Endomorphins: Localization, Release and Action on Rat Dorsal Horn Neurons

Dun, N. J., Dun, S. L., Wu, S. Y., Williams, C. A., Kwok, E. H.

01 January 2000

Endomorphin (Endo) 1 and 2, two tetrapeptides isolated from the bovine and human brain, have been proposed to be the endogenous ligand for the μ- opiate receptor. A multi-disciplinary study was undertaken to address the issues of localization, release and biological action of Endo with respect to the rat dorsal horn. First, immunohistochemical studies showed that Endo-1- or Endo-2-like immunoreactivity (Endo-1- or Endo-2-LI) is selectively expressed in fiber-like elements occupying the superficial layers of the rat dorsal horn, which also exhibit a high level of μ-opiate receptor immunoreactivity. Second, release of immunoreactive Endo-2-like substances (irEndo) from the in vitro rat spinal cords upon electrical stimulation of dorsal root afferent fibers was detected by the immobilized antibody microprobe technique. The site of release corresponded to laminae I and II where the highest density of Endo-2-LI fibers was localized. Lastly, whole- cell patch clamp recordings from substantia gelatinosa (SG) neurons of rat lumbar spinal cord slices revealed two distinct actions of exogenous Endo-1 and Endo-2: (1) depression of excitatory and/or inhibitory postsynaptic potentials evoked by stimulation of dorsal root entry zone, and (2) hyperpolarization of SG neurons. These two effects were prevented by the selective μ-opiate receptor antagonist β-funaltrexamine. The localization of endomorphin-positive fibers in superficial layers of the dorsal horn and the release of irEndo upon stimulation of dorsal root afferents together with the observation that Endo inhibits the activity of SG neurons by interacting with μ-opiate receptors provide additional support of a role of Endo as the endogenous ligand for the μ-opiate receptor in the rat dorsal horn.

excitatory postsynaptic currents

inhibitory postsynaptic currents

μ-opiate receptors

Recurrent inhibitory network among cholinergic inerneurons of the striatum

Sullivan, Matthew Alexander

08 November 2012

The striatum is the initial input nuclei of the basal ganglia, and it serves as an integral processing center for action selection and sensorimotor learning. Glutamatergic projections from the cortex and thalamus converge with dense dopaminergic axons from the midbrain to provide the primary inputs to the striatum. Striatal output is then relayed to downstream basal ganglia nuclei by GABAergic medium – sized spiny neurons, which comprise at least 95% of the population of neurons in the striatum. The remaining population of local circuit neurons is dedicated to regulating the activity of spiny projection neurons, and although spiny neurons form a weak lateral inhibitory network among themselves via local axon collaterals, feedforward modulation exerts more powerful control over spiny neuron excitability. Of the striatal interneurons, only one class is not GABAergic. These neurons are cholinergic and correspond to the tonically active neurons (TANs) recorded in vivo, which respond to specific environmental stimuli with a transient depression, or pause, of tonic firing. Striatal cholinergic interneurons account for less than 2 % of the striatal neuronal population, yet their axons form an extensive and complex network that permeates the entire striatum and significantly shapes striatal output by acting at numerous targets via varied receptor types. Indeed, the persistent level of ambient striatal acetylcholine as well as changes to that basal acetylcholine level underlie the major mechanisms of cholinergic signaling in the striatum, however regulation of this system by the local striatal microcircuitry is not well understood. This dissertation finds that activation of intrastriatal cholinergic fibers elicits polysynaptic GABAA inhibitory postsynaptic currents (IPSCs) in cholinergic interneurons recorded in brain slices. Excitation of striatal GABAergic neurons via nicotinic acetylcholine receptors (nAChRs) mediates this polysynaptic inhibition in a manner independent of dopamine. Moreover, activation of a single cholinergic interneuron is capable of eliciting polysynaptic GABAA IPSCs onto itself and nearby cholinergic interneurons. These findings provide an important insight into the striatal microcircuitry controlling cholinergic neuron excitability. / text

Intrastriatal cholinergic fibers

Inhibitory postsynaptic currents

Cholinergic interneurons

Striatal GABAergic neurons

Nicotinic acetylcholine receptors

Polysynaptic inhibition

Elektrophysiologische Charakterisierung von GABA-Rezeptor-vermittelter Inhibition an Martinotti-Zellen der Schicht 5 im Barrel-Kortex / Electrophysiological characterization of GABA-receptor-mediated inhibition on Martinotti cells in layer 5 of the barrel cortex

Glöckner, Kristina

10 December 2020

No description available.

610

Barrel-Kortex

Inhibitorische Interneurone

Martinotti-Zelle

GIN-Maus

Patch-clamp-Ableitungen

postsynaptische GABAA-Rezeptoren

inhibitorische postsynaptische Ströme

präsynaptische GABAB-Rezeptoren

Kurzzeitplastizität

barrel cortex

inhibitory interneurons

Martinotti cell

GIN mouse

patch-clamp recordings

postsynaptic GABAA receptors

inhibitory postsynaptic currents

presynaptic GABAB receptors

short-term plasticity

Medizin (PPN619874732)