The metal sites on sarcoplasmic reticulum membranes that bind lanthanide ions with the highest affinity are not the ATPase Ca2+ transport sites.

F Henao,S Orlowski,Z Merah,P Champeil

doi:10.1016/s0021-9258(19)50018-7

Abstract

We attempted to establish whether lanthanide ions, when added to sarcoplasmic reticulum (SR) membranes in the absence of nucleotide, compete with Ca2+ for binding to the transport sites of the Ca(2+)-ATPase in these membranes, or whether they bind to different sites. Equilibrium measurements of the effect of lanthanide ions on the intrinsic fluorescence of SR ATPase and on 45Ca2+ binding to it were performed either at neutral pH (pH 6.8), i.e. when endogenous or contaminating Ca2+ was sufficient to nearly saturate the ATPase transport sites, or at acid pH (pH 5.5), which greatly reduced the affinity of calcium for its sites on the ATPase. These measurements did reveal apparent competition between Ca2+ and the lanthanide ions La3+, Gd3+, Pr3+, and Tb3+, which all behaved similarly, but this competition displayed unexpected features: lanthanide ions displaced Ca2+ with a moderate affinity and in a noncooperative way, and the pH dependence of this displacement was smaller than that of the Ca2+ binding to its own sites. Simultaneously, we directly measured the amount of Tb3+ bound to the ATPase relative to the amount of Ca2+ and found that Tb3+ ions only reduced significantly the amount of Ca2+ bound after a considerable number of Tb3+ ions had bound. Furthermore, when we tested the effect of Ca2+ on the amount of Tb3+ bound to the SR membranes, we found that the Tb3+ ions which bound at low Tb3+ concentrations were not displaced when Ca2+ was added at concentrations which saturated the Ca2+ transport sites. We conclude that the sites on SR ATPase to which lanthanide ions bind with the highest affinity are not the high affinity Ca2+ binding and transport sites. At higher concentrations, lanthanide ions did not appear to be able to replace Ca2+ ions and preserve the native structure of their binding pocket, as evaluated in rapid filtration measurements from the effect of moderate concentrations of lanthanide ions on the kinetics of Ca2+ dissociation. Thus, the presence of lanthanide ions slowed down the dissociation from its binding site of the first, superficially bound 45Ca2+ ion, instead of specifically preventing the dissociation of the deeply bound 45Ca2+ ion. These results highlight the need for caution when interpreting, in terms of calcium sites, experimental data collected using lanthanide ions as spectroscopic probes on SR membrane ATPase.

Highlights

The Metal Sites on Sarcoplasmic Reticulum Membranes That Bind Lanthanide Ionswith the Highest Affinity Are Not the ATPase Ca2+ Transport Sites*
In addition,when we studied the ATPase relative to the membrane surface or to other sitesefofenct of lanthanide ions on the kinetiocfs dissociation of the theATPase, including thecatalyticsiteand individually two Ca" ions bound to the ATPasew,e found that moderate labeled amino acids (Stephens and Grisha1m9,79; Highsmith concentrations of theselanthanideions slowed down the and Murphy, 1984; Scott, 1985;Herrmann et ul., 1986a; Teruel dissociation of the first Ca2+ion to leave its binding pocket, and G6mez-Fernhdez, 1986; Squier et al, 1987, 1990; Jona which is clearevidence forbinding at a site different from the et al.,1990; see a discussion in Martonosi et al, 1990)
Lowering the medium pH greatly reducesthe affinity of these sites for calcium (Watanabeet al., 1981;Guillain et al, 1982), so that at acid pHandin the absence ofextra Ca2+,most sites can be expectedto remain unoccupiedT. his expectation is confirmed by traceA of Fig. 1,which showsthat at pH 5.5 k 0.1, addition of excess EGTA to sarcoplasmic reticulum (SR) vesiclesonlyslightlyreducedtheir intrinsic fluorescence level, known to be a reliable index of site occupancy by Ca2+, whereas addition of excess Ca2+ did