Mycoplasma DnaK expression increases cancer development in vivo upon DNA damage.
Francesca BenedettiGiovannino SilvestriFrank DenaroGiovanni FinessoRafael Contreras-GalindoArshi MunawwarSumiko WilliamsHarry DavisJoseph BryantYin WangEnrico RadaelliChozha V RathinamRobert C GalloDavide ZellaPublished in: Proceedings of the National Academy of Sciences of the United States of America (2024)
Well-controlled repair mechanisms are involved in the maintenance of genomic stability, and their failure can precipitate DNA abnormalities and elevate tumor risk. In addition, the tumor microenvironment, enriched with factors inducing oxidative stress and affecting cell cycle checkpoints, intensifies DNA damage when repair pathways falter. Recent research has unveiled associations between certain bacteria, including Mycoplasmas , and various cancers, and the causative mechanism(s) are under active investigation. We previously showed that Mycoplasma fermentans DnaK, an HSP70 family chaperone protein, hampers the activity of proteins like PARP1 and p53, crucial for genomic integrity. Moreover, our analysis of its interactome in human cancer cell lines revealed DnaK's engagement with several components of DNA-repair machinery. Finally, in vivo experiments performed in our laboratory using a DnaK knock-in mouse model generated by our group demonstrated that DnaK exposure led to increased DNA copy number variants, indicative of genomic instability. We present here evidence that expression of DnaK is linked to increased i) incidence of tumors in vivo upon exposure to urethane, a DNA damaging agent; ii) spontaneous DNA damage ex vivo; and iii) expression of proinflammatory cytokines ex vivo, variations in reactive oxygen species levels, and increased β-galactosidase activity across tissues. Moreover, DnaK was associated with increased centromeric instability. Overall, these findings highlight the significance of Mycoplasma DnaK in the etiology of cancer and other genetic disorders providing a promising target for prevention, diagnostics, and therapeutics.
Keyphrases
- dna damage
- copy number
- dna repair
- oxidative stress
- mitochondrial dna
- papillary thyroid
- cell cycle
- poor prognosis
- genome wide
- mouse model
- squamous cell
- reactive oxygen species
- cell proliferation
- heat shock protein
- dna damage response
- dna methylation
- heat shock
- binding protein
- induced pluripotent stem cells
- squamous cell carcinoma
- gene expression
- social media
- small molecule
- single cell
- induced apoptosis