Transforming G protein-coupled receptors transduce potent mitogenic signals in NIH 3T3 cells independent on cAMP inhibition or conventional protein kinase C.

We have used the expression of human acetylcholine muscarinic receptor (mAChR) genes in NIH 3T3 cells as a model for dissecting the molecular basis of cellular transformation induced by G protein-coupled receptors. Those mAChR subtypes efficiently coupled to PIP2 hydrolysis (m1, m3 and m5) induced agonist-dependent cell transformation whereas those inhibiting adenylyl cyclase (m2, m4) lack transforming activity. In the present study, we demonstrate that in cells expressing m1 but not m2 mAChRs the cholinergic agonist (carbachol) is alone as potent a stimulant for DNA synthesis as platelet-derived growth factor (PDGF) or serum. Furthermore, induction of DNA synthesis is shown to correlate with activation of PIP2 hydrolysis but not with inhibition of adenylyl cyclase. We also examined the role of protein kinase C (PKC) in mitogenic signalling through m1 mAChRs, and found that NIH 3T3 cells express PKC-alpha and PCK-zeta as the only conventional or Ca(2+)-independent PKC isozyme, respectively. Prolonged treatment with TPA depleted cells of PKC-alpha but not of PKC-zeta. In TPA-treated NIH 3T3 cells, the mitogenic response to a subsequent stimulation with TPA was absolutely abolished, but the response to PDGF or serum was not. Moreover, PKC depletion did not decrease DNA synthesis induced by carbachol. We conclude that carbachol potently induces reinitiation of DNA synthesis through the activation of transforming mAChR subtypes, independently of inhibition of adenylyl cyclase and conventional PKCs.

Measurement of DNA-protein crosslinks in mammalian cells without X-irradiation.

To study the mechanisms of formation and repair of DNA-protein crosslinks in mammalian cells, the best general method to assay these lesions is the Kohn membrane alkaline elution procedure. Use of this sensitive technique requires the introduction of random strand breaks in the DNA by X-irradiation to reduce the very high molecular weight so that it elutes off the filter at an appropriate rate. This report describes an alternative method for fragmenting the DNA in the absence of X-irradiation equipment. Convenient reproducible elution rates of DNA from various mouse and human cells in culture without X-irradiation result from elution through polyvinyl chloride filters with 75 mM sodium hydroxide (0.33 ml/min) instead of the standard 20 mM EDTA-tetrapropylammonium hydroxide, pH 12.2 (0.03 to 0.04 ml/min). Dose-dependent retardation of the DNA elution was observed over the range 0 to 30 microM trans-platinum(II)diamminedichloride, and proteinase K treatment during cell lysis restored the elution rate to that of the untreated control cell DNA. In the absence of X-irradiation, this elution method measures DNA-protein crosslinks with higher sensitivity and equivalent reproducibility as the air-burst procedure.

Repair of DNA-protein cross-links in an excision repair-deficient human cell line and its simian virus 40-transformed derivative.

DNA-protein cross-links are induced in mammalian cells by X-rays, ultraviolet light, fluorescent light, and numerous chemical carcinogens. Others have shown that these cross-links are repaired by normal cells but that excision repair-deficient xeroderma pigmentosum (XP) Group A cells, XP12BE, are deficient in repair of these bulky adducts. This paper compares the DNA-protein cross-link repair competency of another XP Group A strain, XP20S, with its more rapidly proliferating simian virus 40-transformed derivative line and with normal human skin fibroblasts. DNA-protein cross-links were induced with 20 microM transplatinum(II)diamminedichloride and assayed by the membrane alkaline elution procedure of Kohn. Treated and untreated cells are lysed on a polycarbonate membrane filter, and the coelution rates of the DNA at pH 12.2 are compared; DNA-protein cross-links retard elution of DNA. The repair competency of XP20S cells for trans-platinum(II)diamminedichloride-induced DNA-protein cross-links was similar to that of XP12BE cells, but the competency of the simian virus 40-transformed XP20S cells was nearly equal to that of normal human skin fibroblasts. These results suggest that either cell cycling compensates for the genetic deficiency present in the nucleotide excision process of XP Group A cells or that a process other than nucleotide excision can repair these lesions; this process requires cell cycling or activation by the virus.

Effect of visible light on benzo(a)pyrene binding to DNA of cultured human skin epithelial cells.

The ubiquity of the photosensitive carcinogen benzo(a)pyrene (BP) and visible light in the environment suggests that their interaction might lead to photoproducts harmful to humans. To test the combined impact of these two agents on human epithelial cells, binding of BP to cellular DNA was assessed following treatment of cultures with BP and low-intensity (4.6 watts/sq m) intermittent (12 hr daily, 3 to 5 days) cool white fluorescent light. Light exposure reduced the formation of covalent BP adducts 20-fold (from 150 to 7 pmol BP per mg DNA) in cells treated with 1 microgram BP per ml and completely inhibited cytotoxicity; even with 10 microgram BP per ml, light exposure markedly inhibited cytotoxicity. However, at low BP dosage (0.1 microgram/ml), covalent adducts (2 pmol/mg DNA) to cellular DNA are produced and their formation is not influenced by light. These adducts persisted for at least 7 days following treatment; this observation suggests that chronic low-level exposure of human epithelium to BP may lead to an accumulation of DNA damage.

Visible light-induced DNA crosslinks in cultured mouse and human cells.

Cool-white fluorescent light induces crosslinks in DNA when proliferating cells are exposed at 37 degrees C for 20 h to 4.6 J/m2/s in culture medium supplemented with fetal bovine serum. Using the Kohn alkaline elution technique, we now find that: 1. Increased light intensity increases DNA crosslinks. 2. The crosslinking is medium-mediated. 3. Oxygen enhances the crosslinking. 4. The extent of crosslinking is decreased at high cell density. 5. The crosslinks can be removed by digestion with proteinase K (0.02 to 0.50 mg/ml). 6. Human cell lines including those derived from adult prostate, fetal lung (IMR-90) and mixed fetal tissues are susceptible to light-induced crosslinks. 7. Crosslinkage is not decreased by addition of catalase to the medium and the effective wavelength is probably between 450 nm and 490 nm. From these results we conclude that the mechanism of light-induced crosslinks differs from that of light-induced chromatid breaks and that the major lesion observed is protein-DNA cross-linkage rather than DNA strand breaks.