Your search keyword '"Susumu Tonegawa"' showing total 417 results

1. Cingulate-motor circuits update rule representations for sequential choice decisions

Author

Daigo Takeuchi, Dheeraj Roy, Shruti Muralidhar, Takashi Kawai, Andrea Bari, Chanel Lovett, Heather A. Sullivan, Ian R. Wickersham, and Susumu Tonegawa

Subjects

Science

Abstract

The anterior cingulate cortex allows an animal to update its behaviour when the environment changes. In this work, the authors identify a pathway from cingulate to secondary motor cortex, critical for updating motor rules following behavioural errors.

Published

2022

2. Brain-wide mapping reveals that engrams for a single memory are distributed across multiple brain regions

Author

Dheeraj S. Roy, Young-Gyun Park, Minyoung E. Kim, Ying Zhang, Sachie K. Ogawa, Nicholas DiNapoli, Xinyi Gu, Jae H. Cho, Heejin Choi, Lee Kamentsky, Jared Martin, Olivia Mosto, Tomomi Aida, Kwanghun Chung, and Susumu Tonegawa

Subjects

Science

Abstract

Where memories are located in our brains is not well understood. In this paper, the authors demonstrate that memories are spread out throughout multiple brain regions.

Published

2022

3. Reinforcement biases subsequent perceptual decisions when confidence is low, a widespread behavioral phenomenon

Author

Armin Lak, Emily Hueske, Junya Hirokawa, Paul Masset, Torben Ott, Anne E Urai, Tobias H Donner, Matteo Carandini, Susumu Tonegawa, Naoshige Uchida, and Adam Kepecs

Subjects

reinforcement learning, uncertainty, reward, sensory decision, Medicine, Science, Biology (General), QH301-705.5

Abstract

Learning from successes and failures often improves the quality of subsequent decisions. Past outcomes, however, should not influence purely perceptual decisions after task acquisition is complete since these are designed so that only sensory evidence determines the correct choice. Yet, numerous studies report that outcomes can bias perceptual decisions, causing spurious changes in choice behavior without improving accuracy. Here we show that the effects of reward on perceptual decisions are principled: past rewards bias future choices specifically when previous choice was difficult and hence decision confidence was low. We identified this phenomenon in six datasets from four laboratories, across mice, rats, and humans, and sensory modalities from olfaction and audition to vision. We show that this choice-updating strategy can be explained by reinforcement learning models incorporating statistical decision confidence into their teaching signals. Thus, reinforcement learning mechanisms are continually engaged to produce systematic adjustments of choices even in well-learned perceptual decisions in order to optimize behavior in an uncertain world.

Published

2020

4. Development of schemas revealed by prior experience and NMDA receptor knock-out

Author

George Dragoi and Susumu Tonegawa

Subjects

learning and memory, NMDA, hippocampus, cellular assemblies, schema, Medicine, Science, Biology (General), QH301-705.5

Abstract

Prior experience accelerates acquisition of novel, related information through processes like assimilation into mental schemas, but the underlying neuronal mechanisms are poorly understood. We investigated the roles that prior experience and hippocampal CA3 N-Methyl-D-aspartate receptor (NMDAR)-dependent synaptic plasticity play in CA1 place cell sequence encoding and learning during novel spatial experiences. We found that specific representations of de novo experiences on linear environments were formed on a framework of pre configured network activity expressed in the preceding sleep and were rapidly, flexibly adjusted via NMDAR-dependent activity. This prior experience accelerated encoding of subsequent experiences on contiguous or isolated novel tracks, significantly decreasing their NMDAR-dependence. Similarly, de novo learning of an alternation task was facilitated by CA3 NMDARs; this experience accelerated subsequent learning of related tasks, independent of CA3 NMDARs, consistent with a schema-based learning. These results reveal the existence of distinct neuronal encoding schemes which could explain why hippocampal dysfunction results in anterograde amnesia while sparing recollection of old, schema-based memories.

Published

2013

5. Molecular Approach to Uterine Leiomyosarcoma: LMP2-Deficient Mice as an Animal Model of Spontaneous Uterine Leiomyosarcoma

Author

Takuma Hayashi, Akiko Horiuchi, Kenji Sano, Nobuyoshi Hiraoka, Yae Kanai, Tanri Shiozawa, Susumu Tonegawa, and Ikuo Konishi

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Uterine leiomyosarcoma (LMS) develops more often in the muscle tissue layer of the uterine body than in the uterine cervix. The development of gynecologic tumors is often correlated with female hormone secretion; however, the development of uterine LMS is not substantially correlated with hormonal conditions, and the risk factors are not yet known. Importantly, a diagnostic-biomarker which distinguishes malignant LMS from benign tumor leiomyoma (LMA) is yet to be established. Accordingly, it is necessary to analyze risk factors associated with uterine LMS, in order to establish a treatment method. LMP2-deficient mice spontaneously develop uterine LMS, with a disease prevalence of ~40% by 14 months of age. We found LMP2 expression to be absent in human LMS, but present in human LMA. Therefore, defective LMP2 expression may be one of the risk factors for LMS. LMP2 is a potential diagnostic-biomarker for uterine LMS, and may be targeted-molecule for a new therapeutic approach.

Published

2011

6. A role for calcium-permeable AMPA receptors in synaptic plasticity and learning.

Author

Brian J Wiltgen, Gordon A Royle, Erin E Gray, Andrea Abdipranoto, Nopporn Thangthaeng, Nate Jacobs, Faysal Saab, Susumu Tonegawa, Stephen F Heinemann, Thomas J O'Dell, Michael S Fanselow, and Bryce Vissel

Subjects

Medicine, Science

Abstract

A central concept in the field of learning and memory is that NMDARs are essential for synaptic plasticity and memory formation. Surprisingly then, multiple studies have found that behavioral experience can reduce or eliminate the contribution of these receptors to learning. The cellular mechanisms that mediate learning in the absence of NMDAR activation are currently unknown. To address this issue, we examined the contribution of Ca(2+)-permeable AMPARs to learning and plasticity in the hippocampus. Mutant mice were engineered with a conditional genetic deletion of GluR2 in the CA1 region of the hippocampus (GluR2-cKO mice). Electrophysiology experiments in these animals revealed a novel form of long-term potentiation (LTP) that was independent of NMDARs and mediated by GluR2-lacking Ca(2+)-permeable AMPARs. Behavioral analyses found that GluR2-cKO mice were impaired on multiple hippocampus-dependent learning tasks that required NMDAR activation. This suggests that AMPAR-mediated LTP interferes with NMDAR-dependent plasticity. In contrast, NMDAR-independent learning was normal in knockout mice and required the activation of Ca(2+)-permeable AMPARs. These results suggest that GluR2-lacking AMPARs play a functional and previously unidentified role in learning; they appear to mediate changes in synaptic strength that occur after plasticity has been established by NMDARs.

Published

2010

7. POTENTIAL DIAGNOSTIC BIOMARKERS FOR HUMAN MESENCHYMAL TUMORS, ESPECIALLY LMP2/Β1I AND CYCLIN E1/MIB1 DIFFERENTIAL EXPRESSION: PRUMIBIO STUDY.

Author

Yuriko Tanabe, Takuma Hayashi, Mako Okada, Hiroyuki Aburatani, Susumu Tonegawa, Kaoru Abiko, and Ikuo Konishi

Published

2024

8. Importance of diagnostic methods for round ligament leiomyomas in clinical practice

Author

Takuma Hayashi, Nobuo Yaegashi, Susumu Tonegawa, and Ikuo Konishi

Subjects

Radiology, Nuclear Medicine and imaging

Abstract

Benign uterine leiomyoma (U.LMA) and malignant uterine leiomyosarcoma (U.LMS), which are both uterine mesenchymal tumors, are distinguished by the number of cells with mitotic activity. However, uterine mesenchymal tumors contain tumor cells with various cell morphologies; therefore, making a diagnosis, including differentiation between benign tumors and malignant tumors, is difficult. For example, round ligament leiomyomas are uterine leiomyomas with a very rare placental lobed tissue morphology that can be misdiagnosed as a malignant uterine leiomyosarcoma because of its rarity and characteristic appearance on gross examination. Similar to the detection of a suspicious malignant mass during magnetic resonance imaging (MRI) examination by medical staff, healthcare professionals must understand the characteristic appearance of round ligament leiomyomas. Clinicians and pathologists must understand the oncologic features of round ligament leiomyomas to prevent misdiagnosis of malignancy and consequent overtreatment.

