Your search keyword '"Kind, Peter C."' showing total 7 results

1. Identifying foetal forebrain interneurons as a target for monogenic autism risk factors and the polygenic 16p11.2 microdeletion

Author

Yang, Yifei, Booker, Sam A., Clegg, James M., Quintana-Urzainqui, Idoia, Sumera, Anna, Kozic, Zrinko, Dando, Owen, Martin Lorenzo, Sandra, Herault, Yann, Kind, Peter C., Price, David J., and Pratt, Thomas

Published

2023

2. Reduced local input to fast‐spiking interneurons in the somatosensory cortex in the GABAA γ2 R43Q mouse model of absence epilepsy

Author

Currie, Stephen P., Luz, Liliana L., Booker, Sam A., Wyllie, David J. A., Kind, Peter C., and Daw, Michael I.

Subjects

Male, Analysis of Variance, Patch-Clamp Techniques, Full‐Length Original Research, Action Potentials, Glutamic Acid, Somatosensory Cortex, Development, In Vitro Techniques, Arginine, Receptors, GABA-A, Synapse, Animal models, Mice, Inbred C57BL, Disease Models, Animal, Mice, Animals, Newborn, Epilepsy, Absence, Inhibitory Postsynaptic Potentials, Interneurons, Animals, Point Mutation, Female, Inhibition

Abstract

Summary Objective Absence seizures in childhood absence epilepsy are initiated in the thalamocortical (TC) system. We investigated if these seizures result from altered development of the TC system before the appearance of seizures in mice containing a point mutation in γ‐aminobutyric acid A (GABAA) receptor γ2 subunits linked to childhood absence epilepsy (R43Q). Findings from conditional mutant mice indicate that expression of normal γ2 subunits during preseizure ages protect from later seizures. This indicates that altered development in the presence of the R43Q mutation is a key contributor to the R43Q phenotype. We sought to identify the cellular processes affected by the R43Q mutation during these preseizure ages. Methods We examined landmarks of synaptic development at the end of the critical period for somatosensory TC plasticity using electrophysiologic recordings in TC brain slices from wild‐type mice and R43Q mice. Results We found that the level of TC connectivity to layer 4 (L4) principal cells and the properties of TC synapses were unaltered in R43Q mice. Furthermore, we show that, although TC feedforward inhibition and the total level of GABAergic inhibition were normal, there was a reduction in the local connectivity to cortical interneurons. This reduction leads to altered inhibition during bursts of cortical activity. Significance This altered inhibition demonstrates that alterations in cortical circuitry precede the onset of seizures by more than a week.

Published

2017

3. Reduced local input to fast-spiking interneurons in the somatosensory cortex in the GABAA γ2 R43Q mouse model of absence epilepsy.

Author

Currie, Stephen P., Luz, Liliana L., Booker, Sam A., Wyllie, David J. A., Kind, Peter C., and Daw, Michael I.

Subjects

INTERNEURONS, EPILEPSY, SOMATOSENSORY cortex, SPASMS, PARIETAL lobe

Abstract

Objective Absence seizures in childhood absence epilepsy are initiated in the thalamocortical ( TC) system. We investigated if these seizures result from altered development of the TC system before the appearance of seizures in mice containing a point mutation in γ-aminobutyric acid A ( GABAA) receptor γ2 subunits linked to childhood absence epilepsy (R43Q). Findings from conditional mutant mice indicate that expression of normal γ2 subunits during preseizure ages protect from later seizures. This indicates that altered development in the presence of the R43Q mutation is a key contributor to the R43Q phenotype. We sought to identify the cellular processes affected by the R43Q mutation during these preseizure ages. Methods We examined landmarks of synaptic development at the end of the critical period for somatosensory TC plasticity using electrophysiologic recordings in TC brain slices from wild-type mice and R43Q mice. Results We found that the level of TC connectivity to layer 4 (L4) principal cells and the properties of TC synapses were unaltered in R43Q mice. Furthermore, we show that, although TC feedforward inhibition and the total level of GABAergic inhibition were normal, there was a reduction in the local connectivity to cortical interneurons. This reduction leads to altered inhibition during bursts of cortical activity. Significance This altered inhibition demonstrates that alterations in cortical circuitry precede the onset of seizures by more than a week. [ABSTRACT FROM AUTHOR]

