The study shows how a protein called p67 can protect another protein, eIF‑2, from being turned off by an enzyme (dsI) that adds phosphate groups. At low levels of the enzyme, p67 works well, but when the enzyme is abundant, it overpowers p67 unless a lot more p67 is present. The enzyme also phosphorylates itself, and p67 blocks both its own and eIF‑2’s phosphorylation.

Mechanism of regulation of eIF-2 alpha-subunit phosphorylation by dsI and p67 was studied. The results are as follows: (1) At low dsI concentration, p67 protected equimolar concentration of eIF-2. (2) At high dsI concentration, dsI efficiently phosphorylated eIF-2 alpha-subunit even when equimolar concentrations of both p67 and eIF-2 were present. Significantly increased p67 concentration was necessary to protect eIF-2 alpha-subunit at high dsI concentration. (3) dsI was also phosphorylated as it phosphorylated eIF-2 alpha-subunit. p67 inhibited both eIF-2 alpha-subunit and dsI phosphorylation similarly. (4) Although the [32P]-labelled dsI formed during the reaction could be effectively chased upon subsequent addition of excess unlabelled eIF-2 and ATP, the [32P] labelled eIF-2 formed under identical conditions, retained most of the radioactivity. (5) dsI coimmunoprecipitated with three subunit eIF-2 and p67 inhibited this coimmunoprecipitation reaction. It has been proposed: Three subunit eIF-2 and free p67 are in equilibrium with eIF-2 bound to p67 and, eIF-2.p67 complex is resistant to dsI phosphorylation. Activated dsI is already phosphorylated. At high concentration, dsI(P) can bind to free three subunit eIF-2 and form eIF-2.dsI(P) complex. dsI(P) in this complex then transfers its phosphoryl residue to eIF-2 and forms eIF-2 alpha(P) in an irreversible reaction. In a subsequent reaction, unphosphorylated dsI is autophosphorylated using [gamma 32P]-ATP and the cycle continues. Inhibition of eIF-2 alpha-subunit phosphorylation by p67 blocks this phosphorylation cycle and consequent dsI phosphorylation.