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63 results on '"PYRAMIDAL neurons"'

1. Early impairments of visually-driven neuronal ensemble dynamics in the rTg4510 tauopathy mouse model

Author: Parka, Aleksandra, Degel, Caroline, Dreyer, Jakob, Richter, Ulrike, Hall, Benjamin, Bastlund, Jesper F., Laursen, Bettina, Nedergaard, Maiken, Sotty, Florence, Botta, Paolo, Parka, Aleksandra, Degel, Caroline, Dreyer, Jakob, Richter, Ulrike, Hall, Benjamin, Bastlund, Jesper F., Laursen, Bettina, Nedergaard, Maiken, Sotty, Florence, and Botta, Paolo
Abstract: Tau protein pathology is a hallmark of many neurodegenerative diseases, including Alzheimer's Disease or frontotemporal dementia. Synaptic dysfunction and abnormal visual evoked potentials have been reported in murine models of tauopathy, but little is known about the state of the network activity on a single neuronal level prior to brain atrophy. In the present study, oscillatory rhythms and single-cell calcium activity of primary visual cortex pyramidal neuron population were investigated in basal and light evoked states in the rTg4510 tauopathy mouse model prior to neurodegeneration. We found a decrease in their responsivity and overall activity which was insensitive to GABAergic modulation. Despite an enhancement of basal state coactivation of cortical pyramidal neurons, a loss of input-output synchronicity was observed. Dysfunction of cortical pyramidal function was also reflected in a reduction of basal theta oscillations and enhanced susceptibility to a sub-convulsive dose of pentylenetetrazol in rTg4510 mice. Our results unveil impairments in visual cortical pyramidal neuron processing and define aberrant oscillations as biomarker candidates in early stages of neurodegenerative tauopathies., Tau protein pathology is a hallmark of many neurodegenerative diseases, including Alzheimer's Disease or frontotemporal dementia. Synaptic dysfunction and abnormal visual evoked potentials have been reported in murine models of tauopathy, but little is known about the state of the network activity on a single neuronal level prior to brain atrophy. In the present study, oscillatory rhythms and single-cell calcium activity of primary visual cortex pyramidal neuron population were investigated in basal and light evoked states in the rTg4510 tauopathy mouse model prior to neurodegeneration. We found a decrease in their responsivity and overall activity which was insensitive to GABAergic modulation. Despite an enhancement of basal state coactivation of cortical pyramidal neurons, a loss of input-output synchronicity was observed. Dysfunction of cortical pyramidal function was also reflected in a reduction of basal theta oscillations and enhanced susceptibility to a sub-convulsive dose of pentylenetetrazol in rTg4510 mice. Our results unveil impairments in visual cortical pyramidal neuron processing and define aberrant oscillations as biomarker candidates in early stages of neurodegenerative tauopathies.
Published: 2023

2. Early impairments of visually-driven neuronal ensemble dynamics in the rTg4510 tauopathy mouse model

Author: Parka, Aleksandra, Degel, Caroline, Dreyer, Jakob, Richter, Ulrike, Hall, Benjamin, Bastlund, Jesper F., Laursen, Bettina, Nedergaard, Maiken, Sotty, Florence, Botta, Paolo, Parka, Aleksandra, Degel, Caroline, Dreyer, Jakob, Richter, Ulrike, Hall, Benjamin, Bastlund, Jesper F., Laursen, Bettina, Nedergaard, Maiken, Sotty, Florence, and Botta, Paolo
Abstract: Tau protein pathology is a hallmark of many neurodegenerative diseases, including Alzheimer's Disease or frontotemporal dementia. Synaptic dysfunction and abnormal visual evoked potentials have been reported in murine models of tauopathy, but little is known about the state of the network activity on a single neuronal level prior to brain atrophy. In the present study, oscillatory rhythms and single-cell calcium activity of primary visual cortex pyramidal neuron population were investigated in basal and light evoked states in the rTg4510 tauopathy mouse model prior to neurodegeneration. We found a decrease in their responsivity and overall activity which was insensitive to GABAergic modulation. Despite an enhancement of basal state coactivation of cortical pyramidal neurons, a loss of input-output synchronicity was observed. Dysfunction of cortical pyramidal function was also reflected in a reduction of basal theta oscillations and enhanced susceptibility to a sub-convulsive dose of pentylenetetrazol in rTg4510 mice. Our results unveil impairments in visual cortical pyramidal neuron processing and define aberrant oscillations as biomarker candidates in early stages of neurodegenerative tauopathies., Tau protein pathology is a hallmark of many neurodegenerative diseases, including Alzheimer's Disease or frontotemporal dementia. Synaptic dysfunction and abnormal visual evoked potentials have been reported in murine models of tauopathy, but little is known about the state of the network activity on a single neuronal level prior to brain atrophy. In the present study, oscillatory rhythms and single-cell calcium activity of primary visual cortex pyramidal neuron population were investigated in basal and light evoked states in the rTg4510 tauopathy mouse model prior to neurodegeneration. We found a decrease in their responsivity and overall activity which was insensitive to GABAergic modulation. Despite an enhancement of basal state coactivation of cortical pyramidal neurons, a loss of input-output synchronicity was observed. Dysfunction of cortical pyramidal function was also reflected in a reduction of basal theta oscillations and enhanced susceptibility to a sub-convulsive dose of pentylenetetrazol in rTg4510 mice. Our results unveil impairments in visual cortical pyramidal neuron processing and define aberrant oscillations as biomarker candidates in early stages of neurodegenerative tauopathies.
Published: 2023

3. Preferential in vivo inhibitory action of serotonin in rat infralimbic versus prelimbic cortex: relevance for antidepressant treatments

Author: Ministerio de Economía y Competitividad (España), European Commission, Instituto de Salud Carlos III, Centro de Investigación Biomédica en Red Salud Mental (España), Generalitat de Catalunya, López-Terrones, Elena, Celada, Pau, Riga, Maurizio, Artigas, Francesc, Ministerio de Economía y Competitividad (España), European Commission, Instituto de Salud Carlos III, Centro de Investigación Biomédica en Red Salud Mental (España), Generalitat de Catalunya, López-Terrones, Elena, Celada, Pau, Riga, Maurizio, and Artigas, Francesc
Abstract: The infralimbic (IL) cortex is the rodent equivalent of human ventral anterior cingulate cortex (vACC), which plays a key role in the pathophysiology and treatment of major depressive disorder (MDD). The modulation of glutamatergic neurotransmission in IL [but not in the adjacent prelimbic (PrL) cortex] evokes antidepressant-like or depressive-like behaviors, associated with changes in serotonin (5-HT) function, highlighting the relevance of glutamate/serotonin interactions in IL for emotional control. 5-HT modulates neuronal activity in PrL and cingulate (Cg) cortex but its effects in IL are largely unknown. We therefore compared the in vivo effects of 5-HT on pyramidal neuron activity in IL (n = 61) and PrL (n = 50) of anesthetized rats. IL pyramidal neurons were more responsive to physiological dorsal raphe stimulation (0.9 Hz) than PrL neurons (84% vs. 64%, respectively) and were inhibited to a greater extent (64% vs. 36%, respectively). Orthodromic activations (8% in PrL) were absent in IL, whereas biphasic responses were similar (20%) in both areas. Excitations were mediated by 5-HT2A-R activation, whereas inhibitions involved 3 different components: 5-HT1A-R, 5-HT3-R and GABAA-R, respectively. The remarkable inhibitory action of 5-HT in IL suggests that 5-HT-enhancing drugs may exert their antidepressant action by normalizing a glutamatergic hyperactivity in the vACC of MDD patients.
Published: 2022

4. Regulation of dendritic development by Zeb2

Author: Larkum, Matthew, Wernet, Mathias F., de Rocha Rosario, Marta, Salina, Valentina, Larkum, Matthew, Wernet, Mathias F., de Rocha Rosario, Marta, and Salina, Valentina
Abstract: Dendritische Defekte vermitteln Störungen der Erregbarkeit, Modulation und Plastizität von Neuronen, die zur Entwicklung neurodegenerativer Krankheiten führen können. Eine Mutation des Transkriptionsregulators Zeb2 führt zur Entwicklung des Mowat-Wilson-Syndroms, einer Erkrankung, die mit kognitiven Störungen und einem erkennbaren Gesichtsphänotyp einhergeht. Obwohl kognitive Defekte häufig mit Defekten bei der Bildung des dendritischen Baums in Verbindung gebracht werden, wurde die Rolle von Zeb2 bei der dendritischen Entwicklung bisher nicht untersucht. Hier zeige ich, dass Zeb2-defiziente Neuronen in den oberen neokortikalen Schichten einen abnormalen dendritische Baum aufweisen. Außerdem führt der Verlust von Zeb2 zu einer Fehlorientierung des apikalen Dendriten in einer nicht senkrechten Ausrichtung zur Pia. Darüber hinaus habe ich die Signalwege analysiert, die an der Regulierung der Morphologie des Dendritenbaum stromabwärts von Zeb2 beteiligt sind, und zwar durch Deep Sequencing des Transkriptoms von Zeb2-defizienten und Wildtyp-Neokortices sowie durch Massenspektrometrie-Screens auf Veränderungen in der Expression von Zelloberflächenproteinen nach dem Verlust von Zeb2. Für die vielversprechenden Kandidaten habe ich ein in situ-Hybridisierungs-Screening bei E15,5 durchgeführt. Eine Reihe von Genen, die an der neuronalen Morphologie und an Membranproteinen beteiligt sind, darunter Neuropilin1 und Cadherin6, werden in Gehirnen mit Zeb2-Mangel überexprimiert. Insbesondere habe ich die Rolle der neuen nachgeschalteten Zielgene Nrp1, Cdh6 und Wnt5a analysiert. Ich verwendete shRNA von Nrp1, Cdh6 und Wnt5a in neuronale Zellkultur, um zu zeigen, dass Nrp1 und Wnt5a eine erhöhte dendritische Komplexität in den Zeb2-defizienten neuronalen Zellen fördern. Die Überexpression von Nrp1 in Neuronen der oberen Schicht in vivo mittels in utero Elektroporation ist ausreichend, um die dendritische Komplexität zu fördern. Darüber hinaus zeige ich durch in utero Elektroporation, Dendritic defects mediate disturbances in the excitability, modulation and plasticity of neurons, which can lie at the cause of neurodegenerative diseases. Mutation of the transcriptional regulator, Zeb2, causes the development of Mowat-Wilson syndrome, a condition associated with cognitive defects and a recognizable facial phenotype. Although cognitive defects are often associated with defects in the formation of the dendritic tree, the role of Zeb2 in dendritic development had not been studied previously. Here, I show that Zeb2- deficient neurons in the upper neocortical layers have abnormal dendritic trees. Also, loss of Zeb2 results in the mis-orientation of the apical dendrite to a non-perpendicular orientation to the pia. Furthermore, I have analysed the signalling pathways involved in regulation of dendritic tree morphology downstream of Zeb2 by deep sequencing of the transcriptome of Zeb2-deficient and wildtype neocortices and mass spectrometry screens for changes in the expression of cell surface proteins upon loss of Zeb2. For the promising candidates, I have performed in situ hybridization screening at E15.5. A number of genes involved in neuronal morphology and membrane proteins, including Neuropilin1 and Cadherin6, become overexpressed in Zeb2- deficient brains. In particular, I analysed the role of the novel downstream target genes Nrp1, Cdh6 and Wnt5a. I used shRNA of Nrp1, Cdh6 and Wnt5a in cortical neuron cultures to demonstrate that Nrp1 and Wnt5a promote increased dendritic complexity in Zeb2-deficient neuronal cells. Overexpression of Nrp1 in upper layer neurons in vivo, using in utero electroporation, is sufficient to promote dendritic complexity. In addition, I show using in utero electroporation of an shRNA against Nrp1 into Zeb2-deficient animals, that repression of Nrp1 by Zeb2 is required for suppressing excessive branching during development. It is not needed however for the orientation of the dendritic tree. Taken together, these data sho
Published: 2022

