Your search keyword '"Yasuyuki Shima"' showing total 19 results

1. Deletion of Stk11 and Fos in mouse BLA projection neurons alters intrinsic excitability and impairs formation of long-term aversive memory

Author

David Levitan, Tracy Yang, Sacha B. Nelson, Jian-You Lin, Joseph Wachutka, Troy A Richter, Donald B. Katz, Yasuyuki Shima, Yasmin Marrero, Chenghao Liu, Eduardo da Veiga Beltrame, and Ramin Ali Marandi Ghoddousi

Subjects

Male, 0301 basic medicine, Memory, Long-Term, Mouse, fos, QH301-705.5, Science, Conditioning, Classical, STK11, AMP-Activated Protein Kinases, Protein Serine-Threonine Kinases, Biology, General Biochemistry, Genetics and Molecular Biology, memory, Gene Knockout Techniques, Mice, 03 medical and health sciences, 0302 clinical medicine, excitability, medicine, Memory formation, Animals, Biology (General), Gene, Neurons, General Immunology and Microbiology, Basolateral Nuclear Complex, Kinase, General Neuroscience, General Medicine, Impaired memory, 030104 developmental biology, medicine.anatomical_structure, Taste, Taste aversion, Stk11, Medicine, Female, Proto-Oncogene Proteins c-fos, Immediate early gene, Neuroscience, 030217 neurology & neurosurgery, basolateral amygdala, Research Article, Basolateral amygdala

Abstract

Conditioned taste aversion (CTA) is a form of one-trial learning dependent on basolateral amygdala projection neurons (BLApn). Its underlying cellular and molecular mechanisms remain poorly understood. RNAseq from BLApn identified changes in multiple candidate learning-related transcripts including the expected immediate early gene Fos and Stk11, a master kinase of the AMP-related kinase pathway with important roles in growth, metabolism and development, but not previously implicated in learning. Deletion of Stk11 in BLApn blocked memory prior to training, but not following it and increased neuronal excitability. Conversely, BLApn had reduced excitability following CTA. BLApn knockout of a second learning-related gene, Fos, also increased excitability and impaired learning. Independently increasing BLApn excitability chemogenetically during CTA also impaired memory. STK11 and C-FOS activation were independent of one another. These data suggest key roles for Stk11 and Fos in CTA long-term memory formation, dependent at least partly through convergent action on BLApn intrinsic excitability.

Published

2020

2. Mapping the transcriptional diversity of genetically and anatomically defined cell populations in the mouse brain

Author

David L Hunt, Anton Schulmann, Yasuyuki Shima, Serge Picard, Erin A. Clark, Sacha B. Nelson, Lihua Wang, Jayaram Chandrashekar, Dimitri Tränkner, Andrew L. Lemire, Ken Sugino, Nelson Spruston, Bryan M. Hooks, and Adam W. Hantman

Subjects

0301 basic medicine, Cell type, Mouse, QH301-705.5, Science, Biology, homeobox transcription factors, General Biochemistry, Genetics and Molecular Biology, Transcriptome, 03 medical and health sciences, Mice, 0302 clinical medicine, medicine, Animals, Biology (General), Transcription factor, Gene, long genes, Neurons, General Immunology and Microbiology, Effector, General Neuroscience, Gene Expression Profiling, Robustness (evolution), Brain, General Medicine, neuronal diversity, medicine.disease, Tools and Resources, 030104 developmental biology, nervous system, Evolutionary biology, Homeobox, Medicine, RNA-seq, cell types, 030217 neurology & neurosurgery, Transcriptional noise, Neuroscience

Abstract

Understanding the principles governing neuronal diversity is a fundamental goal for neuroscience. Here, we provide an anatomical and transcriptomic database of nearly 200 genetically identified cell populations. By separately analyzing the robustness and pattern of expression differences across these cell populations, we identify two gene classes contributing distinctly to neuronal diversity. Short homeobox transcription factors distinguish neuronal populations combinatorially, and exhibit extremely low transcriptional noise, enabling highly robust expression differences. Long neuronal effector genes, such as channels and cell adhesion molecules, contribute disproportionately to neuronal diversity, based on their patterns rather than robustness of expression differences. By linking transcriptional identity to genetic strains and anatomical atlases, we provide an extensive resource for further investigation of mouse neuronal cell types.

