Your search keyword '"flp"' showing total 3 results

1. BEAM: A combinatorial recombinase toolbox for binary gene expression and mosaic genetic analysis.

Author

Greig, Luciano, Woodworth, Mollie, Poulopoulos, Alexandros, Lim, Stephanie, and Macklis, Jeffrey

Subjects

CP: Cell biology, Cre, Flp, genetic analysis, mosaicism, recombinase, Animals, Recombinases, Mosaicism, Luminescent Proteins, Mice, Gene Expression, Red Fluorescent Protein, Green Fluorescent Proteins, Humans

Abstract

We describe a binary expression aleatory mosaic (BEAM) system, which relies on DNA delivery by transfection or viral transduction along with nested recombinase activity to generate two genetically distinct, non-overlapping populations of cells for comparative analysis. Control cells labeled with red fluorescent protein (RFP) can be directly compared with experimental cells manipulated by genetic gain or loss of function and labeled with GFP. Importantly, BEAM incorporates recombinase-dependent signal amplification and delayed reporter expression to enable sharper delineation of control and experimental cells and to improve reliability relative to existing methods. We applied BEAM to a variety of known phenotypes to illustrate its advantages for identifying temporally or spatially aberrant phenotypes, for revealing changes in cell proliferation or death, and for controlling for procedural variability. In addition, we used BEAM to test the cortical protomap hypothesis at the individual radial unit level, revealing that area identity is cell autonomously specified in adjacent radial units.

Published

2024

2. Mapping Brain-Wide Afferent Inputs of Parvalbumin-Expressing GABAergic Neurons in Barrel Cortex Reveals Local and Long-Range Circuit Motifs

Author

Mirko Witte, Jochen F. Staiger, Nidhi Subhashini, Yoon Seok Kim, Lief E. Fenno, Karl Deisseroth, Julien Guy, Edward M. Callaway, Charu Ramakrishnan, Georg Hafner, Karl-Klaus Conzelmann, and Martina Oberhuber

Subjects

0301 basic medicine, Thalamus, Population, Sensory system, Biology, Inhibitory postsynaptic potential, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Neural Pathways, medicine, Humans, GABAergic Neurons, education, lcsh:QH301-705.5, Cerebral Cortex, education.field_of_study, Cre, Flp, GABAergic neuron, barrel cortex, intersectional, parvalbumin, rabies tracing, Barrel cortex, 030104 developmental biology, Visual cortex, medicine.anatomical_structure, Parvalbumins, lcsh:Biology (General), nervous system, biology.protein, GABAergic, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin

Abstract

Summary: Parvalbumin (PV)-expressing GABAergic neurons are the largest class of inhibitory neocortical cells. We visualize brain-wide, monosynaptic inputs to PV neurons in mouse barrel cortex. We develop intersectional rabies virus tracing to specifically target GABAergic PV cells and exclude a small fraction of excitatory PV cells from our starter population. Local inputs are mainly from layer (L) IV and excitatory cells. A small number of inhibitory inputs originate from LI neurons, which connect to LII/III PV neurons. Long-range inputs originate mainly from other sensory cortices and the thalamus. In visual cortex, most transsynaptically labeled neurons are located in LIV, which contains a molecularly mixed population of projection neurons with putative functional similarity to LIII neurons. This study expands our knowledge of the brain-wide circuits in which PV neurons are embedded and introduces intersectional rabies virus tracing as an applicable tool to dissect the circuitry of more clearly defined cell types. : Hafner et al. develop constructs for intersectional rabies virus tracing to map brain-wide, monosynaptic inputs to cortical inhibitory parvalbumin cells. They find extensive local innervation by excitatory cells, inputs from inhibitory cells in layer I, and a strong contribution of layer IV projection neurons to cortical long-range inputs. Keywords: parvalbumin, GABAergic neuron, barrel cortex, rabies tracing, intersectional, Cre, Flp

Published

2018

3. Mapping Brain-Wide Afferent Inputs of Parvalbumin-Expressing GABAergic Neurons in Barrel Cortex Reveals Local and Long-Range Circuit Motifs.

Author

Hafner, Georg, Witte, Mirko, Guy, Julien, Subhashini, Nidhi, Fenno, Lief E., Ramakrishnan, Charu, Kim, Yoon Seok, Deisseroth, Karl, Callaway, Edward M., Oberhuber, Martina, Conzelmann, Karl-Klaus, and Staiger, Jochen F.

Abstract

Parvalbumin (PV)-expressing GABAergic neurons are the largest class of inhibitory neocortical cells. We visualize brain-wide, monosynaptic inputs to PV neurons in mouse barrel cortex. We develop intersectional rabies virus tracing to specifically target GABAergic PV cells and exclude a small fraction of excitatory PV cells from our starter population. Local inputs are mainly from layer (L) IV and excitatory cells. A small number of inhibitory inputs originate from LI neurons, which connect to LII/III PV neurons. Long-range inputs originate mainly from other sensory cortices and the thalamus. In visual cortex, most transsynaptically labeled neurons are located in LIV, which contains a molecularly mixed population of projection neurons with putative functional similarity to LIII neurons. This study expands our knowledge of the brain-wide circuits in which PV neurons are embedded and introduces intersectional rabies virus tracing as an applicable tool to dissect the circuitry of more clearly defined cell types. • Intersectional strategy to target neurons defined by two molecular markers • Inputs to PV cells are mostly local and include inhibitory connections from layer I • PV cells receive long-range input from other sensory areas and the thalamus • Layer IV in visual cortex stands out as an important projection layer Hafner et al. develop constructs for intersectional rabies virus tracing to map brain-wide, monosynaptic inputs to cortical inhibitory parvalbumin cells. They find extensive local innervation by excitatory cells, inputs from inhibitory cells in layer I, and a strong contribution of layer IV projection neurons to cortical long-range inputs. [ABSTRACT FROM AUTHOR]

Published

2019