5. Common Microscale and Macroscale Principles of Connectivity in the Human Brain

Author: Netherlands Brain Bank and Netherlands Brain Bank
Abstract: The brain requires efficient information transfer between neurons and large-scale brain regions. Brain connectivity follows predictable organizational principles. At the cellular level, larger supragranular pyramidal neurons have larger, more branched dendritic trees, more synapses, and perform more complex computations; at the macroscale, region-to-region connections display a diverse architecture with highly connected hub areas facilitating complex information integration and computation. Here, we explore the hypothesis that the branching structure of large-scale region-to-region connectivity follows similar organizational principles as the neuronal scale. We examine microscale connectivity of basal dendritic trees of supragranular pyramidal neurons (300+) across 10 cortical areas in five human donor brains (1 male, 4 female). Dendritic complexity was quantified as the number of branch points, tree length, spine count, spine density, and overall branching complexity. High-resolution diffusion-weighted MRI was used to construct white matter trees of corticocortical wiring. Examining complexity of the resulting white matter trees using the same measures as for dendritic trees shows heteromodal association areas to have larger, more complex white matter trees than primary areas (p < 0.0001) and macroscale complexity to run in parallel with microscale measures, in terms of number of inputs (r = 0.677, p = 0.032), branch points (r = 0.797, p = 0.006), tree length (r = 0.664, p = 0.036), and branching complexity (r = 0.724, p = 0.018). Our findings support the integrative theory that brain connectivity follows similar principles of connectivity at neuronal and macroscale levels and provide a framework to study connectivity changes in brain conditions at multiple levels of organization.SIGNIFICANCE STATEMENT Within the human brain, cortical areas are involved in a wide range of processes, requiring different levels of information integration and local computation.
Published: 2022
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6. Refinement of Active and Passive Membrane Properties of Layer V Pyramidal Neurons in Rat Primary Motor Cortex During Postnatal Development

Author: Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, Carrascal Moreno, María Livia, Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, and Carrascal Moreno, María Livia
Abstract: Achieving the distinctive complex behaviors of adult mammals requires the development of a great variety of specialized neural circuits. Although the development of these circuits begins during the embryonic stage, they remain immature at birth, requiring a postnatal maturation process to achieve these complex tasks. Understanding how the neuronal membrane properties and circuits change during development is the first step to understand their transition into efficient ones. Thus, using whole cell patch clamp recordings, we have studied the changes in the electrophysiological properties of layer V pyramidal neurons of the rat primary motor cortex during postnatal development. Among all the parameters studied, only the voltage threshold was established at birth and, although some of the changes occurred mainly during the second postnatal week, other properties such as membrane potential, capacitance, duration of the post-hyperpolarization phase or the maximum firing rate were not defined until the beginning of adulthood. Those modifications lead to a decrease in neuronal excitability and to an increase in the working range in young adult neurons, allowing more sensitive and accurate responses. This maturation process, that involves an increase in neuronal size and changes in ionic conductances, seems to be influenced by the neuronal type and by the task that neurons perform as inferred from the comparison with other pyramidal and motor neuron populations.
Published: 2021

7. Refinement of Active and Passive Membrane Properties of Layer V Pyramidal Neurons in Rat Primary Motor Cortex During Postnatal Development

Author: Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, Carrascal Moreno, María Livia, Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, and Carrascal Moreno, María Livia
Abstract: Achieving the distinctive complex behaviors of adult mammals requires the development of a great variety of specialized neural circuits. Although the development of these circuits begins during the embryonic stage, they remain immature at birth, requiring a postnatal maturation process to achieve these complex tasks. Understanding how the neuronal membrane properties and circuits change during development is the first step to understand their transition into efficient ones. Thus, using whole cell patch clamp recordings, we have studied the changes in the electrophysiological properties of layer V pyramidal neurons of the rat primary motor cortex during postnatal development. Among all the parameters studied, only the voltage threshold was established at birth and, although some of the changes occurred mainly during the second postnatal week, other properties such as membrane potential, capacitance, duration of the post-hyperpolarization phase or the maximum firing rate were not defined until the beginning of adulthood. Those modifications lead to a decrease in neuronal excitability and to an increase in the working range in young adult neurons, allowing more sensitive and accurate responses. This maturation process, that involves an increase in neuronal size and changes in ionic conductances, seems to be influenced by the neuronal type and by the task that neurons perform as inferred from the comparison with other pyramidal and motor neuron populations.
Published: 2021

8. Refinement of Active and Passive Membrane Properties of Layer V Pyramidal Neurons in Rat Primary Motor Cortex During Postnatal Development

Author: Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, Carrascal Moreno, María Livia, Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, and Carrascal Moreno, María Livia
Abstract: Achieving the distinctive complex behaviors of adult mammals requires the development of a great variety of specialized neural circuits. Although the development of these circuits begins during the embryonic stage, they remain immature at birth, requiring a postnatal maturation process to achieve these complex tasks. Understanding how the neuronal membrane properties and circuits change during development is the first step to understand their transition into efficient ones. Thus, using whole cell patch clamp recordings, we have studied the changes in the electrophysiological properties of layer V pyramidal neurons of the rat primary motor cortex during postnatal development. Among all the parameters studied, only the voltage threshold was established at birth and, although some of the changes occurred mainly during the second postnatal week, other properties such as membrane potential, capacitance, duration of the post-hyperpolarization phase or the maximum firing rate were not defined until the beginning of adulthood. Those modifications lead to a decrease in neuronal excitability and to an increase in the working range in young adult neurons, allowing more sensitive and accurate responses. This maturation process, that involves an increase in neuronal size and changes in ionic conductances, seems to be influenced by the neuronal type and by the task that neurons perform as inferred from the comparison with other pyramidal and motor neuron populations.
Published: 2021

9. Refinement of Active and Passive Membrane Properties of Layer V Pyramidal Neurons in Rat Primary Motor Cortex During Postnatal Development

Author: Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, Carrascal Moreno, María Livia, Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, and Carrascal Moreno, María Livia
Abstract: Achieving the distinctive complex behaviors of adult mammals requires the development of a great variety of specialized neural circuits. Although the development of these circuits begins during the embryonic stage, they remain immature at birth, requiring a postnatal maturation process to achieve these complex tasks. Understanding how the neuronal membrane properties and circuits change during development is the first step to understand their transition into efficient ones. Thus, using whole cell patch clamp recordings, we have studied the changes in the electrophysiological properties of layer V pyramidal neurons of the rat primary motor cortex during postnatal development. Among all the parameters studied, only the voltage threshold was established at birth and, although some of the changes occurred mainly during the second postnatal week, other properties such as membrane potential, capacitance, duration of the post-hyperpolarization phase or the maximum firing rate were not defined until the beginning of adulthood. Those modifications lead to a decrease in neuronal excitability and to an increase in the working range in young adult neurons, allowing more sensitive and accurate responses. This maturation process, that involves an increase in neuronal size and changes in ionic conductances, seems to be influenced by the neuronal type and by the task that neurons perform as inferred from the comparison with other pyramidal and motor neuron populations.
Published: 2021

10. Refinement of Active and Passive Membrane Properties of Layer V Pyramidal Neurons in Rat Primary Motor Cortex During Postnatal Development

Author: Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, Carrascal Moreno, María Livia, Universidad de Sevilla. Departamento de Fisiología, Pérez García, Patricia, Pardillo Díaz, Ricardo, Geribaldi Doldán, Noelia, Gómez Oliva, Ricardo, Domínguez García, Samuel, Castro, Carmen, Núñez Abades, Pedro Antonio, and Carrascal Moreno, María Livia
Abstract: Achieving the distinctive complex behaviors of adult mammals requires the development of a great variety of specialized neural circuits. Although the development of these circuits begins during the embryonic stage, they remain immature at birth, requiring a postnatal maturation process to achieve these complex tasks. Understanding how the neuronal membrane properties and circuits change during development is the first step to understand their transition into efficient ones. Thus, using whole cell patch clamp recordings, we have studied the changes in the electrophysiological properties of layer V pyramidal neurons of the rat primary motor cortex during postnatal development. Among all the parameters studied, only the voltage threshold was established at birth and, although some of the changes occurred mainly during the second postnatal week, other properties such as membrane potential, capacitance, duration of the post-hyperpolarization phase or the maximum firing rate were not defined until the beginning of adulthood. Those modifications lead to a decrease in neuronal excitability and to an increase in the working range in young adult neurons, allowing more sensitive and accurate responses. This maturation process, that involves an increase in neuronal size and changes in ionic conductances, seems to be influenced by the neuronal type and by the task that neurons perform as inferred from the comparison with other pyramidal and motor neuron populations.
Published: 2021

11. Unexpected Transcriptional Programs Contribute to Hippocampal Memory Deficits and Neuronal Stunting after Early-Life Adversity.

