, physiological, and molecular levels. Next, I reduced MeCP2 using an antisense oligonucleotide (ASO) strategy, which has greater translational potential. I found that ASO treatment induced a broad phenotypic rescue in adult symptomatic MECP2 duplication mice, abolished abnormal EEG discharges and behavioral seizures, and corrected abnormal gene expression in the hippocampus. I am currently characterizing a novel “humanized” mouse model of MECP2 duplication syndrome that will precisely mimic the human condition by having two copies of human MECP2 and no copies of the mouse gene. These mice will serve as the ideal model for preclinical tests as they represent the closest construct validity model for the human condition. In addition, I am generating and characterizing neurons and cortical spheroids induced from patients’ derived pluripotent stem cells (iPSCs).

Encoding of action by the Purkinje cells of the cerebellum

Lecture
Date:
Sunday, September 25, 2016
Hour: 14:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Reza Shadmehr
|
Biomedical Engineering and Neuroscience Johns Hopkins University

The curious case of Dr. Scoville and Mr. Molaison or: How the famous amnesic patient H.M. is not forgotten and stirs much unrest in the neuroscience community

Lecture
Date:
Tuesday, September 20, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Yadin Dudai
|
Department of Neurobiology, WIS

The contribution of ventromedial prefrontal cortex to memory and decision making

Lecture
Date:
Sunday, September 18, 2016
Hour: 12:30
Location:
Nella and Leon Benoziyo Building for Brain Research
Prof. Asaf Gilboa
|
Rotman Research Institute at Baycrest Health Sciences and Dept of Psychology, University of Toronto

The Self and the Friend in Space

Lecture
Date:
Tuesday, September 6, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Dr. Pia Rotshtein
|
School of Psychology, Birmingham University Imaging Centre, University of Birmingham UK

Understanding the Self has fascinated artists, writers, philosophers and psychologist for generation. In the past two decades cognitive and neurocognitive tools have been applied to the study of the Self. The talk will present research on the Self and the Friend. Not surprisingly, it is consistently found that our brain prioritize the Self. For example, deciding whether a face looks to the left or right is faster on one’s own face than on a face of a friend. This prioritization transcend time, showing similar prioritization to one’s face in the past as in the present. Lesions to the fusiform gyrus hinders Self facilitation, while lesions to lateral frontal cortices amplifies it. Associating a simple geometric shape to oneself is done much more efficiently than to a stranger an effect that is mediated via the left STS, medial and lateral frontal cortices. Participants are also better at judging a perspective of an avatar if it is tagged as them than as a stranger. But in all these studies the Friend is also prioritized relative to a stranger. Why is the friend prioritized, is it because it is relevant, or because it is liked? In a simple shape-identity matching task, we manipulated orthogonally the valence and relevance of familiar identities. We found that prioritization is given based on relevance and valence in Western culture, but primarily based on valance in Asian cultures. Using spatial maps to represent the social space, we observed consistent representation of social relations as physical distances. Physical distance between identities was affected by the valence and relevance factors, though this was modulated by the participants’ culture. Finally, presenting participants with incongruent spatial maps of their social relations, resulted in increase and decrease responses in a large network of regions including the Amygdala and superior temporal structure known to play a rule in social cognition. Taken together this body of work highlight neurocognitive mechanism by which our brain prioritize information based on social rules.

Full humanisation of the mouse immunoglobulin loci

Lecture
Date:
Thursday, August 25, 2016
Hour: 10:00
Location:
Wolfson Building for Biological Research
Prof. Allan Bradley
|
Kymab, Cambridge MA

Professor Bradley is internationally recognized as a pioneer in developing the techniques, technology and tools for genetic manipulation in the mouse over more than 3 decades. He served as Director of the Welcome Trust Sanger Institute from 2000 to 2010. He was honored by election to the fellowship of the Royal Society in 2002. Among many projects that Dr. Bradley has established and led, is the international project to systematically knockout all genes in the mouse genome, the most ambitious use of ES-cell technology ever attempted. Over the last 30 years, Dr. Bradley has authored more than 280 publications. In his lecture, Dr. Bradley will be describing the scientific history and the technology behind the creation of the Kymouse strains which are transgenic for the total human immunoglobulin gene diversity. The platform provides a valuable means to isolate therapeutic monoclonal antibodies. Kymab has also developed single B cell-based methods to capture both the heavy and light chains of antibodies at scale. Combined with deep sequencing of millions of B cells we are able to build networks of histories of B cell families which we use to isolate rare antibodies with unique properties. The combined use of Kymouse with B cell network analysis, facilitates vaccine antigen discovery and predictive pre-clinical assessment of candidate vaccine antigens prior to clinical trials in humans.

