Detection, significance, and mechanism of sister chromatid exchange formation: past experiments, current concepts, future challenges

Analysis of sister-chromatid exchanges

Two requirements for the cytogenetic analysis of sister-chromatid exchanges (SCEs) in somatic cells are (1) a population of actively proliferating cells that will provide an adequate number of metaphases and (2) sister chromatids that in some way are differentially labeled or stained in the metaphases. SCEs can be recognized as abrupt discontinuities in the staining patterns of the two chromatids of a metaphase chromosome at what appear to be identical sites, with reciprocal switching from one chromatid to its sister. This protocol uses phytohemagglutinin (PHA)-stimulated cultures of blood lymphocytes as a source of proliferating cells. The cells are incubated with the thymidine analog BrdU. Slides prepared from fixed cells with BrdU-substituted chromosomes are treated with Hoechst 33258, exposed to light and heat, and then Giemsa-stained to produce differentially stained chromosomes. The chromatids with bifilar substitution exhibit a lighter purple stain than their unifilarly substituted sister chromatids.

Induction of cytogenetic damage in human lymphocytes in vitro and of antineoplastic effects in Ehrlich ascites tumor cells in vivo treated by methotrexate, hyperthermia and/or caffeine

The synergistic effect of methotrexate (at concentrations between 3. 1 and 100 nM) and its combinations with caffeine (618 microM) and/or hyperthermia (42 degreesC for 2 h) on the frequency of sister chromatid exchanges (SCEs), the proliferating rate index and the mitotic index in cultured human lymphocytes, was examined. Also, the in vivo antineoplastic effects of methotrexate (at a concentration of 0.45 microg/g body weight) and its combination with caffeine (120 microg/g body weight), both on the survival time and the increase of the weight of tumor of BALB/c mice inoculated with Ehrlich ascites tumor cells was examined in the present study. The results indicated that: (a) the triple combination of methotrexate, caffeine and hyperthermia synergistically increased the levels of SCEs and exerted cytostatic and cytotoxic action and (b) the combination of methotrexate and caffeine significantly increased the survival span of the mice inoculated with Ehrlich ascites tumor cells and reduced the increase of the weight of their tumors at rates higher than in the case of methotrexate by itself. It is suggested that the above triple combination (methotrexate plus caffeine plus hyperthermia) could achieve increased effectiveness of methotrexate, better therapy results, and could be successfully applied in the treatment of various types of cancer.

Sister chromatid exchange in methotrexate resistant and sensitive C3H10T1/2 mouse cells

Sister chromatid exchange (SCE) induction by methotrexate (MTX) was analyzed in C3H10T1/2 clone 8 mouse cells and in two MTX-resistant subclones with numerous double minute chromosomes (DM) present in the majority of cells. Significantly higher SCE levels were found, as expected, in sensitive cells after treatments with 10(-2) or 10(-5) M MTX but not in resistant cells permanently growing in the presence of a high concentration of MTX (2 x 10(-3) M) and characterized by a markedly lower cell cycle replication index (R.I.), i.e. in conditions that are known to otherwise favour SCE induction. These observations suggest, for the MTX-resistant cells under study, the existence of conditions limiting SCE formation.

Cytological, flow cytometric, and molecular analysis of the rapid evolution of mammalian chromosomes containing highly amplified DNA sequences

Transfection of a mouse dihydrofolate reductase (DHFR) cDNA contained in a plasmid "expression vector" into DHFR deficient Chinese hamster cells, followed by progressive selection of cells in increasing concentrations of methotrexate (MTX), leads to marked amplification of the exogenous DHFR sequences in the recipient hamster cells. This gene amplification is evident at the cytological level, in the form of homogeneously staining chromosomal regions (HSRs), at a gene expression level, in the form of fluorescein-methotrexate binding, and at the DNA level. Flow sorting, based on variable fluorescein-MTX binding, or direct cellular cloning, followed by chromosome analysis, revealed intercellular heterogeneity of HSRs in size and distribution. This suggested that there was a rapid evolution of HSRs in MTX-resistant transfectants. Chromosomal analysis of HSR evolution in situ, by examining individual colonies presumably derived from one or a few cells, underscored this impression of chromosome structural fluidity. Rates of HSR change in excess of 0.01 per cell division, increased by low doses of the recombinogen, mitomycin C, were detected. The Chinese hamster DHFR transfectants described should be amenable to detailed, coordinate cytological and molecular characterization. Such an analysis should contribute to an understanding of processes such as homologous recombination in mediating HSR evolution in mammalian chromosomes.