Theserum deprivation responsegene (SDPR,aliassdr) has been previously isolated for its high mRNA expression in serum-starved cells compared to contact-inhibited NIH3T3 cells; such regulation is not ...observed in single-oncogene transformed NIH3T3 cells after serum starvation. More recently Sdpr has been identified as a substrate of protein kinase C (PKC): this interaction determines the compartimentalization of PKC to caveolae, a plasma membrane invagination of which Sdpr is a major component. Lack of Sdpr–PKC interaction in transformed cells has been proposed to be involved in the alteration of PKC subcellular localization and substrate specificity. Here we report the cloning of the humanSDPRhomologue (HGMW-approved symbolSDPR) and its mapping to 2q32–q33 in the human genome. In analogy with the murine system,SDPRmRNA expression is increased when human fibroblasts are serum starved, it becomes down-regulated during synchronous cell-cycle reentry, but it is not induced in cells arrested by contact inhibition. Analysis ofSDPRexpression in human tissues reveals a near ubiquitous expression, with highest levels found in heart and lung. We show that humanSDPRencodes PS-p68, a previously characterized phosphatidylserine-binding protein purified from human platelets. Accordingly, recombinant Sdpr is able to specifically bind phosphatidylserine in the absence of Ca2+.SDPRis homologous to two genes in the databank, one of which,srbc,is similarly regulated during growth arrest and encodes a phosphatidylserine-binding protein that is a substrate of PKC.
The serum deprivation response gene (SDPR, alias sdr) has been previously isolated for its high mRNA expression in serum-starved cells compared to contact-inhibited NIH3T3 cells; such regulation is ...not observed in single-oncogene transformed NIH3T3 cells after serum starvation. More recently Sdpr has been identified as a substrate of protein kinase C (PKC): this interaction determines the compartimentalization of PKC to caveolae, a plasma membrane invagination of which Sdpr is a major component. Lack of Sdpr-PKC interaction in transformed cells has been proposed to be involved in the alteration of PKC subcellular localization and substrate specificity. Here we report the cloning of the human SDPR homologue (HGMW-approved symbol SDPR) and its mapping to 2q32-q33 in the human genome. In analogy with the murine system, SDPR mRNA expression is increased when human fibroblasts are serum starved, it becomes down-regulated during synchronous cell-cycle reentry, but it is not induced in cells arrested by contact inhibition. Analysis of SDPR expression in human tissues reveals a near ubiquitous expression, with highest levels found in heart and lung. We show that human SDPR encodes PS-p68, a previously characterized phosphatidylserine-binding protein purified from human platelets. Accordingly, recombinant Sdpr is able to specifically bind phosphatidylserine in the absence of Ca2+. SDPR is homologous to two genes in the databank, one of which, srbc, is similarly regulated during growth arrest and encodes a phosphatidylserine-binding protein that is a substrate of PKC.
The product of the c-myc proto-oncogene is an important regulator of cell proliferation and apoptosis in murine fibroblasts. Addition of the tumor promoter, phorbol myristate acetate (PMA), prevents ...apoptotic cell death induced by low serum concentrations in NIH3T3 cells that constitutively express and are transformed by v-myc. The protective effect of PMA allowed us to analyse the ability of normal c-Myc and Myc deletion mutants to induce serum starved, untransformed NIH3T3 cells to enter S phase. By microinjecting these quiescent cells with wild type and mutant human c-myc plasmids, we showed that full length c-myc is able to induce S phase entry in presence of PMA, but that c-Myc mutants that delete amino acids delta 7/91, delta 41/53, delta 56/103, delta 106/143, delta 265/317 and delta 414/433 are totally inactive. c-Myc did not shorten the period before entry into S phase, since Myc overexpressing cells entered S phase with the same kinetics as control cells when both were stimulated with 20% fetal calf serum (FCS). However, c-Myc overexpression did increase the percentage of cells entering S phase when these cells were stimulated with 2% fetal calf serum. Interestingly, this ability to enhance stimulation by a suboptimal concentration of FCS was retained to a significant degree by Myc mutants that delete amino acids delta 41/53, delta 56/103 or delta 265/317. Finally, Myc mutants that delete delta 106/143 or delta 414/433 exerted a dominant negative effect on S phase entry both in quiescent cells stimulated with 2% FCS and in unsynchronized, cycling cells.