Abstract

The overall objective of this proposal is to determine the effect(s) of radiosensitizing hyperthermic treatments on cell nuclear structure and function. In particular we will determine the effect(s) of: 1) acute heating (AH; 43 to 45 degrees); 2) step- down-heating (SDH; AH followed by chronic exposure to 41 degrees); 3) chronic heating at 41 degrees (tolerance development) before X-irradiation; and 4) chronic heating at 41 degrees subsequent to X-irradiation on the induction and/or repair of radiation-induced DNA double strand breaks (dsb), apurinic (AP) sites, DNA protein crosslinks (DPC) and chromosome aberration induction in CHO cells grown in monolayer. The hypothesis we will test is that a hyperthermia-induced increase in the induction frequency, and/or inhibition of repair, of one or more of these radiation-induced DNA lesions correlates with radiosensitization at the cellular level. To date, this hypothesis has not proven generally true in the case of DNA single strand breaks (ssb). The induction frequency and repairability (rate and extent) of radiation-induced lesions (ssb and dsb) in specific DNA sequences will be measured in control and heated cells. Bulk DNA will be isolated by alkaline/neutral filter elution or alkaline sucrose gradient sedimentation from irradiated cells, and cells during the repair of DNA lesions. Bulk DNA collected onto nitrocellulose filters will be probed by filter hybridization against nucleic acid probes for transcriptionally active and/or inert DNA sequences. The possible role heat-induced alterations of nuclear structure and/or composition in the inhibition of DNA damage removal will also be assessed. The kinetics of increase, and removal, of polyeptides in nuclesomal and nunnucleosomal chromatin DNA and in cell nuclear matrices will be determined by exogenous nuclease digestion of DNA, centrifugal isolation of nuclear components and polypeptide quantitation and characterizations by polyacrylamide gel electrophoresis. The extent to which hyperthermic exposure alters the number and/or conformation of nuclear matrix DNA binding sites will be determined by assessing the DNA """"""""domain"""""""" size and frequency in control and heated cells.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA045156-04
Application #
3188182
Study Section
Radiation Study Section (RAD)
Project Start
1987-07-01
Project End
1992-06-30
Budget Start
1990-07-01
Budget End
1991-06-30
Support Year
4
Fiscal Year
1990
Total Cost
Indirect Cost

  Institution

Name
Wake Forest University Health Sciences
Department
Type
Schools of Medicine
DUNS #
041418799
City
Winston-Salem
State
NC
Country
United States
Zip Code
27106

  Publications

Kalia, V K; Al-Nabulsi, I; Wallen, C A et al. (2000) Radiation-induced DNA damage in tumors and normal tissues. VI. Estimation of the hypoxic fraction of experimental tumors. Radiat Res 153:548-56
Xu, L; Tay, C H; Huber, B T et al. (2000) Cloning of an infectious milk-borne mouse mammary tumor virus (MMTV) DNA from a mammary tumor that developed in an endogenous MMTV-free wild mouse. Virology 273:325-32
Al-Nabulsi, I; Wheeler, K T (1999) Radiation-induced DNA damage in tumors and normal tissues: V. Influence of pH and nutrient depletion on the formation of DNA-protein crosslinks in irradiated partially and fully hypoxic tumor cells. Radiat Res 151:188-94
Kalandarishvili, F; Wheeler, K T (1999) Accumulation of DNA damage in pre- and posthepatectomized liver of aged rats. Mech Ageing Dev 110:25-35
Mach, R H; Smith, C R; al-Nabulsi, I et al. (1997) Sigma 2 receptors as potential biomarkers of proliferation in breast cancer. Cancer Res 57:156-61
Al-Nabulsi, I; Wheeler, K T (1997) Temperature dependence of radiation-induced DNA-protein crosslinks formed under hypoxic conditions. Radiat Res 148:568-74
Miyagi, Y; Zhang, H; Wheeler, K T (1997) Radiation-induced DNA damage in tumors and normal tissues: IV. Influence of proliferation status and cell type on the formation of oxygen-dependent DNA damage in cultured cells. Radiat Res 148:29-34
Zhang, H; Wheeler, K T (1996) Influence of topoisomerase II on the formation of oxygen-dependent radiation-induced DNA damage. Br J Cancer Suppl 27:S196-9
Swarts, S G; Smith, G S; Miao, L et al. (1996) Effects of formic acid hydrolysis on the quantitative analysis of radiation-induced DNA base damage products assayed by gas chromatography/mass spectrometry. Radiat Environ Biophys 35:41-53
Zhang, H; Koch, C J; Wallen, C A et al. (1995) Radiation-induced DNA damage in tumors and normal tissues. III. Oxygen dependence of the formation of strand breaks and DNA-protein crosslinks. Radiat Res 142:163-8

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