2012
, 2012
Delay Compensation with Dynamical Synapses
Lecture
Thursday, November 8, 2012
Hour: 15:00
Location:
Gerhard M.J. Schmidt Lecture Hall
Delay Compensation with Dynamical Synapses
Dr. Si Wu
Key Lab of Cognitive Neuroscience & Learning
Beijing Normal University
Beijing, China
Time delay is pervasive in neural information processing. To achieve real-time tracking, it is critical to compensate the transmission and processing delays in a neural system. In the present study we show that dynamical synapses with short-term depression can enhance the mobility of a continuous attractor network to the extent that the system tracks time-varying stimuli in a timely manner. The state of the network can either track the instantaneous position of a moving stimulus perfectly (with zero-lag) or lead it with an effectively constant time, in agreement with experiments on the head-direction systems in rodents.
The parameter regions for delayed, perfect and anticipative tracking correspond to network states that are static, ready-to-move and spontaneously moving, respectively, demonstrating the strong correlation between tracking performance and the intrinsic dynamics of the network.
Unexpected plasticity in retinal circuits
Lecture
Wednesday, November 7, 2012
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Unexpected plasticity in retinal circuits
Dr. Michal Rivlin-Etzion
Dept of Molecular and Cell Biology and the Helen Wills Neurosciences Institute,
UC Berkeley
Direction selective retinal ganglion cells encode motion in the visual field. They respond strongly to an object moving in one direction, called the preferred direction, and weakly to an object moving in the opposite direction. This response is thought to arise by asymmetric wiring of inhibitory neurons onto the direction selective cells. I will demonstrate that adaptation with short visual stimulation of a direction selective ganglion cell using drifting gratings can reverse this cell’s directional preference by 180 degrees. This reversal is robust, long-lasting, and independent of the animal’s age. My findings indicate that, even within circuits that are hardwired, the computation of direction can be altered by dynamic circuit mechanisms that are guided by visual stimulation.
Neural codes for 2-D and 3-D space in the hippocampal formation of bats
Lecture
Tuesday, November 6, 2012
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Neural codes for 2-D and 3-D space in the hippocampal formation of bats
Prof. Nachum Ulanovsky
Dept of Neurobiology, WIS
The work in our lab focuses on understanding the neural basis of behavior, particularly spatial cognition, in freely-moving, freely behaving mammals – employing the echolocating bat as a novel animal model. I will describe our recent studies, including: (i) recordings of 3-D head-direction cells in the presubiculum of crawling bats, as well as recordings from hippocampal 3-D place cells in freely-flying bats, using a custom neural telemetry system – which revealed an elaborate 3-D spatial representation in the mammalian brain; and (ii) recordings of 'grid cells' in the bat's medial entorhinal cortex, in the absence of theta oscillations – which strongly argues against the prevailing computational model of grid formation. I will also describe our recent studies of spatial memory and navigation of fruit bats in the wild, using micro-GPS devices, which revealed outstanding navigational abilities and provided the first evidence for a large-scale 'cognitive map' in a mammal.
Humans and the Other: Blade Runner
Lecture
Thursday, November 1, 2012
Hour: 16:00
Location:
Dolfi and Lola Ebner Auditorium
Humans and the Other: Blade Runner
Humans and the Other: Planet of the Apes
Lecture
Thursday, October 25, 2012
Hour: 16:00
Location:
Dolfi and Lola Ebner Auditorium
Humans and the Other: Planet of the Apes
The Power of Testing in Enhancing Memory
Lecture
Sunday, October 21, 2012
Hour: 14:00
Location:
Gerhard M.J. Schmidt Lecture Hall
The Power of Testing in Enhancing Memory
Dr. Henry L. Roediger III and Dr. Kathleen McDermott
Department of Psychology
Washington University in St. Louis
Humans and the Other: Project Nim
Lecture
Thursday, October 18, 2012
Hour: 16:00
Location:
Dolfi and Lola Ebner Auditorium
Humans and the Other: Project Nim
A rodent model for social neuroscience
Lecture
Tuesday, September 4, 2012
Hour: 15:00
Location:
Arthur and Rochelle Belfer Building for Biomedical Research
A rodent model for social neuroscience
Prof. Zuoxin Wang
Department of Psychology and Program in Neuroscience
Florida State University FL, USA
Sites of androgen action in the nervous system
Lecture
Sunday, September 2, 2012
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Sites of androgen action in the nervous system
Prof. Marc Breedlove
Departments of Psychology and Zoology, Michigan State University
It is clear that much of the masculinization of the brain in rats and mice is mediated by aromatized metabolites of testicular androgens acting upon estrogen receptors (ERs). For example, exogenous estrogens, which presumably exert little effect on androgen receptors (ARs), can reverse the loss of masculine behavior and neural morphology in males that have been castrated, both in development and adulthood. However, we find that rats and mice carrying a dysfunctional AR gene, so-called testicular feminization mutation (Tfm) males, are partly or completely demasculinized in terms of at least one non-reproductive behavior and each of the numerous brain regions we have examined so far. These findings indicate that in fact AR normally plays a role in the masculinization of at least some behaviors, and potentially every brain region, in rodents.