Published

2019

3. Author response: Mapping the transcriptional diversity of genetically and anatomically defined cell populations in the mouse brain

Author

Serge Picard, Adam W. Hantman, Nelson Spruston, Andrew L. Lemire, Bryan M. Hooks, Ken Sugino, Yasuyuki Shima, David L Hunt, Jayaram Chandrashekar, Lihua Wang, Dimitri Tränkner, Sacha B. Nelson, Erin A. Clark, and Anton Schulmann

Subjects

medicine.anatomical_structure, Evolutionary biology, media_common.quotation_subject, Cell, medicine, Biology, Diversity (politics), media_common

Published

2019

4. ATAC-seq on Sorted Adult Mouse Neurons

Author

Erin A. Clark, Yasuyuki Shima, and Sacha B. Nelson

Subjects

Cell type, Strategy and Management, Mechanical Engineering, Cell, Metals and Alloys, ATAC-seq, Computational biology, Biology, Genome, Industrial and Manufacturing Engineering, Chromatin, medicine.anatomical_structure, Methods Article, medicine, Transcriptional regulation, Neuron, Transposase

Abstract

Transcription regulation is a key aspect of cellular identity established during development and maintained into adulthood. Molecular and biochemical assays that probe the genome are critical tools in exploring mechanisms of transcription regulation and cell type identity. The mammalian brain is composed of a huge diversity of cell types with distinct properties and functions. To understand these specific roles, it is necessary to selectively target cell populations for study. However, the need to selectively study restricted cell populations poses a challenge in neurobiology. It is often difficult to collect sufficient cellular input for many standard biochemical and molecular assays. Recently, important advances have been made to scale assays down, opening up new frontiers to explore molecular mechanisms in neurons. Concurrently, methodologies for preparing neurons for such assays has advanced taking into consideration specific methods to preserve the cell biology meant to be assayed. Here we describe a method for preparing live neurons from adult brain tissue for the Assay for Transposase Accessible Chromatin (ATAC).

Published

2019

5. Upregulation of μ3A Drives Homeostatic Plasticity by Rerouting AMPAR into the Recycling Endosomal Pathway

Author

Chris M. Hempel, Celine C. Steinmetz, Sacha B. Nelson, Mary E. Lambo, Heather Lin, Yasuyuki Shima, Benjamin W. Okaty, Ken Sugino, Gina G. Turrigiano, Anne Joseph, Michael Rutlin, Vedakumar Tatavarty, Suzanne Paradis, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, and Lambo, Mary E.

Subjects

0301 basic medicine, Adaptor Protein Complex 3, Endosome, Protein subunit, Nerve Tissue Proteins, Endosomes, AMPA receptor, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Discs Large Homolog 1 Protein, Mice, 03 medical and health sciences, Downregulation and upregulation, Homeostatic plasticity, Animals, Homeostasis, Receptors, AMPA, lcsh:QH301-705.5, Adaptor Proteins, Signal Transducing, Neuronal Plasticity, Synaptic scaling, Pyramidal Cells, musculoskeletal, neural, and ocular physiology, Glutamate receptor, Signal transducing adaptor protein, Dendrites, Endocytosis, Adaptor Protein Complex mu Subunits, Up-Regulation, Cell biology, 030104 developmental biology, lcsh:Biology (General), nervous system, Gene Knockdown Techniques, Synapses, Transcriptome

Abstract

SummarySynaptic scaling is a form of homeostatic plasticity driven by transcription-dependent changes in AMPA-type glutamate receptor (AMPAR) trafficking. To uncover the pathways involved, we performed a cell-type-specific screen for transcripts persistently altered during scaling, which identified the μ subunit (μ3A) of the adaptor protein complex AP-3A. Synaptic scaling increased μ3A (but not other AP-3 subunits) in pyramidal neurons and redistributed dendritic μ3A and AMPAR to recycling endosomes (REs). Knockdown of μ3A prevented synaptic scaling and this redistribution, while overexpression (OE) of full-length μ3A or a truncated μ3A that cannot interact with the AP-3A complex was sufficient to drive AMPAR to REs. Finally, OE of μ3A acted synergistically with GRIP1 to recruit AMPAR to the dendritic membrane. These data suggest that excess μ3A acts independently of the AP-3A complex to reroute AMPAR to RE, generating a reservoir of receptors essential for the regulated recruitment to the synaptic membrane during scaling up.

Published

2016

6. The Transcriptional Logic of Mammalian Neuronal Diversity

Author

Andrew L. Lemire, David L Hunt, Lihua Wang, Ken Sugino, Serge Picard, Nelson Spruston, Adam W. Hantman, Yasuyuki Shima, Dimitri Tränkner, Bryan M. Hooks, Jayaram Chandrashekar, Anton Schulmann, Erin A. Clark, and Sacha B. Nelson

Subjects

Genetics, Cell type, Interspersed repeat, Intron, Homeobox, Computational biology, Biology, Mobile genetic elements, Genome, Gene, Transcription factor

