Purinergic signalling: what is missing and needed next? The use of transgenic mice, crystallographic analysis and MicroRNA.

While ATP is recognized as an intracellular energy source for many biochemical reactions, it is now recognised it is also an important extracellular signalling molecule. ATP is involved in both physiological and pathological events in most cell types, and receptor subtypes have been cloned and characterised. An important goal of purinergic research today is to annotate the human genome with functional information regarding the role of genes for purinergic receptors, ectonucleotidases and transporters, in brain physiology and pathology. Insights into these roles have been gained also from studies of the various purinergic knockouts, and here we report on the generation of these purinergic receptor/ectonucleotidase-null mice. Recent X-ray structures of purinergic ligand-activated receptors provide promising templates to understand the molecular mechanism of receptor actions at the atomic level, and to deploy X-ray structures to be used for structure-based drug design. In the present work we also summarize recent findings about X-ray structures of ionotropic and metabotropic purinergic receptors and ectonucleotidases. A novel and prominent role as modulators of signal propagation in animal cells is played by microRNAs. By acting as genetic switches, they might become stringent regulators of the variety of cellular responses triggered by the dynamic interactions between purinergic receptors, nucleotides/nucleosides, transporters and ectonucleotidases. In this review we highlight data on the regulation of purinergic mechanisms by microRNAs. Finally, we would like to illustrate what information is still missing or needed for the acquisition of a more complete knowledge of purinergic signalling.

Indirect effect of guanine nucleotides on antagonist binding to A1 adenosine receptors: occupation of cryptic binding sites by endogenous vesicular adenosine.

Guanine nucleotides such as guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) have been found to increase the binding of antagonists to adenosine A1 receptors. This response can be attributed either to a direct effect of GTP on receptors to increase antagonist affinity or to an indirect effect to decrease the affinity of receptors for a pool of endogenous adenosine that cannot be readily removed from membranes. In this study, adenosine content was measured in preparations of membranes and 3-[(3-cholamidopropyl)dimethylamino]-1-propanesulfonate (CHAPS)-solubilized receptors by a sensitive radioimmunoassay. In both preparations, pools of adenosine (2.5-10 pmol/mg of protein) were detected that were resistant to deamination by added adenosine deaminase (0.5-3 units/ml) unless membrane lipids were first dissolved in acetone. Electron microscopic examination of crude CHAPS-solubilized receptors revealed the existence of small vesicles (< 1 microns in diameter). Furthermore, most "solubilized" receptors were retained by a 0.1-microns filter. The effects of GTP gamma S were evaluated on the binding of an antagonist, 3-(4-amino-3-125I-phenethyl)-1-propyl-8-cyclopentylxanthine (125I-BW-A844U), to A1 receptors of bovine brain membranes, receptors solubilized in CHAPS (crude solubilized), or receptors partially co-purified with G proteins by agonist affinity chromatography (partially purified). GTP gamma S (10 microM) increased antagonist binding to membranes (20-50%) and crude CHAPS-solubilized receptors (> 200%) but increased binding to partially purified receptors by only 10-15%. GTP gamma S decreased agonist (125I-N6-aminobenzyladenosine) binding and increased antagonist Bmax, but did not significantly decrease (5%) the dissociation rate of the antagonist. Omission of Mg2+ mimicked the effects of GTP gamma S on agonist and antagonist binding and increased both the association and dissociation rates of 125I-BW-A844U. These data suggest that a Mg(2+)-dependent GTP gamma S-induced increase in antagonist binding to membranes and solubilized receptors is primarily due to unmasking of cryptic binding sites occupied by contaminating vesicular adenosine. These findings are consistent with the observation that adenosine receptor antagonists have been found to have little or no inverse agonist physiological effects in well oxygenated tissues.

Dispositions of junctional feet in muscles of invertebrates.

The structure and disposition of the feet occupying the junctions between sarcoplasmic reticulum (SR) and surface membrane/transverse tubules were studied in muscles from a variety of invertebrates. Feet were imaged by rotary shadowing of isolated junctional SR vesicles and by filtering of micrographs from grazing views of the junction in thin sections. The overall size and shape of invertebrate feet is the same as that of feet in skeletal and cardiac muscle of vertebrates. However, the arrangement of feet in invertebrate muscles differs from that in vertebrates. These findings are discussed in terms of known variations in properties of excitation-contraction coupling of the two phyla.