Topoisomerase deficiencies subtly enhance global genomic repair of ultraviolet-induced DNA damage in Saccharomyces cerevisiae

Structural integrity of centromeric chromatin and faithful chromosome segregation requires Pat1

The kinetochore (centromeric DNA and associated protein complex) is essential for faithful chromosome segregation and maintenance of genome stability. Here we report that an evolutionarily conserved protein Pat1 is a structural component of Saccharomyces cerevisiae kinetochore and associates with centromeres in a NDC10-dependent manner. Consistent with a role for Pat1 in kinetochore structure and function, a deletion of PAT1 results in delay in sister chromatid separation, errors in chromosome segregation, and defects in structural integrity of centromeric chromatin. Pat1 is involved in topological regulation of minichromosomes as altered patterns of DNA supercoiling were observed in pat1Δ cells. Studies with pat1 alleles uncovered an evolutionarily conserved region within the central domain of Pat1 that is required for its association with centromeres, sister chromatid separation, and faithful chromosome segregation. Taken together, our data have uncovered a novel role for Pat1 in maintaining the structural integrity of centromeric chromatin to facilitate faithful chromosome segregation and proper kinetochore function.

Baicalin modulates microRNA expression in UVB irradiated mouse skin

This study aimed to evaluate the effects of baicalin on ultraviolet radiation B (UVB)-mediated microRNA (miRNA) expression in mouse skin. We determined miRNA expression profiles in UVB irradiated mice, baicalin treated irradiated mice, and untreated mice, and conducted TargetScan and Gene Ontology analyses to predict miRNA targets. Three miRNAs (mmu-miR-125a-5p, mmu-miR-146a, and mmu-miR-141) were downregulated and another three (mmu-miR-188-5p, mmu-miR-223 and mmu-miR-22) were upregulated in UVB irradiated mice compared with untreated mice. Additionally, these miRNAs were predicted to be related to photocarcinogenesis, hypomethylation and apoptosis. Three miRNAs (mmu-miR-378, mmu-miR-199a-3p and mmu-miR-181b) were downregulated and one (mmu-miR-23a) was upregulated in baicalin treated mice compared with UVB irradiated mice, and they were predicted to be related to DNA repair signaling pathway. These deregulated miRNAs are potentially involved in the pathogenesis of photodamage, and may aid treatment and prevention of UVB-induced dermatoses.

Repeated small perturbation approach reveals transcriptomic steady states

The study of biological systems dynamics requires elucidation of the transitions of steady states. A "small perturbation" approach can provide important information on the "steady state" of a biological system. In our experiments, small perturbations were generated by applying a series of repeating small doses of ultraviolet radiation to a human keratinocyte cell line, HaCaT. The biological response was assessed by monitoring the gene expression profiles using cDNA microarrays. Repeated small doses (10 J/m2) of ultraviolet B (UVB) exposure modulated the expression profiles of two groups of genes in opposite directions. The genes that were up-regulated have functions mainly associated with anti-proliferation/anti-mitogenesis/apoptosis, and the genes that were down-regulated were mainly related to proliferation/mitogenesis/anti-apoptosis. For both groups of genes, repetition of the small doses of UVB caused an immediate response followed by relaxation between successive small perturbations. This cyclic pattern was suppressed when large doses (233 or 582.5 J/m2) of UVB were applied. Our method and results contribute to a foundation for computational systems biology, which implicitly uses the concept of steady state.

Lethal and mutagenic interactions between γ-rays, cisplatin and etoposide at the cellular and molecular levels

PURPOSE

We analysed the lethal and mutagenic interactions between γ-rays, cisplatin (Pt) and etoposide (E), three agents used in tumour chemoradiotherapy. Corresponding results at cellular and molecular levels could provide additional elements on involved mechanisms and, on antitumour activity and toxicity in combined cancer treatments.

MATERIALS AND METHODS

The yeast Saccharomyces cerevisiae SC7K(lys2-3) (auxotrophic for lysine) was used as eukaryotic model. Exponential growing cells were exposed to the mentioned agents, as single and combined treatments. Lethal and mutation interaction equations were determined as a function of doses according to quantitative models. DNA double-strand breaks were evaluated immediately after treatments, through pulsed-field electrophoresis and laser densitometry.