Author: Bolton, Jessica L, Bolton, Jessica L, Schulmann, Anton, Garcia-Curran, Megan M, Regev, Limor, Chen, Yuncai, Kamei, Noriko, Shao, Manlin, Singh-Taylor, Akanksha, Jiang, Shan, Noam, Yoav, Molet, Jenny, Mortazavi, Ali, Baram, Tallie Z, Bolton, Jessica L, Bolton, Jessica L, Schulmann, Anton, Garcia-Curran, Megan M, Regev, Limor, Chen, Yuncai, Kamei, Noriko, Shao, Manlin, Singh-Taylor, Akanksha, Jiang, Shan, Noam, Yoav, Molet, Jenny, Mortazavi, Ali, and Baram, Tallie Z
Abstract: Early-life adversity (ELA) is associated with lifelong memory deficits, yet the responsible mechanisms remain unclear. We impose ELA by rearing rat pups in simulated poverty, assess hippocampal memory, and probe changes in gene expression, their transcriptional regulation, and the consequent changes in hippocampal neuronal structure. ELA rats have poor hippocampal memory and stunted hippocampal pyramidal neurons associated with ~140 differentially expressed genes. Upstream regulators of the altered genes include glucocorticoid receptor and, unexpectedly, the transcription factor neuron-restrictive silencer factor (NRSF/REST). NRSF contributes critically to the memory deficits because blocking its function transiently following ELA rescues spatial memory and restores the dendritic arborization of hippocampal pyramidal neurons in ELA rats. Blocking NRSF function in vitro augments dendritic complexity of developing hippocampal neurons, suggesting that NRSF represses genes involved in neuronal maturation. These findings establish important, surprising contributions of NRSF to ELA-induced transcriptional programming that disrupts hippocampal maturation and memory function.
Published: 2020

12. Unexpected Transcriptional Programs Contribute to Hippocampal Memory Deficits and Neuronal Stunting after Early-Life Adversity.

Author: Bolton, Jessica L, Bolton, Jessica L, Schulmann, Anton, Garcia-Curran, Megan M, Regev, Limor, Chen, Yuncai, Kamei, Noriko, Shao, Manlin, Singh-Taylor, Akanksha, Jiang, Shan, Noam, Yoav, Molet, Jenny, Mortazavi, Ali, Baram, Tallie Z, Bolton, Jessica L, Bolton, Jessica L, Schulmann, Anton, Garcia-Curran, Megan M, Regev, Limor, Chen, Yuncai, Kamei, Noriko, Shao, Manlin, Singh-Taylor, Akanksha, Jiang, Shan, Noam, Yoav, Molet, Jenny, Mortazavi, Ali, and Baram, Tallie Z
Abstract: Early-life adversity (ELA) is associated with lifelong memory deficits, yet the responsible mechanisms remain unclear. We impose ELA by rearing rat pups in simulated poverty, assess hippocampal memory, and probe changes in gene expression, their transcriptional regulation, and the consequent changes in hippocampal neuronal structure. ELA rats have poor hippocampal memory and stunted hippocampal pyramidal neurons associated with ~140 differentially expressed genes. Upstream regulators of the altered genes include glucocorticoid receptor and, unexpectedly, the transcription factor neuron-restrictive silencer factor (NRSF/REST). NRSF contributes critically to the memory deficits because blocking its function transiently following ELA rescues spatial memory and restores the dendritic arborization of hippocampal pyramidal neurons in ELA rats. Blocking NRSF function in vitro augments dendritic complexity of developing hippocampal neurons, suggesting that NRSF represses genes involved in neuronal maturation. These findings establish important, surprising contributions of NRSF to ELA-induced transcriptional programming that disrupts hippocampal maturation and memory function.
Published: 2020

13. The stress-induced transcription factor NR4A1 adjusts mitochondrial function and synapse number in prefrontal cortex

Author: Jeanneteau, Freddy, Barrère, Christian, Vos, Mariska, De Vries, Carlie J.M., Rouillard, Claude, Lévesque, Daniel, Dromard, Yann, Moisan, Marie-Pierre, Duric, Vanja, Franklin, Tina C., Duman, Ronald S., Lewis, David A., Ginsberg, Stephen D., Jeanneteau, Freddy, Barrère, Christian, Vos, Mariska, De Vries, Carlie J.M., Rouillard, Claude, Lévesque, Daniel, Dromard, Yann, Moisan, Marie-Pierre, Duric, Vanja, Franklin, Tina C., Duman, Ronald S., Lewis, David A., and Ginsberg, Stephen D.
Abstract: The energetic costs of behavioral chronic stress are unlikelyto be sustainable without neuronal plasticity. Mitochondria havethe capacity to handle synaptic activity up to a limit before energetic depletion occurs. Protective mechanisms driven by the induction of neuronal genes likely evolved to buffer the consequences of chronic stress on excitatory neurons in prefrontal cortex (PFC), as this circuitry is vulnerable to excitotoxic insults. Little is known about the genes involved in mitochondrial adaptation to the buildup of chronic stress. Using combinations of genetic manipulations and stress for analyzing structural, transcriptional, mitochondrial, and behavioral outcomes, we characterized NR4A1 as a stress-inducible modifier of mitochondrial energetic competence and dendritic spine number in PFC. NR4A1 acted as a transcription factor for changing the expression of target genes previously involved in mitochondrial uncoupling, AMP-activated protein kinase activation, and synaptic growth. Maintenance of NR4A1 activity by chronic stress played a critical role in the regressive synaptic organization in PFC of mouse models of stress (male only). Knockdown, dominant-negative approach, and knockout of Nr4a1 in mice and rats (male only) protected pyramidal neurons against the adverse effects of chronic stress. In human PFC tissues of men and women, high levels of the transcriptionally active NR4A1 correlated with measures of synaptic loss and cognitive impairment. In the context of chronic stress, prolonged expression and activity of NR4A1 may lead to responses of mitochondria and synaptic connectivity that do not match environmental demand, resulting in circuit malfunction between PFC and other brain regions, constituting a pathological feature across disorder
Published: 2018

14. The stress-induced transcription factor NR4A1 adjusts mitochondrial function and synapse number in prefrontal cortex

Author: Jeanneteau, Freddy, Lévesque, Daniel, Barrère, Christian, Rouillard, Claude, Vos, Mariska, De Vries, Carlie J.M., Dromard, Yann, Moisan, Marie-Pierre, Duric, Vanja, Franklin, Tina C., Duman, Ronald S., Lewis, David A., Ginsberg, Stephen D., Jeanneteau, Freddy, Lévesque, Daniel, Barrère, Christian, Rouillard, Claude, Vos, Mariska, De Vries, Carlie J.M., Dromard, Yann, Moisan, Marie-Pierre, Duric, Vanja, Franklin, Tina C., Duman, Ronald S., Lewis, David A., and Ginsberg, Stephen D.
Abstract: The energetic costs of behavioral chronic stress are unlikely to be sustainable without neuronal plasticity. Mitochondria have the capacity to handle synaptic activity up to a limit before energetic depletion occurs. Protective mechanisms driven by the induction of neuronal genes likely evolved to buffer the consequences of chronic stress on excitatory neurons in prefrontal cortex (PFC), as this circuitry is vulnerable to excitotoxic insults. Little is known about the genes involved in mitochondrial adaptation to the build up of chronic stress. Using combinations of genetic manipulations and stress for analyzing structural, transcriptional, mitochondrial and behavioral outcomes, we characterized NR4A1 as a stress-inducible modifier of mitochondrial energetic competence and dendritic spine number in PFC. NR4A1 acted as transcription factor for changing the expression of target genes previously involved in mitochondrial uncoupling, AMPK activation and synaptic growth. Maintenance of NR4A1 activity by chronic stress played a critical role in the regressive synaptic organization in PFC of mouse models of stress (male only). Knockdown, dominant negative and knockout of NR4A1 in mice and rats (male only) protected pyramidal neurons against the adverse effects of chronic stress. In human PFC tissues of men and women, high levels of the transcriptionally-active NR4A1 correlated with measures of synaptic loss and cognitive impairment. In the context of chronic stress, prolonged expression and activity of NR4A1 may lead to responses of mitochondria and synaptic connectivity that do not match environmental demand, resulting in circuit malfunction between PFC and other brain regions constituting a pathological feature across disorders.
Published: 2018

15. Time and dose dependent effects of oxidative stress induced by cumene hydroperoxide in neuronal excitability of rat motor cortex neurons

Author: Universidad de Sevilla. Departamento de Bioquímica y Biología Molecular, Universidad de Sevilla. Departamento de Fisiología, European Regional Development Fund, Pardillo Díaz, Ricardo, Carrascal Moreno, María Livia, Muñoz Pinto, Mario Faustino, Ayala Gómez, Antonio, Núñez Abades, Pedro Antonio, Universidad de Sevilla. Departamento de Bioquímica y Biología Molecular, Universidad de Sevilla. Departamento de Fisiología, European Regional Development Fund, Pardillo Díaz, Ricardo, Carrascal Moreno, María Livia, Muñoz Pinto, Mario Faustino, Ayala Gómez, Antonio, and Núñez Abades, Pedro Antonio
Published: 2016

16. Optical Clearing of the Mouse Central Nervous System Using Passive CLARITY.

Author: Roberts, Dustin G, Roberts, Dustin G, Johnsonbaugh, Hadley B, Spence, Rory D, MacKenzie-Graham, Allan, Roberts, Dustin G, Roberts, Dustin G, Johnsonbaugh, Hadley B, Spence, Rory D, and MacKenzie-Graham, Allan
Abstract: Traditionally, tissue visualization has required that the tissue of interest be serially sectioned and imaged, subjecting each tissue section to unique non-linear deformations, dramatically hampering one's ability to evaluate cellular morphology, distribution and connectivity in the central nervous system (CNS). However, optical clearing techniques are changing the way tissues are visualized. These approaches permit one to probe deeply into intact organ preparations, providing tremendous insight into the structural organization of tissues in health and disease. Techniques such as Clear Lipid-exchanged Acrylamide-hybridized Rigid Imaging-compatible Tissue-hYdrogel (CLARITY) achieve this goal by providing a matrix that binds important biomolecules while permitting light-scattering lipids to freely diffuse out. Lipid removal, followed by refractive index matching, renders the tissue transparent and readily imaged in 3 dimensions (3D). Nevertheless, the electrophoretic tissue clearing (ETC) used in the original CLARITY protocol can be challenging to implement successfully and the use of a proprietary refraction index matching solution makes it expensive to use the technique routinely. This report demonstrates the implementation of a simple and inexpensive optical clearing protocol that combines passive CLARITY for improved tissue integrity and 2,2'-thiodiethanol (TDE), a previously described refractive index matching solution.
Published: 2016