For example, the medial amygdala (MeA) is about 150% larger in volume in wildtype (wt) male rats than in wt females. Tfm males display an intermediate volume, significantly greater than wt females yet significantly less than wt males. Astrocytes in the posterodorsal portion of the MeA (MePD) of rats are also sexually dimorphic, both in number and arbor complexity, and Tfm males are wholly feminine in these features. Likewise, in our measurements of sexually dimorphic characters in the ventromedial hypothalamus (VMH), the suprachiasmatic nucleus (SCN), and the paraventricular nucleus (PVN), Tfm males are wholly feminine. Even in the sexually dimorphic nucleus of the preoptic area (SDNPOA), where the volume is masculine in Tfm males, the size of the neurons is nevertheless reduced in Tfm males compared to wt males.
It is difficult to assess masculine reproductive behavior in Tfm males because they have an entirely feminine exterior phenotype, with a clitoris, vagina, etc. Nevertheless, they have been reported to show many masculine reproductive behaviors, as would be expected if those were mediated by ERs. However, we find that anxiety-related behaviors, such as measured in an open field with a novel object, the elevated plus maze, and the light/dark box, are greater in Tfm males than in wt males in both rats and mice. Tfm animals also show a heightened corticosterone response to mild stress. These results suggest that masculinization of anxiety-related behavior is heavily reliant on stimulation of AR, presumably in the brain. We are exploring the sites of AR action by use of Cre- lox technology to delete AR in selective tissues.
We are using the same technology to explore the site(s) of androgen action on the spinal nucleus of the bulbocavernosus (SNB), a group of motoneurons that innervate two striated muscles, the bulbocavernosus and levator ani (BC/LA), which are attached to the base of the penis. By selectively deleting AR in either motoneurons alone, or in muscle fibers alone, we hope to understand how androgen spares this system from apoptosis in development, and regulates neural plasticity of the motoneurons in adulthood.
Towards a link between hippocampal network dynamics and exploratory behavior
Lecture
Tuesday, August 28, 2012
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Towards a link between hippocampal network dynamics and exploratory behavior
Dr. Anton Sirota
Centre for Integrative Neuroscience, Tubingen University, Germany
Pages
2012
, 2012
Delay Compensation with Dynamical Synapses
Lecture
Thursday, November 8, 2012
Hour: 15:00
Location:
Gerhard M.J. Schmidt Lecture Hall
Delay Compensation with Dynamical Synapses
Dr. Si Wu
Key Lab of Cognitive Neuroscience & Learning
Beijing Normal University
Beijing, China
Time delay is pervasive in neural information processing. To achieve real-time tracking, it is critical to compensate the transmission and processing delays in a neural system. In the present study we show that dynamical synapses with short-term depression can enhance the mobility of a continuous attractor network to the extent that the system tracks time-varying stimuli in a timely manner. The state of the network can either track the instantaneous position of a moving stimulus perfectly (with zero-lag) or lead it with an effectively constant time, in agreement with experiments on the head-direction systems in rodents.
The parameter regions for delayed, perfect and anticipative tracking correspond to network states that are static, ready-to-move and spontaneously moving, respectively, demonstrating the strong correlation between tracking performance and the intrinsic dynamics of the network.
Unexpected plasticity in retinal circuits
Lecture
Wednesday, November 7, 2012
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Unexpected plasticity in retinal circuits
Dr. Michal Rivlin-Etzion
Dept of Molecular and Cell Biology and the Helen Wills Neurosciences Institute,
UC Berkeley
Direction selective retinal ganglion cells encode motion in the visual field. They respond strongly to an object moving in one direction, called the preferred direction, and weakly to an object moving in the opposite direction. This response is thought to arise by asymmetric wiring of inhibitory neurons onto the direction selective cells. I will demonstrate that adaptation with short visual stimulation of a direction selective ganglion cell using drifting gratings can reverse this cell’s directional preference by 180 degrees. This reversal is robust, long-lasting, and independent of the animal’s age. My findings indicate that, even within circuits that are hardwired, the computation of direction can be altered by dynamic circuit mechanisms that are guided by visual stimulation.
Neural codes for 2-D and 3-D space in the hippocampal formation of bats
Lecture
Tuesday, November 6, 2012
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Neural codes for 2-D and 3-D space in the hippocampal formation of bats
Prof. Nachum Ulanovsky
Dept of Neurobiology, WIS
The work in our lab focuses on understanding the neural basis of behavior, particularly spatial cognition, in freely-moving, freely behaving mammals – employing the echolocating bat as a novel animal model. I will describe our recent studies, including: (i) recordings of 3-D head-direction cells in the presubiculum of crawling bats, as well as recordings from hippocampal 3-D place cells in freely-flying bats, using a custom neural telemetry system – which revealed an elaborate 3-D spatial representation in the mammalian brain; and (ii) recordings of 'grid cells' in the bat's medial entorhinal cortex, in the absence of theta oscillations – which strongly argues against the prevailing computational model of grid formation. I will also describe our recent studies of spatial memory and navigation of fruit bats in the wild, using micro-GPS devices, which revealed outstanding navigational abilities and provided the first evidence for a large-scale 'cognitive map' in a mammal.
