UV irradiation of normal or immortalized cells induces a rapid increase in the expression of several transcription factors and is thought to serve a protective function. The human fibrosarcoma cell line, HT1080 clone H4, expresses almost undetectable levels of Egr-1 and does not respond to UV-C irradiation by the induction of Egr-1. The H4 cells are hypersensitive to UV which induces apoptosis and reduces clonogenicity. The introduction of exogenous Egr-1 into H4 (H4E9 and H4E4 cell-lines) confers protection from UV damage as measured by a number of assays. In both NIH3T3 (with inducible Egr-1) and H4E9 (constitutive Egr-1) cells, UV irradiation gave enhanced transactivation of Egr-1 reporters that correlated with phosphorylated Egr-1. Studies using inhibitors indicated that protein kinase-C and tyrosine kinases are involved in the anti-apoptotic effects of Egr-1 after UV damage. This is the first description of a biological effect of phosphorylated Egr-1.
The PTEN tumor suppressor phosphatase directly counteracts the multiple functions of phosphatidylinositol 3-kinase by removing phosphate from the D3 position of inositol phospholipids. Like many lymphomas and leukemias, the Jurkat T cell line lacks PTEN protein due to frame-shift mutations in both PTEN alleles and therefore survives in long-term cell culture. We report that PTEN reintroduced into Jurkat was highly phosphorylated on serines 380 and 385 in its C terminus, particularly the former site. Phosphate was also detected at Ser380 in PTEN in untransformed human T cells. Treatments that reduced the levels of D3-phospholipids in the cells resulted in reduced phosphorylation and accelerated degradation of PTEN. In contrast, expression of inactive PTEN-C124G or coexpression of a constitutively active protein kinase B led to increased phosphorylation and slower degradation of PTEN. These results suggest that PTEN normally is subjected to a feedback mechanism of regulation aimed at maintaining homeostatic levels of D3-phosphoinositides, which are crucial for T cell survival and activation.
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