RESULTS

All three agents induced significant mutant frequency. The γ +Pt + E combination determined maximal lethal and mutagenic synergism, followed by γ + Pt and γ + E combinations. Meanwhile, Pt + E combination showed lethal additivity and very low mutagenic synergism. Pt + E double combination determined moderate DNA degradation. DNA degradation after γ-exposure, was similar to that of γ + Pt, γ + E and γ + Pt + E combinations.

CONCLUSIONS

Synergistic lethal and mutagenic interactions indicate crosstalk between non-homologous end joining, homologous recombination and postreplicative repair pathways. Pt + E additivity indicate independence of involved repair pathways. Furthermore, the quantification of interactive events may be an additional suitable tool in tumour therapy planning.

Microarray analysis of microRNA expression in skin of Xpc⁺/⁻ mice and wild-type mice

BACKGROUND AND AIM

MicroRNAs (miRNAs) are noncoding RNA molecules of 21-24 nt that regulate the expression of target genes in a post-transcriptional manner. Evidence indicates that miRNAs play essential roles in embryogenesis, cell differentiation, and pathogenesis of human diseases including skin cancer. To investigate possible mechanisms of photocarcinogenesis, we describe a comparison between miRNA expression profile of Xpc heterozygous partially repair-deficient mice and WT repair-proficient mice.

METHODS

We analyzed the miRNA expression profiles in 2 pairs of Xpc(+/-) mice and WT mice, using a mammalian miRNA microarray containing whole mice mature and precursor miRNA sequences. MiRBase and GO analysis were employed for the prediction of miRNA targets.

RESULTS

A total of 20 miRNAs were differentially expressed in which 13 miRNAs down-regulated and 7 miRNAs up-regulated in Xpc heterozygous mice compared with the WT counterpart. Differentially expressed miRNAs were predicted to have some relationships with several signaling pathway in skin cells, of which regulation of epidermal growth factor receptor signaling pathway and transforming growth factor beta receptor signaling pathway should be noted.

CONCLUSION

The differential miRNA expression identified in this study may be of use in the diagnosis and/or treatment of UV-induced skin cancers.

TOP2 gene disruption reduces drug susceptibility by increasing intracellular ergosterol biosynthesis in Candida albicans

In this study the role of the TOP2 gene in fungal drug susceptibility was investigated by disrupting and overexpressing the gene in Candida albicans. MIC determination and a spot assay showed that a top2Delta/Delta null mutant (strain T2bc) was more resistant to the antifungals tested than the wild-type (strain CAI4). Real-time RT-PCR and rhodamine 6G efflux examination showed that TOP2 did not influence the activity of drug efflux pumps. Sterol analysis with GC/high-resolution MS indicated that the intracellular ergosterol composition of the top2Delta/Delta mutant was significantly increased. Subsequently, fluorescence polarization measurements also revealed that Top2-deprived cells displayed a decrease in membrane fluidity, resulting in enhanced passive diffusion of the drugs. Quantitative real-time RT-PCR analysis further confirmed that the ERG11 gene, an essential gene in ergosterol biosynthesis, was upregulated. These results demonstrate a close relationship between the TOP2 gene and drug susceptibility in C. albicans.

The RAD9-dependent gene trans-activation is required for excision repair of active genes but not for repair of non-transcribed DNA

The Saccharomyces cerevisiae RAD9 and RAD24 are two cell cycle checkpoint genes required for UV-dependent up-regulation of a battery of genes involved in different metabolic pathways. RAD9 is also implicated in nucleotide excision repair (NER); however, its precise role is still unclear. For the present study, we made use of the high-resolution primer extension technique to show that the RAD9-deleted cells are deficient in the repair of both strands of the URA3 gene. Interestingly, this defect was suppressed by over-expressing the RAD24 gene, suggesting that the role of RAD9 in NER is indirect probably through the UV-dependent trans-activation of some NER factors. Accordingly, we present evidence that the inhibition of UV-related de novo protein synthesis by cycloheximide has no effect on the rad9Delta mutant while it suppresses the correcting effect of RAD24 over-expression. Importantly, we have also shown that RAD9 has no role in repair of transcriptionally inactive DNA sequences (URA3 promoter and transcriptionally silent GAL10 gene). Furthermore, de novo protein synthesis was not required for NER in the absence of transcription-coupled NER. This implies that RAD9-dependent gene up-regulation is required for NER only when this process is coupled to transcription.