Increased uptake and efflux of calcium with acetylcholine stimulation in smooth muscle of toad stomach

Transmembrane 45Ca fluxes in isolated smooth muscle cells: basal Ca2+ fluxes

Methods are described for monitoring unidirectional fluxes of 45Ca in smooth muscle cells in suspension. Compartmental analysis of 45Ca influx data indicate that 45Ca exchange consists of two kinetically distinguishable components in the toad stomach muscle cells: a relatively small (approximately 100-pmol X cm-2) component with a rapid rate of exchange (t1/2 approximately 1.4 min) and a larger (approximately 930-pmol X cm-2) component, which exchanges more slowly (t1/2 congruent to 87 min). The rate of exchange of the latter but not the former Ca2+ pool is increased on exposure of the cells to elevated K+ levels; thus the "slow" component of uptake appears to reflect transmembrane Ca2+ flux, whereas the "rapid" component may reflect exchange of surface-bound label. Consistent with this interpretation is the finding that under conditions in which surface 45Ca is rapidly and completely displaced, 45Ca efflux occurs as a simple monoexponential process with a slow rate of exchange (k = 7.80 X 10(-5) s-1). The apparent rate of transmembrane Ca2+ flux in smooth muscle cells at rest is approximately 0.1 pmol X cm-2 X s-1. Cellular processes that could give rise to an apparent transmembrane flux rate of this magnitude are discussed, and a model is presented which appears to describe cellular 45Ca exchange in the isolated smooth muscle cells.

Mechanism of vanadate-induced contraction of airways smooth muscle of the guinea-pig

The characteristics of vanadate-induced contraction of airways smooth muscle are described in isolated preparations of guinea-pig central and peripheral airways. Vanadate (1-1000 microM) induced sustained contractions of trachea and lung parenchymal strips within 1 min of challenge. It was more potent (P less than 0.001) on the lung strip (EC50 = 63 microM) than on the trachea (EC50 = 123 microM). The lung strip also developed greater maximum isometric tension (P less than 0.001) than the trachea. The efficacy on the lung strip was 2 and the trachea 0.6, relative to the response to acetylcholine (efficacy = 1). Vanadate-induced contractions of the trachea were not inhibited by atropine, mepyramine, phentolamine or indomethacin, nor after mast cell depletion by compound 48/80, showing that contractions were not mediated via specific receptors or by release of endogenous mediators of tone. Inorganic phosphate specifically inhibited vanadate responses in a dose-dependent and reversible manner, suggesting a common site of action. Contractions could be elicited in depolarized muscle and after treatment with ouabain plus propranolol, showing that membrane depolarization and inhibition of the Na, K-ATPase system were not involved in the contractile action of vanadate. Pretreatment of tracheal smooth muscle with verapamil had no influence on contractions elicited by vanadate. After removal of extracellular calcium, vanadate-induced contractions declined slowly with time, indicating that influx of extracellular calcium was not giving rise to contractions elicited by vanadate. Vanadate markedly increased the rate of calcium efflux from trachealis muscle loaded with 45Ca into both Ca2+-free and normal Krebs solutions; this is compatible with vanadate mobilizing an intracellular store of Ca2+. Such a store involving sites with Ca-ATPase activity would be consistent with the action of vanadate in isolated membrane preparations. Membrane-skinned tracheal fibres contracted by micromolar Ca2+ were relaxed by vanadate in a reversible dose-related manner, indicating that the contractile action of vanadate was not related to its interaction with proteins at the cross-bridge level.

[Innervation of the anterior byssus retractor muscle (ABRM) in Mytilus edulis L. and in Mytilus galloprovincialis Lmk. V. Cytochemical localization of cholinesterase activities (author's transl)]

Specific and non specific cholinesterase activities were demonstrated in the ABRM of Mytilus edulis L. and Mytilus galloprovincialis L. by means of different techniques. The results were found identical for both species: neuromuscular junctions "en grappe"-type scarely distributed within the ABRM, contain AChE. According to the histochemical inhibition tests, (a) the eserine inhibits AChE activity of the ABRM with a level of 5-10(-5) M or higher, (b) the ChE non specific activities are inhibited by iso-OMPA level between 5.10(-5) to 10(-4) M. The histo- and cytochemical observations were completed by showing the existence of neuromuscular junctions containing small clear vesicles: they probably are the morphological support for ACh presence. Moreover, specific and non specific ChE activities were localized in the glio-interstitial cells. AChE precipitates were developed along the ABRM sarcolemma, some muscle mitochondria and in the intercellular spaces remain enigmatic.

Sarcoplasmic reticulum and excitation-contraction coupling in mammalian smooth muscles

The sarcoplasmic reticulum (SR) was studied in the smooth muscles of rabbit main pulmonary artery, mesenteric vein, aorta, mesenteric artery, taenia coli, guinea pig mesenteric artery, and human uterus, and correlated with contractions of the smooth muscles in Ca-free media. SR volumes were determined in main pulmonary artery (5.1%), aorta (5%), portal-anterior mesenteric vein (2.2%), taenia coli (2%), and mesenteric artery (1.8%): because of tangentially sectioned membranes these estimates are subject to a correction factor of up to +50% of the values measured. Smooth muscles that contained a relatively large volume of SR maintained significant contractile responses to drugs in the virtual absence of extracellular calcium at room temperatures, while smooth muscles that had less SR did not. The unequal maximal contractions of main pulmonary artery elicited by different drugs were also observed in Ca-free, high potassium-depolarizing solution, indicating that they were secondary to some mechanism independent of changes in membrane potential or calcium influx. Longitudinal tubules of SR run between and are fenestrated about groups of surface vesicles separated from each other by intervening dense bodies. Extracellular markers (ferritin and lanthanum) entered the surface vesicles, but not the SR. The peripheral SR formed couplings with the surface membrane: the two membranes were separated by gaps of approximately 10 nm traversed by electron-opaque connections suggestive of a periodicity of approximately 20-25 nm. These couplings are considered to be the probable sites of electromechanical coupling in twitch smooth muscles. Close contacts between the SR and the surface vesicles may have a similar function, or represent sites of calcium extrusion. The presence of both thick and thin myofilaments and of rough SR in smooth muscles supports the dual, contractile and morphogenetic, function of smooth muscle.