Calcium gating of H+ fluxes in chloroplasts affects acid-base-driven ATP formation

Abstract

In previous work, calcium ions, bound at the lumenal side of the CF₀H⁺ channel, were suggested to keep a H⁺ flux gating site closed, favoring sequestered domain H⁺ ions flowing directly into the CF₀-CF₁ and driving ATP formation by a localized $\Delta \tilde \mu _{H^ + } $ gradient. Treatments expected to displace Ca⁺⁺ from binding sites had the effect of allowing H⁺ ions in the sequestered domains to equilibrate with the lumen, and energy coupling showed delocalized characteristics. The existence of such a gating function implies that a closed-gate configuration would block lumenal H⁺ ions from entering the CF₀-CF₁ complex. In this work that prediction was tested using as an assay the dark, acid-base jump ATP formation phenomenon driven by H⁺ ions derived from succinic acid loaded into the lumen. Chlorpromazine, a photoaffinity probe for many proteins having high-affinity Ca⁺⁺-binding sites, covalently binds to the 8-kDa CF₀ subunit in the largest amounts when there is sufficient Ca⁺⁺ to favor the localized energy coupling mode, i.e., the “gate closed” configuration. Photoaffinity-bound chlorpromazine blocked 50% or more of the succinate-dependent acid-base jump ATP formation, provided that the ionic conditions during the UV photoaffinity treatment were those which favor a localized energy coupling pattern and a higher level of chlorpromazine labeling of the 8-kDa CF₀ subunit. Thylakoids held under conditions favoring a delocalized energy coupling mode and less chlorpromazine labeling of the CF₀ subunit did not show any inhibition of acid-base jump ATP formation. Chlorpromazine and calmidazolium, another Ca⁺⁺-binding site probe, were also shown to block redox-derived H⁺ initially released into sequestered domains from entering the lumen, at low levels of domain H⁺ accumulation, but not at higher H⁺ uptake levels; ie., the closed gate state can be overcome by sufficiently acidic conditions. That is consistent with the observation that the inhibition of lumenal succinate-dependent ATP formation by photoaffinity-attached chlorpromazine can be reversed by lowering the pH of the acid stage from 5.5 to 4.5. The evidence is consistent with the concept that Ca⁺⁺ bound at the lumenal side of the CF₀ H⁺ channel can block H⁺ flux from either direction, consistent with the existence of a molecular structure in the CF₀ complex having the properties of a gate for H⁺ flux across the inner boundary of the CF₀. Such a gate could control the expression of localized or delocalized $\Delta _\mu {H^ + }^ \sim $ energy coupling gradients.