Published

2017

4. Stimulated Emission Depletion (STED) Microscopy Reveals Nanoscale Defects in the Developmental Trajectory of Dendritic Spine Morphogenesis in a Mouse Model of Fragile X Syndrome.

Author

Wijetunge, Lasani S., Angibaud, Julie, Frick, Andreas, Kind, Peter C., and Valentin Näger, U.

Subjects

FRAGILE X syndrome, NEURODEVELOPMENTAL treatment, LABORATORY mice, SPINAL cord compression, DENDRITES, HIGH resolution electron microscopy, STIMULATED emission

Abstract

Dendritic spines are basic units of neuronal information processing and their structure is closely reflected in their function. Defects in synaptic development are common in neurodevelopmental disorders, making detailed knowledge of age-dependent changes in spine morphology essential for understanding disease mechanisms. However, little is known about the functionally important finemorphological structures, such as spine necks, due to the limited spatial resolution of conventional light microscopy. Using stimulated emission depletion microscopy (STED), we examined spine morphology at the nanoscale during normal development in mice, and tested the hypothesis that it is impaired in a mouse model of fragile X syndrome (FXS). In contrast to common belief, we find that, in normal development, spine heads become smaller, while their necks become wider and shorter, indicating that synapse compartmentalization decreases substantially with age. In the mouse model of FXS, this developmental trajectory is largely intact, with only subtle differences that are dependent on age and brain region. Together, our findings challenge current dogmas of both normal spine development as well as spine dysgenesis in FXS, highlighting the importance of super-resolution imaging approaches for elucidating structure-function relationships of dendritic spines. [ABSTRACT FROM AUTHOR]

Published

2014

5. mGluR5 Regulates Glutamate-Dependent Development of the Mouse Somatosensory Cortex.

Author

Wijetunge, Lasani S., Till, Sally M., Gillingwater, Thomas H., Ingham, Cali A., and Kind, Peter C.

Subjects

LABORATORY mice, LABORATORY animals -- Abnormalities, SOMATOSENSORY evoked potentials, SPREADING cortical depression, NEURONS

Abstract

We have previously reported that mGluR5 signaling via PLC-β1 regulates the development of whisker patterns within S1 (barrel) cortex of mice (Hannan et al., 2001). However, whether these defects arise from the loss of postsynaptic mGluR5 signaling, and whether the level of mGluR5 is important for barrel formation, was not examined. Furthermore, whether mGluR5 regulates other developmental processes that occur before or after barrel development is not known. We now show that mGluR5 is present postsynaptically at thalamocortical synapses during barrel formation. In addition, Mglur5-/- mice exhibit normal TCA patch formation but reduced cellular segregation in layer 4, indicating a dose-dependent role for mGluR5 in the regulation of pattern formation. Furthermore Mglur5-/- and Mglur5-/- mice display normal cortical arealization, layer formation, and size of PMBSF indicating the defects within S1 do not result from general abnormalities of cortical mapping during earlier stages of development. At P21 layer 4 neurons from Mglur5-/- and Mglur5-/- mice show a significant reduction in spine density but normal dendritic complexity compared with Mglur5-/- mice indicating a role in synaptogenesis during cortical development. Finally, mGluR5 regulates pattern formation throughout the trigeminal system of mice as the representation of the AS whiskers in the PrV, VpM, and S1 cortex was disrupted in Mglur5-/- mice. Together these data indicate a key role for mGluR5 at both early and late stages of neuronal development in the trigeminal system of mice. [ABSTRACT FROM AUTHOR]

Published

2008

6. Involvement of Protein Kinase A in Patterning of the Mouse Somatosensory Cortex.

Author

Watson, Ruth F., Abdel-Majid, Raja M., Barnett, Mark W., Willis, Brandon S., Katsnelson, Alla, Gillingwater, Thomas H., McKnight, G. Stanley, Kind, Peter C., and Neumann, Paul E.

