Selectivity sequences in a model calcium channel: role of electrostatic field strength.

The energetics that give rise to selectivity sequences of ionic binding selectivity of Li(+), Na(+), K(+), Rb(+), and Cs(+) in a model of a calcium channel are considered. This work generalizes Eisenman's classic treatment (Biophys J 2(Suppl. 2):259, 1962) by including multiple, mobile binding site oxygens that coordinate many permeating ions (all modeled as charged, hard spheres). The selectivity filter of the model calcium channel allows the carboxyl terminal groups of glutamate and aspartate side chains to directly interact with and coordinate the permeating ions. Ion dehydration effects are represented with a Born energy between the dielectric coefficients of the selectivity filter and the bath. High oxygen concentration creates a high field strength site that prefers small ions, as in Eisenman's model. On the other hand, a low filter dielectric constant also creates a high field strength site, but this site prefers large ions, contrary to Eisenman's model. These results indicate that field strength does not have a unique effect on ionic binding selectivity sequences once entropic, electrostatic, and dehydration forces are included in the model. Thus, Eisenman's classic relationship between field strength and selectivity sequences must be supplemented with additional information about selectivity filters such as the calcium channel that has amino acid side chains mixing with ions to make a crowded permeation pathway.

Receptor-operated cation entry--more than esoteric terminology?

Many hormones and neurotransmitters elicit an increase in the intracellular calcium concentration by binding to phospholipase C-linked G protein-coupled receptors. Activated receptors signal to calcium-permeable cation channels in the plasma membrane, which are distinct from those engaged by emptying of intracellular stores of calcium. The TRPC family of the mammalian homologs of the Drosophila transient receptor potential (TRP) cation channel represents likely molecular correlates underlying receptor-operated cation entry. While all TRPC family members are gated in a phospholipase C-dependent manner, the exact activation mechanism still remains elusive, although lipids such as diacylglycerol and polyunsaturated fatty acids are potential diffusible messengers. Functional TRPC channel complexes in the plasma membrane are thought to be composed of four distinct subunits whose stoichiometry and composition under physiological conditions are still largely unknown. However, recent progress in defining the combinatorial rules of TRPC channel assembly may lead to the identification of TRPC-dependent ion fluxes in living cells. Because of the large number of TRP proteins and their frequently overlapping functional characteristics, the central question is whether TRP proteins are functionally interchangeable or whether unique physiological roles can be ascribed to them. Receptor-operated cation entry is critically involved in the control of airway and vascular smooth muscle tone; hence, TRPC proteins are promising new drug targets.

Ectonucleotide diphosphohydrolase activity in Crithidia deanei.

In this work we describe the ability of living Crithidia deanei to hydrolyze extracellular ATP. In intact cells at pH 7.2, a low level of ATP hydrolysis was observed in the absence of any divalent metal (0.41+/-0.13 nmol P(i) h(-1) 10(7) cells(-1)). The ATP hydrolysis was stimulated by MgCl(2) and the Mg(2+)-dependent ecto-ATPase activity was 4.05+/-0.17 nmol P(i) h(-1) 10(7) cells(-1). Mg(2+)-dependent ecto-ATPase activity increased linearly with cell density and with time for at least 60 min. The addition of MgCl(2) to extracellular medium increased the ecto-ATPase activity in a dose-dependent manner. At 5 mM ATP, half-maximal stimulation of ATP hydrolysis was obtained with 0.93+/-0.26 mM MgCl(2). This stimulatory activity was also observed when MgCl(2) was replaced by MnCl(2), but not CaCl(2) or SrCl(2). The apparent K(m) for Mg-ATP(2-) was 0.26+/-0.03 mM. ATP was the best substrate for this enzyme; other nucleotides, such as ITP, GTP, UTP and CTP, produced lower reaction rates. In the pH range from 6.6 to 8.4, in which the cells were viable, the acid phosphatase activity also present in this cell decreased, while the Mg(2+)-dependent ATPase activity did not change. This ecto-ATPase activity was insensitive to inhibitors of other ATPase and phosphatase activities, such as oligomycin, sodium azide, bafilomycin A(1), ouabain, vanadate, molybdate, sodium fluoride and tartrate. To confirm that this Mg(2+)-dependent ATPase was an ecto-ATPase, we used the impermeant inhibitor 4, 4'-diisothiocyanostylbene 2'-2'-disulfonic acid as well as suramin, an antagonist of P(2) purinoreceptors and inhibitor of some ecto-ATPases. These two reagents inhibited the Mg(2+)-dependent ATPase activity in a dose-dependent manner. The cell surface location of the ATP-hydrolyzing site was also confirmed by cytochemical analysis.