Humans and the Other: Blade Runner
Lecture
Thursday, November 1, 2012
Hour: 16:00
Location:
Dolfi and Lola Ebner Auditorium
Humans and the Other: Blade Runner
Humans and the Other: Planet of the Apes
Lecture
Thursday, October 25, 2012
Hour: 16:00
Location:
Dolfi and Lola Ebner Auditorium
Humans and the Other: Planet of the Apes
The Power of Testing in Enhancing Memory
Lecture
Sunday, October 21, 2012
Hour: 14:00
Location:
Gerhard M.J. Schmidt Lecture Hall
The Power of Testing in Enhancing Memory
Dr. Henry L. Roediger III and Dr. Kathleen McDermott
Department of Psychology
Washington University in St. Louis
Humans and the Other: Project Nim
Lecture
Thursday, October 18, 2012
Hour: 16:00
Location:
Dolfi and Lola Ebner Auditorium
Humans and the Other: Project Nim
A rodent model for social neuroscience
Lecture
Tuesday, September 4, 2012
Hour: 15:00
Location:
Arthur and Rochelle Belfer Building for Biomedical Research
A rodent model for social neuroscience
Prof. Zuoxin Wang
Department of Psychology and Program in Neuroscience
Florida State University FL, USA
Sites of androgen action in the nervous system
Lecture
Sunday, September 2, 2012
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Sites of androgen action in the nervous system
Prof. Marc Breedlove
Departments of Psychology and Zoology, Michigan State University
It is clear that much of the masculinization of the brain in rats and mice is mediated by aromatized metabolites of testicular androgens acting upon estrogen receptors (ERs). For example, exogenous estrogens, which presumably exert little effect on androgen receptors (ARs), can reverse the loss of masculine behavior and neural morphology in males that have been castrated, both in development and adulthood. However, we find that rats and mice carrying a dysfunctional AR gene, so-called testicular feminization mutation (Tfm) males, are partly or completely demasculinized in terms of at least one non-reproductive behavior and each of the numerous brain regions we have examined so far. These findings indicate that in fact AR normally plays a role in the masculinization of at least some behaviors, and potentially every brain region, in rodents.
For example, the medial amygdala (MeA) is about 150% larger in volume in wildtype (wt) male rats than in wt females. Tfm males display an intermediate volume, significantly greater than wt females yet significantly less than wt males. Astrocytes in the posterodorsal portion of the MeA (MePD) of rats are also sexually dimorphic, both in number and arbor complexity, and Tfm males are wholly feminine in these features. Likewise, in our measurements of sexually dimorphic characters in the ventromedial hypothalamus (VMH), the suprachiasmatic nucleus (SCN), and the paraventricular nucleus (PVN), Tfm males are wholly feminine. Even in the sexually dimorphic nucleus of the preoptic area (SDNPOA), where the volume is masculine in Tfm males, the size of the neurons is nevertheless reduced in Tfm males compared to wt males.
It is difficult to assess masculine reproductive behavior in Tfm males because they have an entirely feminine exterior phenotype, with a clitoris, vagina, etc. Nevertheless, they have been reported to show many masculine reproductive behaviors, as would be expected if those were mediated by ERs. However, we find that anxiety-related behaviors, such as measured in an open field with a novel object, the elevated plus maze, and the light/dark box, are greater in Tfm males than in wt males in both rats and mice. Tfm animals also show a heightened corticosterone response to mild stress. These results suggest that masculinization of anxiety-related behavior is heavily reliant on stimulation of AR, presumably in the brain. We are exploring the sites of AR action by use of Cre- lox technology to delete AR in selective tissues.
We are using the same technology to explore the site(s) of androgen action on the spinal nucleus of the bulbocavernosus (SNB), a group of motoneurons that innervate two striated muscles, the bulbocavernosus and levator ani (BC/LA), which are attached to the base of the penis. By selectively deleting AR in either motoneurons alone, or in muscle fibers alone, we hope to understand how androgen spares this system from apoptosis in development, and regulates neural plasticity of the motoneurons in adulthood.
Towards a link between hippocampal network dynamics and exploratory behavior
Lecture
Tuesday, August 28, 2012
Hour: 12:30
Location:
Gerhard M.J. Schmidt Lecture Hall
Towards a link between hippocampal network dynamics and exploratory behavior
Dr. Anton Sirota
Centre for Integrative Neuroscience, Tubingen University, Germany
Pages
2012
, 2012
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