A novel 3D skin explant model to study anaerobic bacterial infection

Skin infection studies are often limited by financial and ethical constraints, and alternatives, such as monolayer cell culture, do not reflect many cellular processes limiting their application. For a more functional replacement, 3D skin culture models offer many advantages such as the maintenance of the tissue structure and the cell types present in the host environment. A 3D skin culture model can be set up using tissues acquired from surgical procedures or post slaughter, making it a cost effective and attractive alternative to animal experimentation. The majority of 3D culture models have been established for aerobic pathogens, but currently there are no models for anaerobic skin infections. Footrot is an anaerobic bacterial infection which affects the ovine interdigital skin causing a substantial animal welfare and financial impact worldwide. Dichelobacter nodosus is a Gram-negative anaerobic bacterium and the causative agent of footrot. The mechanism of infection and host immune response to D. nodosus is poorly understood. Here we present a novel 3D skin ex vivo model to study anaerobic bacterial infections using ovine skin explants infected with D. nodosus. Our results demonstrate that D. nodosus can invade the skin explant, and that altered expression of key inflammatory markers could be quantified in the culture media. The viability of explants was assessed by tissue integrity (histopathological features) and cell death (DNA fragmentation) over 76 h showing the model was stable for 28 h. D. nodosus was quantified in all infected skin explants by qPCR and the bacterium was visualized invading the epidermis by Fluorescent in situ Hybridization. Measurement of pro-inflammatory cytokines/chemokines in the culture media revealed that the explants released IL1β in response to bacteria. In contrast, levels of CXCL8 production were no different to mock-infected explants. The 3D skin model realistically simulates the interdigital skin and has demonstrated that D. nodosus invades the skin and triggered an early cellular inflammatory response to this bacterium. This novel model is the first of its kind for investigating an anaerobic bacterial infection

A distinct bacterial dysbiosis associated skin inflammation in ovine footrot

Ovine footrot is a highly prevalent bacterial disease caused by Dichelobacter nodosus and characterised by the separation of the hoof horn from the underlying skin. The role of innate immune molecules and other bacterial communities in the development of footrot lesions remains unclear. This study shows a significant association between the high expression of IL1β and high D. nodosus load in footrot samples. Investigation of the microbial population identified distinct bacterial populations in the different disease stages and also depending on the level of inflammation. Treponema (34%), Mycoplasma (29%) and Porphyromonas (15%) were the most abundant genera associated with high levels of inflammation in footrot. In contrast, Acinetobacter (25%), Corynebacteria (17%) and Flavobacterium (17%) were the most abundant genera associated with high levels of inflammation in healthy feet. This demonstrates for the first time there is a distinct microbial community associated with footrot and high cytokine expression

Arsenic Induces Human Keratinocyte Apoptosis by the FAS/FAS Ligand Pathway, Which Correlates with Alterations in Nuclear Factor-κB and Activator Protein-1 Activity

Epidemiologic studies demonstrated that long-term exposure to arsenic induces arsenical skin cancers, including Bowen's disease. Immunohistochemically, Bowen's disease shows proliferating and apoptotic characteristics. The transcription factors nuclear factor-κB (NF-κB) and activator protein-1 (AP-1) functionally regulate cell proliferation, transformation, and apoptosis. To investigate the mechanism of arsenic-induced apoptosis and related alterations in NF-κB and AP-1 activity, we exposed cultured human foreskin keratinocytes to different concentrations of sodium arsenite. At lower concentrations (≤1 μM), arsenic induced keratinocyte proliferation and enhanced both NF-κB and AP-1 activity. At higher concentrations (≥5 μM), arsenic induced keratinocyte apoptosis by the Fas/Fas ligand (FasL) pathway. At apoptosis induction concentrations, NF-κB activity was not enhanced; however, AP-1 activity was further enhanced. These results indicated that upregulation of NF-κB at lower arsenic concentrations was correlated with keratinocyte proliferation. In contrast, higher concentrations of arsenic enhanced AP-1 and induced Fas/FasL-associated apoptosis. The concentration-dependent arsenic effects on transcription factors activity can help to clarify the mechanisms in arsenic-induced proliferation and apoptosis in keratinocytes