Abstract

The mammalian nervous system is constructed of many neuronal cell types, but the principles underlying this diversity are poorly understood. To begin to assess brain-wide transcriptional diversity, we sequenced the transcriptomes of the largest collection of genetically and/or anatomically identified neuronal classes from throughout the central nervous system. Using improved expression metrics that distinguish information content from signal-to-noise-ratio, we found that homeobox transcription factors contain the highest information about cell types and have the lowest noise. Non-transcription factors that contribute the most to neuronal diversity tend to be long, due to large introns, and are enriched in genes specifically involved in neuronal function. Genome accessibility measurements reveal that long genes have more candidate regulatory elements arrayed in more distinct patterns. These candidate regulatory elements frequently overlap interspersed repeats and the pattern of repeats is predictive of gene expression. Elongation of neuronal genes by insertions of mobile elements and the resulting new regulatory sites may be an evolutionary force enhancing nervous system complexity.

Published

2017

7. Distinct projection patterns of different classes of layer 2 principal neurons in the olfactory cortex

Author

C. Geoffrey Lau, Yasuyuki Shima, Venkatesh N. Murthy, Camille Mazo, and Julien Grimaud

Subjects

0301 basic medicine, Olfactory system, Genetically modified mouse, Science, Fluorescent Antibody Technique, Gene Expression, Piriform Cortex, Biology, Article, Mice, 03 medical and health sciences, 0302 clinical medicine, Projection (mathematics), Genes, Reporter, Piriform cortex, Animals, Neurons, Multidisciplinary, Extramural, Olfactory Bulb, Retrograde tracing, Axons, Olfactory bulb, Olfactory Cortex, 030104 developmental biology, Odor, Medicine, Neuroscience, Biomarkers, 030217 neurology & neurosurgery

Abstract

The broadly-distributed, non-topographic projections to and from the olfactory cortex may suggest a flat, non-hierarchical organization in odor information processing. Layer 2 principal neurons in the anterior piriform cortex (APC) can be divided into 2 subtypes: semilunar (SL) and superficial pyramidal (SP) cells. Although it is known that SL and SP cells receive differential inputs from the olfactory bulb (OB), little is known about their projections to other olfactory regions. Here, we examined axonal projections of SL and SP cells using a combination of mouse genetics and retrograde labeling. Retrograde tracing from the OB or posterior piriform cortex (PPC) showed that the APC projects to these brain regions mainly through layer 2b cells, and dual-labeling revealed many cells extending collaterals to both target regions. Furthermore, a transgenic mouse line specifically labeling SL cells showed that they send profuse axonal projections to olfactory cortical areas, but not to the OB. These findings support a model in which information flow from SL to SP cells and back to the OB is mediated by a hierarchical feedback circuit, whereas both SL and SP cells broadcast information to higher olfactory areas in a parallel manner.

Published

2017

8. Striosome-dendron bouquets highlight a unique striatonigral circuit targeting dopamine-containing neurons

Author

David E. Housman, Sacha B. Nelson, Ann M. Graybiel, Paul W. Tillberg, Charles R. Gerfen, Michael H. Riad, Yasuyuki Shima, Jeffrey Curry, Edward S. Boyden, and Jill R. Crittenden

Subjects

0301 basic medicine, Dendrimers, Striosome, Dopamine, Nigrostriatal pathway, Nanotechnology, Striatum, Biology, Basal Ganglia, 03 medical and health sciences, Glutamatergic, Mice, 0302 clinical medicine, medicine, Animals, Humans, Brain Mapping, Multidisciplinary, Dopaminergic Neurons, Parkinson Disease, Dendrites, Biological Sciences, Retrograde tracing, Corpus Striatum, Neostriatum, Substantia Nigra, 030104 developmental biology, medicine.anatomical_structure, Cholinergic, GABAergic, Neuroscience, 030217 neurology & neurosurgery, medicine.drug

Abstract

The dopamine systems of the brain powerfully influence movement and motivation. We demonstrate that striatonigral fibers originating in striosomes form highly unusual bouquet-like arborizations that target bundles of ventrally extending dopamine-containing dendrites and clusters of their parent nigral cell bodies. Retrograde tracing showed that these clustered cell bodies in turn project to the striatum as part of the classic nigrostriatal pathway. Thus, these striosome–dendron formations, here termed “striosome–dendron bouquets,” likely represent subsystems with the nigro–striato–nigral loop that are affected in human disorders including Parkinson’s disease. Within the bouquets, expansion microscopy resolved many individual striosomal fibers tightly intertwined with the dopamine-containing dendrites and also with afferents labeled by glutamatergic, GABAergic, and cholinergic markers and markers for astrocytic cells and fibers and connexin 43 puncta. We suggest that the striosome–dendron bouquets form specialized integrative units within the dopamine-containing nigral system. Given evidence that striosomes receive input from cortical regions related to the control of mood and motivation and that they link functionally to reinforcement and decision-making, the striosome–dendron bouquets could be critical to dopamine-related function in health and disease.