Published

2023

9. Differential attentional control mechanisms by two distinct noradrenergic coeruleo-frontal cortical pathways

Author

Susumu Tonegawa, Jiesi Feng, Andrea Bari, Sangyu Xu, Daigo Takeuchi, Yulong Li, and Michele Pignatelli

Subjects

Prefrontal Cortex, Mice, Transgenic, Biology, Optogenetics, Impulsivity, Mice, Norepinephrine, Cognition, medicine, Animals, Premovement neuronal activity, Attention, Prefrontal cortex, Neurons, Multidisciplinary, Attentional control, Brain, Biological Sciences, Frontal Lobe, Inhibition, Psychological, Impulsive Behavior, Locus coeruleus, Locus Coeruleus, Orbitofrontal cortex, medicine.symptom, Neuroscience, medicine.drug

Abstract

The attentional control of behavior is a higher-order cognitive function that operates through attention and response inhibition. The locus coeruleus (LC), the main source of norepinephrine in the brain, is considered to be involved in attentional control by modulating the neuronal activity of the prefrontal cortex (PFC). However, evidence for the causal role of LC activity in attentional control remains elusive. Here, by using behavioral and optogenetic techniques, we investigate the effect of LC neuron activation or inhibition in operant tests measuring attention and response inhibition (i.e., a measure of impulsive behavior). We show that LC neuron stimulation increases goal-directed attention and decreases impulsivity, while its suppression exacerbates distractibility and increases impulsive responding. Remarkably, we found that attention and response inhibition are under the control of two divergent projections emanating from the LC: one to the dorso-medial PFC and the other to the ventro-lateral orbitofrontal cortex, respectively. These findings are especially relevant for those pathological conditions characterized by attention deficits and elevated impulsivity.

Published

2020

10. Reply to Lehr and Stöber: What's in a name? On the distinction between temporal coding and internally driven activity

Author

Christopher J. MacDonald and Susumu Tonegawa

Subjects

Cognitive science, Multidisciplinary, Interpretation (logic), Letter, Computer science, Perspective (graphical), Content (measure theory), Names, Mnemonic, Constant (mathematics), Spatial memory, Task (project management), Coding (social sciences)

Abstract

In a recent letter (1), Lehr and Stober argue against our interpretation of neural activity during the mnemonic delay period of a spatial working memory task as temporal coding (2). Because external cues (environmental and body derived) are kept constant during this period, they suggest activity reflects internally driven maintenance of spatial mnemonic content (3). From this perspective, they interpret our findings as evidence that the dCA2→dCA1 pathway stabilizes internally driven neural sequences. In support for their argument, Lehr and Stober (1) propose that, because elapsed time is not informative about which choice the mouse should make, there ought to be no “explicit time … [↵][1]1To whom correspondence may be addressed. Email: cjmac{at}mit.edu or tonegawa{at}mit.edu. [1]: #xref-corresp-1-1

Published

2021

11. Profiling of Target Molecules for Immunotherapy in Mesenchymal Tumors

Author

Yae Kanai, Kenji Sano, Dorit Zharhary, Hiroyuki Aburatani, Takuma Hayashi, Ikuo Konishi, Tomoyuki Ichimura, Susumu Tonegawa, and Nobuo Yaegashi

Subjects

Text mining, business.industry, medicine.medical_treatment, Mesenchymal stem cell, Medicine, Profiling (information science), General Medicine, Computational biology, Immunotherapy, business, Letter to the Editor

Published

2019

12. Cingulate-motor circuits update rule representations for sequential choice decisions

Author

Lovett C, Heather A. Sullivan, Kawai T, Dheeraj S. Roy, Takeuchi D, Shruti Muralidhar, Ian R. Wickersham, and Susumu Tonegawa

Subjects

Cingulate cortex, medicine.anatomical_structure, Computer science, medicine, Cortical neurons, Sequential choice, Optogenetics, Adaptive choice, Neuroscience, Anterior cingulate cortex, Motor cortex

Abstract

Anterior cingulate cortex mediates the flexible updating of an animal’s choice responses upon rule changes in the environment. However, how anterior cingulate cortex entrains motor cortex to reorganize rule representations and generate required motor outputs remains unclear. Here, we demonstrate that chemogenetic silencing of the projection terminals of cingulate cortical neurons in secondary motor cortex disrupted sequential choice performance in trials immediately following rule switches, suggesting that these inputs are necessary to update rule representations for choice decisions stored in the motor cortex. Indeed, the silencing of cingulate cortex decreased rule selectivity of secondary motor cortical neurons. Furthermore, optogenetic silencing of cingulate cortical neurons that was temporally targeted to error trials immediately after rule switches exacerbated errors in following trials. These results suggest that cingulate cortex monitors behavioral errors and update rule representations in motor cortex, revealing a critical role for cingulate-motor circuits in adaptive choice behaviors.

Published

2021

13. Crucial role for CA2 inputs in the sequential organization of CA1 time cells supporting memory

Author

Susumu Tonegawa and Christopher J. MacDonald

Subjects

Sequential organization, Multidisciplinary, Computer science, Ran, Place cell, Hippocampus, Mnemonic, Biological Sciences, Optogenetics, Hippocampal formation, Neuroscience, Coding (social sciences)

Abstract

There is considerable evidence for hippocampal time cells that briefly activate in succession to represent the temporal structure of memories. Previous studies have shown that time cells can be disrupted while leaving place cells intact, indicating that spatial and temporal information can be coded in parallel. However, the circuits in which spatial and temporal information are coded have not been clearly identified. Here we investigated temporal and spatial coding by dorsal hippocampal CA1 (dCA1) neurons in mice trained on a classic spatial working-memory task. On each trial, the mice approached the same choice point on a maze but were trained to alternate between traversing one of two distinct spatial routes (spatial coding phase). In between trials, there was a 10-s mnemonic delay during which the mouse continuously ran in a fixed location (temporal coding phase). Using cell-type–specific optogenetic methods, we found that inhibiting dorsal CA2 (dCA2) inputs into dCA1 degraded time cell coding during the mnemonic delay and impaired the mouse’s subsequent memory-guided choice. Conversely, inhibiting dCA2 inputs during the spatial coding phase had a negligible effect on place cell activity in dCA1 and no effect on behavior. Collectively, our work demonstrates that spatial and temporal coding in dCA1 is largely segregated with respect to the dCA2–dCA1 circuit and suggests that CA2 plays a critical role in representing the flow of time in memory within the hippocampal network.

Published

2021

14. Author response: Reinforcement biases subsequent perceptual decisions when confidence is low, a widespread behavioral phenomenon

Author

Matteo Carandini, Tobias H. Donner, Armin Lak, Junya Hirokawa, Adam Kepecs, Paul Masset, Anne E Urai, Emily Hueske, Naoshige Uchida, Torben Ott, and Susumu Tonegawa

Subjects

Perception, media_common.quotation_subject, Phenomenon, Reinforcement, Psychology, Cognitive psychology, media_common

Published

2020

15. Memory engrams: Recalling the past and imagining the future

Author

Sheena A. Josselyn, Susumu Tonegawa, RIKEN-MIT Center for Neural Circuit Genetics, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Biology, and Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences

Subjects

Cognitive science, Brain Chemistry, Neurons, 0303 health sciences, Memory Disorders, Multidisciplinary, Brain chemistry, Extramural, Neural substrate, Brain, Engram, Article, 03 medical and health sciences, 0302 clinical medicine, Mental Recall, Animals, Humans, Psychology, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

