Pharmacological and biochemical criteria can be used to separate those dopamine receptors which are linked to the enzyme adenylyl cyclase and those which are not.

Multiple receptors for dopamine.

Excitatory amino acid transmitters

Inwardly rectifying K+ (Kir) channels allow K+ to move more easily into rather than out of the cell. They have diverse physiological functions depending on their type and their location. There are ...

Inwardly Rectifying Potassium Channels: Their Structure, Function, and Physiological Roles

Except in rare cases, the stomach can withstand exposure to highly concentrated hydrochloric acid, refluxed bile salts, alcohol, and foodstuffs with a wide range of temperatures and osmolarity. This is attributed to a number of physiological responses by the mucosal lining to potentially harmful luminal agents, and to an ability to rapidly repair damage when it does occur. Since the discovery in 1971 that prostaglandin synthesis could be blocked by aspirin and other nonsteroidal anti-inflammatory drugs (NSAIDs), there has been great interest in the contribution of prostaglandins to gastric mucosal defense. Prostaglandins modulate virtually every aspect of mucosal defense, and the importance of this contribution is evident by the increased susceptibility of the stomach to injury following ingestion of an NSAID. With chronic ingestion of these drugs, the development of ulcers in the stomach is a significant clinical concern. Research over the past two decades has helped to identify some of the key events triggered by NSAIDs that contribute to ulcer formation and/or impair ulcer healing. Recent research has also highlighted the fact that the protective functions of prostaglandins in the stomach can be carried out by other mediators, in particular the gaseous mediators nitric oxide and hydrogen sulfide. Better understanding of the mechanisms through which the stomach is able to resist injury in the presence of luminal irritants is helping to drive the development of safer anti-inflammatory drugs, and therapies to accelerate and improve the quality of ulcer healing.

Prostaglandins, NSAIDs, and Gastric Mucosal Protection: Why Doesn't the Stomach Digest Itself?

Early events in neuronal differentiation are generally considered to be regulated by factors independent of alterations in membrane permeability. Weaver mice harbour a mutation that blocks neuronal differentiation just after cessation of cell division, prior to cell migration and synaptogenesis. Cerebellar granule cells in homozygous weaver mice fail to differentiate, either because intrinsic cues are absent or because the granule cells are unable to respond to those cues. We now report that weaver mice have a missense mutation in a gene encoding a G–protein coupled inward rectifier potassium channel. The mutation alters the putative ion–permeable, pore–forming domain of the protein, suggesting that granule cell differentiation is regulated by changes in membrane permeability.

A potassium channel mutation in weaver mice implicates membrane excitability in granule cell differentiation.

The dopamine system in weaver mutant mice (B6CBA-Aw-J/A background) was studied. Dopamine was 27% lower in the olfactory tubercle, 77% lower in the frontal cortex, and 75% lower in the striatum of 6-month-old weaver mice compared to control mice of the same age. Norepinephrine and serotonin were not lower in these brain areas. Tyrosine hydroxylase activity in the striatum was measured with a radiometric assay and was 70% lower in weaver mice. Examination of mice from 11 to 180 days of age revealed that the dopamine system failed to develop in weaver mice. Motor activity in individual animals was assessed using circular photocell activity cages with minimal illumination. Apomorphine and pergolide, direct dopamine agonists, increased activity more in weaver mice than in normal littermates. Amphetamine, which releases endogenous stores of dopamine, was less active in mutant mice. These findings provide suggestive evidence that postsynaptic dopamine receptors in weaver mutants might have become supersensitive as a result of lower levels of dopamine in motor areas of the brain. Anatomical evidence of dopamine system abnormalities was found in weaver mice by examination of serial sections cut from the midbrain of mutant and normal mice. The pars compacta of the substantia nigra in weaver mice appeared hypocellular when compared with the corresponding sections from controls. Fewer large neurons were seen in the affected animals. This study illustrates that weaver mice have specific deficiencies in the dopamine system. The weaver mouse might provide a way of examining the biochemical and behavioral effects of long term dopamine deficiency and a way to examine drugs to treat dopamine-deficient states in vivo.

https://www.jneurosci.org/content/jneuro/2/3/376.full.pdf

Michael J. Schmidt

Papers

Dopamine deficiency in the weaver mutant mouse

Inhibition of polymorphonuclear leukocyte adherence by prostacyclin.

Effect of aging on neurotransmitter receptor binding in rat and human brain.

Cyclic AMP and cyclic GMP accumulation in vitro in brain regions of young, old and aged rats.

Effects of ergots on adenylate cyclase activity in the corpus striatum and pituitary.