Your search keyword '"Sabine Grosser"' showing total 4 results

1. The RNA-binding protein ARPP21 controls dendritic branching by functionally opposing the miRNA it hosts

Author

Frederick Rehfeld, Daniel Maticzka, Sabine Grosser, Pina Knauff, Murat Eravci, Imre Vida, Rolf Backofen, and F. Gregory Wulczyn

Subjects

Science

Abstract

Many microRNA encoding regions are within introns of other coding genes, and yet the molecular or functional interaction between the two is unclear. This study shows that miR-128′s function is opposed by its host gene ARPP21, and they have complementary effects on neuronal development.

Published

2018

2. miR-128 regulates neuronal migration, outgrowth and intrinsic excitability via the intellectual disability gene Phf6

Author

Eleonora Franzoni, Sam A Booker, Srinivas Parthasarathy, Frederick Rehfeld, Sabine Grosser, Swathi Srivatsa, Heiko R Fuchs, Victor Tarabykin, Imre Vida, and F Gregory Wulczyn

Subjects

Börjeson-Forssman-Lehmann syndrome, cortical development, developmental timing, post-translational gene regulation, Medicine, Science, Biology (General), QH301-705.5

Abstract

miR-128, a brain-enriched microRNA, has been implicated in the control of neurogenesis and synaptogenesis but its potential roles in intervening processes have not been addressed. We show that post-transcriptional mechanisms restrict miR-128 accumulation to post-mitotic neurons during mouse corticogenesis and in adult stem cell niches. Whereas premature miR-128 expression in progenitors for upper layer neurons leads to impaired neuronal migration and inappropriate branching, sponge-mediated inhibition results in overmigration. Within the upper layers, premature miR-128 expression reduces the complexity of dendritic arborization, associated with altered electrophysiological properties. We show that Phf6, a gene mutated in the cognitive disorder Börjeson-Forssman-Lehmann syndrome, is an important regulatory target for miR-128. Restoring PHF6 expression counteracts the deleterious effect of miR-128 on neuronal migration, outgrowth and intrinsic physiological properties. Our results place miR-128 upstream of PHF6 in a pathway vital for cortical lamination as well as for the development of neuronal morphology and intrinsic excitability.

Published

2015

3. Hilar somatostatin interneurons contribute to synchronized GABA activity in an in vitro epilepsy model.

Author

Sabine Grosser, Bridget N Queenan, Rupa R Lalchandani, and Stefano Vicini

Subjects

Medicine, Science

Abstract

Epilepsy is a disorder characterized by excessive synchronized neural activity. The hippocampus and surrounding temporal lobe structures appear particularly sensitive to epileptiform activity. Somatostatin (SST)-positive interneurons within the hilar region have been suggested to gate hippocampal activity, and therefore may play a crucial role in the dysregulation of hippocampal activity. In this study, we examined SST interneuron activity in the in vitro 4-aminopyridine (4-AP) model of epilepsy. We employed a multi-disciplinary approach, combining extracellular multi-electrode array (MEA) recordings with patch-clamp recordings and optical imaging using a genetically encoded calcium sensor. We observed that hilar SST interneurons are strongly synchronized during 4-AP-induced local field potentials (LFPs), as assayed by Ca(2+) imaging as well as juxtacellular or intracellular recording. SST interneurons were particularly responsive to GABA-mediated LFPs that occurred in the absence of ionotropic glutamatergic transmission. Our results present evidence that the extensive synchronized activity of SST-expressing interneurons contribute to the generation of GABAergic LFPs in an in vitro model of temporal lobe seizures.