BACKGROUND: The idea that memory is stored as enduring changes in the brain dates back at least to the time of Plato and Aristotle (circa 350 BCE), but its scientific articulation emerged in the 20th century when Richard Semon introduced the term “engram” to describe the neural substrate for storing and recalling memories. Essentially, Semon proposed that an experience activates a population of neurons that undergo persistent chemical and/or physical changes to become an engram. Subsequent reactivation of the engram by cues available at the time of the experience induces memory retrieval. After Karl Lashley failed to find the engram in a rat brain, studies attempting to localize an engram were largely abandoned. Spurred by Donald O. Hebb’s theory that augmented synaptic strength and neuronal connectivity are critical for memory formation, many researchers showed that enhanced synaptic strength was correlated with memory. Nonetheless, the causal relationship between these enduring changes in synaptic connectivity with a specific, behaviorally identifiable memory at the level of the cell ensemble (an engram) awaited further advances in experimental technologies. ADVANCES: The resurgence in research examining engrams may be linked to two complementary studies that applied intervention strategies to target individual neurons in an engram supporting a specific memory in mice. One study showed that ablating the subset of lateral amygdala neurons allocated to a putative engram disrupted subsequent memory retrieval (loss of function). The second study showed that artificially reactivating a subset of hippocampal dentate gyrus neurons that were active during a fearful experience (and, therefore, part of a putative engram) induced memory retrieval in the absence of external retrieval cues (gain of function). Subsequent findings from many labs used similar strategies to identify engrams in other brain regions supporting different types of memory. There are several recent advances in engram research. First, eligible neurons within a given brain region were shown to compete for allocation to an engram, and relative neuronal excitability determines the outcome of this competition. Excitability-based competition also guides the organization of multiple engrams in the brain and determines how these engrams interact. Second, research examining the nature of the off-line, enduring changes in engram cells (neurons that are critical components of an engram) found increased synaptic strength and spine density in these neurons as well as preferential connectivity to other downstream engram cells. Therefore, both increased intrinsic excitability and synaptic plasticity work hand in hand to form engrams, and these mechanisms are also implicated in memory consolidation and retrieval processes. Third, it is now possible to artificially manipulate memory encoding and retrieval processes to generate false memories, or even create a memory in mice without any natural sensory experience (implantation of a memory for an experience that did not occur). Fourth, “silent” engrams were discovered in amnesic mice; artificial reactivation of silent engrams induces memory retrieval, whereas natural cues cannot. Endogenous engram silencing may contribute to the change in memory over time (e.g., systems memory consolidation) or in different circumstances (e.g., fear memory extinction). These findings suggest that once formed, an engram may exist in different states (from silent to active) on the basis of their retrievability. Although initial engram studies focused on single brain regions, an emerging concept is that a given memory is supported by an engram complex, composed of functionally connected engram cell ensembles dispersed across multiple brain regions, with each ensemble supporting a component of the overall memory. OUTLOOK: The ability to identify and manipulate engram cells and brainwide engram complexes has introduced an exciting new era of memory research. The findings from many labs are beginning to define an engram as the basic unit of memory. However, many questions remain. In the short term, it is critical to characterize how information is stored in an engram, including how engram architecture affects memory quality, strength, and precision; how multiple engrams interact; how engrams change over time; and the role of engram silencing in these processes. The long-term goal of engram research is to leverage the fundamental findings from rodent engram studies to understand how information is acquired, stored, and used in humans and facilitate the treatment of human memory, or other information-processing, disorders. The development of low- to noninvasive technology may enable new human therapies based on the growing knowledge of engrams in rodents.

Published

2020

16. The role of engram cells in the systems consolidation of memory

Author

Takashi Kitamura, Susumu Tonegawa, Mark D. Morrissey, RIKEN-MIT Center for Neural Circuit Genetics, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, and Massachusetts Institute of Technology. Department of Biology

Subjects

Neurons, 0301 basic medicine, General Neuroscience, Models, Neurological, fungi, Brain, Prefrontal Cortex, Context (language use), Engram, Hippocampus, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Mental Recall, Neural Pathways, Animals, Humans, Memory consolidation, sense organs, skin and connective tissue diseases, Psychology, Neuroscience, 030217 neurology & neurosurgery, Memory Consolidation

Abstract

What happens to memories as days, weeks and years go by has long been a fundamental question in neuroscience and psychology. For decades, researchers have attempted to identify the brain regions in which memory is formed and to follow its changes across time. The theory of systems consolidation of memory (SCM) suggests that changes in circuitry and brain networks are required for the maintenance of a memory with time. Various mechanisms by which such changes may take place have been hypothesized. Recently, several studies have provided insight into the brain networks driving SCM through the characterization of memory engram cells, their biochemical and physiological changes and the circuits in which they operate. In this Review, we place these findings in the context of the field and describe how they have led to a revamped understanding of SCM in the brain.

Published

2018

17. Author Correction: Hippocampal neurons represent events as transferable units of experience

Author

Susumu Tonegawa, Jared Martin, Wannan Yang, and Chen Sun

Subjects

General Neuroscience, Published Erratum, MEDLINE, Hippocampal formation, Psychology, Neuroscience

Published

2021

18. Hippocampal neurons represent events as transferable units of experience

Author

Jared Martin, Wannan Yang, Susumu Tonegawa, and Chen Sun

Subjects

0301 basic medicine, Neurons, General Neuroscience, digestive, oral, and skin physiology, Sensory system, Hippocampal formation, Biology, 03 medical and health sciences, Mice, 030104 developmental biology, 0302 clinical medicine, Animals, Maze Learning, Neuroscience, CA1 Region, Hippocampal, 030217 neurology & neurosurgery, Event (probability theory)

Abstract

The brain codes continuous spatial, temporal and sensory changes in daily experience. Recent studies suggest that the brain also tracks experience as segmented subdivisions (events), but the neural basis for encoding events remains unclear. Here, we designed a maze for mice, composed of four materially indistinguishable lap events, and identify hippocampal CA1 neurons whose activity are modulated not only by spatial location but also lap number. These 'event-specific rate remapping' (ESR) cells remain lap-specific even when the maze length is unpredictably altered within trials, which suggests that ESR cells treat lap events as fundamental units. The activity pattern of ESR cells is reused to represent lap events when the maze geometry is altered from square to circle, which suggests that it helps transfer knowledge between experiences. ESR activity is separately manipulable from spatial activity, and may therefore constitute an independent hippocampal code: an 'event code' dedicated to organizing experience by events as discrete and transferable units.

Published

2019

19. Brain-wide mapping of contextual fear memory engram ensembles supports the dispersed engram complex hypothesis

Author

Jared Martin, Lee Kamensky, Heejin Choi, Susumu Tonegawa, Jae H. Cho, Kwanghun Chung, Dheeraj S. Roy, Sachie K. Ogawa, and Young Gyun Park

Subjects

0303 health sciences, Recall, Hippocampus, Engram, Optogenetics, Contextual fear, Biology, Amygdala, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Cortex (anatomy), medicine, Abstract Summary, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

GRAPHICAL ABSTRACT SUMMARY Neuronal ensembles that hold specific memory (memory engrams) have been identified in the hippocampus, amygdala, and cortex. It has been hypothesized that engrams for a specific memory are distributed among multiple brain regions that are functionally connected. Here, we report the hitherto most extensive engram map for contextual fear memory by characterizing activity-tagged neurons in 409 regions using SHIELD-based tissue phenotyping. The mapping was aided by a novel engram index, which identified cFos+ brain regions holding engrams with a high probability. Optogenetic manipulations confirmed previously known engrams and revealed new engrams. Many of these engram holding-regions were functionally connected to the CA1 or amygdala engrams. Simultaneous chemogenetic reactivation of multiple engrams, which mimics natural memory recall, conferred a greater level of memory recall than reactivation of a single engram ensemble. Overall, our study supports the hypothesis that a memory is stored in functionally connected engrams distributed across multiple brain regions.

Published

2019

20. CA1 pyramidal cells organize an episode by segmented and ordered events

Author

Jared Martin, Chen Sun, Yang W, and Susumu Tonegawa

Subjects

Computer science, business.industry, Chunking (psychology), Pattern recognition, Artificial intelligence, business

Abstract

A prevailing view is that the brain represents episodic experience as the continuous moment to moment changes in the experience. Whether the brain also represents the same experience as a sequence of discretely segmented events, is unknown. Here, we report a hippocampal CA1 “chunking code”, tracking an episode as its discrete event subdivisions (“chunks”) and the sequential relationships between them. The chunking code is unaffected by unpredicted variations within the events, reflecting the code’s flexible nature by being organized around events as abstract units. The chunking code changes accordingly when relationships between events are disrupted or modified. The discrete chunking code and continuous spatial code are represented in the same cells, but in an orthogonal manner, and can be independently perturbed. Optogenetic inactivation of MEC inputs to CA1 disrupts the chunking but not spatial code. The chunking code may be fundamental for representing an episode, alongside codes tracking continuous changes.

