Margarita C. Currás scite author profile

SUMMARY1. Intracellular neuronal activity was recorded in rat preoptic-anterior hypothalamic tissue slices. Thirty neurones were classified as warm sensitive, cold sensitive or temperature insensitive, based on their firing rate response to temperature changes. Seventy-seven per cent of the neurones were temperature insensitive, which included both spontaneously firing and silent neurones. Of all neurones, 10% were warm sensitive and 13% were cold sensitive.2. Silent temperature-insensitive neurones had lower input resistances (126 + 21 MQ2) than thermosensitive neurones (179 + 24 MQ). Regardless of neuronal type, however, resistance was inversely related to temperature.3. Warm-sensitive neurones were characterized by a slow, depolarizing prepotential, whose rate of rise was temperature dependent. This depolarizing potential disappeared during current-induced hyperpolarization, suggesting that intrinsic mechanisms are responsible for neuronal warm sensitivity.4. Spike activity in cold-sensitive neurones correlated with putative excitatory and inhibitory postsynaptic potentials, whose frequency was thermosensitive. This suggests that cold sensitivity in these neurones depends on synaptic input from nearby neurones.5. Like cold-sensitive neurones, action potentials of temperature-insensitive neurones often were preceded by short duration (< 20 ms), rapidly rising prepotentials, whose rates of rise were not affected by temperature. In some temperature-insensitive neurones, depolarizing current injection increased both firing rate (by 5-8 impulses s-1) and warm sensitivity, with pre-potentials having temperature-dependent rates of rise. We suggest that temperature-insensitive neurones employ two opposing, thermally dependent mechanisms: a voltagedependent depolarizing conductance and a hyperpolarizing sodium-potassium pump.t To whom reprint requests should be sent. MS 85159 PH Y, 440

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Lateral hypothalamic NMDA receptor subunits NR2A and/or NR2B mediate eating: immunochemical/behavioral evidence

Khan

Currás

Dao

et al. 1999

American Journal of Physiology-Regulatory, Integrative and Comp

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Cells within the lateral hypothalamic area (LHA) are important in eating control. Glutamate or its analogs, kainic acid (KA) and N-methyl-d-aspartate (NMDA), elicit intense eating when microinjected there, and, conversely, LHA-administered NMDA receptor antagonists suppress deprivation- and NMDA-elicited eating. The subunit composition of LHA NMDA receptors (NMDA-Rs) mediating feeding, however, has not yet been determined. Identifying this is important, because distinct second messengers/modulators may be activated by NMDA-Rs with differing compositions. To begin to address this, we detected LHA NR2A and NR2B subunits by immunoblotting and NR2B subunits by immunohistochemistry using subunit-specific antibodies. To help determine whether NMDA-Rs mediating feeding might contain these subunits, we conducted behavioral studies using LHA-administered ifenprodil, an antagonist selective for NR2A- and/or NR2B-containing NMDA-Rs at the doses we used (0.001–100 nmol). Ifenprodil maximally suppressed NMDA- and deprivation-elicited feeding by 63 and 39%, respectively, but failed to suppress KA-elicited eating, suggesting its actions were behaviorally specific. Collectively, these results suggest that LHA NMDA-Rs, some of which contribute to feeding control, are composed of NR2A and/or NR2B subunits, and implicate NR2A- and/or NR2B-linked signal transduction in feeding behavior.

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Increased expression of the N-methyl-d-aspartate receptor subunit, NR1, in immunohistochemically identified magnocellular hypothalamic neurons during dehydration

Decavel

Currás

1997

Neuroscience

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Neurophysiological Aspects of Thermoregulation

Boulant¹,

Currás²,

Dean

1989

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Functional activation of punch-cultured magnocellular neuroendocrine cells by glutamate receptor subtypes

Meeker¹,

Currás²,

Stewart³

et al. 1999

Journal of Neuroscience Methods

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