<HashMap><database>GEO</database><file_versions><headers><Content-Type>application/xml</Content-Type></headers><body><files><Other>ftp://ftp.ncbi.nlm.nih.gov/geo/series/GSE336nnn/GSE336622/</Other></files><type>primary</type></body><statusCode>OK</statusCode><statusCodeValue>200</statusCodeValue></file_versions><scores/><additional><omics_type>Transcriptomics</omics_type><species>Homo sapiens</species><gds_type>Expression profiling by high throughput sequencing</gds_type><full_dataset_link>https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE336622</full_dataset_link><repository>GEO</repository><entry_type>GSE</entry_type></additional><is_claimable>false</is_claimable><name>Trivalent arsenicals enhance UVA-associated genomic instability in human keratinocyte models</name><description>Inorganic arsenic is a well-established human carcinogen strongly associated with non-melanoma skin cancer, yet its interaction with solar radiation remains incompletely understood. Arsenic-related tumors arise preferentially in sun-exposed regions and frequently exhibit mutational patterns associated with oxidative stress rather than classical ultraviolet B signatures, implicating ultraviolet A (UVA) radiation as a potential co-exposure factor. Here, we evaluated the effects of physiologically relevant concentrations of trivalent arsenicals on UVA-associated genomic instability using keratinocyte models differing in p53 status. A multi-endpoint platform integrating comet assay kinetics, micronucleus analysis, Bliss synergy modeling, and transcriptomic profiling was used to characterize combinational responses. Sub-micromolar arsenicals alone produced minimal cytotoxicity and negligible increases in comet-detectable DNA damage. In contrast, co-exposure with UVA significantly increased chromosomal instability, particularly in p53-deficient and p53-mutant cells, despite limited additional comet signal. Repair kinetics demonstrated efficient lesion resolution in primary keratinocytes, whereas monomethylarsonous acid (MMA(III)) selectively impaired repair progression in p53-mutant HaCaT cells. Transcriptomic analysis identified altered expression of replication- and checkpoint-associated pathways in transformed keratinocytes. Across models, micronucleus formation was disproportionately elevated relative to measurable strand-break induction, indicating a dissociation between initial DNA damage and downstream genomic outcomes. Collectively, these findings support a model in which arsenicals enhance UVA-associated genomic instability by altering the processing and persistence of oxidative DNA damage rather than substantially increasing initial lesion burden.</description><dates><publication>2026/06/30</publication></dates><accession>GSE336622</accession><cross_references><GSM>GSM9838900</GSM><GSM>GSM9838901</GSM><GSM>GSM9838902</GSM><GSM>GSM9838903</GSM><GSM>GSM9838896</GSM><GSM>GSM9838897</GSM><GSM>GSM9838898</GSM><GSM>GSM9838899</GSM><GPL>20301</GPL><GSE>336622</GSE><taxon>Homo sapiens</taxon></cross_references></HashMap>