Sequentially-induced responses define tumour cell radiosensitivity.

Purpose: Our aim was to define dose-dependent and genotype-dependent components of radiosensitivity by resolving patterns of radiation-induced clonal inactivation into specific responses.

Methods: In a set of 10 tumour cells with varying expression of radiosensitivity and genotype, we identified doses at which all tumour cells change in their rate of clonogenic inactivation. We tested intervening dose-segments as to whether inactivation was constant, expressing inactivation as a log-linear function of dose.

Tumor response to radiotherapy is dependent on genotype-associated mechanisms in vitro and in vivo.

Background: We have previously shown that in vitro radiosensitivity of human tumor cells segregate non-randomly into a limited number of groups. Each group associates with a specific genotype. However we have also shown that abrogation of a single gene (p21) in a human tumor cell unexpectedly sensitized xenograft tumors comprised of these cells to radiotherapy while not affecting in vitro cellular radiosensitivity.

Overview of radiosensitivity of human tumor cells to low-dose-rate irradiation.

Purpose: We compared clonogenic survival in 27 human tumor cell lines that vary in genotype after low-dose-rate (LDR) or high-dose rate (HDR) irradiation. We measured susceptibility to LDR-induced redistribution in the cell cycle in eight of these cell lines.

Methods And Materials: We measured clonogenic survival after up to 96 hours of LDR (0.

A quantitative overview of radiosensitivity of human tumor cells across histological type and TP53 status.

Purpose: We have previously shown in a limited number of tumor cell lines derived from only two histological types that clonogenic survival patterns fall into radiosensitivity groups, each group associating with a specific genotype. We now establish a global, quantitative description of human tumor cells based on genotype-dependent radiosensitivity across histological types.

Methods: We measure clonogenic radiosensitivity in 39 human tumor cell lines that vary in histological type (colorectal, glioblastoma, prostate, bladder, teratoma, breast, melanoma and liver) and expression of several genes purported to influence radiosensitivity: ATM (ataxia telangiectasia mutated), TP53 (tumor protein 53), CDKN1A (cyclin-dependent kinase N1A), 14-3-3sigma (an isoform of the 14-3-3 gene) and DNA mismatch repair genes .

Genotype-dependent radiosensitivity: clonogenic survival, apoptosis and cell-cycle redistribution.

Purpose: We describe variations of three radiation-induced endpoints on the basis of cell genotype: Clonogenic survival, expression of apoptosis and cell-cycle redistribution.

Methods: Clonogenic survival, apoptosis and cell-cycle redistribution are measured in multiple cell lines after exposure to radiation between 2 and 16 Gy. Cell lines varied in clonogenic radiosensitivity and expression of specific genes.

Human tumor cells segregate into radiosensitivity groups that associate with ATM and TP53 status.

We seek to determine whether cellular radiosensitivity in nineteen human colorectal tumor cell lines and three human glioblastoma tumor cell lines segregate into statistically distinct groups and whether such groups correlate with gene expression. We measure clonogenic survival in 22 cell lines that vary in radiosensitivity and in expression of selected genes: ATM, TP53, CDKN1A, 14-3-3sigma, Ki-ras and DNA mismatch repair genes. We describe and compare radiosensitivity in these cell lines by one-parameter or two parameter analysis.

Time-targeted therapy (TTT): proof of principle using doxorubicin and radiation in a cultured cell system.

We test the hypothesis that a pulse of the anti-cancer agent doxorubicin renders cells more sensitive to ionizing radiation in a strongly time-specific, dose-specific manner. We have treated cultured cells from a human tumor line, HepG2, with graded doses of two agents: doxorubicin (Dox) and ionizing radiation (XR), delivered in sequence-specific, time-specific, dose-specific patterns. We observe a strong increase in cell killing, up to 120 fold, between pulsed treatment with Dox followed exactly 4 hours later with acute XR.