Published

2019

21. Amygdala Reward Neurons Form and Store Fear Extinction Memory

Author

Joshua Kim, Xiangyu Zhang, Susumu Tonegawa, Massachusetts Institute of Technology. Department of Biology, and Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences

Subjects

0301 basic medicine, Male, Fear memory, Dopamine and cAMP-Regulated Phosphoprotein 32, Mice, Transgenic, Engram, Amygdala, Extinction, Psychological, 03 medical and health sciences, Mice, 0302 clinical medicine, Reward, Memory, Conditioning, Psychological, Biological neural network, medicine, Animals, Valence (psychology), Neuronal population, Neurons, General Neuroscience, Extinction (psychology), social sciences, Fear, humanities, Optogenetics, 030104 developmental biology, medicine.anatomical_structure, nervous system, Extinction memory, Neuron, Psychology, Neuroscience, 030217 neurology & neurosurgery, Basolateral amygdala

Abstract

SummaryThe ability to extinguish conditioned fear memory is critical for adaptive control of fear response, and its impairment is a hallmark of emotional disorders like post-traumatic stress disorder (PTSD). Fear extinction is thought to take place when animals form a new memory that suppresses the original fear memory. However, little is known about the nature and the site of formation and storage of the new extinction memory. Here, we demonstrate that a fear extinction memory engram is formed and stored in a genetically distinct basolateral amygdala (BLA) neuronal population that drive reward behaviors and antagonize the BLA’s original fear neurons. The activation of the fear extinction engram neurons and natural reward-responsive neurons overlap extensively in the BLA. Furthermore, these two neuron subsets are mutually interchangeable in driving reward behaviors and fear extinction behaviors. Thus, fear extinction memory is a newly formed reward memory.

Published

2019

22. A Hippocampal Code for Experience Via Its Events as Abstract Units

Author

Jared Martin, Chen Sun, Wannan Yang, and Susumu Tonegawa

Subjects

Computer science, Encoding (memory), digestive, oral, and skin physiology, Code (cryptography), Abstract knowledge, Sensory system, Hippocampal formation, Spatial code, equipment and supplies, Transfer of learning, human activities, Neuroscience

Abstract

The brain codes continuous spatial, temporal, and sensory changes in daily experience. Recent studies suggest that the brain also tracks experience as segmented subdivisions (events), but the neural basis for the encoding of events remains unclear. We designed a maze for mice composed of 4 materially indistinguishable lap events, and report hippocampal CA1 neurons whose activity is modulated by lap number. This lap-specific ‘chunk code’ is separate from the spatial code. The chunk code remains lap-specific even when the maze length is unpredictably altered within the laps, showing that this code treats segmented lap events as abstract and fundamental units of the experience. The chunk code is reused to represent lap events when the maze geometry is altered from a square to a circle, suggesting that this code promotes a transfer of abstract knowledge between similar experiences. The chunk code tracks events and may be a fundamental representation of experience.

Published

2019

23. Potential biomarkers associated with malignancy in uterine mesenchymal tumors.

Author

Takuma Hayashi, Nobuo Yaegashi, Susumu Tonegawa, and Ikuo Konishi

Published

2021

24. Potential biomarkers associated with malignancy in uterine mesenchymal tumors

Author

Nobuo Yaegashi, Ikuo Konishi, Susumu Tonegawa, and Takuma Hayashi

Subjects

Oncology, business.industry, Potential biomarkers, Mesenchymal stem cell, Cancer research, Obstetrics and Gynecology, Medicine, business, Malignancy, medicine.disease

Published

2021

25. Restoration of early thymocyte differentiation in T-cell receptor beta-chain-deficient mutant mice by transmembrane signaling through CD3 epsilon

Author

Levelt, Christiaan N., Mombaerts, Peter, Iglesias, Antonio, Susumu Tonegawa, and Eichmann, Klaus

Subjects

T cells -- Receptors, Interleukin-2 -- Receptors, Monoclonal antibodies -- Analysis, Cellular signal transduction -- Research, Science and technology

Abstract

Investigation confirm that the treatment of fetal thymic organ cultures with anti-CD3 epsilon monocloned antibodies in various T-cell receptor (TCR) beta-chain-deficient mouse strains can induce the CD4+8+ double-positive phase. The expression of CD3 epsilon on the thymocyte surface occurs before, regardless of the TCR beta chain.

Published

1993

26. Amino acid substitutions in the floor of the putative antigen-binding site of H-2T22 affect recognition by a gamma delta T-cell receptor

Author

Shigeru Moriwaki, Korn, Bobby S., Yoshiaki Ichikawa, Van Kaer, Luc, and Susumu Tonegawa

Subjects

T cells -- Receptors, Mutagenesis -- Usage, Major histocompatibility complex -- Analysis, Clone cells -- Analysis, Antigen receptors, T cell -- Analysis, Science and technology

Abstract

In vitro mutagenesis analysis of the H-2T region gene product T22b gene, in which a self-reactive gamma delta T-cell clone (KN6) is specific, was used to explore the possible role of a peptide in the association between the KN6 gamma delta T-cell receptor and T22b. Recognition by the gamma delta T-cell receptor is influenced by mutations at the bottom of the putative antigen-binding groove of T22b. The association does involve a peptide.

Published

1993

27. Spontaneous development on inflammatory bowel disease in T cell receptor mutant mice

Author

Mombaerts, Peter, Mizoguchi, Emiko, Grusby, Michael J., Glimcher, Laurie H., Bhan, Atul K., and Susumu Tonegawa

Subjects

T cells -- Receptors, Inflammatory bowel diseases -- Genetic aspects, Mutation (Biology) -- Analysis, Biological sciences

Abstract

Inflammatory bowel disease (IBD) simultaneously accompanies the phenomenon of aging in T cell receptor (TCR) mutant mice. The existence of B lymphocytes and the nonoccurrence of class II major histocompatibility complex-restricted CD4+ alpha-beta T cells are the prerequisites for the onset of chronic colitis in TCR alpha mutant, TCR beta mutant and TCR beta times delta double mutant. Molecular basis for the pathogenesis of certain kinds of IBD in humans may involve abnormal functioning of mucosal immune system.

Published

1993

28. Different roles of alpha beta and gamma delta T cells in immunity against an intracellular bacterial pathogen

Author

Mombaerts, Peter, Arnoldi, Jorg, Russ, Friedemann, Susumu Tonegawa, and Kaufmann, Stefan H.E.

Subjects

Infection -- Causes of, T cells -- Influence, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Researches on mice with no alpha-beta or gamma-delta T cells and infected with listeria monocytogenes revealed that secondary infection resistance is primarily due to alpha-beta T cells. Abnormal lever lesions were observed in infected mice with deficiency in gamma-delta T cells. Either alpha-beta or gamma-delta T cells are adequate for initial protection against primary listeriosis. The formation of granulomatous lesions is determined by the alpha-beta T cell subset.

Published

1993

29. Cytotoxic and interferon gamma-producing activities of gamma-delta T cells in the mouse intestinal epithelium are strain dependent

Author

Hiromichi Ishikawa, Yuqing Li, Abeliovich, Asa, Shigeki Yamamoto, Kaufmann, Stefan H.E., and Susumu Tonegawa

Subjects

Mice -- Physiological aspects, Cell metabolism -- Research, Major histocompatibility complex -- Analysis, Science and technology

Abstract

The anti T-cell receptor monoclonal antibody-mediated redirected lysis formed the base for attempts to explore the cytolytic action of newly isolated intraepithelial T cells (i-/EL) from the intestines of various mouse strains. Unlike the cytolytic activity of alpha-beta-i-IEL, the activity of delta-i-/EL was strain dependent. The cytoxicity is regulated by at least a pair of genes expressed in hemopoietic cells. One of them is associated with the major histocompatibility complex.

