The G protein beta5 subunit interacts selectively with the Gq alpha subunit.

The diversity in the heterotrimeric G protein alpha, beta, and gamma subunits may allow selective protein-protein interactions and provide specificity for signaling pathways. We examined the ability of five alpha subunits (alphai1, alphai2, alphao, alphas, and alphaq) to associate with three beta subunits (beta1, beta2, and beta5) dimerized to a gamma2 subunit containing an amino-terminal hexahistidine-FLAG affinity tag (gamma2HF). Sf9 insect cells were used to overexpress the recombinant proteins. The hexahistidine-FLAG sequence does not hinder the function of the beta1gamma2HF dimer as it can be specifically eluted from an alphai1-agarose column with GDP and AlF4-, and purified beta1gamma2HF dimer stimulates type II adenylyl cyclase. The beta1gamma2HF and beta2gamma2HF dimers immobilized on an anti-FLAG affinity column bound all five alpha subunits tested, whereas the beta5gamma2HF dimer bound only alphaq. The ability of other alpha subunits to compete with the alphaq subunit for binding to the beta5gamma2HF dimer was tested. Addition of increasing amounts of purified, recombinant alphai1 to the alphaq in a Sf9 cell extract did not decrease the amount of alphaq bound to the beta5gamma2HF column. When G proteins in an extract of brain membranes were activated with GDP and AlF4- and deactivated in the presence of equal amounts of the beta1gamma2HF or beta5gamma2HF dimers, only alphaq bound to the beta5gamma2HF dimer. The alphaq-beta5gamma2HF interaction on the column was functional as GDP, and AlF4- specifically eluted alphaq from the column. These results indicate that although the beta1 and beta2 subunits interact with alpha subunits from the alphai, alphas, and alphaq families, the structurally divergent beta5 subunit only interacts with alphaq.

Subcellular localization of metallothionein IIA in human bladder tumor cells using a novel epitope-specific antiserum.

Human metallothioneins (hMTs) are a family of highly homologous proteins thought to be critical in cellular protection against toxins. The comparative function of individual isoforms is, however, obscure. Antibodies to individual MT isoforms might help clarify this issue but their generation has been challenging. We now describe a strategy that has successfully produced an epitope-specific antiserum to a major human isoform, hMT IIA. The immunogen, a conjugated tridecyl amino acid synthetic peptide unique to residues 8-20 in hMT IIA (AAGDSCTCAGSCK), yielded an antiserum (B2) that reacted specifically with hMT IIA in a concentration- and titer-dependent manner and showed no reactivity with human or rabbit liver MT I or horse MTs. This antiserum recognized rabbit liver MT II and, surprisingly, also reacted weakly with chicken MT. MT amino acid sequence comparisons and peptide blocking studies suggested aspartate-11 and threonine-14 are important antigenic determinants for B2. Using confocal immunofluorescence microscopy and B2 antiserum, we observed nuclear localization of hMT IIA with human bladder T24 tumor cells in exponential growth but more cytoplasmic localization at confluence. These results suggest the subcellular location of hMT IIA is a function of cell density in T24 bladder carcinoma cells. The general approach of epitope-specific antibodies may be useful for the generation of antibodies to other MT isoforms and for studying the role of individual MT isoforms in biology and toxicology.