Two serine residues control sequential steps during catalysis of the yeast copper ATPase through different mechanisms that involve kinase-mediated phosphorylations.

Ccc2, the yeast copper-transporting ATPase, pumps copper from the cytosol to the Golgi lumen. During its catalytic cycle, Ccc2 undergoes auto-phosphorylation on Asp(627) and uses the energy gained to transport copper across the cell membrane. We previously demonstrated that cAMP-dependent protein kinase controls the energy interconversion (Cu)E∼P → E-P + Cu when Ser(258) is phosphorylated. We now demonstrate that Ser(258) is essential in vivo for copper homeostasis in extremely low copper and iron concentrations. The S258A mutation abrogates all phosphorylations of Ccc2, whereas the S971A mutation leads to a 100% increase in its global regulatory phosphorylation. With S258A, the first-order rate constant of catalytic phosphorylation by ATP decreases from 0.057 to 0.030 s(-1), with an 8-fold decrease in the burst of initial phosphorylation. With the S971A mutant, the rate constant decreases to 0.007 s(-1). decreases the amount of the aspartylphosphate intermediate (EP) in Ccc2 wt by 50% within 1 min, but not in S258A, S971A, or S258A/S971A. The increase of the initial burst and the extremely slow phosphorylation when the "phosphomimetic" mutant S258D was assayed (k = 0.0036 s(-1)), indicate that electrostatic and conformational (non-electrostatic) mechanisms are involved in the regulatory role of Ser(258). Accumulation of an ADP-insensitive form in S971A demonstrates that Ser(971) is required to accelerate the hydrolysis of the E-P form during turnover. We propose that Ser(258) and Ser(971) are under long-range intramolecular, reciprocal and concerted control, in a sequential process that is crucial for catalysis and copper transport in the yeast copper ATPase.

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