Published

1993

30. TAP1-dependent peptide translocation in vitro is ATP dependent and peptide selective

Author

Shepherd, James C., Schumacher, Ton N.M., Ashton-Rickardt, Philip G., Suguru Imaeda, Ploegh, Hidde L., Janeway, Charles A., Jr., and Susumu Tonegawa

Subjects

T cells -- Research, Peptides -- Identification and classification, Biological sciences

Abstract

Foreign protein peptide recognizing by T cells enables impairment prevention. This was predominantly observed in proteins attached to the major histocompatibility complex (MHC) class 1 molecules, which are responsible for peptide-endoplasmic reticulum binding. Two MHC class II locus genes encoding proteins are essential for a substantial peptides presence. Three genes are considered transporters associated with antigen processing (TAP 1 and TAP 2), and belong to the membrane translocating ATP-binding family.

Published

1993

31. Peptide contributes to the specificity of positive selection of CD8+ T cells in the thymus

Author

Ashton-Rickardt, Philip G., Luc Van Kaer, Schumacher, Ton N.M., Ploegh, Hidde L., and Susumu Tonegawa

Subjects

Peptides -- Usage, Biological sciences

Abstract

The residues involved in the interaction with TCRS were altered resulting in the conversion of a nonselecting peptide into a mixture of selecting peptides. Self-peptides were derived from C57 BL/6 and employed in the experiment which revealed that self-peptides influence the properties of CD8+ T cells. Mice lacking in the specific gene which encodes the peptide dealing with antigen processing have been found to have lower levels of MH4 class I molecular and fewer CD8+ T cells.

Published

1993

32. The Identification Of Somatic Mutations In Interferon-g Signal Molecules In Human Uterine Leiomyosarcoma

Author

Susumu Tonegawa, Hirofumi Ando, Takuma Hayashi, Tomoyuki Ichimura, Nobuo Yaegashi, Koichi Ida, Tanri Shiozawa, Hiroyuki Aburatani, Ikuo Konishi, Miki Kawano, and Yae Kanai

Subjects

Germline mutation, Somatic cell, Interferon, Uterine leiomyosarcoma, business.industry, Immunology, Cancer research, medicine, Identification (biology), business, medicine.drug

Published

2016

33. Memory retrieval by activating engram cells in mouse models of early Alzheimer’s disease

Author

Michele Pignatelli, Teryn I. Mitchell, Dheeraj S. Roy, Tomás J. Ryan, Susumu Tonegawa, and Autumn Arons

Subjects

Male, 0301 basic medicine, Aging, Memory, Long-Term, Dendritic Spines, Memory, Episodic, Long-Term Potentiation, Hippocampus, Amnesia, Mice, Transgenic, Plaque, Amyloid, tau Proteins, Engram, Biology, Amyloid beta-Protein Precursor, Mice, 03 medical and health sciences, 0302 clinical medicine, Alzheimer Disease, Early Medical Intervention, Presenilin-1, medicine, Animals, Humans, Transgenes, Episodic memory, Multidisciplinary, Long-term memory, Dentate gyrus, Neuroanatomy of memory, Optogenetics, Disease Models, Animal, 030104 developmental biology, Dentate Gyrus, Synapses, Memory consolidation, medicine.symptom, Neuroscience, 030217 neurology & neurosurgery

Abstract

Alzheimer's disease (AD) is a neurodegenerative disorder characterized by progressive memory decline and subsequent loss of broader cognitive functions. Memory decline in the early stages of AD is mostly limited to episodic memory, for which the hippocampus has a crucial role. However, it has been uncertain whether the observed amnesia in the early stages of AD is due to disrupted encoding and consolidation of episodic information, or an impairment in the retrieval of stored memory information. Here we show that in transgenic mouse models of early AD, direct optogenetic activation of hippocampal memory engram cells results in memory retrieval despite the fact that these mice are amnesic in long-term memory tests when natural recall cues are used, revealing a retrieval, rather than a storage impairment. Before amyloid plaque deposition, the amnesia in these mice is age-dependent, which correlates with a progressive reduction in spine density of hippocampal dentate gyrus engram cells. We show that optogenetic induction of long-term potentiation at perforant path synapses of dentate gyrus engram cells restores both spine density and long-term memory. We also demonstrate that an ablation of dentate gyrus engram cells containing restored spine density prevents the rescue of long-term memory. Thus, selective rescue of spine density in engram cells may lead to an effective strategy for treating memory loss in the early stages of AD.

Published

2016

34. Biological Analyses for Characterization of the Uterine Sarcoma Using Mouse Model

Author

Yae Kanai, Hirofumi Ando, Tomoyuki Ichimura, Nobuo Yaegashi, Ikuo Konishi, Koichi Ida, Takuma Hayashi, Mari Kasai, and Susumu Tonegawa

Subjects

Uterine sarcoma, business.industry, Critical factors, Mesenchymal stem cell, Cancer research, Medicine, Uterine body, Sarcoma, business, medicine.disease

Abstract

Uterine sarcomas are neoplastic malignancies that typically arise in tissues of a mesenchymal origin in uterine body. The identifi cation of novel molecular mechanisms leading to sarcoma formation, and the establishment of new therapies and biomarkers has been hampered by several critical factors.

Published

2017

35. Somatic mutations in IFN-γ-Signal molecules in human uterine leiomyosarcoma

Author

Dorit Zharhary, Israel SIGMA-Aldrich Israel, Ikuo Konishi, Hiroyuki Aburatani, Susumu Tonegawa, Tomoyuki Ichimura, Nobuo Yaegashi, Takuma Hayashi, Yae Kanai, Mari Kasai, and Kenji Sano

Subjects

Somatic cell, Uterine leiomyosarcoma, Chemistry, Cancer research, General Earth and Planetary Sciences, Signal, General Environmental Science

Published

2018

36. Engram Cell Excitability State Determines the Efficacy of Memory Retrieval

Author

Chanel Lovett, Lillian M. Smith, Susumu Tonegawa, Shruti Muralidhar, Tomás J. Ryan, Michele Pignatelli, Dheeraj S. Roy, RIKEN-MIT Center for Neural Circuit Genetics, Massachusetts Institute of Technology. Department of Biology, Picower Institute for Learning and Memory, and Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences

Subjects

0301 basic medicine, Patch-Clamp Techniques, Hippocampus, Mice, Transgenic, Engram, Membrane Potentials, 03 medical and health sciences, Mice, 0302 clinical medicine, Bacterial Proteins, Channelrhodopsins, Transduction, Genetic, Conditioning, Psychological, Animals, Potassium Channels, Inwardly Rectifying, Freezing Reaction, Cataleptic, Adaptive behavior, Neurons, Protein Synthesis Inhibitors, Microscopy, Confocal, Recall, General Neuroscience, Imidazoles, Context recognition, Pattern completion, Luminescent Proteins, 030104 developmental biology, Gene Expression Regulation, Doxycycline, Dentate Gyrus, Mental Recall, State (computer science), Contextual memory, Psychology, Neuroscience, 030217 neurology & neurosurgery, Anisomycin, Phenanthrolines

Abstract

Animals need to optimize the efficacy of memory retrieval to adapt to environmental circumstances for survival. The recent development of memory engram labeling technology allows a precise investigation of the processes associated with the recall of a specific memory. Here, we show that engram cell excitability is transiently increased following memory reactivation. This short-term increase of engram excitability enhances the subsequent retrieval of specific memory content in response to cues and is manifest in the animal's ability to recognize contexts more precisely and more effectively. These results reveal a hitherto unknown transient enhancement of context recognition based on the plasticity of engram cell excitability. They also suggest that recall of a contextual memory is influenced by previous but recent activation of the same engram. The state of excitability of engram cells mediates differential behavioral outcomes upon memory retrieval and may be crucial for survival by promoting adaptive behavior.