17. Optical Clearing of the Mouse Central Nervous System Using Passive CLARITY.

Author: Roberts, Dustin G, Roberts, Dustin G, Johnsonbaugh, Hadley B, Spence, Rory D, MacKenzie-Graham, Allan, Roberts, Dustin G, Roberts, Dustin G, Johnsonbaugh, Hadley B, Spence, Rory D, and MacKenzie-Graham, Allan
Abstract: Traditionally, tissue visualization has required that the tissue of interest be serially sectioned and imaged, subjecting each tissue section to unique non-linear deformations, dramatically hampering one's ability to evaluate cellular morphology, distribution and connectivity in the central nervous system (CNS). However, optical clearing techniques are changing the way tissues are visualized. These approaches permit one to probe deeply into intact organ preparations, providing tremendous insight into the structural organization of tissues in health and disease. Techniques such as Clear Lipid-exchanged Acrylamide-hybridized Rigid Imaging-compatible Tissue-hYdrogel (CLARITY) achieve this goal by providing a matrix that binds important biomolecules while permitting light-scattering lipids to freely diffuse out. Lipid removal, followed by refractive index matching, renders the tissue transparent and readily imaged in 3 dimensions (3D). Nevertheless, the electrophoretic tissue clearing (ETC) used in the original CLARITY protocol can be challenging to implement successfully and the use of a proprietary refraction index matching solution makes it expensive to use the technique routinely. This report demonstrates the implementation of a simple and inexpensive optical clearing protocol that combines passive CLARITY for improved tissue integrity and 2,2'-thiodiethanol (TDE), a previously described refractive index matching solution.
Published: 2016

18. Wiring economy of pyramidal cells in the juvenile rat somatosensory cortex

Author: Anton-Sanchez, Laura, Bielza, Concha, Larrañaga, Pedro, DeFelipe, Javier, Anton-Sanchez, Laura, Bielza, Concha, Larrañaga, Pedro, and DeFelipe, Javier
Abstract: Ever since Cajal hypothesized that the structure of neurons is designed in such a way as to save space, time and matter, numerous researchers have analyzed wiring properties at different scales of brain organization. Here we test the hypothesis that individual pyramidal cells, the most abundant type of neuron in the cerebral cortex, optimize brain connectivity in terms of wiring length. In this study, we analyze the neuronal wiring of complete basal arborizations of pyramidal neurons in layer II, III, IV, Va, Vb and VI of the hindlimb somatosensory cortical region of postnatal day 14 rats. For each cell, we search for the optimal basal arborization and compare its length with the length of the real dendritic structure. Here the optimal arborization is defined as the arborization that has the shortest total wiring length provided that all neuron bifurcations are respected and the extent of the dendritic arborizations remain unchanged. We use graph theory and evolutionary computation techniques to search for the minimal wiring arborizations. Despite morphological differences between pyramidal neurons located in different cortical layers, we found that the neuronal wiring is near-optimal in all cases (the biggest difference between the shortest synthetic wiring found for a dendritic arborization and the length of its real wiring was less than 5%). We found, however, that the real neuronal wiring was significantly closer to the best solution found in layers II, III and IV. Our studies show that the wiring economy of cortical neurons is related not to the type of neurons or their morphological complexities but to general wiring economy principles.
Published: 2016

19. Expression of Serotonin2C Receptors in Pyramidal and GABAergic Neurons of Rat Prefrontal Cortex. A Comparison with Striatum

Author: Ministerio de Economía y Competitividad (España), European Commission, Generalitat de Catalunya, Centro de Investigación Biomédica en Red Salud Mental (España), Santana, Noemí, Artigas, Francesc, Ministerio de Economía y Competitividad (España), European Commission, Generalitat de Catalunya, Centro de Investigación Biomédica en Red Salud Mental (España), Santana, Noemí, and Artigas, Francesc
Abstract: The prefrontal cortex (PFC) is enriched in several serotonin receptors, including 5-HT1A-R, 5- HT2A-R and 5-HT3-R. These receptors modulate PFC activity due to their expression in large neuronal populations (5-HT1A-R, 5-HT2A-R) or in selected GABAergic populations (5-HT3-R). They are also relevant for antidepressant and antipsychotic drug action. Less is known about the localization of 5-HT2C-R, for which atypical antipsychotics show high affinity. Here we report on the cellular distribution of 5-HT2C-R in rat PFC and striatum, using double in situ hybridization histochemistry. In PFC, 5-HT2C-R are expressed in pyramidal (VGLUT1-positive) and GABAergic (GAD-positive) neurons, including parvalbumin-positive neurons. There is a marked dorsoventral gradient in the proportion of VGLUT1-positive cells expressing 5-HT2C-R, (9% in cingulate cortex, 61% in tenia tecta and 66% in piriform cortex), less marked for GABAergic neurons (13-27%). There is also a laminar gradient, with more cells expressing 5-HT2C-R in deep (V-VI) than in intermediate (II-III) layers. In common with 5-HT3-R, layer I GABAergic cells express 5-HT2C-R. The proportion of 5-HT2C-R-expressing striatal neurons was 23% (dorsolateral caudate-putamen), 37% (ventromedial caudate-putamen), 53% (nucleus accumbens-core) and 49% (nucleus accumbens-shell). These results help to better understand the serotonergic modulation of PFC-based networks, including basal ganglia circuits, and atypical antipsychotic drug action.
Published: 2016

20. Involvement of 5-HT3 receptors in the action of vortioxetine in rat brain: focus on glutamatergic and GABAergic neurotransmission

Author: Lundbeck Foundation, Ministerio de Economía y Competitividad (España), European Commission, Centro de Investigación Biomédica en Red Salud Mental (España), Generalitat de Catalunya, Riga, Maurizio, Sánchez, Connie, Celada, Pau, Artigas, Francesc, Lundbeck Foundation, Ministerio de Economía y Competitividad (España), European Commission, Centro de Investigación Biomédica en Red Salud Mental (España), Generalitat de Catalunya, Riga, Maurizio, Sánchez, Connie, Celada, Pau, and Artigas, Francesc
Abstract: The antidepressant vortioxetine is a 5-HT3-R, 5-HT7-R and 5-HT1D-R antagonist, 5-HT1B-R partial agonist, 5-HT1A-R agonist, and serotonin (5-HT) transporter (SERT) inhibitor. Vortioxetine occupies all targets at high therapeutic doses and only SERT and 5-HT3-R at low doses. Vortioxetine increases extracellular monoamine concentrations in rat forebrain more than selective serotonin reuptake inhibitors (SSRI) and shows pro-cognitive activity in preclinical models. Given its high affinity for 5-HT3-R (Ki = 3.7 nM), selectively expressed in GABA interneurons, we hypothesized that vortioxetine may disinhibit glutamatergic and monoaminergic neurotransmission following 5-HT3-R blockade. Here we assessed vortioxetine effect on pyramidal neuron activity and extracellular 5-HT concentration using in vivo extracellular recordings of rat medial prefrontal cortex (mPFC) pyramidal neurons and microdialysis in mPFC and ventral hippocampus (vHPC). Vortioxetine, but not escitalopram, increased pyramidal neuron discharge in mPFC. This effect was prevented by SR57227A (5-HT3-R agonist) and was mimicked by ondansetron (5-HT3-R antagonist) and by escitalopram/ondansetron combinations. In microdialysis experiments, ondansetron augmented the 5-HT-enhancing effect of escitalopram in mPFC and vHPC. Local ondansetron in vHPC augmented escitalopram effect, indicating the participation of intrinsic mechanisms. Since 5-HT neurons express GABAB receptors, we examined their putative involvement in controlling 5-HT release after 5-HT3-R blockade. Co-perfusion of baclofen (but not muscimol) reversed the increased 5-HT levels produced by vortioxetine and escitalopram/ondansetron combinations in vHPC. The present results suggest that vortioxetine increases glutamatergic and serotonergic neurotransmission in rat forebrain by blocking 5-HT3 receptors in GABA interneurons.
Published: 2016

21. Subchronic vortioxetine treatment –but not escitalopram- enhances pyramidal neuron activity in the rat prefrontal cortex

Author: Ministerio de Economía y Competitividad (España), European Commission, Instituto de Salud Carlos III, Centro de Investigación Biomédica en Red Salud Mental (España), Generalitat de Catalunya, Riga, Maurizio, Teruel-Martí, Vicent, Sánchez, Connie, Celada, Pau, Artigas, Francesc, Ministerio de Economía y Competitividad (España), European Commission, Instituto de Salud Carlos III, Centro de Investigación Biomédica en Red Salud Mental (España), Generalitat de Catalunya, Riga, Maurizio, Teruel-Martí, Vicent, Sánchez, Connie, Celada, Pau, and Artigas, Francesc
Abstract: Vortioxetine (VOR) is a multimodal antidepressant drug. VOR is a 5-HT3-R, 5-HT7-R and 5-HT1D-R antagonist, 5-HT1B-R partial agonist, 5-HT1A-R agonist, and serotonin transporter (SERT) inhibitor. VOR shows pro-cognitive activity in animal models and beneficial effects on cognitive dysfunction in major depressive patients. Here we compared the effects of 14-day treatments with VOR and escitalopram (ESC, selective serotonin reuptake inhibitor) on neuronal activity in the medial prefrontal cortex (mPFC). Ten groups of rats (5 standard, 5 depleted of 5-HT with p-chlorophenylalanine-pCPA-, used as model of cognitive impairment) were fed with control food or with two doses of VOR-containing food. Four groups were implanted with minipumps delivering vehicle or ESC 10 mg/kg·day s.c. The two VOR doses enable occupation by VOR of SERT+5-HT3-R and all targets, respectively, and correspond to SERT occupancies in patients treated with 5 and 20 VOR mg/day, respectively. Putative pyramidal neurons (n=985) were recorded extracellularly in the mPFC of anesthetized rats. Sub-chronic VOR administration (but not ESC) significantly increased neuronal discharge in standard and 5-HT-depleted conditions, with a greater effect of the low VOR dose in standard rats. VOR increased neuronal discharge in infralimbic (IL) and prelimbic (PrL) cortices. Hence, oral VOR doses evoking SERT occupancies similar to those in treated patients increase mPFC neuronal discharge. The effect in 5-HT-depleted rats cannot be explained by an antagonist action of VOR at 5-HT3-R and suggests a non-canonical interaction of VOR with 5-HT3-R. These effects may underlie the superior pro-cognitive efficacy of VOR compared with SSRIs in animal models
Published: 2016

22. Effects of chronic stress on prefrontal cortex structure and function

Author: Armario García, Antonio, Molina Molina, Patricia, Universitat Autònoma de Barcelona. Facultat de Biociències, Armario García, Antonio, Molina Molina, Patricia, and Universitat Autònoma de Barcelona. Facultat de Biociències
Published: 2015

23. Preliminary findings suggest the number and volume of supragranular and infragranular pyramidal neurons are similar in the anterior superior temporal area of control subjects and subjects with autism.