Published

2016

9. A Mammalian enhancer trap resource for discovering and manipulating neuronal cell types

Author

Sacha B. Nelson, Praveen Taneja, Chris M. Hempel, Yasuyuki Shima, Carlos Lois, Masami Shima, James B. Bullis, Sonam Mehta, and Ken Sugino

Subjects

0301 basic medicine, Genetically modified mouse, Nervous system, transgenic animals, Cell type, Mouse, QH301-705.5, Science, Transgene, Mice, Transgenic, Computational biology, Biology, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, Neurobiology, medicine, Animals, Enhancer trap, Biology (General), Enhancer, Molecular Biology, Gene, Neurons, Genetics, Staining and Labeling, General Immunology and Microbiology, General Neuroscience, cell type, General Medicine, Tools and Resources, Transgenesis, 030104 developmental biology, medicine.anatomical_structure, enhancer trap, Medicine, Neuroscience

Abstract

There is a continuing need for driver strains to enable cell-type-specific manipulation in the nervous system. Each cell type expresses a unique set of genes, and recapitulating expression of marker genes by BAC transgenesis or knock-in has generated useful transgenic mouse lines. However, since genes are often expressed in many cell types, many of these lines have relatively broad expression patterns. We report an alternative transgenic approach capturing distal enhancers for more focused expression. We identified an enhancer trap probe often producing restricted reporter expression and developed efficient enhancer trap screening with the PiggyBac transposon. We established more than 200 lines and found many lines that label small subsets of neurons in brain substructures, including known and novel cell types. Images and other information about each line are available online (enhancertrap.bio.brandeis.edu). DOI: http://dx.doi.org/10.7554/eLife.13503.001, eLife digest Scientists can track and even alter the activity of different kinds of neurons, as well as the connections between neurons, by manipulating their genes. However, most genes are active in many different kinds of cells in many different places in the brain, making it difficult to track or target only a particular neuron or brain area. Enhancers are sections of DNA that can regulate the activity of nearby genes so that they are only active in very specific cell types, and an “enhancer trap” is a genetic approach that essentially hijacks enhancers to express artificial genes in those same cell types. The technique relies on inserting a genetic marker, which can be easily tracked, into random locations in the genome. If this marker then interacts with an enhancer, it is activated and the effect of the enhancer on gene expression can be assessed. This method has been used in fruit flies and fish to identify enhancers that specifically restrict gene expression to a small subset of cells. Now, Shima et al. show that enhancer traps can be used successfully in mammals too. The experiments produced over 200 different strains of mice, many with the fluorescent marker only in specific brain areas or in specific kinds of brain cells. Some of the types of brain cells uncovered by these experiments are new, and the labelling of specific brain cells and brain areas in different strains makes these mice a useful resource for future work. Furthermore, it will be relatively straightforward to produce many more strains of these mice, because it would simply involve crossbreeding mice. It is likely that some of these to-be-discovered strains will be useful tools for research as well. DOI: http://dx.doi.org/10.7554/eLife.13503.002

Published

2016

10. Author response: A Mammalian enhancer trap resource for discovering and manipulating neuronal cell types

Author

Yasuyuki Shima, Sonam Mehta, Chris M. Hempel, Praveen Taneja, James B. Bullis, Masami Shima, Sacha B. Nelson, Ken Sugino, and Carlos Lois

Subjects

Cell type, Resource (biology), Enhancer trap, Computational biology, Biology

Published

2016

11. Differential activities, subcellular distribution and tissue expression patterns of three members of Slingshot family phosphatases that dephosphorylate cofilin

Author

Kazuyoshi Kousaka, Kensaku Mizuno, Ryusuke Niwa, Yusaku Ohta, Kazumasa Ohashi, Yasuyuki Shima, Aya Muramoto, Kyoko Nagata-Ohashi, and Tadashi Uemura

Subjects

endocrine system, Slingshot, Phosphatase, macromolecular substances, Cell Biology, In situ hybridization, Cofilin, Biology, Molecular biology, Isozyme, Cell biology, Dephosphorylation, Genetics, Phosphorylation, Actin

