Abstract
Effects of Ca2+ and hormones on short-term protein synthesis were examined utilizing intact Ca2+-depleted and Ca2+-restored GH3 pituitary tumor cells as a model system. Amino acid incorporation by cells in complete growth medium during short incubations was markedly reduced by EGTA concentrations in excess of Ca2+. Thyrotropin-releasing hormone (TRH) rapidly enhanced amino acid incorporation and prolactin production, with both effects being reserved by EGTA in excess of extracellular Ca2+ or prevented by cellular Ca2+ depletion. Epidermal growth factor and phorbol myristate acetate (PMA) also stimulated amino acid incorporation and prolactin production; absolute increases in protein synthesis provided by these agents were significantly greater in Ca2+-restored than in Ca2+-depleted preparations. TRH and PMA concentrations which raised prolactin production were identical to those increasing the rate of amino acid incorporation into overall protein. The extracellular Ca2+ concentration dependencies of amino acid incorporation and prolactin production were similar and were unchanged by hormone. PMA, the most efficacious of the agents tested, and Ca2+ promoted incorporation of amino acid into the same spectrum of proteins. Stimulation of protein synthesis by hormones was not attributable to alterations in amino acid uptake, attachment to substrata, hormone binding, protein catabolism or transcription. Trifluoperazine selectively prevented the stimulation by Ca2+ of amino acid incorporation and prolactin production. Unlike total prolactin, the total protein content of GH3 cells during these short incubations was not altered by Ca2+, hormones or trifluoperazine. It is proposed that hormones and Ca2+, which have been demonstrated to regulate prolactin secretion and prolactin mRNA transcription in GH3 cells, also exert translational controls which serve to facilitate the overall expression of the prolactin gene.
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