Abstract

On the basis of paradigms in development wherein discrete transcriptional events are pivotal regulatory steps, we tested the hypothesis that transcriptional sodium (Na+)-response mechanisms are involved in in vivo Na+-induced responses relevant to normal (homeostatic) and pathophysiological (salt-sensitive hypertension) conditions. We used Na,K-ATPase alpha-subunit genes as molecular probes and the Na+ ionophore monensin to induce a dose-specific incremental increase in [Na+]i in rat A10 embryonic aortic smooth muscle cells. RNA blot analysis of rat A10 cells revealed a dose-specific (0.022 to 30 micromol/L monensin) upregulation of alpha1-, alpha2-, and beta1-subunit Na,K-ATPase RNA levels. Control beta-actin and alpha-tropomyosin RNA levels did not change. With the use of chloramphenicol acetyltransferase (CAT) as reporter gene, CAT assays of rat alpha1[-1288]CAT and human alpha2[-798]CAT promoter constructs exhibited induction of CAT activity in monensin (10 micromol/L)-treated A10 cells compared with untreated A10 cells. Promoter deletion constructs for rat alpha1[-1288]CAT defined a positive Na+-response regulatory region within -358 to -169 that is distinct from the basal transcriptional activation region of -155 to -49 previously defined. Similarly, a positive Na+-response regulatory region is delimited to within -301 in the human alpha2 Na,K-ATPase 5' flanking region. Analysis of transgenic TgH alpha2[-798]CAT rats demonstrated sodium activation of human alpha2[-798]CAT transgene expression in aorta parallel to observations made in rat A10 aortic tissue culture cells. Southwestern blot analysis of nuclear extracts from monensin (10 micromol/L)-treated and control untreated A10 cells revealed a nuclear DNA binding protein (approximately 95 kD) that is upregulated by increased [Na+]i. These data provide initial characterization of a transcriptional Na+-response mechanism delimiting a positive Na+-response regulatory region in two target genes (alpha1 and alpha2 Na,K-ATPase) as well as detection of a Na+-response nuclear DNA binding protein. The in vitro data are corroborated by in vivo experimental and transgenic promoter expression studies, thus validating the biological relevance of the observations.