Abstract

Background: Cofilin, a key regulator of actin filament dynamics, is inactivated by phosphorylation at Ser-3 by LIM-kinases and is reactivated by dephosphorylation by a family of protein phosphatases, termed Slingshot (SSH). Results: We have identified two novel isoforms of SSHs, termed SSH-2L and SSH-3L and characterized them in comparison with SSH-1L that was previously reported. SSH-1L and SSH-2L, but not SSH-3L, tightly bound to and co-localized with actin filaments. When expressed in cultured cells, SSH-1L, SSH-2L and SSH-3L decreased the level of Ser-3-phosphorylated cofilin (P-cofilin) in cells and suppressed LIM-kinase-induced actin reorganization, although SSH-3L was less effective than SSH-1L and SSH-2L. In cell-free assays, SSH-1L and SSH-2L efficiently dephosphorylated P-cofilin, whereas SSH-3L did do so only weakly. Using deleted mutants of SSH-1L and SSH-2L, we found that the N-terminal and C-terminal extracatalytic regions are critical for cofilin-phosphatase and F-actin-binding activities, respectively. In situ hybridization analyses revealed characteristic patterns of expression of each of the mouse Ssh genes in both neuronal and non-neuronal tissues; in particular, expression of Ssh-3 in epithelial tissues is evident. Conclusion: SSH-1L, SSH-2L and SSH-3L have the potential to dephosphorylate P-cofilin, but subcellular distribution, F-actin-binding activity, specific phosphatase activity and expression patterns significantly differ, which suggests that they have related but distinct functions in various cellular and developmental events.

Published

2003

12. Differential expression of the seven-pass transmembrane cadherin genesCelsr1-3 and distribution of the Celsr2 protein during mouse development

Author

Yasuyuki Shima, Tadashi Uemura, Masatoshi Takeichi, Nancy A. Jenkins, Neal G. Copeland, Osamu Chisaka, and Debra J. Gilbert

Subjects

Central Nervous System, Fetal Proteins, Nervous system, Time Factors, Blotting, Western, Immunoblotting, Receptors, Cell Surface, Hippocampal formation, Biology, Transfection, Hippocampus, Cell Line, Receptors, G-Protein-Coupled, Mice, Purkinje Cells, medicine, Animals, Humans, Tissue Distribution, RNA, Messenger, Cloning, Molecular, Gene, Cells, Cultured, Crosses, Genetic, In Situ Hybridization, Cochlea, Neurons, Models, Genetic, Cadherin, Chromosome Mapping, Cadherins, Embryonic stem cell, Molecular biology, Transmembrane protein, medicine.anatomical_structure, Chromosome 3, Ear, Inner, RNA, Developmental Biology

Abstract

Drosophila Flamingo (Fmi) is an evolutionally conserved seven-pass transmembrane receptor of the cadherin superfamily. Fmi plays multiple roles in patterning neuronal processes and epithelial planar cell polarity. To explore the in vivo roles of Fmi homologs in mammals, we previously cloned one of the mouse homologs, mouse flamingo1/Celsr2. Here, we report the results of our study of its embryonic and postnatal expression patterns together with those of two other paralogs, Celsr1 and Celsr3. Celsr1-3 expression was initiated broadly in the nervous system at early developmental stages, and each paralog showed characteristic expression patterns in the developing CNS. These genes were also expressed in several other organs, including the cochlea, where hair cells develop planar polarity, the kidney, and the whisker. The Celsr2 protein was distributed at intercellular boundaries in the whisker and on processes of neuronal cells such as hippocampal pyramidal cells, Purkinje cells, and olfactory neurons. Celsr2 is mapped to a distal region of the mouse chromosome 3. We discussed possible functions of seven-pass transmembrane cadherins in mouse development.

Published

2002

13. Convergence of pontine and proprioceptive streams onto multimodal cerebellar granule cells

Author

Suxia Bai, Brett D. Mensh, Yasuyuki Shima, Sacha B. Nelson, Cheng-Chiu Huang, Ken Sugino, Caiying Guo, and Adam W. Hantman

Subjects

Cerebellum, Mouse, cerebellum, QH301-705.5, proprioception, Science, Sensory system, Biology, Motor Activity, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Nerve Fibers, Pons, medicine, Animals, Biology (General), Motor skill, 030304 developmental biology, Neurons, 0303 health sciences, General Immunology and Microbiology, Proprioception, General Neuroscience, Granule (cell biology), General Medicine, Granule cell, medicine.anatomical_structure, corollary discharge, Excitatory postsynaptic potential, Medicine, Body region, Neuroscience, 030217 neurology & neurosurgery, Research Article

