DNA double-strand breaks (DSBs) arise spontaneously after the conversion of DNA adducts or single-strand breaks by DNA repair or replication and can be introduced experimentally by expression of specific endonucleases. Correct repair of DSBs is central to the maintenance of genomic integrity in mammalian cells, since errors give rise to translocations, deletions, duplications, and expansions, which accelerate the multistep process of tumor progression. For p53 direct regulatory roles in homologous recombination (HR) and in non-homologous end joining (NHEJ) were postulated. To systematically analyze the involvement of p53 in DSB repair, we generated a fluorescence-based assay system with a series of episomal and chromosomally integrated substrates for I-SceI meganuclease-triggered repair. Our data indicate that human wild-type p53, produced either stably or transiently in a p53-negative background, inhibits HR between substrates for conservative HR (cHR) and for gene deletions. NHEJ via microhomologies flanking the I-SceI cleavage site was also downregulated after p53 expression. Interestingly, the p53-dependent downregulation of homology-directed repair was maximal during cHR between sequences with short homologies. Inhibition was minimal during recombination between substrates that support reporter gene reconstitution by HR and NHEJ. p53 with a hotspot mutation at codon 281, 273, 248, 175, or 143 was severely defective in regulating DSB repair (frequencies elevated up to 26-fold). For the transcriptional transactivation-inactive variant p53(138V) a defect became apparent with short homologies only. These results suggest that p53 plays a role in restraining DNA exchange between imperfectly homologous sequences and thereby in suppressing tumorigenic genome rearrangements.In response to DNA damage the tumor suppressor p53 induces a transient cell cycle arrest by transcriptional transactivation of target genes or triggers apoptotic cell death by transcriptional transactivation-dependent and -independent pathways (25). The generation of mice nullizygous for p53 made clear that, in addition, p53 counteracts aneuploidies, allelic losses, sister chromatid exchanges, and gene amplifications (17,28). With respect to the underlying mechanism, a direct participation of p53 in DNA repair was proposed. This was due to biochemical observations that revealed activities of p53 in the recognition of DNA damage, in DNA reannealing, and in exonucleolytic DNA degradation (1). p53 also binds to a plethora of repair-related proteins. The meaning of most of these interactions is not yet clear. Thus, uncertainties exist, whether p53 participates in nucleotide excision repair by modulating TFIIH activities (12, 32, 48) or rather counteracts sister chromatic exchanges after UV irradiation (7, 17).More convincingly, several groups unanimously reported on 5-to Ͼ100-fold rate increases of spontaneous inter-and intrachromosomal homologous recombination (HR), when wildtype p53 (wtp53) was inactivated genetically or by interactions with viral ...
Immunotherapeutic treatment strategies for glioblastoma (GBM) are under investigation in clinical trials. However, our understanding of the immune phenotype of GBM-infiltrating T cells (tumor-infiltrating lymphocytes; TILs) and changes during disease progression is limited. Deeper insight is urgently needed to therapeutically overcome tumor-induced immune exhaustion. We used flow cytometry and cytokine assays to profile TILs and peripheral blood lymphocytes (PBLs) from patients with GBM, comparing newly diagnosed or recurrent GBM to long-term survivors (LTS) and healthy donors. TCR sequencing was performed on paired samples of newly diagnosed and recurrent GBM. We identified a clear immune signature of exhaustion and clonal restriction in the TILs of patients with GBM. Exhaustion of CD8 TILs was defined by an increased prevalence of PD-1, CD39, Tim-3, CD45RO, HLA-DR marker expression, and exhibition of an effector-/transitional memory differentiation phenotype, whereas KLRG1 and CD57 were underrepresented. Immune signatures were similar in primary and recurrent tumors; however, restricted TCR repertoire clonality and a more activated memory phenotype were observed in TILs from recurrent tumors. Moreover, a reduced cytokine response to PHA stimulation in the blood compartment indicates a dysfunctional peripheral T-cell response in patients with GBM. LTS displayed a distinct profile, with abundant naïve and less exhausted CD8 T cells. TILs and PBLs exhibit contrasting immune profiles, with a distinct exhaustion signature present in TILs. While the exhaustion profiles of primary and recurrent GBM are comparable, TCR sequencing demonstrated a contracted repertoire in recurrent GBM, concomitant with an increased frequency of activated memory T cells in recurrent tumors. .
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