Miwako Koizumi scite author profile

Functional magnetic resonance imaging (fMRI) based on the blood oxygenation level-dependent (BOLD) signal has been used to infer sites of neuronal activation in the brain. A recent study demonstrated, however, unexpected BOLD signal generation without neuronal excitation, which led us to hypothesize the presence of another cellular source for BOLD signal generation. Collective assessment of optogenetic activation of astrocytes or neurons, fMRI in awake mice, electrophysiological measurements, and histochemical detection of neuronal activation, coherently suggested astrocytes as another cellular source. Unexpectedly, astrocyte-evoked BOLD signal accompanied oxygen consumption without modulation of neuronal activity. Imaging mass spectrometry of brain sections identified synthesis of acetyl-carnitine via oxidative glucose metabolism at the site of astrocyte-, but not neuron-evoked BOLD signal. Our data provide causal evidence that astrocytic activation alone is able to evoke BOLD signal response, which may lead to reconsideration of current interpretation of BOLD signal as a marker of neuronal activation.

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Exogenous, but not endogenous nociceptin modulates mesolimbic dopamine release in mice

Koizumi

Midorikawa

Takeshima

et al. 2004

Journal of Neurochemistry

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The effect of nociceptin (an endogenous ligand of the ORL1 receptor) on mesolimbic dopamine release and simultaneous horizontal locomotion was studied in freely moving mice undergoing microdialysis of the nucleus accumbens. Intracerebroventricular (i.c.v.) administration of nociceptin (7 nmol) induced a long-lasting suppression of mesolimbic dopamine release and horizontal locomotion in wild-type but not ORL1 knockout mice. I.c.v. administration of the recently reported peptide nociceptin antagonist [Nphe1, Arg14, Lys15] nociceptin-NH 2 (known also as UFP-101, 5 nmol) completely abolished the suppressive effect of nociceptin on mesolimbic dopamine release. However, UFP-101 administration alone induced a mild and lasting suppression of mesolimbic dopamine release in both wild-type and ORL1 knockout mice that was magnified in ORL1 knockout mice by coadministration of nociceptin. UFP-101 administration alone suppressed locomotion in both genotypes. These results confirm that the suppressive action of nociceptin on mesolimbic dopamine release is mediated entirely by the ORL1 receptor, and that UFP-101 effectively antagonizes this action. However, the lack of a stimulatory effect of UFP-101 in wild-type mice indicates that despite being sensitive to exogenous nociceptin action, basal mesolimbic dopaminergic activity is not determined by endogenous nociceptin in mice.

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The NOP (ORL1) receptor antagonist Compound B stimulates mesolimbic dopamine release and is rewarding in mice by a non‐NOP‐receptor‐mediated mechanism

Koizumi

Sakoori

Midorikawa

et al. 2004

British J Pharmacology

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1 Compound B (1-[(3R, 4R)-1-cyclooctylmethyl-3-hydroxymethyl-4-piperidyl]-3-ethyl-1,3-dihydro-2H-benzimidazol-2-one, CompB) is a nociceptin/orphanin FQ (N/OFQ) antagonist showing high selectivity for the NOP (ORL1) receptor over classical opioid receptors. We studied the effect of subcutaneous CompB administration on the release of mesolimbic dopamine (DA) and the expression of hedonia in mice. 2 CompB (0.3-30 mg kg À1 ) dose dependently stimulated mesolimbic DA release as measured by in vivo freely moving microdialysis, without any change in locomotor activity. However, intracerebroventricular administered N/OFQ (endogenous agonist of the NOP receptor, 6 nmol) did not influence CompB-(10 mg kg À1 ) induced DA release, despite clearly suppressing release when administered alone. 3 Studies using NOP receptor knockout mice and no-net-flux microdialysis revealed mildly, but not statistically significantly higher endogenous DA levels in mice lacking the NOP receptor compared to wild-type mice. Administration of CompB (10 mg kg À1) induced identical increases in mesolimbic DA release in wild-type and NOP receptor knockout mice. 4 CompB was rewarding in approximately the same dose range in which CompB induced major increases in mesolimbic DA release when assayed using a conditioned place preference paradigm. The rewarding effect of CompB (30 mg kg À1 ) was maintained in NOP receptor knockout mice. 5 These results show that CompB stimulates mesolimbic DA release and is rewarding by an action independent of the NOP receptor, the precise site of which is unclear. Consequently, caution should be exercised when interpreting the results of studies using this drug, particularly when administered by a peripheral route.

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Striatonigral direct pathway activation is sufficient to induce repetitive behaviors

Bouchekioua

Tsutsui-Kimura

Sano

et al. 2018

Neuroscience Research

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Increased body weight in mice lacking mu-opioid receptors

Han¹,

Hata²,

Imbe³

et al. 2006

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Opioids have been suggested to affect feeding behaviour. To clarify the role of mu-opioid receptors in feeding, we measured several parameters relating to food intake in mu-opioid receptor knockout mice. Here, we show that the knockout mice had increased body weight in adulthood, although the intake amount of standard food was similar between the wild-type and knockout littermates. Serum markers for energy homeostasis were not significantly altered in the knockout mice. Hypothalamic neuropeptide Y mRNA, however, was higher in knockouts than in wild-type mice. Our results suggest that the up-regulated expression of neuropeptide Y mRNA might contribute to the increased weights of adult mu-opioid receptor knockout mice.

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Miwako Koizumi

Optogenetic astrocyte activation evokes BOLD fMRI response with oxygen consumption without neuronal activity modulation

Exogenous, but not endogenous nociceptin modulates mesolimbic dopamine release in mice

The NOP (ORL1) receptor antagonist Compound B stimulates mesolimbic dopamine release and is rewarding in mice by a non‐NOP‐receptor‐mediated mechanism

Striatonigral direct pathway activation is sufficient to induce repetitive behaviors

Increased body weight in mice lacking mu-opioid receptors

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