Increasing evidence supports a role for PKC␣ in growth arrest and tumor suppression in the intestinal epithelium. In contrast, the Id1 transcriptional repressor has pro-proliferative and tumorigenic properties in this tissue. Here, we identify Id1 as a novel target of PKC␣ signaling. Using a highly specific antibody and a combined morphological/biochemical approach, we establish that Id1 is a nuclear protein restricted to proliferating intestinal crypt cells. A relationship between PKC␣ and Id1 was supported by the demonstration that (a) down-regulation of Id1 at the crypt/villus junction coincides with PKC␣ activation, and (b) loss of PKC␣ in intestinal tumors is associated with increased levels of nuclear Id1. Manipulation of PKC␣ activity in IEC-18 nontransformed intestinal crypt cells determined that PKC␣ suppresses Id1 mRNA and protein via an Erk-dependent mechanism. PKC␣, but not PKC␦, also inhibited Id1 expression in colon cancer cells. Id1 was found to regulate cyclin D1 levels in IEC-18 and colon cancer cells, pointing to a role for Id1 suppression in the antiproliferative/tumor suppressive activities of PKC␣. Notably, Id1 expression was elevated in the intestinal epithelium of PKC␣-knock-out mice, confirming that PKC␣ regulates Id1 in vivo. A wider role for PKC␣ in control of inhibitor of DNA binding factors is supported by its ability to downregulate Id2 and Id3 in IEC-18 cells, although their suppression is more modest than that of Id1. This study provides the first demonstrated link between a specific PKC isozyme and inhibitor of DNA binding factors, and it points to a role for a PKC␣ 3 Erk ٜ Id1 3 cyclin D1 signaling axis in the maintenance of intestinal homeostasis.The intestinal epithelium is a continually self-renewing tissue, organized into well defined proliferative and functional compartments (1). Maintenance of tissue integrity relies on tight control of the balance between proliferative activity, differentiation, and apoptosis. Both positive and negative growth regulatory signaling pathways have been implicated in orchestrating the renewal process in this tissue, and disruption of these pathways and/or their downstream targets results in various diseases, including cancer. Increasing evidence points to the PKC enzyme system as a key regulator of intestinal homeostasis (2-6). PKC is a family of phospholipid-dependent serine-threonine kinases, consisting of at least 10 isozymes that act as central players in signal transduction. Members of the family can have tumor promoting (e.g. PKCII, -⑀, and -) or tumor suppressive (e.g. PKC␣ and -␦) activity, dependent on the isozyme and tissue context (2,5,7,8). Although several PKC isozymes have been implicated in the regulation of intestinal homeostasis (e.g. PKC␣, -II, -␦, -⑀, and -), increasing evidence points to PKC␣ as a key negative regulator of proliferation and tumorigenesis in this tissue (4, 9, 10).PKC␣ is activated precisely at the point of growth arrest in the crypts of both the small intestine and colon (11, 12). Consistent with a role i...
