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The Journal of Neuroscience, November 8, 2006, 26(45)

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This Week in The Journal
This Week in The Journal

Cellular/Molecular

Intersubunit Anesthetic Binding on GABA_A Receptors

Guo-Dong Li, David C. Chiara, Gregory W. Sawyer, S. Shaukat Husain, Richard W. Olsen, and Jonathan B. Cohen

(see pages 11599–11605)

Anesthesia has revolutionized medicine since its introduction in 1846. But the molecular workings of the responsible agents have remained surprisingly elusive. This week, Li et al. tackled the problem using photoaffinity labeling, a technique for labeling binding sites on proteins. Because most general anesthetics enhance the activity of GABA_A receptors, the authors photolabeled GABA_A receptors, purified from bovine cortex, with a photoreactive analog of the intravenous anesthetic etomidate. By protein microsequencing, they identified two labeled methionines. GABA_A receptors are heteromers of five subunits each having extracellular domains and four membrane-spanning domains (M1–4). One photolabeled methionine was in the M1 region of the subunit and the other was in M3 of the subunit. Structural models predict that the anesthetic site is a water-filled pocket located in the same subunit interface as the GABA binding site in the extracellular domain, some 50 Å away. The perfect place for an allosteric modulatory site, it would seem.

View larger version (88K): [in this window] [in a new window]   A portion of the GABAA receptor homology model showing the intersubunit anesthetic binding pocket between the 3 and 1 subunit. The bound etomidate analog (gold) is in contact with residues identified by photoaffinity labeling, Met236 and Met286. See Li et al. for details.

 
Development/Plasticity/Repair

Transcranial Imaging of Visual Cortical Plasticity

Manavu Tohmi, Hiroki Kitaura, Seiji Komagata, Masaharu Kudoh, and Katsuei Shibuki

(see pages 11775–11785)

Several tricks have been used to map brain activity noninvasively, thus avoiding potentially toxic dyes and manipulation of the tissue. This week, Tohmi et al. report on a noninvasive imaging technique that is powered by mitochondria. The authors compared the well studied intrinsic optical imaging method to that of endogenous flavoprotein fluorescence, the latter of which relies on activity-induced changes in the fluorescence of mitochondrial flavoproteins. The authors measured transcranial fluorescence in the visual cortex of anesthetized mice before and after one eye had been sewn shut for days or weeks. As expected, monocular deprivation led to decreased light responses from the deprived eye, whereas responses from the nondeprived eye increased in the binocular, but not the monocular, zone of the cortex. Imaging by endogenous flavoprotein fluorescence proved to be superior to imaging of intrinsic signals both in terms of signal-to-noise ratio and temporal resolution.

Behavioral/Systems/Cognitive

Probing Cerebellar Granule Cell Function In Vivo

Henrik Jörntell and Carl-Fredrik Ekerot

(see pages 11786–11797)

Often the simplest explanation can be the best one. Jörntell and Ekerot argue that this is the case for the way in which cerebellar granule cells process somatosensory information. A granule cell has about four dendrites, each receiving input from a single excitatory mossy fiber synapse, which in turn transmits signals from a specific site (or receptive field) on the skin. The authors recorded synaptic activity in granule cells in the forelimb area of the cerebellar C3 zone in decerebrate/unanesthetized cats after different types of skin stimulation. Each mossy fiber input to a granule cell contributed to spiking. There was little evidence of convergence from different types of inputs or from different receptive fields. In other words, these granule cells did not integrate different types of inputs, as has been proposed in sparse-coding theories, but rather acted as signal-to-noise-enhancing threshold detectors for a single, specific type of input.

Neurobiology of Disease

Altered AMPA Receptor Trafficking and ALS

Chen Lai, Chengsong Xie, Stefanie G. McCormack, Hsueh-Cheng Chiang, Marta K. Michalak, Xian Lin, Jayanth Chandran, Hoon Shim, Mika Shimoji, Mark R. Cookson, Richard L. Huganir, Jeffrey D. Rothstein, Donald L. Price, Philip C. Wong, Lee J. Martin, J. Julius Zhu, and Huaibin Cai

(see pages 11798–11806)

Loss-of-function mutations in the ALS2 gene cause a juvenile form of amyotrophic lateral sclerosis, resulting in a progressive loss of motor neurons. This week, Lai et al., using a combination of molecular and electrophysiological approaches, found that loss of the ALS2 gene product alsin in ALS2^–/– mice causes defects in AMPA receptor trafficking. When Lai et al. looked for proteins that interact with alsin, they fished out the glutamate receptor interacting protein 1 (GRIP1), whose role is to shuttle the AMPA receptor subunit GluR2 to the postsynaptic membrane. In neurons from ALS2^–/– mice, neither GRIP1 nor GluR2-containing AMPA receptors made their way to the synapse. This is not inconsequential because AMPA receptors lacking GluR2 subunits are more permeable to calcium, which rendered neurons more vulnerable to excitotoxicity. Thus, impaired AMPA trafficking in the absence of normal alsin could contribute to motor neuron degeneration.

Related articles in J. Neurosci.:

Identification of a GABA_A Receptor Anesthetic Binding Site at Subunit Interfaces by Photolabeling with an Etomidate Analog

Guo-Dong Li, David C. Chiara, Gregory W. Sawyer, S. Shaukat Husain, Richard W. Olsen, and Jonathan B. Cohen
J. Neurosci. 2006 26: 11599-11605. [Abstract] [Full Text]  

Enduring Critical Period Plasticity Visualized by Transcranial Flavoprotein Imaging in Mouse Primary Visual Cortex

Manavu Tohmi, Hiroki Kitaura, Seiji Komagata, Masaharu Kudoh, and Katsuei Shibuki
J. Neurosci. 2006 26: 11775-11785. [Abstract] [Full Text]  

Properties of Somatosensory Synaptic Integration in Cerebellar Granule Cells In Vivo

Henrik Jörntell and Carl-Fredrik Ekerot
J. Neurosci. 2006 26: 11786-11797. [Abstract] [Full Text]  

Amyotrophic Lateral Sclerosis 2-Deficiency Leads to Neuronal Degeneration in Amyotrophic Lateral Sclerosis through Altered AMPA Receptor Trafficking

Chen Lai, Chengsong Xie, Stefanie G. McCormack, Hsueh-Cheng Chiang, Marta K. Michalak, Xian Lin, Jayanth Chandran, Hoon Shim, Mika Shimoji, Mark R. Cookson, Richard L. Huganir, Jeffrey D. Rothstein, Donald L. Price, Philip C. Wong, Lee J. Martin, J. Julius Zhu, and Huaibin Cai
J. Neurosci. 2006 26: 11798-11806. [Abstract] [Full Text]  

This Article Full Text (PDF) Submit an eLetter Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Services Email this article to a friend Related articles in J. Neurosci. Similar articles in this journal Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Search for Related Content

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