Hedgehog signaling enables repair of ribosomal DNA double-strand breaks.

Ribosomal DNA (rDNA) consists of highly repeated sequences that are prone to incurring damage. Delays or failure of rDNA double-strand break (DSB) repair are deleterious, and can lead to rDNA transcriptional arrest, chromosomal translocations, genomic losses, and cell death. Here, we show that the zinc-finger transcription factor GLI1, a terminal effector of the Hedgehog (Hh) pathway, is required for the repair of rDNA DSBs. We found that GLI1 is activated in triple-negative breast cancer cells in response to ionizing radiation (IR) and localizes to rDNA sequences in response to both global DSBs generated by IR and site-specific DSBs in rDNA. Inhibiting GLI1 interferes with rDNA DSB repair and impacts RNA polymerase I activity and cell viability. Our findings tie Hh signaling to rDNA repair and this heretofore unknown function may be critically important in proliferating cancer cells.

[Changes induced by low doses of ionizing radiation in the accessibility to DNA restriction enzymes of the ribosomal gene system of human lymphocytes]. / Izmeneniia dostupnosti fermentam restriktsii DNK sistemy ribosomnykh genov limfotsitov cheloveka, indutsirovannye malymi dozami ioniziruiushchego izlucheniia.

Human lymphocytes were X-irradiated at doses 0-10(-2) Gy and allowed to repair for some time. Nuclei were prepared and digested with restriction endonuclease Rsa I to selectively release 28S RNA gene fragment fraction, containing the DNA-binding protein, Hpa II digestion of nuclei was used to investigate the methylation of the 28S RNA gene fragment. There was a differential enrichment of 28S RNA gene binding protein for different X-ray doses with maximum enrichment for dose 2-3 x 10(-2) Gy with following diminish to 10 x 10(-2). The enrichment of less methylated fractions of 28S RNA gene was observed during X-irradiation. This might be explained by a different X-ray-induced changes of methylated and unmethylated rDNA binding with nuclear proteins. The possible mechanism for this phenomena are discussed.

Strand breaks are repaired efficiently in human ribosomal genes.

We examined repair of DNA strand breaks induced by the anti-cancer drug bleomycin in both Pol I and Pol II transcribed genes in permeabilized human fibroblasts. The majority of these breaks (>80%) are single strand breaks (SSBs) thought to be repaired by base excision repair enzymes. Repair was examined in each strand of a 7. 2-kilobase fragment, completely within the Pol I transcribed region of ribosomal DNA (rDNA) and an 8.3-kilobase fragment completely within the Pol II transcribed region of the dihydrofolate reductase (DHFR) gene. Bleomycin dose-response studies revealed no bias for SSBs in either strand of the rDNA fragment. Furthermore, repair of SSBs is rapid (approximately 80% resealed in 60 min) in both the transcribed and nontranscribed strands of rDNA. Rapid repair of SSBs is also observed in both strands of the DHFR gene (approximately 60% resealed in 60 min). In contrast, little (or no) repair of UV photodimers occurs in either strand of human rDNA, regardless of whether cells are confluent or actively growing. Thus, DNA lesions in human ribosomal genes may be more accessible to base excision repair enzymes than those involved in nucleotide excision repair.

Rapid conversion of rDNA intergenic spacer of diploid mutants of rice derived from gamma-ray irradiated tetraploids.

The organization of tandemly repeated sequences of ribosomal DNA (rDNA) in rice mutants derived from gamma-irradiated tetraploids was analyzed. Southern hybridization analysis of nuclear DNA revealed that most of the intergenic spacers (IGSs) in mutant rDNA are replaced concertedly by new molecular species. The new IGSs are produced by the amplification of a subrepeat of about 250 bp. Results obtained from sequence analyses indicate that various intermediate molecular species of the subrepeat were formed during structuring of the IGS region and that many rearrangements occurred between them. These findings demonstrate the effectiveness of recurrent irradiation of tetraploids for inducing artificial genome rearrangement, and also indicate the extreme plasticity and variability of genome structure in plants.

Lack of transcription-coupled repair in mammalian ribosomal RNA genes.

We studied the induction and removal of UV-induced cyclobutane pyrimidine dimers (CPDs) in the ribosomal RNA genes (rDNA) in cultured hamster and human cells. In these genes, which are transcribed by RNA polymerase I, we found no evidence for transcription-coupled repair. The induction of CPDs was heterogeneous in rDNA due to nucleotide sequence: it was lower on the transcribed strand than on the nontranscribed strand and slightly lower in the coding region than in the nontranscribed spacer. Nevertheless, no dramatic difference in CPD induction was observed between rDNA and the dihydrofolate reductase (DHFR) gene. In Chinese hamster ovary cells, we observed no removal of CPDs from either rDNA strand within 24 h after UV irradiation. In these experiments, we did observe efficient repair of the transcribed, but not the nontranscribed, strand of the DHFR gene, in agreement with published results. In human cells, repair of rDNA was observed, but it showed no strand preference and was slower than that reported for the genome overall. No significant differences in repair were observed between restriction fragments from transcribed and nontranscribed regions or between growth-arrested and proliferating human cells, with presumably different levels of transcription of rDNA. We conclude that the modest level of rDNA repair is accomplished by a transcription-independent repair system and that repair is impeded by the nucleolar compartmentalization of rDNA. We discuss the possibility that recombination, rather than repair, maintains the normal sequence of rDNA in mammalian cells.

Characterization of a protein binding sequence in the promoter region of the 16S rRNA gene of the spinach chloroplast genome.

By means of mobility-shift assays and Exonuclease III mapping we have determined a 14 bp sequence (named CDF2 binding site) located in front of the 16S rRNA initiation start site which is protected by a spinach chloroplast extract. This region does not include neither one of the two '-35' nor of the two '-10' E. coli-like promoter elements which are recognised by E. coli RNA polymerase in vitro. The CDF2 binding site is specifically recognized by two small polypeptides which migrate corresponding to 35 and 33 kDa respectively as shown by UV cross-linking experiments. In vivo transcription initiation of the 16S rRNA gene occurs 13 nucleotides downstream of the 14 bp sequence and is different from the transcription start site which is used by E.coli polymerase in vitro.