Published

2018

37. Memory engram storage and retrieval

Author

Michele Pignatelli, Dheeraj S. Roy, Tomás J. Ryan, Susumu Tonegawa, Picower Institute for Learning and Memory, Tonegawa, Susumu, Pignatelli di Spinazzola, Michele, Roy, Dheeraj, and Ryan, Tomas John

Subjects

Neurons, Neuronal Plasticity, Hardware_MEMORYSTRUCTURES, Recall, Long-term memory, Neuroscience(all), General Neuroscience, Amnesia, Engram, Spatial memory, Optogenetics, Memory, Mental Recall, Neuroplasticity, Explicit memory, medicine, Animals, Humans, Amnesia, Retrograde, Memory consolidation, Nerve Net, medicine.symptom, Psychology, Genes, Immediate-Early, Neuroscience

Abstract

A great deal of experimental investment is directed towards questions regarding the mechanisms of memory storage. Such studies have traditionally been restricted to investigation of the anatomical structures, physiological processes, and molecular pathways necessary for the capacity of memory storage, and have avoided the question of how individual memories are stored in the brain. Memory engram technology allows the labeling and subsequent manipulation of components of specific memory engrams in particular brain regions, and it has been established that cell ensembles labeled by this method are both sufficient and necessary for memory recall. Recent research has employed this technology to probe fundamental questions of memory consolidation, differentiating between mechanisms of memory retrieval from the true neurobiology of memory storage.

Published

2015

38. Memory Engram Cells Have Come of Age

Author

Roger L. Redondo, Xu Liu, Steve Ramirez, Susumu Tonegawa, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, tonegawa, susumu, Tonegawa, Susumu, Liu, Xu, Ramirez Moreno, Steve, and Redondo Pena, Roger L

Subjects

Cognitive science, Neurons, Neuronal Plasticity, Recall, Conceptualization, General Neuroscience, Neuroscience(all), Models, Neurological, Brain, Engram, Optogenetics, Memory, Synaptic plasticity, Animals, Humans, Nerve Net, Psychology, Content (Freudian dream analysis), Neuroscience

Abstract

The idea that memory is stored in the brain as physical alterations goes back at least as far as Plato, but further conceptualization of this idea had to wait until the 20th century when two guiding theories were presented: the “engram theory” of Richard Semon and Donald Hebb’s “synaptic plasticity theory.” While a large number of studies have been conducted since, each supporting some aspect of each of these theories, until recently integrative evidence for the existence of engram cells and circuits as defined by the theories was lacking. In the past few years, the combination of transgenics, optogenetics, and other technologies has allowed neuroscientists to begin identifying memory engram cells by detecting specific populations of cells activated during specific learning epochs and by engineering them not only to evoke recall of the original memory, but also to alter the content of the memory., RIKEN Brain Science Institute, Howard Hughes Medical Institute, JPB Foundation

Published

2015

39. Entorhinal–hippocampal neuronal circuits bridge temporally discontiguous events

Author

Christopher J. MacDonald, Susumu Tonegawa, Takashi Kitamura, Massachusetts Institute of Technology. Department of Biology, Picower Institute for Learning and Memory, RIKEN-MIT Center for Neural Circuit Genetics, Kitamura, Takashi, MacDonald, Christopher J, and Tonegawa, Susumu

Subjects

Cognitive Neuroscience, Association Learning, Hippocampus, Review, Hippocampal formation, Time perception, Inhibitory postsynaptic potential, Entorhinal cortex, Associative learning, Cellular and Molecular Neuroscience, Neuropsychology and Physiological Psychology, Neural Pathways, Time Perception, Biological neural network, Animals, Entorhinal Cortex, Humans, Psychology, Neuroscience, Episodic memory

Abstract

The entorhinal cortex (EC)–hippocampal (HPC) network plays an essential role for episodic memory, which preserves spatial and temporal information about the occurrence of past events. Although there has been significant progress toward understanding the neural circuits underlying the spatial dimension of episodic memory, the relevant circuits subserving the temporal dimension are just beginning to be understood. In this review, we examine the evidence concerning the role of the EC in associating events separated by time—or temporal associative learning—with emphasis on the function of persistent activity in the medial entorhinal cortex layer III (MECIII) and their direct inputs into the CA1 region of HPC. We also discuss the unique role of Island cells in the medial entorhinal cortex layer II (MECII), which is a newly discovered direct feedforward inhibitory circuit to CA1. Finally, we relate the function of these entorhinal cortical circuits to recent findings concerning hippocampal time cells, which may collectively activate in sequence to bridge temporal gaps between discontiguous events in an episode., RIKEN Brain Science Institute, Howard Hughes Medical Institute, JPB Foundation

Published

2015

40. Differentiation of forebrain and hippocampal dopamine 1-class receptors, D1R and D5R, in spatial learning and memory

Author

Susumu Tonegawa and Joshua Sariñana

Subjects

0301 basic medicine, Cognitive Neuroscience, Dentate gyrus, Ventral striatum, Hippocampus, In situ hybridization, Water maze, Hippocampal formation, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Dopamine, Forebrain, medicine, Psychology, Neuroscience, 030217 neurology & neurosurgery, medicine.drug

Abstract

Activation of prefrontal cortical (PFC), striatal, and hippocampal dopamine 1-class receptors (D1R and D5R) is necessary for normal spatial information processing. Yet the precise role of the D1R versus the D5R in the aforementioned structures, and their specific contribution to the water-maze spatial learning task remains unknown. D1R- and D5R-specific in situ hybridization probes showed that forebrain restricted D1R and D5R KO mice (F-D1R/D5R KO) displayed D1R mRNA deletion in the medial (m)PFC, dorsal and ventral striatum, and the dentate gyrus (DG) of the hippocampus. D5R mRNA deletion was limited to the mPFC, the CA1 and DG hippocampal subregions. F-D1R/D5R KO mice were given water-maze training and displayed subtle spatial latency differences between genotypes and spatial memory deficits during both regular and reversal training. To differentiate forebrain D1R from D5R activation, forebrain restricted D1R KO (F-D1R KO) and D5R KO (F-D5R KO) mice were trained on the water-maze task. F-D1R KO animals exhibited escape latency deficits throughout regular and reversal training as well as spatial memory deficits during reversal training. F-D1R KO mice also showed perseverative behavior during the reversal spatial memory probe test. In contrast, F-D5R KO animals did not present observable deficits on the water-maze task. Because F-D1R KO mice showed water-maze deficits we tested the necessity of hippocampal D1R activation for spatial learning and memory. We trained DG restricted D1R KO (DG-D1R KO) mice on the water-maze task. DG-D1R KO mice did not present detectable spatial memory deficit, but did show subtle deficits during specific days of training. Our data provides evidence that forebrain D5R activation plays a unique role in spatial learning and memory in conjunction with D1R activation. Moreover, these data suggest that mPFC and striatal, but not DG D1R activation are essential for spatial learning and memory. © 2015 Wiley Periodicals, Inc.

Published

2015

41. Distinct speed dependence of entorhinal island and ocean cells, including respective grid cells

Author

Lacey J. Kitch, Takashi Kitamura, Chen Sun, Jun Yamamoto, Susumu Tonegawa, Jared Martin, Mark J. Schnitzer, and Michele Pignatelli

Subjects

Male, Models, Neurological, Action Potentials, Hippocampus, Mice, Transgenic, Biology, Mice, Calcium imaging, Medial entorhinal cortex, Neural Pathways, Path integration, Fluorescence microscope, Animals, Entorhinal Cortex, Fluorescent Dyes, Neurons, Brain Mapping, Multidisciplinary, Grid cell, Biological Sciences, Dependovirus, Mammalian brain, Entorhinal cortex, Cell biology, Mice, Inbred C57BL, Microscopy, Fluorescence, Calcium, Neuroscience

Abstract

Entorhinal-hippocampal circuits in the mammalian brain are crucial for an animal's spatial and episodic experience, but the neural basis for different spatial computations remain unknown. Medial entorhinal cortex layer II contains pyramidal island and stellate ocean cells. Here, we performed cell type-specific Ca(2+) imaging in freely exploring mice using cellular markers and a miniature head-mounted fluorescence microscope. We found that both oceans and islands contain grid cells in similar proportions, but island cell activity, including activity in a proportion of grid cells, is significantly more speed modulated than ocean cell activity. We speculate that this differential property reflects island cells' and ocean cells' contribution to different downstream functions: island cells may contribute more to spatial path integration, whereas ocean cells may facilitate contextual representation in downstream circuits.