Author: Kim, Esther, Kim, Esther, Camacho, Jasmin, Combs, Zachary, Ariza, Jeanelle, Lechpammer, Mirna, Noctor, Stephen C, Martínez-Cerdeño, Verónica, Kim, Esther, Kim, Esther, Camacho, Jasmin, Combs, Zachary, Ariza, Jeanelle, Lechpammer, Mirna, Noctor, Stephen C, and Martínez-Cerdeño, Verónica
Abstract: We investigated the cytoarchitecture of the anterior superior temporal area (TA2) of the postmortem cerebral cortex in 9 subjects with autism and 9 age-matched typically developing subjects between the ages of 13 and 56 years. The superior temporal gyrus is involved in auditory processing and social cognition and its pathology has been correlated with autism. We quantified the number and soma volume of pyramidal neurons in the supragranular layers and pyramidal neurons in the infragranular layers in each subject. We did not find significant differences in the number or volume of supragranular or infragranular neurons in the cerebral cortex of subjects with autism compared to typically developing subjects. This report does not support an alteration of supragranular to infragranular neurons in autism. However, further stereological analysis of the number of cells and cell volumes in specific cortical areas is needed to better establish the cellular phenotype of the autistic cerebral cortex and to understand its clinical relevance in autism.
Published: 2015

24. Cochlear injury and adaptive plasticity of the auditory cortex

Author: Fetoni, Anna Rita, Troiani, Diana, Petrosini, L, Paludetti, Gaetano, Fetoni, Anna Rita (ORCID:0000-0001-5405-4301), Troiani, Diana (ORCID:0000-0002-5665-7410), Paludetti, Gaetano (ORCID:0000-0003-2480-1243), Fetoni, Anna Rita, Troiani, Diana, Petrosini, L, Paludetti, Gaetano, Fetoni, Anna Rita (ORCID:0000-0001-5405-4301), Troiani, Diana (ORCID:0000-0002-5665-7410), and Paludetti, Gaetano (ORCID:0000-0003-2480-1243)
Abstract: Growing evidence suggests that cochlear stressors as noise exposure and aging can induce homeostatic/maladaptive changes in the central auditory system from the brainstem to the cortex. Studies centered on such changes have revealed several mechanisms that operate in the context of sensory disruption after insult (noise trauma, drug-, or age-related injury). The oxidative stress is central to current theories of induced sensory-neural hearing loss and aging, and interventions to attenuate the hearing loss are based on antioxidant agent. The present review addresses the recent literature on the alterations in hair cells and spiral ganglion neurons due to noise-induced oxidative stress in the cochlea, as well on the impact of cochlear damage on the auditory cortex neurons. The emerging image emphasizes that noise-induced deafferentation and upward spread of cochlear damage is associated with the altered dendritic architecture of auditory pyramidal neurons. The cortical modifications may be reversed by treatment with antioxidants counteracting the cochlear redox imbalance. These findings open new therapeutic approaches to treat the functional consequences of the cortical reorganization following cochlear damage.
Published: 2015

25. Reduced density of dendritic spines in pyramidal neurons of rats exposed to alcohol during early postnatal life

Author: De Giorgio, Andrea, Granato, Alberto, De Giorgio, Andrea (ORCID:0000-0003-4679-286X), Granato, Alberto (ORCID:0000-0003-3755-1036), De Giorgio, Andrea, Granato, Alberto, De Giorgio, Andrea (ORCID:0000-0003-4679-286X), and Granato, Alberto (ORCID:0000-0003-3755-1036)
Abstract: Dendritic spines are the main postsynaptic sites of excitatory connections of neocortical pyramidal neurons. Alterations of spine shape, number, and density can be observed in different mental diseases, including those caused by developmental alcohol exposure. Pyramidal neurons of layer 2/3 are the most abundant cells of the neocortex and represent the main source of associative cortico-cortical connections. These neurons are essential for higher functions mediated by the cortex such as feature selection and perceptual grouping. Furthermore, their connections have been shown to be altered in experimental models of fetal alcohol spectrum disorders. Here, we used a Golgi-like tracing method to study the spine density of layer 2/3 associative pyramidal neurons in the somatosensory cortex of adult rats exposed to alcohol during the first postnatal week. The main result of the present study is represented by the decreased spine density in the apical dendrite of alcohol-treated rats, as compared to controls. As to the basal dendritic tree, there were no significant differences between the experimental and the control group. A decreased density of dendritic spines in the apical dendrite may impair the excitatory input onto pyramidal neurons, thus resulting in a widespread alteration of the cortical information flow.
Published: 2015

26. Neuronal circuitry dissected by immunocytochemistry combined with retrograde tracing and electrophysiology

Author: Merighi, Adalberto, Lossi, Laura, Granato, Alberto, De Giorgio, Andrea, Granato, Alberto (ORCID:0000-0003-3755-1036), De Giorgio, Andrea (ORCID:0000-0003-4679-286X), Merighi, Adalberto, Lossi, Laura, Granato, Alberto, De Giorgio, Andrea, Granato, Alberto (ORCID:0000-0003-3755-1036), and De Giorgio, Andrea (ORCID:0000-0003-4679-286X)
Abstract: Several substances, once injected in a given central structure, are taken up by axon terminals and transported retrogradely over long distances, to the cell bodies of neurons projecting to the injection area. They are then visualized by means of histochemical (or immunohistochemical) reactions, making it possible to trace neural pathways . Here we describe a method to label retrogradely neocortical pyramidal neurons in a Golgi-like fashion. This method allows reconstructing the entire dendritic tree of retrogradely labeled cells and can be easily combined with immunohistochemical techniques. Methods suitable to establish relationships between morphological and functional features of projecting neurons are also discussed.
Published: 2015

27. Evolution, development, and plasticity of the human brain: from molecules to bones.

Author: Hrvoj-Mihic, Branka, Hrvoj-Mihic, Branka, Bienvenu, Thibault, Stefanacci, Lisa, Muotri, Alysson R, Semendeferi, Katerina, Hrvoj-Mihic, Branka, Hrvoj-Mihic, Branka, Bienvenu, Thibault, Stefanacci, Lisa, Muotri, Alysson R, and Semendeferi, Katerina
Abstract: Neuroanatomical, molecular, and paleontological evidence is examined in light of human brain evolution. The brain of extant humans differs from the brains of other primates in its overall size and organization, and differences in size and organization of specific cortical areas and subcortical structures implicated into complex cognition and social and emotional processing. The human brain is also characterized by functional lateralizations, reflecting specializations of the cerebral hemispheres in humans for different types of processing, facilitating fast and reliable communication between neural cells in an enlarged brain. The features observed in the adult brain reflect human-specific patterns of brain development. Compared to the brains of other primates, the human brain takes longer to mature, promoting an extended period for establishing cortical microcircuitry and its modifications. Together, these features may underlie the prolonged period of learning and acquisition of technical and social skills necessary for survival, creating a unique cognitive and behavioral niche typical of our species. The neuroanatomical findings are in concordance with molecular analyses, which suggest a trend toward heterochrony in the expression of genes implicated in different functions. These include synaptogenesis, neuronal maturation, and plasticity in humans, mutations in genes implicated in neurite outgrowth and plasticity, and an increased role of regulatory mechanisms, potentially promoting fast modification of neuronal morphologies in response to new computational demands. At the same time, endocranial casts of fossil hominins provide an insight into the timing of the emergence of uniquely human features in the course of evolution. We conclude by proposing several ways of combining comparative neuroanatomy, molecular biology and insights gained from fossil endocasts in future research.
Published: 2013

28. Evolution, development, and plasticity of the human brain: from molecules to bones.

Author: Hrvoj-Mihic, Branka, Hrvoj-Mihic, Branka, Bienvenu, Thibault, Stefanacci, Lisa, Muotri, Alysson R, Semendeferi, Katerina, Hrvoj-Mihic, Branka, Hrvoj-Mihic, Branka, Bienvenu, Thibault, Stefanacci, Lisa, Muotri, Alysson R, and Semendeferi, Katerina
Abstract: Neuroanatomical, molecular, and paleontological evidence is examined in light of human brain evolution. The brain of extant humans differs from the brains of other primates in its overall size and organization, and differences in size and organization of specific cortical areas and subcortical structures implicated into complex cognition and social and emotional processing. The human brain is also characterized by functional lateralizations, reflecting specializations of the cerebral hemispheres in humans for different types of processing, facilitating fast and reliable communication between neural cells in an enlarged brain. The features observed in the adult brain reflect human-specific patterns of brain development. Compared to the brains of other primates, the human brain takes longer to mature, promoting an extended period for establishing cortical microcircuitry and its modifications. Together, these features may underlie the prolonged period of learning and acquisition of technical and social skills necessary for survival, creating a unique cognitive and behavioral niche typical of our species. The neuroanatomical findings are in concordance with molecular analyses, which suggest a trend toward heterochrony in the expression of genes implicated in different functions. These include synaptogenesis, neuronal maturation, and plasticity in humans, mutations in genes implicated in neurite outgrowth and plasticity, and an increased role of regulatory mechanisms, potentially promoting fast modification of neuronal morphologies in response to new computational demands. At the same time, endocranial casts of fossil hominins provide an insight into the timing of the emergence of uniquely human features in the course of evolution. We conclude by proposing several ways of combining comparative neuroanatomy, molecular biology and insights gained from fossil endocasts in future research.
Published: 2013

29. 5-HT3 receptors are involved in the mechanism of action of the new antidepressant drug vortioxetine

Author: Artigas, Francesc, Riga, Maurizio, Celada, Pau, Sánchez, Connie, Artigas, Francesc, Riga, Maurizio, Celada, Pau, and Sánchez, Connie
Published: 2013

30. Expression of 5-HT2A receptors in prefrontal cortex pyramidal neurons projecting to nucleus accumbens. Potential relevance for atypical antipsychotic action

Author: Ministerio de Economía y Competitividad (España), Instituto de Salud Carlos III, Centro de Investigación Biomédica en Red Salud Mental (España), Mocci, Giuseppe, Jiménez-Sánchez, Laura, Adell, Albert, Cortés, Roser, Artigas, Francesc, Ministerio de Economía y Competitividad (España), Instituto de Salud Carlos III, Centro de Investigación Biomédica en Red Salud Mental (España), Mocci, Giuseppe, Jiménez-Sánchez, Laura, Adell, Albert, Cortés, Roser, and Artigas, Francesc
Abstract: The prefrontal cortex (PFC) is involved in higher brain functions altered in schizophrenia. Classical antipsychotic drugs modulate information processing in cortico-limbic circuits via dopamine D2 receptor blockade in nucleus accumbens (NAc) whereas atypical antipsychotic drugs preferentially target cortical serotonin (5-HT) receptors. The brain networks involved in the therapeutic action of atypical drugs are not fully understood. Previous work indicated that medial PFC (mPFC) pyramidal neurons projecting to ventral tegmental area express 5-HT2A receptors suggesting that atypical antipsychotic drugs modulate dopaminergic activity distally, via 5-HT2A receptor (5-HT2A-R) blockade in PFC. Since the mPFC also projects heavily to NAc, we examined whether NAc-projecting pyramidal neurons also express 5-HT2A-R. Using a combination of retrograde tracing experiments and in situ hybridization we report that a substantial proportion of mPFC-NAc pyramidal neurons in rat brain express 5-HT2A-R mRNA in a layer- and area-specific manner (up to 68% in layer V of contralateral cingulate). The functional relevance of 5-HT2A-R to modulate mPFC-NAc projections was examined in dual-probe microdialysis experiments. The application of the preferential 5-HT2A-R agonist DOI into mPFC enhanced glutamate release locally (+66 ± 18%) and in NAc (+74 ± 12%) indicating that cortical 5-HT2A-R activation augments glutamatergic transmission in NAc. Since NAc integrates glutamatergic and dopaminergic inputs, blockade of 5-HT2A-R by atypical drugs may reduce cortical excitatory inputs onto GABAergic neurons of NAc, adding to dopamine D2 receptor blockade. Together with previous observations, the present results suggest that atypical antipsychotic drugs may control the activity of the mesolimbic pathway at cell body and terminal level.
Published: 2013

