Kathryne A. Medeiros scite author profile

Kathryne A. Medeiros

5Publications

67Citation Statements Received

119Citation Statements Given

How they've been cited

How they cite others

117

Affiliations

University of Massachusetts Amherst

Publications

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Engineering a Light-Regulated GABA_A Receptor for Optical Control of Neural Inhibition

et al. 2014

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Optogenetics has become an emerging technique for neuroscience investigations owing to the great spatiotemporal precision and the target selectivity it provides. Here we extend the optogenetic strategy to GABAA receptors (GABAARs), the major mediators of inhibitory neurotransmission in the brain. We generated a light-regulated GABAA receptor (LiGABAR) by conjugating a photoswitchable tethered ligand (PTL) onto a mutant receptor containing the cysteine-substituted α1-subunit. The installed PTL can be advanced to or retracted from the GABA-binding pocket with 500 and 380 nm light, respectively, resulting in photoswitchable receptor antagonism. In hippocampal neurons, this LiGABAR enabled a robust photoregulation of inhibitory postsynaptic currents. Moreover, it allowed reversible photocontrol over neuron excitation in response to presynaptic stimulation. LiGABAR thus provides a powerful means for functional and mechanistic investigations of GABAAR-mediated neural inhibition.

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The GABAA receptor as a target for photochromic molecules

Feliciano¹,

Vytla²,

Medeiros³

et al. 2010

Bioorganic & Medicinal Chemistry

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Photochromic ligands, molecules that can be induced to change their physical properties through applied light, are currently the topic of much chemical biology research. This specialized class of small organic structures are, surprisingly to many, fairly common in nature. At the core of a number of natural biological processes lies a small molecule that changes shape or some other measurable property in response to light absorption. For instance, conformational changes invoked by reversible photoisomerization of a retinoid small molecule found in the photoreceptors of the human eye leads to vision. In plants, photoisomerization of a cinnamate moiety leads to altered gene expression. The photosensitive molecule can be viewed simply as a nanosensor of light, much like a photosensitive electrical component might be added to a circuit to sense day versus night to turn an electrical circuit on or off. Synthetic organic chemists and chemical biologists have been, for at least the last 15 years, trying to either mimic or exploit the native photochromism found in nature. Here, we describe the design process to develop a photochromic molecule to be used in neurobiology.

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Optical Control of Neuronal Inhibition with Genetically Engineered Light Inhibited GABAA Receptors (Li-GABARs)

Davenport

Lin

Mourot

et al. 2012

Biophysical Journal

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Novel Strategies to Modulate Synaptic Communication and Investigate the Role of Hdac6 in Alzheimer’s Disease

Medeiros¹

2014

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Optogenetic GABAA Receptors: Controlling Neural Inhibition with Light

Lin

Mourot

Vytla

et al. 2011

Biophysical Journal

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