Abstract

Cerebellar granule cells constitute the majority of neurons in the brain and are the primary conveyors of sensory and motor-related mossy fiber information to Purkinje cells. The functional capability of the cerebellum hinges on whether individual granule cells receive mossy fiber inputs from multiple precerebellar nuclei or are instead unimodal; this distinction is unresolved. Using cell-type-specific projection mapping with synaptic resolution, we observed the convergence of separate sensory (upper body proprioceptive) and basilar pontine pathways onto individual granule cells and mapped this convergence across cerebellar cortex. These findings inform the long-standing debate about the multimodality of mammalian granule cells and substantiate their associative capacity predicted in the Marr-Albus theory of cerebellar function. We also provide evidence that the convergent basilar pontine pathways carry corollary discharges from upper body motor cortical areas. Such merging of related corollary and sensory streams is a critical component of circuit models of predictive motor control. DOI: http://dx.doi.org/10.7554/eLife.00400.001, eLife digest Learning a new motor skill, from riding a bicycle to eating with chopsticks, involves the cerebellum—a structure located at the base of the brain underneath the cerebral hemispheres. Although its name translates as ‘little brain' in Latin, the cerebellum contains more neurons than all other regions of the mammalian brain combined. Most cerebellar neurons are granule cells which, although numerous, are simple neurons with an average of only four excitatory inputs, from axons called mossy fibers. These inputs are diverse in nature, originating from virtually every sensory system and from command centers at multiple levels of the motor hierarchy. However, it is unclear whether individual granule cells receive inputs from only a single sensory source or can instead mix modalities. This distinction has important implications for the functional capabilities of the cerebellum. Now, Huang et al. have addressed this question by mapping, at extremely high resolution, the projections of two pathways onto individual granule cells—one carrying sensory feedback from the upper body (the proprioceptive stream), and another carrying motor-related information (the pontine stream). Using a combination of genetic and viral techniques to label the pathways, Huang and co-workers identified regions where the two types of fiber terminated in close proximity. They then showed that around 40% of proprioceptive granule cells formed junctions, or synapses, with two (or more) fibers carrying different types of input. These cells were not uniformly distributed throughout the cerebellum but tended to occur in ‘hotspots’. Lastly, Huang et al. examined the type of information conveyed by the sensory and motor-related input streams whenever they contacted a single granule cell. They confirmed that when the sensory input consisted of feedback from the upper body, the motor input consisted of copies of motor commands related to the same body region. Because it is thought that the cerebellum converts sensory information into representations of the body's movements, directing motor commands to these same circuits may allow the cerebellum to predict the consequences of a planned movement prior to, or without, the actual movement occurring. The work of Huang et al. provides evidence to support the previously controversial idea that granule cells in the mammalian cerebellum receive both sensory and motor-related inputs. The labeling technique that they used could also be deployed to study the inputs to the cerebellum in greater detail, which should yield new insights into the functioning of this part of the brain. DOI: http://dx.doi.org/10.7554/eLife.00400.002

Published

2013

14. Expression, identification and purification of Dictyostelium acetoacetyl-coa thiolase expressed in Escherichia coli

Author

Tetsuo Ohmachi, Koki Nagayama, Takashi Yoshida, Naoki Ogawa, Takeshi Tanaka, and Yasuyuki Shima

Subjects

DNA, Complementary, Cloning, Organism, cloning, Biology, medicine.disease_cause, Applied Microbiology and Biotechnology, Polymerase Chain Reaction, Dictyostelium discoideum, acetoacety-CoA thiolase, protein purification, Protein purification, medicine, Escherichia coli, Dictyostelium, Amino Acid Sequence, Acetyl-CoA C-Acetyltransferase, DNA, Fungal, Molecular Biology, Peptide sequence, Ecology, Evolution, Behavior and Systematics, chemistry.chemical_classification, Base Sequence, cDNA library, Thiolase, Cell Biology, biology.organism_classification, Molecular biology, Enzyme, Biochemistry, chemistry, protein processing, Acetyl-CoA C-acetyltransferase, Developmental Biology, Research Paper

Abstract

Acetoacetyl-CoA thiolase (AT) is an enzyme that catalyses the CoA-dependent thiolytic cleavage of acetoacetyl-CoA to yield 2 molecules of acetyl-CoA, or the reverse condensation reaction. A full-length cDNA clone pBSGT-3, which has homology to known thiolases, was isolated from Dictyostelium cDNA library. Expression of the protein encoded in pBSGT-3 in Escherichia coli, its thiolase enzyme activity, and the amino acid sequence homology search revealed that pBSGT-3 encodes an AT. The recombinant AT (r-thiolase) was expressed in an active form in an E. coli expression system, and purified to homogeneity by selective ammonium sulfate fractionation and two steps of column chromatography. The purified enzyme exhibited a specific activity of 4.70 mU/mg protein. Its N-terminal sequence was (NH2)-Arg-Met-Tyr-Thr-Thr-Ala-Lys-Asn-Leu-Glu-, which corresponds to the sequence from positions 15 to 24 of the amino acid sequence deduced from pBSGT-3 clone. The r-thiolase in the inclusion body expressed highly in E. coli was the precursor form, which is slightly larger than the purified r-thiolase. When incubated with the cell-free extract of Dictyostelium cells, the precursor was converted to the same size to the purified r-thiolase, suggesting that the presequence at the N-terminus is removed by a Dictyostelium processing peptidase.