31. Laminar circuit organization and response modulation in mouse visual cortex

Author: Olivas, Nicholas D, Olivas, Nicholas D, Quintanar-Zilinskas, Victor, Nenadic, Zoran, Xu, Xiangmin, Olivas, Nicholas D, Olivas, Nicholas D, Quintanar-Zilinskas, Victor, Nenadic, Zoran, and Xu, Xiangmin
Published: 2012

32. Laminar circuit organization and response modulation in mouse visual cortex

Author: Olivas, Nicholas D, Olivas, Nicholas D, Quintanar-Zilinskas, Victor, Nenadic, Zoran, Xu, Xiangmin, Olivas, Nicholas D, Olivas, Nicholas D, Quintanar-Zilinskas, Victor, Nenadic, Zoran, and Xu, Xiangmin
Published: 2012

33. Laminar circuit organization and response modulation in mouse visual cortex

Author: Olivas, Nicholas D, Olivas, Nicholas D, Quintanar-Zilinskas, Victor, Nenadic, Zoran, Xu, Xiangmin, Olivas, Nicholas D, Olivas, Nicholas D, Quintanar-Zilinskas, Victor, Nenadic, Zoran, and Xu, Xiangmin
Published: 2012

34. Theory of Electric Resonance in the Neocortical Apical Dendrite

Author: Kasevich, Ray S., Kasevich, Ray S., LaBerge, David, Kasevich, Ray S., Kasevich, Ray S., and LaBerge, David
Abstract: Pyramidal neurons of the neocortex display a wide range of synchronous EEG rhythms, which arise from electric activity along the apical dendrites of neocortical pyramidal neurons. Here we present a theoretical description of oscillation frequency profiles along apical dendrites which exhibit resonance frequencies in the range of 10 to 100 Hz. The apical dendrite is modeled as a leaky coaxial cable coated with a dielectric, in which a series of compartments act as coupled electric circuits that gradually narrow the resonance profile. The tuning of the peak frequency is assumed to be controlled by the average amplitude of voltage-gated outward currents, which in turn are regulated by the subthreshold noise in the thousands of synaptic spines that are continuously bombarded by local circuits. The results of simulations confirmed the ability of the model both to tune the peak frequency in the 10–100 Hz range and to gradually narrow the resonance profile. Considerable additional narrowing of the resonance profile is provided by repeated looping through the apical dendrite via the corticothalamocortical circuit, which reduced the width of each resonance curve (at half-maximum) to approximately 1 Hz. Synaptic noise in the neural circuit is discussed in relation to the ways it can influence the narrowing process.
Published: 2011

35. Theory of Electric Resonance in the Neocortical Apical Dendrite

Author: Kasevich, Ray S., Kasevich, Ray S., LaBerge, David, Kasevich, Ray S., Kasevich, Ray S., and LaBerge, David
Abstract: Pyramidal neurons of the neocortex display a wide range of synchronous EEG rhythms, which arise from electric activity along the apical dendrites of neocortical pyramidal neurons. Here we present a theoretical description of oscillation frequency profiles along apical dendrites which exhibit resonance frequencies in the range of 10 to 100 Hz. The apical dendrite is modeled as a leaky coaxial cable coated with a dielectric, in which a series of compartments act as coupled electric circuits that gradually narrow the resonance profile. The tuning of the peak frequency is assumed to be controlled by the average amplitude of voltage-gated outward currents, which in turn are regulated by the subthreshold noise in the thousands of synaptic spines that are continuously bombarded by local circuits. The results of simulations confirmed the ability of the model both to tune the peak frequency in the 10–100 Hz range and to gradually narrow the resonance profile. Considerable additional narrowing of the resonance profile is provided by repeated looping through the apical dendrite via the corticothalamocortical circuit, which reduced the width of each resonance curve (at half-maximum) to approximately 1 Hz. Synaptic noise in the neural circuit is discussed in relation to the ways it can influence the narrowing process.
Published: 2011

36. Peripheral facial nerve lesion induced long-term dendritic retraction in pyramidal cortico-facial neurons

Author: Urrego, Diana, Múnera, Alejandro, Troncoso, Julieta, Urrego, Diana, Múnera, Alejandro, and Troncoso, Julieta
Abstract: Introduction. Little evidence is available concerning the morphological modifications of motor cortex neurons associated with peripheral nerve injuries, and the consequences of those injuries on postlesion functional recovery.Objective. Dendritic branching of cortico-facial neurons was characterized with respect to the effects of irreversible facial nerve injury.Materials and methods. Twenty-four adult male rats were distributed into four groups: sham (no lesion surgery), and dendritic assessment at 1, 3 and 5 weeks post surgery. Eighteen lesion animals underwent surgical transection of the mandibular and buccal branches of the facial nerve. Dendritic branching was examined by contralateral primary motor cortex slices stained with the Golgi-Cox technique. Layer V pyramidal (cortico-facial) neurons from sham and injured animals were reconstructed and their dendritic branching was compared using Sholl analysis.Results. Animals with facial nerve lesions displayed persistent vibrissal paralysis throughout the fiveweek observation period. Compared with control animal neurons, cortico-facial pyramidal neuronsof surgically injured animals displayed shrinkage of their dendritic branches at statistically significant levels. This shrinkage persisted for at least five weeks after facial nerve injury.Discussion. Irreversible facial motoneuron axonal damage induced persistent dendritic arborization shrinkage in contralateral cortico-facial neurons. This morphological reorganization may be thephysiological basis of functional sequelae observed in peripheral facial palsy patients., Introducción. Poco se sabe sobre las modificaciones morfológicas de las neuronas de la corteza motora tras lesiones en nervios periféricos, y de la implicancia de dichos cambios en la recuperaciónfuncional tras la lesión.Objetivo. Caracterizar en ratas el efecto de la lesión del nervio facial sobre la morfología de las neuronas piramidales de la capa V de la corteza motora primaria contralateral.Materiales y métodos. Se reconstruyeron neuronas piramidales teñidas con la técnica de Golgi-Cox, de animales control (sin lesión) y animales con lesiones y sacrificados a distintos tiempos luego de la lesión. Se utilizaron cuatro grupos: sham (control), lesión 1S, lesión 3S y lesión 5S (animales con lesiones y evaluados 1, 3 y 5 semanas después de la lesión irreversible del nervio facial, respectivamente). Se evaluaron mediante el análisis de Sholl, las ramificaciones dendríticas de las células piramidales de la corteza motora contralateral a la lesión.Resultados. Los animales con lesiones presentaron parálisis completa de las vibrisas mayores durante las cinco semanas de observación. Comparadas con neuronas de animales sin lesiones, las células piramidales córtico-faciales de los lesionados mostraron una disminución significativa de sus ramificaciones dendríticas. Esta disminución se mantuvo hasta cinco semanas después de la lesión.Conclusiones. Las lesiones irreversibles de los axones de las motoneuronas del núcleo facial, provocan una retracción sostenida del árbol dendrítico en las neuronas piramidales córtico-faciales.Esta reorganización morfológica cortical persistente podría ser el sustrato fisiopatológico de algunas de las secuelas funcionales que se observan en los pacientes con parálisis facial periférica.
Published: 2011

37. Activation of thalamocortical networks by the N-methyl-D-aspartate receptor antagonist phencyclidine: reversal by clozapine

Author: Santana, Noemí, Troyano-Rodriguez, Eva, Mengod Los Arcos, Guadalupe, Celada, Pau, Artigas, Francesc, Santana, Noemí, Troyano-Rodriguez, Eva, Mengod Los Arcos, Guadalupe, Celada, Pau, and Artigas, Francesc
Abstract: [Background]: Noncompetitive N-methyl-D-aspartate receptor antagonists are widely used as pharmacological models of schizophrenia. Their neurobiological actions are still poorly understood, although the prefrontal cortex (PFC) appears as a key target area., [Methods]: We examined the effect of phencyclidine (PCP) on neuronal activity of the mediodorsal (MD) and centromedial (CM) thalamic nuclei, reciprocally connected with the PFC, using extracellular recordings (n = 50 neurons from 35 Wistar rats) and c-fos expression., [Results]: Phencyclidine (.25 mg/kg intravenous [IV]) markedly disorganized the activity of MD/CM neurons, increasing (424%) and decreasing (41%) the activity of 57% and 20% of the recorded neurons, respectively (23% remained unaffected). Phencyclidine reduced delta oscillations (.15–4 Hz) as assessed by recording local field potentials. The subsequent clozapine administration (1 mg/kg IV) reversed PCP effects on neuronal discharge and delta oscillations. Double in situ hybridization experiments revealed that PCP (10 mg/kg intraperitoneal [IP]) markedly increased c-fos expression in glutamatergic neurons of several cortical areas (prefrontal, somatosensory, retrosplenial, entorhinal) and in thalamic nuclei, including MD/CM. Phencyclidine also increased c-fos expression in the amygdala; yet, it had a small effect in the hippocampus. Phencyclidine did not increase c-fos expression in gamma-aminobutyric acidergic cells except in hippocampus, amygdala, somatosensory, and retrosplenial cortices. Clozapine (5 mg/kg IP) had no effect by itself but significantly prevented PCP-induced c-fos expression., [Conclusions]: Phencyclidine likely exerts its psychotomimetic action by increasing excitatory neurotransmission in thalamo-cortico-thalamic networks involving, among others, PFC, retrosplenial, and somatosensory cortices. The antipsychotic action of clozapine includes, among other actions, an attenuation of the neuronal hyperactivity in thalamocortical networks.
Published: 2011

38. Reconciling coherent oscillation with modulation of irregular spiking activity in selective attention: gamma-range synchronization between sensory and executive cortical areas