Population receptive fields in the human ventral stream and their role in face perception

Lecture
Date:
Tuesday, July 12, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Kalanit Grill-Spector
|
Dept of Psychology and Stanford Neurosciences Institute Stanford University, CA

The cortical system for processing faces is a model system for studying the functional neuroanatomy of ventral temporal cortex and its role in perception for two reasons. First, the functional organization of the cortical face system is well understood. Second, activations in ventral face-selective regions are causally related to face perception. Here, I will describe recent results from our research elucidating the computations performed by population receptive field (pRFs) in the cortical system for face perception. In contrast to predictions of classical theories, recent data from my lab reveals that computations in face-selective regions in human ventral temporal cortex can be characterized with a computational pRF model, which predicts the location and spatial extent of the visual field that is processed by the neural population in a voxel. Our research characterizes pRF properties of ventral face-selective regions revealing three main findings. First, pRFs illustrate a hierarchical organization within the face system, whereby pRFs become larger and more foveal across the ventral hierarchy. Second, attention to faces modulates pRFs in face-selective regions, consequently enhancing the representation of faces in the peripheral visual field where visual acuity is the lowest. Third, our research shows that pRF properties in face-selective regions are behaviorally relevant. We find that face perception abilities are correlated with pRF properties: participants with larger pRFs perform better in face recognition than participants with smaller pRFs. These data suggest that computations performed by pRFs in face-selective regions may form a neural basis for holistic processing necessary for face recognition. Overall, these data highlight the importance of elucidating computational properties of neural populations in ventral temporal cortex as they offer a new mechanistic understanding of high-level visual processes such as face perception.

Essential Functions of Chromatin Modifications in Prefrontal Synaptic Plasticity and Working Memory

Lecture
Date:
Tuesday, June 28, 2016
Hour: 14:00
Location:
Nella and Leon Benoziyo Building for Brain Research
Mira Jakovcevski, PhD
|
Max Planck Institute of Psychiatry, Munich

Pages

All events, 2016

Sex differences in the brain: a whole body perspective

Lecture
Date:
Tuesday, November 8, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Greet de Vries
|
Neuroscience Institute, Georgia State University

The hundreds of sex differences found in the brain beg the question as to how they develop and what is their function. Factors that cause sex differences in the brain are sex chromosomal gene expression, gonadal hormones, and environmental interactions. Parsimony dictates that these factors act directly on the brain. In fact, available literature on sexual differentiation of the mammalian brain by and large considers just two organs: the gonads and the brain. This perspective, which leaves out all other body parts, misleads us in several ways. First, there is accumulating evidence that all organs are sexually differentiated, and that sex differences in peripheral organs affect the brain. For example, there are sex differences in muscles, adipose tissue, the liver, immune system, gut, kidneys, bladder, and placenta that directly affect the nervous system and behavior. Sex differences may therefore develop in part because brains reside in fundamentally different bodies. This has consequences for brain function as well. Brains may generate different output autonomously, but if they are wired up to different bodies, similar output will have different consequences. To generate similar behaviors, the nervous system may have to compensate by giving different commands. This interaction between body and brain has to be taken into account for a full understanding of the development as well as function of sex differences in the brain. Considering the consequences of this interaction also provides possible explanations for the often remarkable sex differences in neurological and behavioral disorders. These principles will be demonstrated by discussing the development and function of sex differences in vasopressin signaling in brain and body.

Visual perception as retrospective decoding in working memory

Lecture
Date:
Tuesday, November 1, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Misha Tsodyks
|
Neurobiology Department, WIS In collaboration with Ning Qian, Stephanie Ding and Chris Cueva

When faced with complex visual scene, observers inspect different parts of a scene sequentially, storing corresponding features in working memory for subsequent integration into a holistic perception. Yet models of perception rarely consider working memory explicitly. We probed processing hierarchy by comparing absolute judgements of single orientations and relative/ordinal judgements between two sequentially presented orientations. We found that lower-level, absolute judgements failed to account for higher-level, relative/ordinal judgements. However, when ordinal judgement was used to retrospectively decode memory representations of absolute orientations, striking aspects of absolute judgements, including their correlation and forward/backward aftereffects, were explained. We suggest that the brain prioritizes decoding of more useful, higher-level features, which are more invariant and categorical and thus easier to specify and maintain in noisy working memory, and that more-reliable higher-level decoding.