Published

2015

42. Activating positive memory engrams suppresses depression-like behaviour

Author

Xu Liu, Steve Ramirez, Anthony Moffa, Joanne Zhou, Roger L. Redondo, Susumu Tonegawa, and Christopher J. MacDonald

Subjects

Male, Pleasure, Time Factors, Hippocampus, Engram, Hippocampal formation, Amygdala, Nucleus Accumbens, Article, Mice, Memory, Neural Pathways, medicine, Animals, Chronic stress, Multidisciplinary, Behavior, Animal, Depression, business.industry, Dentate gyrus, Neurogenesis, Anhedonia, Mice, Inbred C57BL, Optogenetics, medicine.anatomical_structure, Female, medicine.symptom, business, Proto-Oncogene Proteins c-fos, Neuroscience, Stress, Psychological

Abstract

Stress is considered a potent environmental risk factor for many behavioural abnormalities, including anxiety and mood disorders. Animal models can exhibit limited but quantifiable behavioural impairments resulting from chronic stress, including deficits in motivation, abnormal responses to behavioural challenges, and anhedonia. The hippocampus is thought to negatively regulate the stress response and to mediate various cognitive and mnemonic aspects of stress-induced impairments, although the neuronal underpinnings sufficient to support behavioural improvements are largely unknown. Here we acutely rescue stress-induced depression-related behaviours in mice by optogenetically reactivating dentate gyrus cells that were previously active during a positive experience. A brain-wide histological investigation, coupled with pharmacological and projection-specific optogenetic blockade experiments, identified glutamatergic activity in the hippocampus-amygdala-nucleus-accumbens pathway as a candidate circuit supporting the acute rescue. Finally, chronically reactivating hippocampal cells associated with a positive memory resulted in the rescue of stress-induced behavioural impairments and neurogenesis at time points beyond the light stimulation. Together, our data suggest that activating positive memories artificially is sufficient to suppress depression-like behaviours and point to dentate gyrus engram cells as potential therapeutic nodes for intervening with maladaptive behavioural states.

Published

2015

43. Engram cells retain memory under retrograde amnesia

Author

Michele Pignatelli, Autumn Arons, Dheeraj S. Roy, Tomás J. Ryan, and Susumu Tonegawa

Subjects

Multidisciplinary, Dendritic spine, Long-term memory, Computer science, Amnesia, Retrograde amnesia, Engram, Optogenetics, medicine.disease, Cell labeling, medicine, Memory consolidation, medicine.symptom, Neuroscience

Abstract

Experimental recovery from retrograde amnesia When memory researchers induce amnesia, they normally assume that the manipulations prevent the memory engram from effective encoding at consolidation. In accordance with this, Ryan et al. found that after the injection of protein synthesis inhibitors, animals could not retrieve a memory. However, to their surprise, the memory could nevertheless be reactivated by light-induced activation of the neurons tagged during conditioning. Increased synaptic strength that is the result of cellular consolidation is thus not a critical requisite for storing a memory. Science , this issue p. 1007

Published

2015

44. Amygdala circuits underlying valence-specific behaviors

Author

Susumu Tonegawa., Massachusetts Institute of Technology. Department of Biology., Kim, Joshua, Ph. D. Massachusetts Institute of Technology, Susumu Tonegawa., Massachusetts Institute of Technology. Department of Biology., and Kim, Joshua, Ph. D. Massachusetts Institute of Technology

Abstract

Thesis: Ph. D., Massachusetts Institute of Technology, Department of Biology, 2018., Cataloged from PDF version of thesis., Includes bibliographical references (pages 54-61)., Threatening and rewarding stimuli evoke a set of distinct stereotyped behaviors, which can be categorized as negative and positive valence-related behaviors, respectively. The stereotypic nature of negative and positive valence-related behaviors suggests that threatening and rewarding stimuli engage evolutionarily predetermined neural circuits in the brain. The amygdala is an important mammalian brain region that is activated by negative and positive stimuli and mediates negative and positive valence-related behaviors. The current prevailing circuit model of the amygdala mainly considers negative behaviors and only recently has cell-type specific models have been proposed. Hence, the substrates, genetically distinct neuronal populations, for negative and positive behaviors are not known. The work presented here describes a genetically-defined amygdala circuit model for negative and positive behaviors. Development of a genetic-based circuit model of the amygdala revealed anatomical and genetic circuit motifs that underlie that amygdala circuits that mediate valence-specific behaviors., NIH Pre-Doctoral Training Grant T32GM007287 RIKEN Brain Science Institute, by Joshua Kim., Ph. D.

Published

2018

45. Neurobiological mechanisms underlying episodic memory retrieval

Author

Susumu Tonegawa., Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences., Roy, Dheeraj, Susumu Tonegawa., Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences., and Roy, Dheeraj

Abstract

Thesis: Ph. D. in Neuroscience, Massachusetts Institute of Technology, Department of Brain and Cognitive Sciences, 2017., Cataloged from PDF version of thesis., Includes bibliographical references (pages 177-192)., Memory is a central function of the brain and is essential to everyday life. Memory disorders range from those of memory transience, such as Alzheimer's disease, to those of memory persistence, such as post-traumatic stress disorder. To treat memory disorders, a thorough understanding of memory formation and retrieval is critical. To date, most research has focused on memory formation, with the neurobiological basis of memory retrieval largely ignored due to experimental limitations. Here, I present our recent advances in the study of memory retrieval using technologies to engineer the representation of a specific memory, memory engram cells, in the brain. First, using animal models of retrograde amnesia, we demonstrated that direct activation of amnesic engram cells in the hippocampus resulted in robust memory retrieval, indicating the persistence of the original memory. Subsequent experiments identified retained engram cell-specific connectivity in amnesic mice although these engram cells lacked augmented synaptic strength and dendritic spine density. We proposed that a specific pattern of connectivity of engram cells may be the crucial substrate for memory information storage and that augmented synaptic strength and spine density critically contribute to the memory retrieval process. Second, we examined memory engrams in transgenic mouse models of early Alzheimer's disease, which required the development of a novel two-virus approach. We demonstrated that optical induction of long-term potentiation at input synapses on engram cells restored both spine density and long-term memory in early Alzheimer mice, providing causal evidence for the crucial role of augmented spine density in memory retrieval. Third, using activity-dependent labeling, we found that dorsal subiculum had enhanced neuronal activity during memory retrieval as compared memory encoding. Taking advantage of a novel transgenic mouse line that permitted specific genetic access to dorsal subiculum neur, by Dheeraj Roy., Ph. D. in Neuroscience

Published

2018

46. The amygdala in value-guided decision making

Author

Susumu Tonegawa., Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences., Jaime-Bustamante, Kean (Kean Willyams), Susumu Tonegawa., Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences., and Jaime-Bustamante, Kean (Kean Willyams)

Abstract

Thesis: Ph. D. in Neuroscience, Massachusetts Institute of Technology, Department of Brain and Cognitive Sciences, 2017., Cataloged from PDF version of thesis., Includes bibliographical references., The amygdala is a structure well known for its role in fear and reward learning, but how these mechanisms are used for decision-making is not well understood. Decision-making involves the rapid updating of cue associations as well as the encoding of a value currency, both processes in which the amygdala has been implicated. In this thesis I develop a strategy to study value-guided decision making in rodents using an olfactory binary choice task. Using a logistic regression model, I show that the value of expected rewards is a strong influence on choice, and can bias perceptual decisions. In addition, I show that decisions are influenced by events in the near past, and a specific bias towards correct choices in the near past can be detected using this analysis. Using genetic targeting of a sub-population of amygdala neurons, I show that this population is required for the rapid learning of an olfactory decision making task. Using in-vivo calcium imaging of this population I show that these neurons are active during the inter-trial interval and modulated by choice history, suggesting a mechanism by which choice history can influence current decisions., by Kean Jaime-Bustamante., Ph. D. in Neuroscience