Author: Universitat Politècnica de València. Instituto de Investigación para la Gestión Integral de Zonas Costeras - Institut d'Investigació per a la Gestió Integral de Zones Costaneres, Kavli Foundation, Volkswagen Foundation, Generalitat de Catalunya, European Regional Development Fund, Ministerio de Ciencia e Innovación, National Institutes of Health, EEUU, Ardid-Ramírez, Joan Salvador, Wang, Xiao-Jing, Gomez-Cabrero, D., Compte, A., Universitat Politècnica de València. Instituto de Investigación para la Gestión Integral de Zonas Costeras - Institut d'Investigació per a la Gestió Integral de Zones Costaneres, Kavli Foundation, Volkswagen Foundation, Generalitat de Catalunya, European Regional Development Fund, Ministerio de Ciencia e Innovación, National Institutes of Health, EEUU, Ardid-Ramírez, Joan Salvador, Wang, Xiao-Jing, Gomez-Cabrero, D., and Compte, A.
Abstract: [EN] In this computational work, we investigated gamma-band synchronization across cortical circuits associated with selective attention. The model explicitly instantiates a reciprocally connected loop of spiking neurons between a sensory-type (area MT) and an executive-type (prefrontal/parietal) cortical circuit (the source area for top-down attentional signaling). Moreover, unlike models in which neurons behave as clock-like oscillators, in our model single-cell firing is highly irregular (close to Poisson), while local field potential exhibits a population rhythm. In this "sparsely synchronized oscillation" regime, the model reproduces and clarifies multiple observations from behaving animals. Top-down attentional inputs have a profound effect on network oscillatory dynamics while only modestly affecting single-neuron spiking statistics. In addition, attentional synchrony modulations are highly selective: interareal neuronal coherence occurs only when there is a close match between the preferred feature of neurons, the attended feature, and the presented stimulus, a prediction that is experimentally testable. When interareal coherence was abolished, attention-induced gain modulations of sensory neurons were slightly reduced. Therefore, our model reconciles the rate and synchronization effects, and suggests that interareal coherence contributes to large-scale neuronal computation in the brain through modest enhancement of rate modulations as well as a pronounced attention-specific enhancement of neural synchrony.
Published: 2010

39. Dynamics of Synaptic Transmission between Fast-Spiking Interneurons and Striatal Projection Neurons of the Direct and Indirect Pathways

Author: Planert, Henrike, Szydlowski, Susanne N., Hjorth, Johannes, Grillner, Sten, Silberberg, Gilad, Planert, Henrike, Szydlowski, Susanne N., Hjorth, Johannes, Grillner, Sten, and Silberberg, Gilad
Abstract: The intrastriatal microcircuit is a predominantly inhibitory GABAergic network comprised of a majority of projection neurons [medium spiny neurons (MSNs)] and a minority of interneurons. The connectivity within this microcircuit is divided into two main categories: lateral connectivity between MSNs, and inhibition mediated by interneurons, in particular fast spiking (FS) cells. To understand the operation of striatum, it is essential to have a good description of the dynamic properties of these respective pathways and how they affect different types of striatal projection neurons. We recorded from neuronal pairs, triplets, and quadruplets in slices of rat and mouse striatum and analyzed the dynamics of synaptic transmission between MSNs and FS cells. Retrograde fluorescent labeling and transgenic EGFP (enhanced green fluorescent protein) mice were used to distinguish between MSNs of the direct (striatonigral) and indirect (striatopallidal) pathways. Presynaptic neurons were stimulated with trains of action potentials, and activity-dependent depression and facilitation of synaptic efficacy was recorded from postsynaptic neurons. We found that FS cells provide a strong and homogeneously depressing inhibition of both striatonigral and striatopallidal MSN types. Moreover, individual FS cells are connected to MSNs of both types. In contrast, both MSN types receive sparse and variable, depressing and facilitating synaptic transmission from nearby MSNs. The connection probability was higher for pairs with presynaptic striatopallidal MSNs; however, the variability in synaptic dynamics did not depend on the types of interconnected MSNs. The differences between the two inhibitory pathways were clear in both species and at different developmental stages. Our findings show that the two intrastriatal inhibitory pathways have fundamentally different dynamic properties that are, however, similarly applied to both direct and indirect striatal projections., QC 20110121
Published: 2010
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40. Novel Use of Matched Filtering for Synaptic Event Detection and Extraction

Author: Shi, Yulin, Shi, Yulin, Nenadic, Zoran, Xu, Xiangmin, Shi, Yulin, Shi, Yulin, Nenadic, Zoran, and Xu, Xiangmin
Abstract: Efficient and dependable methods for detection and measurement of synaptic events are important for studies of synaptic physiology and neuronal circuit connectivity. As the published methods with detection algorithms based upon amplitude thresholding and fixed or scaled template comparisons are of limited utility for detection of signals with variable amplitudes and superimposed events that have complex waveforms, previous techniques are not applicable for detection of evoked synaptic events in photostimulation and other similar experimental situations. Here we report on a novel technique that combines the design of a bank of approximate matched filters with the detection and estimation theory to automatically detect and extract photostimluation-evoked excitatory postsynaptic currents (EPSCs) from individually recorded neurons in cortical circuit mapping experiments. The sensitivity and specificity of the method were evaluated on both simulated and experimental data, with its performance comparable to that of visual event detection performed by human operators. This new technique was applied to quantify and compare the EPSCs obtained from excitatory pyramidal cells and fast-spiking interneurons. In addition, our technique has been further applied to the detection and analysis of inhibitory postsynaptic current (IPSC) responses. Given the general purpose of our matched filtering and signal recognition algorithms, we expect that our technique can be appropriately modified and applied to detect and extract other types of electrophysiological and optical imaging signals.
Published: 2010

41. Reconciling coherent oscillation with modulation of irregular spiking activity in selective attention: gamma-range synchronization between sensory and executive cortical areas

Author: Universitat Politècnica de València. Instituto de Investigación para la Gestión Integral de Zonas Costeras - Institut d'Investigació per a la Gestió Integral de Zones Costaneres, Kavli Foundation, Volkswagen Foundation, Generalitat de Catalunya, European Regional Development Fund, Ministerio de Ciencia e Innovación, National Institutes of Health, EEUU, Ardid-Ramírez, Joan Salvador, Wang, Xiao-Jing, Gomez-Cabrero, D., Compte, A., Universitat Politècnica de València. Instituto de Investigación para la Gestión Integral de Zonas Costeras - Institut d'Investigació per a la Gestió Integral de Zones Costaneres, Kavli Foundation, Volkswagen Foundation, Generalitat de Catalunya, European Regional Development Fund, Ministerio de Ciencia e Innovación, National Institutes of Health, EEUU, Ardid-Ramírez, Joan Salvador, Wang, Xiao-Jing, Gomez-Cabrero, D., and Compte, A.
Abstract: [EN] In this computational work, we investigated gamma-band synchronization across cortical circuits associated with selective attention. The model explicitly instantiates a reciprocally connected loop of spiking neurons between a sensory-type (area MT) and an executive-type (prefrontal/parietal) cortical circuit (the source area for top-down attentional signaling). Moreover, unlike models in which neurons behave as clock-like oscillators, in our model single-cell firing is highly irregular (close to Poisson), while local field potential exhibits a population rhythm. In this "sparsely synchronized oscillation" regime, the model reproduces and clarifies multiple observations from behaving animals. Top-down attentional inputs have a profound effect on network oscillatory dynamics while only modestly affecting single-neuron spiking statistics. In addition, attentional synchrony modulations are highly selective: interareal neuronal coherence occurs only when there is a close match between the preferred feature of neurons, the attended feature, and the presented stimulus, a prediction that is experimentally testable. When interareal coherence was abolished, attention-induced gain modulations of sensory neurons were slightly reduced. Therefore, our model reconciles the rate and synchronization effects, and suggests that interareal coherence contributes to large-scale neuronal computation in the brain through modest enhancement of rate modulations as well as a pronounced attention-specific enhancement of neural synchrony.
Published: 2010

42. Novel Use of Matched Filtering for Synaptic Event Detection and Extraction

Author: Shi, Yulin, Shi, Yulin, Nenadic, Zoran, Xu, Xiangmin, Shi, Yulin, Shi, Yulin, Nenadic, Zoran, and Xu, Xiangmin
Abstract: Efficient and dependable methods for detection and measurement of synaptic events are important for studies of synaptic physiology and neuronal circuit connectivity. As the published methods with detection algorithms based upon amplitude thresholding and fixed or scaled template comparisons are of limited utility for detection of signals with variable amplitudes and superimposed events that have complex waveforms, previous techniques are not applicable for detection of evoked synaptic events in photostimulation and other similar experimental situations. Here we report on a novel technique that combines the design of a bank of approximate matched filters with the detection and estimation theory to automatically detect and extract photostimluation-evoked excitatory postsynaptic currents (EPSCs) from individually recorded neurons in cortical circuit mapping experiments. The sensitivity and specificity of the method were evaluated on both simulated and experimental data, with its performance comparable to that of visual event detection performed by human operators. This new technique was applied to quantify and compare the EPSCs obtained from excitatory pyramidal cells and fast-spiking interneurons. In addition, our technique has been further applied to the detection and analysis of inhibitory postsynaptic current (IPSC) responses. Given the general purpose of our matched filtering and signal recognition algorithms, we expect that our technique can be appropriately modified and applied to detect and extract other types of electrophysiological and optical imaging signals.
Published: 2010

43. The neuroanatomical effect of brain injury during early development in a rat model

Author: Marotta, Jonathan (Psychology) Larson, Susan (Psychology) Del Bigio, Marc (Pathology) Saucier, Deborah (University of Lethbridge), Ivanco, Tammy (Psychology), Hartle, Kelly D., Marotta, Jonathan (Psychology) Larson, Susan (Psychology) Del Bigio, Marc (Pathology) Saucier, Deborah (University of Lethbridge), Ivanco, Tammy (Psychology), and Hartle, Kelly D.
Abstract: The brain responds to injury during early development with alterations in behaviour and dendritic morphology of motor cortex neurons. Rats were exposed to damage either prenatally or after the first postnatal week, using different models of damage and motor cortex was examined. Prenatal injury resulted in a decrease in length, complexity and volume in layer II neurons, but no differences in layer V neurons or behavioural tasks. Postnatal damage produced increases in length of basilar dendrites, but no differences in spine density at 2 months of age, whereas at 6 months of age, an overall decrease in apical and basilar spine density was observed. Findings demonstrate the maturational status of the brain at the time of injury play a crucial role in response to injury.
Published: 2010