Neurodevelopmental disorders from basic science to novel therapeutic approaches

Lecture
Date:
Sunday, October 9, 2016
Hour: 10:00
Location:
Gerhard M.J. Schmidt Lecture Hall
Dr. Yehezkel (Hezi) Sztainberg
|
Dept of Molecular and Human Genetics, Baylor College of Medicine and The Jan and Dan Duncan Neurological Research Institute, Texas Children’s Hospital, Houston TX

Neurodevelopmental disorders encompass a wide range of childhood-onset medical conditions caused by different genetic mutations and interaction with environmental factors, affect ~2% of the population, and are a leading cause of intellectual disability and autism spectrum disorder. Evidence is accumulating that either loss or gain in dosage of proteins involved in cognitive and behavioural processes can be deleterious to the nervous system by causing a failure in the ability to maintain neuronal homeostasis. My studies are focused on the MECP2 duplication syndrome, one of the most common genomic rearrangements in males, characterized by autism, intellectual disability, motor dysfunction, anxiety, epilepsy, recurrent respiratory tract infections and early death. To determine whether the phenotypes of MECP2 duplication are reversible upon normalization of MeCP2 levels, I first generated and characterized a new mouse model that over-expresses a conditional allele of Mecp2 that could be deleted in the adult animal (Nature 2015). Upon normalization of MeCP2 in adult symptomatic mice, several phenotypes were rescued at the behavioral, physiological, and molecular levels. Next, I reduced MeCP2 using an antisense oligonucleotide (ASO) strategy, which has greater translational potential. I found that ASO treatment induced a broad phenotypic rescue in adult symptomatic MECP2 duplication mice, abolished abnormal EEG discharges and behavioral seizures, and corrected abnormal gene expression in the hippocampus. I am currently characterizing a novel “humanized” mouse model of MECP2 duplication syndrome that will precisely mimic the human condition by having two copies of human MECP2 and no copies of the mouse gene. These mice will serve as the ideal model for preclinical tests as they represent the closest construct validity model for the human condition. In addition, I am generating and characterizing neurons and cortical spheroids induced from patients’ derived pluripotent stem cells (iPSCs).

Encoding of action by the Purkinje cells of the cerebellum

Lecture
Date:
Sunday, September 25, 2016
Hour: 14:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Reza Shadmehr
|
Biomedical Engineering and Neuroscience Johns Hopkins University

The curious case of Dr. Scoville and Mr. Molaison or: How the famous amnesic patient H.M. is not forgotten and stirs much unrest in the neuroscience community

Lecture
Date:
Tuesday, September 20, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Yadin Dudai
|
Department of Neurobiology, WIS

The contribution of ventromedial prefrontal cortex to memory and decision making

Lecture
Date:
Sunday, September 18, 2016
Hour: 12:30
Location:
Nella and Leon Benoziyo Building for Brain Research
Prof. Asaf Gilboa
|
Rotman Research Institute at Baycrest Health Sciences and Dept of Psychology, University of Toronto

The Self and the Friend in Space

Lecture
Date:
Tuesday, September 6, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Dr. Pia Rotshtein
|
School of Psychology, Birmingham University Imaging Centre, University of Birmingham UK