Published

2010

15. Slingshot-3 dephosphorylates ADF/cofilin but is dispensable for mouse development

Author

Osamu Chisaka, Yasuyuki Shima, Hiroshi Kiyonari, Tadashi Uemura, Kazuyoshi Kousaka, Akira Nagafuchi, and Naoko Oshima

Subjects

Cofilin 1, endocrine system, Phosphatase, macromolecular substances, Biology, Epithelium, Cell Line, Mice, Endocrinology, Chlorocebus aethiops, Genetics, Phosphoprotein Phosphatases, Animals, Humans, Fetal Viability, Actin, Mice, Knockout, Slingshot, Sequence Homology, Amino Acid, Kinase, Brain, Gene Expression Regulation, Developmental, Cell Biology, Cofilin, Molecular biology, Cell biology, Fertility, Animals, Newborn, Destrin, Knockout mouse, COS Cells, NIH 3T3 Cells, Phosphorylation

Abstract

Actin-depolymerizing factor (ADF) and cofilin constitute a family of key regulators of actin filament dynamics. ADF/cofilin is inactivated by phosphorylation at Ser-3 by LIM-kinases and reactivated by dephosphorylation by Slingshot (SSH) family phosphatases. Defects in LIM kinases or ADF/cofilin have been implicated in morbidity in human or mice; however, the roles of mammalian SSH in vivo have not been addressed. In this study, we examined the endogenous expression of each mouse SSH member in various cell lines and tissues, and showed that SSH-3L protein was strongly expressed in epithelial cells. Our structure-function analysis of SSH-3L suggested the possibility that the C-tail unique to SSH-3L negatively regulates the catalytic activity of this phosphatase. Furthermore we made ssh-3 knockout mice to examine its potential in vivo roles. Unexpectedly, ssh-3 was not essential for viability, fertility, or development of epithelial tissues; and ssh-3 did not genetically modify the corneal disorder of the corn1/ADF/destrin mutant.

Published

2008

16. Opposing roles in neurite growth control by two seven-pass transmembrane cadherins

Author

Mikio Hoshino, Tadashi Uemura, Tomoo Hirano, Kazuyoshi Kosaka, Yasuyuki Shima, Yo-ichi Nabeshima, Shin-ya Kawaguchi, and Manabu Nakayama

Subjects

Neurite, Biology, Cell Enlargement, In Vitro Techniques, Transfection, Hippocampus, Receptors, G-Protein-Coupled, Calcium imaging, medicine, Neurites, Animals, Humans, Axon, Cloning, Molecular, RNA, Small Interfering, Cell Line, Transformed, Neurons, Dose-Response Relationship, Drug, Cadherin, General Neuroscience, Cadherins, Transmembrane protein, Rats, Transmembrane domain, medicine.anatomical_structure, Culture Media, Conditioned, Second messenger system, Mutation, Calcium, Neuron, Neuroscience

Abstract

The growth of neurites (axon and dendrite) should be appropriately regulated by their interactions in the development of nervous systems where a myriad of neurons and their neurites are tightly packed. We show here that mammalian seven-pass transmembrane cadherins Celsr2 and Celsr3 are activated by their homophilic interactions and regulate neurite growth in an opposing manner. Both gene-silencing and coculture assay with rat neuron cultures showed that Celsr2 enhanced neurite growth, whereas Celsr3 suppressed it, and that their opposite functions were most likely the result of a difference of a single amino acid residue in the transmembrane domain. Together with calcium imaging and pharmacological analyses, our results suggest that Celsr2 and Celsr3 fulfill their functions through second messengers, and that differences in the activities of the homologs results in opposite effects in neurite growth regulation.

Published

2007

17. Regulation of dendritic maintenance and growth by a mammalian 7-pass transmembrane cadherin

Author

Tadashi Uemura, Tomoo Hirano, Mineko Kengaku, Masatoshi Takeichi, and Yasuyuki Shima

Subjects

Time Factors, Immunoblotting, Molecular Sequence Data, Biology, Transfection, General Biochemistry, Genetics and Molecular Biology, Animals, Genetically Modified, Purkinje Cells, Slice preparation, RNA interference, Extracellular, Animals, Gene Silencing, RNA, Small Interfering, Rats, Wistar, Molecular Biology, Neurons, Base Sequence, Dose-Response Relationship, Drug, Cadherin, Pyramidal Cells, Cell Membrane, Brain, Cell Biology, Dendrites, Cadherins, Phenotype, Transmembrane protein, Cell biology, Protein Structure, Tertiary, Rats, RNA, Axon guidance, RNA Interference, Intracellular, Cell Division, Gene Deletion, Developmental Biology, Plasmids