44. Alterations of the cortico-cortical network in sensori-motor areas of dystrophin deficient mice.

Author: Minciacchi, Diego, Del Tongo, Claudia, Carretta, Donatella, Nosi, Daniele, Granato, Alberto, Granato, Alberto (ORCID:0000-0003-3755-1036), Minciacchi, Diego, Del Tongo, Claudia, Carretta, Donatella, Nosi, Daniele, Granato, Alberto, and Granato, Alberto (ORCID:0000-0003-3755-1036)
Abstract: The dystrophin defective mdx mouse, acknowledged model of Duchenne Muscular Dystrophy (DMD), bears outstanding alterations of the cortical architecture, that could be responsible for the cognitive impairment often accompanying this pathological condition. Using a retrograde tract tracing technique to label neurons in Golgi-like fashion, we investigated the fine anatomical organization of associative cortico-cortical projections in mdx mice. While the absolute number of associative pyramidal neurons was significantly higher in mdx than in control animals, the ratio between the number of supra- and infragranular cortico-cortical cells was substantially unmodified. Basal dendrites of layer 2/3 pyramidal neurons displayed longer terminal branches in mdx compared to controls. Finally, the density of dendritic spines was significantly lower in mdx animals. The anomalies of associative cortico-cortical projections provide potential groundwork on the neurobiological bases of cognitive involvement in DMD and value the role of cortical microcircuitry alterations as possible source of interference with peripheral motor impairment.
Published: 2010

45. Simultaneous projections from prefrontal cortex to dopaminergic and serotonergic nuclei

Author: Vázquez Borsetti, Pablo Ernesto, Celada, Pau, Cortés, Roser, Artigas, Francesc, Vázquez Borsetti, Pablo Ernesto, Celada, Pau, Cortés, Roser, and Artigas, Francesc
Abstract: Derangements of the prefrontal cortex (PFC) and of brainstem monoaminergic systems occur in depression and schizophrenia. Anatomical and functional evidence supports a PFC control of the brainstem monoaminergic systems. Similarly, the PFC contains a high density of monoamine receptors for which antipsychotic drugs exhibit high affinity. This raises the possibility that pathological or drug-induced changes in PFC may subsequently alter monoaminergic activity. Recent data indicate that a substantial proportion of PFC pyramidal neurons projecting to the ventral tegmental area (VTA) or the dorsal raphe nucleus (DR) express the 5-HT2A receptor mRNA, which suggests that atypical antipsychotic drugs affect serotonergic and dopaminergic function by targeting PFC 5-HT2A receptors. Using electrophysiological and tract-tracing techniques we examined whether PFC pyramidal neurons projecting to DR are segregated from those projecting to the VTA. Sequential electrical stimulation of these nuclei in anaesthetized rats evoked antidromic potentials from both areas in the same pyramidal neurons of the medial PFC (60%, n=30). A similar percentage of dual DR+VTA projection neurons (50%) was obtained using the reciprocal collision test (n=85). Similarly, tracer application (Fluoro-Gold in VTA and cholera toxin B in DR, or vice versa) retrogradely labelled pyramidal neurons in PFC projecting to VTA (81±18), to DR (52±9) and to both nuclei (31±4, n=5 rats). Overall, these results indicate that the PFC may simultaneously coordinate the activity of dopaminergic and serotonergic systems within a short temporal domain, supporting a concerted modulation of the ascending serotonergic and dopaminergic activity during antipsychotic drug treatment.
Published: 2010

46. The neuroanatomical effect of brain injury during early development in a rat model

Author: Marotta, Jonathan (Psychology) Larson, Susan (Psychology) Del Bigio, Marc (Pathology) Saucier, Deborah (University of Lethbridge), Ivanco, Tammy (Psychology), Hartle, Kelly D., Marotta, Jonathan (Psychology) Larson, Susan (Psychology) Del Bigio, Marc (Pathology) Saucier, Deborah (University of Lethbridge), Ivanco, Tammy (Psychology), and Hartle, Kelly D.
Abstract: The brain responds to injury during early development with alterations in behaviour and dendritic morphology of motor cortex neurons. Rats were exposed to damage either prenatally or after the first postnatal week, using different models of damage and motor cortex was examined. Prenatal injury resulted in a decrease in length, complexity and volume in layer II neurons, but no differences in layer V neurons or behavioural tasks. Postnatal damage produced increases in length of basilar dendrites, but no differences in spine density at 2 months of age, whereas at 6 months of age, an overall decrease in apical and basilar spine density was observed. Findings demonstrate the maturational status of the brain at the time of injury play a crucial role in response to injury.
Published: 2010

47. Pyramidal neurons in rat prefrontal cortex projecting to ventral tegmental area and dorsal raphe nucleus express 5-HT2A receptors

Author: Vázquez Borsetti, Pablo Ernesto, Cortés, Roser, Artigas, Francesc, Vázquez Borsetti, Pablo Ernesto, Cortés, Roser, and Artigas, Francesc
Abstract: The prefrontal cortex (PFC) is involved in higher brain functions altered in schizophrenia. Classical antipsychotics modulate corticolimbic circuits mainly through subcortical D2 receptor blockade, whereas second generation (atypical) antipsychotics preferentially target cortical 5-HT receptors. Anatomical and functional evidence supports a PFC-based control of the brainstem monoaminergic nuclei. Using a combination of retrograde tracing experiments and in situ hybridization we report that a substantial proportion of PFC pyramidal neurons projecting to the dorsal raphe (DR) and/or ventral tegmental area (VTA) express 5-HT2A receptors. Choleratoxin B application into the DR and the VTA retrogradely labeled projection neurons in the medial PFC (mPFC) and in orbitofrontal cortex (OFC). In situ hybridization of 5-HT2A receptor mRNA in the same tissue sections labeled a large neuronal population in mPFC and OFC. The percentage of DR-projecting neurons expressing 5-HT2A receptor mRNA was ~60% in mPFC and ~75% in OFC (n 5 3). Equivalent values for VTA-projecting neurons were ~55% in both mPFC and ventral OFC. Thus, 5-HT2A receptor activation/blockade in PFC may have downstream effects on dopaminergic and serotonergic systems via direct descending pathways. Atypical antipsychotics may distally modulate monoaminergic cells through PFC 5-HT2A receptor blockade, presumably decreasing the activity of neurons receiving direct cortical inputs.
Published: 2009

48. Pyramidal neurons in rat prefrontal cortex projecting to ventral tegmental area and dorsal raphe nucleus express 5-HT2A receptors

Author: Vázquez Borsetti, Pablo Ernesto, Cortés, Roser, Artigas, Francesc, Vázquez Borsetti, Pablo Ernesto, Cortés, Roser, and Artigas, Francesc
Abstract: The prefrontal cortex (PFC) is involved in higher brain functions altered in schizophrenia. Classical antipsychotics modulate corticolimbic circuits mainly through subcortical D2 receptor blockade, whereas second generation (atypical) antipsychotics preferentially target cortical 5-HT receptors. Anatomical and functional evidence supports a PFC-based control of the brainstem monoaminergic nuclei. Using a combination of retrograde tracing experiments and in situ hybridization we report that a substantial proportion of PFC pyramidal neurons projecting to the dorsal raphe (DR) and/or ventral tegmental area (VTA) express 5-HT2A receptors. Choleratoxin B application into the DR and the VTA retrogradely labeled projection neurons in the medial PFC (mPFC) and in orbitofrontal cortex (OFC). In situ hybridization of 5-HT2A receptor mRNA in the same tissue sections labeled a large neuronal population in mPFC and OFC. The percentage of DR-projecting neurons expressing 5-HT2A receptor mRNA was ~60% in mPFC and ~75% in OFC (n 5 3). Equivalent values for VTA-projecting neurons were ~55% in both mPFC and ventral OFC. Thus, 5-HT2A receptor activation/blockade in PFC may have downstream effects on dopaminergic and serotonergic systems via direct descending pathways. Atypical antipsychotics may distally modulate monoaminergic cells through PFC 5-HT2A receptor blockade, presumably decreasing the activity of neurons receiving direct cortical inputs.
Published: 2009

49. NMDA antagonist and antipsychotic actions in cortico-subcortical circuits

Author: Kargieman, Lucila, Santana, Noemí, Mengod Los Arcos, Guadalupe, Celada, Pau, Artigas, Francesc, Kargieman, Lucila, Santana, Noemí, Mengod Los Arcos, Guadalupe, Celada, Pau, and Artigas, Francesc
Abstract: Cognitive deficits in schizophrenia are associated with prefrontal cortex (PFC) abnormalities. Schizophrenic patients show a reduced performance in tasks engaging the PFC and a reduction of markers of cellular integrity and function. Non-competitive N-methyl-Daspartate (NMDA) receptor antagonists are widely used as pharmacological models of schizophrenia due to their ability to exacerbate schizophrenia symptoms in patients and to elicit psychotomimetic actions in healthy volunteers. Also, these drugs evoke behavioral alterations in experimental animals that resemble schizophrenia symptoms. The PFC seems to be a key target area for these agents. However, the cellular and network elements involved are poorly known. Cognitive deficits are of particular interest since an early antipsychotic-induced improvement in cognitive performance predicts a better long-term clinical outcome. Here we report that the non-competitive NMDA receptor antagonist phencyclidine (PCP) induces a marked disruption of the activity of PFC. PCP administration increased the activity of a substantial proportion of pyramidal neurons, as evidenced by an increase in discharge rate and inc- fos expression. Examination of the effects of PCP on other brain areas revealed an increasedc- fos expression in a number of cortical and subcortical areas, but notably in thalamic nuclei projecting to the PFC. The administration of classical (haloperidol) and/or atypical (clozapine) antipsychotic drugs reversed PCP effects. These results indicate that PCP induces a marked disruption of the network activity in PFC and that antipsychotic drugs may partly exert their therapeutic effect by normalizing hyperactive cortico-thalamocortical circuits.
Published: 2008

50. Serotonin 1A receptors in human and monkey prefrontal cortex are mainly expressed in pyramidal neurons and in a GABAergic interneuron subpopulation: implications for schizophrenia and its treatment

Author: Almeida, Julián de, Mengod Los Arcos, Guadalupe, Almeida, Julián de, and Mengod Los Arcos, Guadalupe
Abstract: Serotonin 1A (5-HT1A) receptors are found in high densities in prefrontal cortex. However, their distribution within cortical cell populations is unknown in both humans and primates. We used double in situ hybridization histochemistry to quantify the percentage of glutamatergic and GABAergic neurons expressing 5-HT1A receptors in human and monkey prefrontal cortex. Moreover, in the case of the monkey, we also quantified the parvalbumin and calbindin GABAergic subpopulations expressing this receptor. 5-HT1A receptor mRNAs were expressed in about 80% of glutamatergic neurons in external layers II and upper III, and in around 50% in layer VI; they were also present in approximately 20% of GABAergic neurons in both species. Although they were found in up to 43% of the calbindin cell subpopulation they were rarely present in parvalbumin cells in monkey prefrontal cortex. The knowledge of the phenotype of the prefrontal cortex (PFC) cells expressing 5-HT1A will help understanding serotonin actions in PFC.
Published: 2008

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