Published

2018

47. Pathobiology of Human Uterine Leiomyosarcoma for Development of Novel Diagnosis and Clinical Therapy

Author

Yae Kanai, Mari Kasai, Gal Gur, Tomoyuki Ichimura, Nobuo Yaegashi, Takuma Hayashi, Ikuo Konishi, Dorit Zharhary, Pnina Yaish, Susumu Tonegawa, Massachusetts Institute of Technology. Department of Biology, and Tonegawa, Susumu

Subjects

Clinical therapy, Pathology, medicine.medical_specialty, Uterine leiomyosarcoma, business.industry, Medicine, business

Abstract

Uterine sarcomas comprise a group of rare tumours with differing tumour pathobiology, natural history and response to clinical treatment. Diagnosis is often made following surgical treatment for presumed malignant mesenchymal tumours and benign tumours. Currently pre-operative diagnosis does not reliably distinguish between malignant mesenchymal tumours, Uterine Leiomyosarcoma (U-LMS) and benign tumours including Leiomyomas (LMA). U-LMS is the most common sarcoma but other subtypes include endometrial stromal sarcoma (low grade and high grade), undifferentiated uterine sarcoma and adeno sarcoma. Clinical trials have shown no definite survival benefit for adjuvant radiotherapy or chemotherapy, and have been hampered by the rarity and heterogeneity of these tumour types. There is a role of adjuvant treatment in carefully selected cases following multidisciplinary discussion at U-LMS reference centres. In patients with metastatic LMS then systemic chemotherapy can be considered. Accordingly, it is necessary to analyse risk factors associated with human U-LMS, in order to establish a treatment method. Proteasome β-subunit 9 (PSMB9)/β1i-deficient mice spontaneously develop U-LMS, with a disease prevalence of ~37% by 12 months of age. We found PSMB9/β1i expression to be absent in human U-LMS, but present in human LMA. Therefore, defective PSMB9/β1i expression may be one of the risk factors for human U-LMS. PSMB9/β1i is a potential diagnostic-biomarker for human U-LMS, and may be targeted-molecule for a new therapeutic approach. Keywords: PSMB9/β1i; Diagnosis; Mesenchymal tumour; Leiomyosarcoma; Leiomyoma

Published

2017

48. Locus coeruleus input to hippocampal CA3 drives single-trial learning of a novel context

Author

Kuniya Abe, Teruhiro Okuyama, Lillian M. Smith, Akiko Wagatsuma, Susumu Tonegawa, and Chen Sun

Subjects

0301 basic medicine, Male, Hippocampus, Context (language use), Engram, Hippocampal formation, Biology, 03 medical and health sciences, Mice, 0302 clinical medicine, Memory, Neural Pathways, Biological neural network, Learning, Animals, Neurons, Multidisciplinary, Behavior, Animal, Dentate gyrus, Novelty, Temporal Lobe, 030104 developmental biology, nervous system, PNAS Plus, Dentate Gyrus, Locus coeruleus, Calcium, Locus Coeruleus, Neuroscience, 030217 neurology & neurosurgery

Abstract

The memory for a new episode is formed immediately upon experience and can last up to a lifetime. It has been shown that the hippocampal network plays a fundamental role in the rapid acquisition of a memory of a one-time experience, in which the novelty component of the experience promotes the prompt formation of the memory. However, it remains unclear which neural circuits convey the novelty signal to the hippocampus for the single-trial learning. Here, we show that during encoding neuromodulatory input from locus coeruleus (LC) to CA3, but not CA1 or to the dentate gyrus, is necessary to facilitate novel contextual learning. Silencing LC activity during exposure to a novel context reduced subsequent reactivation of the engram cell ensembles in CA3 neurons and in downstream CA1 upon reexposure to the same context. Calcium imaging of the cells reactivated in both novel and familiar contexts revealed that suppression of LC inputs at the time of encoding resulted in more variable place fields in CA3 neurons. These results suggest that neuromodulatory input from LC to CA3 is crucial for the formation of a persistent memory in the hippocampus.

Published

2017

49. Silent memory engrams as the basis for retrograde amnesia

Author

Shruti Muralidhar, Lillian M. Smith, Susumu Tonegawa, and Dheeraj S. Roy

Subjects

Male, 0301 basic medicine, Memory, Long-Term, Dendritic spine, Dendritic Spines, Amnesia, Hippocampus, Mice, Transgenic, Engram, Optogenetics, Mice, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Learning, Neurons, Multidisciplinary, Behavior, Animal, Recall, Long-term memory, Intracellular Signaling Peptides and Proteins, Nuclear Proteins, Retrograde amnesia, Prostheses and Implants, medicine.disease, Spine, Mice, Inbred C57BL, Disease Models, Animal, 030104 developmental biology, PNAS Plus, Mental Recall, Synapses, Amnesia, Retrograde, medicine.symptom, Psychology, Neuroscience, 030217 neurology & neurosurgery

Abstract

Recent studies identified neuronal ensembles and circuits that hold specific memory information (memory engrams). Memory engrams are retained under protein synthesis inhibition-induced retrograde amnesia. These engram cells can be activated by optogenetic stimulation for full-fledged recall, but not by stimulation using natural recall cues (thus, amnesia). We call this state of engrams "silent engrams" and the cells bearing them "silent engram cells." The retention of memory information under amnesia suggests that the time-limited protein synthesis following learning is dispensable for memory storage, but may be necessary for effective memory retrieval processes. Here, we show that the full-fledged optogenetic recall persists at least 8 d after learning under protein synthesis inhibition-induced amnesia. This long-term retention of memory information correlates with equally persistent retention of functional engram cell-to-engram cell connectivity. Furthermore, inactivation of the connectivity of engram cell ensembles with its downstream counterparts, but not upstream ones, prevents optogenetic memory recall. Consistent with the previously reported lack of retention of augmented synaptic strength and reduced spine density in silent engram cells, optogenetic memory recall under amnesia is stimulation strength-dependent, with low-power stimulation eliciting only partial recall. Finally, the silent engram cells can be converted to active engram cells by overexpression of α-p-21-activated kinase 1, which increases spine density in engram cells. These results indicate that memory information is retained in a form of silent engram under protein synthesis inhibition-induced retrograde amnesia and support the hypothesis that memory is stored as the specific connectivity between engram cells.

Published

2017

50. Distinct Neural Circuits for the Formation and Retrieval of Episodic Memories

Author

Atsushi Yoshiki, Sachie K. Ogawa, Yuichi Obata, Chen Sun, Takashi Kitamura, Dheeraj S. Roy, Teruhiro Okuyama, Susumu Tonegawa, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Roy, Dheeraj, Kitamura, Takashi, Okuyama, Teruhiro, Kitamura, Sachie Ogawa, Sun, Chen, and Tonegawa, Susumu

Subjects

Male, 0301 basic medicine, Memory, Episodic, Gene Expression, Hippocampal formation, Biology, Hippocampus, Spatial memory, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, 0302 clinical medicine, Neural Pathways, Animals, Entorhinal Cortex, Semantic memory, Episodic memory, Neurons, Long-term memory, Subiculum, Entorhinal cortex, Neuroanatomy of memory, Mice, Inbred C57BL, Optogenetics, 030104 developmental biology, nervous system, Corticosterone, Neuroscience, 030217 neurology & neurosurgery

Abstract

The formation and retrieval of a memory is thought to be accomplished by activation and reactivation, respectively, of the memory-holding cells (engram cells) by a common set of neural circuits, but this hypothesis has not been established. The medial temporal-lobe system is essential for the formation and retrieval of episodic memory for which individual hippocampal subfields and entorhinal cortex layers contribute by carrying out specific functions. One subfield whose function is poorly known is the subiculum. Here, we show that dorsal subiculum and the circuit, CA1 to dorsal subiculum to medial entorhinal cortex layer 5, play a crucial role selectively in the retrieval of episodic memories. Conversely, the direct CA1 to medial entorhinal cortex layer 5 circuit is essential specifically for memory formation. Our data suggest that the subiculum-containing detour loop is dedicated to meet the requirements associated with recall such as rapid memory updating and retrieval-driven instinctive fear responses., RIKEN Brain Science Institute, Howard Hughes Medical Institute, JPB Foundation

Published

2017