Published

2014

4. miR-128 regulates neuronal migration, outgrowth and intrinsic excitability via the intellectual disability gene Phf6

Author

F. Gregory Wulczyn, Srinivas Parthasarathy, Eleonora Franzoni, Frederick Rehfeld, Heiko Fuchs, Victor Tarabykin, Imre Vida, Sam A. Booker, Sabine Grosser, and Swathi Srivatsa

Subjects

Aging, Börjeson-Forssman-Lehmann syndrome, Time Factors, Transcription, Genetic, Synaptogenesis, 600 Technik, Medizin, angewandte Wissenschaften::610 Medizin und Gesundheit, Mice, Cell Movement, RNA Precursors, Biology (General), Stem Cell Niche, developmental timing, Growth Disorders, Cerebral Cortex, Neurons, General Neuroscience, Neurogenesis, Gene Expression Regulation, Developmental, General Medicine, Corticogenesis, medicine.anatomical_structure, Cerebral cortex, Medicine, Stem cell, Adult stem cell, Research Article, QH301-705.5, Science, Biology, General Biochemistry, Genetics and Molecular Biology, Fingers, Intellectual Disability, microRNA, medicine, Animals, cortical development, Obesity, Cell Shape, mouse, Homeodomain Proteins, Epilepsy, General Immunology and Microbiology, Hypogonadism, Cell Biology, Dendrites, Repressor Proteins, MicroRNAs, Developmental Biology and Stem Cells, Face, Mental Retardation, X-Linked, Neuroscience, Developmental biology, post-translational gene regulation

Abstract

miR-128, a brain-enriched microRNA, has been implicated in the control of neurogenesis and synaptogenesis but its potential roles in intervening processes have not been addressed. We show that post-transcriptional mechanisms restrict miR-128 accumulation to post-mitotic neurons during mouse corticogenesis and in adult stem cell niches. Whereas premature miR-128 expression in progenitors for upper layer neurons leads to impaired neuronal migration and inappropriate branching, sponge-mediated inhibition results in overmigration. Within the upper layers, premature miR-128 expression reduces the complexity of dendritic arborization, associated with altered electrophysiological properties. We show that Phf6, a gene mutated in the cognitive disorder Börjeson-Forssman-Lehmann syndrome, is an important regulatory target for miR-128. Restoring PHF6 expression counteracts the deleterious effect of miR-128 on neuronal migration, outgrowth and intrinsic physiological properties. Our results place miR-128 upstream of PHF6 in a pathway vital for cortical lamination as well as for the development of neuronal morphology and intrinsic excitability. DOI: http://dx.doi.org/10.7554/eLife.04263.001, eLife digest The unique capabilities of the mammalian brain depend on the patterns formed by spatial arrangements and connections between millions (sometimes billions) of electrically active cells called neurons, and on the connections between these neurons. During the development of the cortex, the largest part of the brain, neurons are born in stem cell areas that lie deep inside the brain, and these newly made neurons then migrate outwards to their final positions close to the surface of the adult brain. Franzoni et al. have examined how two molecules, a small RNA called miR-128 and a protein called PHF6, control when and how neurons migrate through the cortex and then grow to form connections with other neurons as they mature. Mutations that disrupt PHF6 can cause intellectual disabilities, and one possible reason for this is that PHF6 is needed to ensure that the neurons migrate to the correction location. Franzoni et al. now show that miR-128 can reduce the production of PHF6 and is therefore responsible for controlling when and where PHF6 is active. Studying miR-128 in detail, they show that although an inactive precursor form of miR-128 is present in stem cells and migrating neurons, the active form of miR-128 is only found in neurons that have already reached their final position in the cortex. Franzoni et al. used genetic methods to override the switch that controls when miR-128 becomes active. When the amount of miR-128 was artificially reduced, the neurons migrated too far. Artificially increasing the amount of miR-128 had the opposite effect: both the movement of the neurons and, later, their growth were defective. PHF6 was the key to these effects: if PHF6 levels were kept close to normal, miR-128 could no longer interfere with the movement and growth of the neurons. Further work will be required to better understand how miR-128 is turned off and on, and how PHF6 acts to control neuronal movement and growth. DOI: http://dx.doi.org/10.7554/eLife.04263.002

Published

2015