Abstract

Patterning of the mouse somatosensory cortex is unusually evident because of the presence of a “barrel field.” Presynaptic serotonin and postsynaptic glutamate receptors regulate barrel formation, but little is known of the intracellular signaling pathways through which they act. To determine whether protein kinase A (PKA) plays a role in the development of the barrel field, we examined five viable PKA subunit-specific knock-out (KO) mouse lines for barrel field abnormalities. Barrels are present in these mice, but those lacking the RIIβ subunit display significantly reduced contrast between the cell densities of barrel hollows and sides compared with wild-type animals. Thalamocortical afferent segregation in the posterior medial barrel subfield appeared normal, suggesting a postsynaptic site of gene action for the RIIβ protein. Immunoelectron microscopy confirmed that RIIβ was selectively localized to dendrites and dendritic spines. Mice lacking RIIβ show reduced glutamate receptor A (GluRA) subunit insertion into the postsynaptic density in postnatal day 7 somatosensory cortex; however, GluRA KO mice developed normal barrels. Our results clearly demonstrate a role for postsynaptic PKA signaling pathways in barrel differentiation. They also demonstrate a clear dissociation between the regulation of GluRA trafficking by PKA and its role in barrel formation. Finally, although a role for PKA downstream of cAMP cannot be ruled out, these data suggest that PKA may not be the principle downstream target because none of the mutants showed a barrelless phenotype similar to that observed in adenylate cyclase type 1 KO mice. These results give insight into activity-dependent mechanisms that regulate barrel formation. [ABSTRACT FROM AUTHOR]

Published

2006

7. Synaptic Ras GTPase Activating Protein Regulates Pattern Formation in the Trigeminal System of Mice.

Author

Barnett, Mark W., Watson, Ruth F., Vitalis, Tania, Porter, Karen, Komiyama, Noboru H., Stoney, Patrick N., Gillingwater, Thomas H., Grant, Seth G. N., and Kind, Peter C.

Subjects

SENSE organs, GUANOSINE triphosphatase, GTPASE-activating protein, METHYL aspartate, LABORATORY rodents

Abstract

The development of ordered connections or "maps" within the nervous system is a common feature of sensory systems and is crucial for their normal function. NMDA receptors are known to play a key role in the formation of these maps; however, the intracellular signaling pathways that mediate the effects of glutamate are poorly understood. Here, we demonstrate that SynGAP, a synaptic Ras GTPase activating protein, is essential for the anatomical development of whisker-related patterns in the developing somatosensory pathways in rodent forebrain. Mice lacking SynGAP show only partial segregation of barreloids in the thalamus, and thalamocortical axons segregate into rows but do not form whisker-related patches. In cortex, layer 4 cells do not aggregate to form barrels. In Syngap+/- animals, barreloids develop normally, and thalamocortical afferents segregate in layer 4, but cell segregation is retarded. SynGAP is not necessary for the development of whisker-related patterns in the brainstem. Immunoelectron microscopy for SynGAP from layer 4 revealed a postsynaptic localization with labeling in developing postsynaptic densities (PSDs). Biochemically, SynGAP associates with the PSD in a PSD-95-independent manner, and Psd-95-/- animals develop normal barrels. These data demonstrate an essential role for SynGAP signaling in the activity-dependent development of whisker-related maps selectively in forebrain structures indicating that the intracellular pathways by which NMDA receptor activation mediates map formation differ between brain regions and developmental stage. [ABSTRACT FROM AUTHOR]

Published

2006