Growth-responsive expression from the murine thymidine kinase promoter: genetic analysis of DNA sequences.

As a first step toward elucidating the biochemical basis of gene regulation at the G1-S boundary of the cell cycle, we have identified regions of the murine thymidine kinase (TK) promoter sufficient to confer appropriately growth-responsive expression to a heterologous gene. Using a series of TK promoter-chloramphenicol acetyltransferase (CAT) gene fusion constructs, we have identified sequences located between -174 base pairs upstream and +159 base pairs downstream of the TK translation initiation site that are sufficient to drive efficient S phase-specific expression of the CAT reporter gene in transfected murine fibroblasts. Both deletion analysis and site-specific mutagenesis experiments indicated that an Sp1 consensus binding site is critical to the activity of this promoter. Synchronized populations of BALB/c 3T3 cells stably transfected with either TK promoter-CAT fusion constructs or TK promoter-beta-globin fusion constructs expressed their respective reporter genes in an S phase-specific manner following serum stimulation. In each case, reporter gene expression was reduced during quiescence and G1 and rose upon entry of cells into S phase. The TK sequences included in these constructs therefore contained information sufficient to confer S phase-specific regulation to these two reporter genes. These results set the stage for a more detailed analysis of the sequences and trans-acting factors responsible for regulating murine TK gene expression and may lead to insights into the control of proliferation in normal and transformed cells.

Identification and characterization of X-ray-induced proteins in human cells.

In order to investigate the biochemical events involved in potentially lethal DNA damage repair (PLDR), we have identified a pleiotropic protein expression response that is activated upon X-irradiation of confluence-arrested human malignant melanoma (U1-Mel) cells. Plateau-phase U1-Mel cells were selected because of their extraordinary capacity for PLDR. Eight major X-ray-induced polypeptides (XIPs) of Mr 126,000-275,000 (i.e., XIP126 through XIP275) were detected by resolving L-[35S]methionine-labeled whole cell extracts using two-dimensional gel electrophoresis. XIPs were found in unirradiated, proliferating U1-Mel cells, shut off under plateau-phase conditions and resynthesized in response to X-irradiation. The expression of three classes of proteins was affected by X-irradiation. Class I proteins, XIP145 and XIP269, were induced linearly with increasing X-ray doses. The rate of synthesis of class II proteins, XIP126, XIP135, XIP138, XIP141, XIP147, and XIP275, increased linearly with low X-irradiation doses, but plateaued at doses of 150-250 cGy. In contrast, the expression of class III proteins, 47,000 and 254,000 Mr proteins, decreased with increasing X-ray doses. Tumor, cancer-prone, and normal human cells, which represent a wide range of cells with varied repair capacities, were investigated to better understand the role of XIPs in DNA damage responses. X-irradiated normal and tumor cells induced the synthesis of XIP145 and XIP269. A strong correlation between the induction of XIP269 and PLDR capacity, as measured by delayed plating of plateau-phase cells, was noted. XIP269 was present in six of seven normal and tumor cells types, but was completely absent in cells from patients with Bloom's syndrome and ataxia telangiectasia. X-irradiated Fanconi's anemia and xeroderma pigmentosum cells synthesized low levels of XIP269. The majority of XIPs synthesized by X-irradiated cells from cancer-prone patients were of low molecular weights. A number of XIP expression characteristics suggest their role in either gross chromosomal PLDR and/or in X-ray adaptivity responses: (a) XIP expression was inhibited by 1 microgram/ml cycloheximide, a dose which decreased survival 6-fold during PLDR holding and resulted in greater than 80% inhibition of protein synthesis; (b) XIP expression was specific for ionizing radiation damage, since heat shock, hypoxia, and alkylating agents failed to induce their synthesis; (c) the time course of expression was long, with the first appearance of XIPs at 3 h and maximal expression at 4 h.