Abstract

Drosophila Flamingo is a 7-pass transmembrane cadherin that is necessary for dendritic patterning and axon guidance. How it works at the molecular level and whether homologs of Flamingo play similar roles in mammalian neurons or not have been unanswered questions. Here, we performed loss-of-function analysis using an RNAi system and organotypic brain slice cultures to address the role of a mammalian Flamingo homolog, Celsr2. Knocking down Celsr2 resulted in prominent simplification of dendritic arbors of cortical pyramidal neurons and Purkinje neurons, and this phenotype seemed to be due to branch retraction. Cadherin domain-mediated homophilic interaction appears to be required for the maintenance of dendritic branches. Furthermore, expression of various Celsr2 forms elicited distinct responses that were dependent on an extracellular subregion outside the cadherin domains and on a portion within the carboxyl intracellular tail. Based on these findings, we discuss how Celsr2 may regulate dendritic maintenance and growth.

Published

2003

18. Flamingo, a Seven-Pass Transmembrane Cadherin, Regulates Planar Cell Polarity under the Control of Frizzled

Author

Shinji Hirano, Tadashi Uemura, Yuko Shimada, Tadao Usui, Masatoshi Takeichi, Thomas Schwarz, Yasuyuki Shima, and Robert W. Burgess

Subjects

Ommatidial rotation, Frizzled, Time Factors, Molecular Sequence Data, Biology, Transfection, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Receptors, G-Protein-Coupled, Mice, Cell polarity, Cell Adhesion, Animals, Drosophila Proteins, Wings, Animal, Amino Acid Sequence, Cytoskeleton, Cell adhesion, Cells, Cultured, Conserved Sequence, Sequence Homology, Amino Acid, Biochemistry, Genetics and Molecular Biology(all), Cadherin, Cell Polarity, Gene Expression Regulation, Developmental, Membrane Proteins, Cadherins, Frizzled Receptors, Transmembrane protein, Cell biology, Mutagenesis, Drosophila, Ectopic expression

Abstract

We identified a seven-pass transmembrane receptor of the cadherin superfamily, designated Flamingo (Fmi), localized at cell–cell boundaries in the Drosophila wing. In the absence of Fmi, planar polarity was distorted. Before morphological polarization of wing cells along the proximal-distal (P-D) axis, Fmi was redistributed predominantly to proximal and distal cell edges. This biased localization of Fmi appears to be driven by an imbalance of the activity of Frizzled (Fz) across the proximal/distal cell boundary. These results, together with phenotypes caused by ectopic expression of fz and fmi, suggest that cells acquire the P-D polarity by way of the Fz-dependent boundary localization of Fmi.

19. A Resource of Cre Driver Lines for Genetic Targeting of GABAergic Neurons in Cerebral Cortex

Author

Ying Lin, Hiroki Taniguchi, Jiangteng Lu, Goichi Miyoshi, Sacha B. Nelson, Sangyong Kim, Ken Sugino, Raehum Paik, Z. Josh Huang, Yasuyuki Shima, Priscilla Wu, Yu Fu, Gord Fishell, Duda Kvitsani, and Miao He

Subjects

Cell type, Interneuron, Neuroscience(all), Transgene, Mice, Transgenic, 010501 environmental sciences, Biology, Cell fate determination, 01 natural sciences, Article, Cell Line, Mice, 03 medical and health sciences, 0302 clinical medicine, Genes, Reporter, Interneurons, Cortex (anatomy), medicine, Biological neural network, Animals, Gene Knock-In Techniques, gamma-Aminobutyric Acid, 0105 earth and related environmental sciences, 030304 developmental biology, Cerebral Cortex, Neurons, 0303 health sciences, Integrases, Stem Cells, General Neuroscience, Cell Differentiation, medicine.anatomical_structure, Gene Expression Regulation, Cerebral cortex, GABAergic, Neuroscience, 030217 neurology & neurosurgery

Abstract

SummaryA key obstacle to understanding neural circuits in the cerebral cortex is that of unraveling the diversity of GABAergic interneurons. This diversity poses general questions for neural circuit analysis: how are these interneuron cell types generated and assembled into stereotyped local circuits and how do they differentially contribute to circuit operations that underlie cortical functions ranging from perception to cognition? Using genetic engineering in mice, we have generated and characterized approximately 20 Cre and inducible CreER knockin driver lines that reliably target major classes and lineages of GABAergic neurons. More select populations are captured by intersection of Cre and Flp drivers. Genetic targeting allows reliable identification, monitoring, and manipulation of cortical GABAergic neurons, thereby enabling a systematic and comprehensive analysis from cell fate specification, migration, and connectivity, to their functions in network dynamics and behavior. As such, this approach will accelerate the study of GABAergic circuits throughout the mammalian brain.