ABSTRACT: We previously reported that, in the membranes of HL-60 cells during activation of G-proteins, a phosphate transfer reaction occurs which involves transient G-protein beta subunit (G beta) phosphorylation [Wieland, Nürnberg, Ulibarri, Kaldenberg-Stasch, Schultz and Jakobs (1993) J. Biol. Chem. 268, 18111-18118]. Here, the generality of this phenomenon is evaluated by studying membranes of various tissues obtained from different mammalian species. All membranes tested expressed at least G beta 1 and G beta 2 subunits. Cell membranes from bovine and porcine brain and liver, rat brain and human blood cells exhibited predominantly G beta 1 or both subtypes at roughly equal concentrations. In contrast, significantly more G beta 2 immunoreactivity was detected in membranes from human placenta. Bovine and porcine liver membranes exhibited weak, G beta-specific immunoreactive signals. Conversely, these membranes showed the highest levels of G beta phosphorylation after incubation with [gamma-32P]GTP or 35S-labelled guanosine 5'-[gamma-thio]triphosphate. Interestingly, G beta-specific phosphorylation of membranes from human erythrocytes and platelets was very weak. G beta phosphorylation was confirmed by immunoprecipitation with G beta-specific antibodies, and the target amino acid was identified as histidine. On SDS/PAGE, phosphorylated or thiophosphorylated G beta-proteins differed in their apparent molecular size from unmodified G beta-proteins. Moreover, phosphorylated G beta-proteins differed in a species-dependent fashion in their electrophoretic mobility. Solubilization of membrane proteins with detergent did not abolish G beta phosphorylation. In contrast, reconstituted purified Gi/Go proteins showed no G beta phosphorylation. From these experiments we conclude that: (i) G beta phosphorylation represents a general phenomenon occurring in the cells of various species to different degrees, (ii) phosphorylated G beta-proteins exhibit species-dependent diverse electrophoretic mobilities, and (iii) G beta phosphorylation requires a membrane-associated cofactor(s) which is lost during routine G-protein purification.