Abstract
Myogenic cells obtained from 12-day-old embryonic chicken hind limb and breast muscle were exposed to 5000 rads of X irradiation. Although 10% of the initial cell dissociates were killed by irradiation, the remaining cells were comparable to controls in plating efficiency and light microscopic morphology. Moreover, there was no increase or loss of cells for at least 72 hr in vitro when plated at a density of 2 × 10 6 cells/60-mm plate. It was found that muscle cell fusion after irradiation proceeded at the same rate and to the same relative extent as in control cultures. Myotubes developed normally; cross-striations were prominent by 5 to 7 days of culture and the cells maintained a well-differentiated state for periods of at least 3 weeks in vitro. In control cultures continuously labeled with 1 μCi/ml of [ 3H]TdR, 75% of the nuclei within myotubes were heavily labeled by 118 hr; less than 15% of the nuclei within syncytia of irradiated cultures were labeled. Quantitative microphotometry of Feulgen-stained cultures demonstrated that all nuclei within control and irradiated myotubes contained the 2C complement of DNA. Similar experiments conducted with cells released from limbs and breasts of 10-day-old embryos revealed lower absolute levels of cytoplasmic fusion in both control and irradiated samples, however, there was slightly more cell death after exposure to X rays in 10-day-old than 12-day-old material. Nevertheless, considerable cell fusion occurred in irradiated limb and breast cell cultures, consistent with the conclusion that the commitment to myogenesis of prefusion myoblasts is extremely stable even in the face of massive ionizing radiation and that neither cell division nor replication of DNA is an obligatory prerequisite for the in vitro fusion and subsequent differentiation of skeletal muscle obtained from 10- and 12-day-old chick embryos.
Published Version
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