Radiation dosimetry and repair kinetics of DNA damage foci in mouse pachytene spermatocyte and round spermatid stages.

Accurate quantification of DNA double strand breaks (DSB) in testicular germ cells is difficult because of cellular heterogeneity and the presence of endogenous γH2AX. Here, we used confocal microscopy to quantify DNA damage and repair kinetics following γ-irradiation (0.5-4 Gy) in three major mouse male germ cell stages, early and late pachytene spermatocytes and round spermatids (RSs), following a defined post irradiation time course. Dose-response curves showing linear best fit validated γH2AX focus as a rapid biodosimetric tool in these substages in response to whole body in vivo exposure. Stage specific foci yield/dose and repair kinetics demonstrated differential radiosensitivity and repair efficiency: early pachytenes (EP) repaired most rapidly and completely followed by late pachytene (LP) and RSs. Repair kinetics for all three stages followed 'exponential decay' in response to each radiation dose. In pachytenes immediate colocalisation of γH2AX and 53BP1, which participates in non-homologous end-joining repair pathway, was followed by dissociation from the major focal area of γH2AX by 4 h demonstrating ongoing DSB repair. These results confirm the differential radiosensitivity and repair kinetics of DSBs in male germ cells at different stages. Taken together, our results provide a simple and accurate method for assessing DNA damage and repair kinetics during spermatogenesis.

Dynamics of radiation induced γH2AX foci in chromatin subcompartments of mouse pachytene spermatocytes and round spermatids.

Chromatin compaction is thought to influence the severity of radiation-induced DNA damage. We assessed how chromatin state affects DNA double-strand break repair within eu-/heterochromatin domains in male germ cells by profiling the spatiotemporal dynamics of γ-radiation-induced γH2AX foci in confocal images of mouse pachytene spermatocytes and round spermatids (5 min to 16 hr post-irradiation, in vivo). In unirradiated cells, all DNA-dense heterochromatin domains showed compaction by anti-H3K9me3-staining, except for peripheral areas. Following irradiation, this signal was lost within 5 min, but regained later (8-16 hr); these two events coincided with the appearance and loss of γH2AX foci, respectively. While euchromatin showed a large number of bright foci in both cell types, heterochromatin had few foci. In spermatids, a few small, faint foci appeared within chromocenters. Pachytene-stage, on the other hand, lacked foci within heterochromatin, although a few were closely associated with the heterochromatin periphery. The number of euchromatin foci in spermatids showed a dose-dependent enhancement following irradiation (0.5-4 Gy), although no significant increase was seen in the quantity of heterochromatin foci. While all foci in pachytene-stage cells were resolved, spermatids showed large residual foci-especially from heterochromatin foci, which remained faint for up to 4 hr, then increased in size between 8-16 hr, expanding at the chromocenter periphery and eventually protruding into euchromatin at H3K9me3-signal-free areas. Thus, this study identified scant foci formation and poor repair within heterochromatin, with distinctly different dynamics in meiotic and post-meiotic stages of spermatogenesis, and provides direct evidence for heterochromatin decompaction following DNA damage, which facilitates repair/repositioning of foci towards euchromatin domains. It is the first demonstration of spatiotemporal mobilization of double-strand breaks with respect to chromatin subdomains in male germ cells.

Homologous recombination-mediated double-strand break repair in mouse testicular extracts and comparison with different germ cell stages.

Homologous recombination (HR) is established as a significant contributor to double-strand break (DSB) repair in mammalian somatic cells; however, its role in mammalian germ cells has not been characterized, although being conservative in nature it is anticipated to be the major pathway in germ cells. The germ cell system has inherent limitations by which intact cell approaches are not feasible. The present study, therefore, investigates HR-mediated DSB repair in mouse germ cell extracts by using an in vitro plasmid recombination assay based on functional rescue of a neomycin (neo) gene. A significantly high-fold increase in neo+ (Kan(R)) colonies following incubation of two plasmid substrates (neo delta1 and neo delta2) with testicular extracts demonstrated the extracts' ability to catalyze intermolecular recombination. A significant enhancement in recombinants upon linearization of one of the plasmids suggested the existence of an HR-mediated DSB repair activity. Comparison of the activity at sequential developmental stages, spermatogonia, spermatocytes and spermatids revealed its presence at all the stages; spermatocyte being the most proficient stage. Further, restriction analysis of recombinant plasmids indicated the predominance of gene conversion in enriched spermatocytes (mostly pachytenes), in contrast to gonial and spermatid extracts that showed higher reciprocal exchange. In conclusion, this study demonstrates HR repair activity at all stages of male germ cells, suggesting an important role of HR-mediated DSB repair during mammalian spermatogenesis. Further, the observed preference of gene conversion over reciprocal exchange at spermatocyte stage correlates with the close association of gene conversion with the meiotic recombination program.

Nonhomologous end joining of complementary and noncomplementary DNA termini in mouse testicular extracts.

Mammalian somatic cells are known to repair DNA double-strand breaks (DSBs) by nonhomologous end joining (NHEJ) and homologous recombination (HR); however, how male germ cells repair DSBs is not yet characterized. We have previously reported the highly efficient and mostly precise DSB joining ability of mouse testicular germ cell extracts for cohesive and blunt ends, with only a minor fraction undergoing terminal deletion [Mutat. Res. 433 (1999) 1]; however, the precise mechanism of joining was not established. In the present study, we therefore tested the ability of testicular extracts to join noncomplementary ends; we have also sequenced the junctions of both complementary and noncomplementary termini and established the joining mechanisms. While a major proportion of complementary and blunt ends were joined by simple ligation, the small fraction having noncleavable junctions predominantly utilized short stretches of direct repeat homology with limited end processing. For noncomplementary ends, the major mechanism was "blunt-end ligation" subsequent to "fill-in" or "blunting", with no insertions or large deletions; the microhomology-dependent joining with end deletion was less frequent. This is the first functional study of the NHEJ mechanism in mammalian male germ cell extracts. Our results demonstrate that testicular germ cell extracts promote predominantly accurate NHEJ for cohesive ends and very efficient blunt-end ligation, perhaps to preserve the genomic sequence with minimum possible alteration. Further, we demonstrate the ability of the extracts to catalyze in vitro plasmid homologous recombination, which suggests the existence of both NHEJ and HR pathways in germ cells.