Understanding the Self has fascinated artists, writers, philosophers and psychologist for generation. In the past two decades cognitive and neurocognitive tools have been applied to the study of the Self. The talk will present research on the Self and the Friend. Not surprisingly, it is consistently found that our brain prioritize the Self. For example, deciding whether a face looks to the left or right is faster on one’s own face than on a face of a friend. This prioritization transcend time, showing similar prioritization to one’s face in the past as in the present. Lesions to the fusiform gyrus hinders Self facilitation, while lesions to lateral frontal cortices amplifies it. Associating a simple geometric shape to oneself is done much more efficiently than to a stranger an effect that is mediated via the left STS, medial and lateral frontal cortices. Participants are also better at judging a perspective of an avatar if it is tagged as them than as a stranger. But in all these studies the Friend is also prioritized relative to a stranger. Why is the friend prioritized, is it because it is relevant, or because it is liked? In a simple shape-identity matching task, we manipulated orthogonally the valence and relevance of familiar identities. We found that prioritization is given based on relevance and valence in Western culture, but primarily based on valance in Asian cultures. Using spatial maps to represent the social space, we observed consistent representation of social relations as physical distances. Physical distance between identities was affected by the valence and relevance factors, though this was modulated by the participants’ culture. Finally, presenting participants with incongruent spatial maps of their social relations, resulted in increase and decrease responses in a large network of regions including the Amygdala and superior temporal structure known to play a rule in social cognition. Taken together this body of work highlight neurocognitive mechanism by which our brain prioritize information based on social rules.

Full humanisation of the mouse immunoglobulin loci

Lecture
Date:
Thursday, August 25, 2016
Hour: 10:00
Location:
Wolfson Building for Biological Research
Prof. Allan Bradley
|
Kymab, Cambridge MA

Professor Bradley is internationally recognized as a pioneer in developing the techniques, technology and tools for genetic manipulation in the mouse over more than 3 decades. He served as Director of the Welcome Trust Sanger Institute from 2000 to 2010. He was honored by election to the fellowship of the Royal Society in 2002. Among many projects that Dr. Bradley has established and led, is the international project to systematically knockout all genes in the mouse genome, the most ambitious use of ES-cell technology ever attempted. Over the last 30 years, Dr. Bradley has authored more than 280 publications. In his lecture, Dr. Bradley will be describing the scientific history and the technology behind the creation of the Kymouse strains which are transgenic for the total human immunoglobulin gene diversity. The platform provides a valuable means to isolate therapeutic monoclonal antibodies. Kymab has also developed single B cell-based methods to capture both the heavy and light chains of antibodies at scale. Combined with deep sequencing of millions of B cells we are able to build networks of histories of B cell families which we use to isolate rare antibodies with unique properties. The combined use of Kymouse with B cell network analysis, facilitates vaccine antigen discovery and predictive pre-clinical assessment of candidate vaccine antigens prior to clinical trials in humans.

Population receptive fields in the human ventral stream and their role in face perception

Lecture
Date:
Tuesday, July 12, 2016
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Prof. Kalanit Grill-Spector
|
Dept of Psychology and Stanford Neurosciences Institute Stanford University, CA

The cortical system for processing faces is a model system for studying the functional neuroanatomy of ventral temporal cortex and its role in perception for two reasons. First, the functional organization of the cortical face system is well understood. Second, activations in ventral face-selective regions are causally related to face perception. Here, I will describe recent results from our research elucidating the computations performed by population receptive field (pRFs) in the cortical system for face perception. In contrast to predictions of classical theories, recent data from my lab reveals that computations in face-selective regions in human ventral temporal cortex can be characterized with a computational pRF model, which predicts the location and spatial extent of the visual field that is processed by the neural population in a voxel. Our research characterizes pRF properties of ventral face-selective regions revealing three main findings. First, pRFs illustrate a hierarchical organization within the face system, whereby pRFs become larger and more foveal across the ventral hierarchy. Second, attention to faces modulates pRFs in face-selective regions, consequently enhancing the representation of faces in the peripheral visual field where visual acuity is the lowest. Third, our research shows that pRF properties in face-selective regions are behaviorally relevant. We find that face perception abilities are correlated with pRF properties: participants with larger pRFs perform better in face recognition than participants with smaller pRFs. These data suggest that computations performed by pRFs in face-selective regions may form a neural basis for holistic processing necessary for face recognition. Overall, these data highlight the importance of elucidating computational properties of neural populations in ventral temporal cortex as they offer a new mechanistic understanding of high-level visual processes such as face perception.

Essential Functions of Chromatin Modifications in Prefrontal Synaptic Plasticity and Working Memory

Lecture
Date:
Tuesday, June 28, 2016
Hour: 14:00
Location:
Nella and Leon Benoziyo Building for Brain Research
Mira Jakovcevski, PhD
|
Max Planck Institute of Psychiatry, Munich

Pages

All events, 2016

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All events, 2016

There are no events to display