Project description:We use a human whole genome microarray to analyze the effects of nanosecond pulsed electric fields on Jurkat cells with the focus on early response genes to DNA damage. Keywords: nanosecond pulsed electric fields, jurkat cells, DNA damage

Project description:Catheter ablation is an effective treatment to prevent recurrence of Atrial fibrillation (AF) and can be used to maintain sinus rhythm and improve symptoms of AF, but to some extent it can cause a range of adverse effects associated with catheter ablation. Pulsed electric field is a newer treatment modality to replace catheter ablation for atrial fibrillation due to its fewer side effects. Different from radiofrequency ablation, which destroys diseased myocardial tissue by thermal energy, pulsed electric field ablation achieves the purpose of atrial fibrillation ablation by inducing damage to diseased myocardial cells through irreversible electroporation. However, some experimental parameters and mechanism of pulsed electric fields remain unclear.

Project description:Gene expression induced by Nanosecond pulsed electric fields

Project description:Effects of Ultra-short Pulsed Electric Fields exposure on Glioblastoma Cells

Project description:The scarcity of effective treatment options for high grade brain tumours has led to a wide ranging search for alternative means of therapy for these difficult to treat tumours. Electrical field therapy is one such area that has been considered. The OptuneTM system is an FDA approved novel anti-mitotic device that delivers continuous alternating electric fields to the patient for the treatment of primary and recurrent Glioblastoma multiforme (GBM) (tumor treating fields - TTFields). Alternative electric fields delivery systems are also being investigated for the treatment of various cancers.To further explore alternative potential mechanisms of electric fields as a whole, we ran Optune, DBS electric fields treated and control untreated KNS42, U87 and GIN-31 (primary) cell lines on Clariom S Human Assays to produce genome-wide expression data.

Project description:The NRF2 transcription factor is a key regulator of the cellular antioxidant response, and pharmacological NRF2 activation is a promising strategy for the prevention of age-related diseases. Here we show, however, that genetic activation of Nrf2 in skin fibroblasts leads to the production of a matrisome, which is similar to aged skin and characterized by reduced synthesis and deposition of selected matrix proteins, including the major skin collagens. Mechanistically, the production of an aging matrisome results from Nrf2-mediated overexpression of microRNAs (miRs), which directly suppress collagen expression independently of myofibroblast differentiation. This is functionally important, as Nrf2 activation in fibroblasts caused structural abnormalities of the dermal ECM and increased the susceptibility to skin tearing, similar to aged skin. Activation of endogenous NRF2 was observed in human skin from elderly individuals in vitro and in vivo. These data implicate a key role for activated NRF2 in controlling age-related molecular and biomechanical skin alterations.

Project description:Skin aging is a physiological problem that remains a concern. Studies have demonstrated that the dermal extracellular matrix (ECM) plays important roles in skin aging; however, changes in ECM characteristics and molecules that are secreted to the extracellular space and involved in the formation of dermal matrix from birth to aging remain unclear. Furthermore, it is not understood how the ECM microenvironment supports the functions of skin development across different age groups. We used a decellularization method and matrisome analysis to compare the composition, expression, and function of the dermal ECM in neonate, teenage, adult, and elderly skin. We found that the collagens, glycoproteins, proteoglycans, and regulatory factors that support skin development and function together with these core ECM proteins were differentially expressed at different ages. We also identified ECM expression markers during the process of skin development. Our results systematically revealed the characteristics of ECM synthesis, response to growth factors, water conservation, anti-oxidation, and the ability of the ECM to support epidermal stem cell growth via the basement membrane in young skin, as well as the characteristics of response to wound repair and fungal invasion in aging skin.

Project description:Electroporation is a versatile method for in vitro or in vivo delivery of different molecules into cells. However, no study so far has analysed the effects of electric pulses used in electrochemotherapy (ECT pulses) or electric pulses used in electrogene therapy (EGT pulses) on malignant cells. We studied the effect of ECT and EGT pulses in human malignant melanoma cells in vitro in order to understand and predict possible effect of electric pulses on gene expression and their possible effect on cell behaviour. We used microarrays with 2698 different oligonucleotides to obtain expression profile of genes involved in apoptosis and development of cancer in a malignant melanoma cell line (SK-MEL28) exposed to ECT pulses and EGT pulses. Cells exposed to ECT pulses showed 68.8% average survival rate and 31.4% average survival rate in cells exposed to EGT pulses. Only seven common genes were found differentially expressed in cells 16 h after exposure to ECT and EGT pulses. We found that ECT and EGT pulses induce HSP70 stress response mechanism, repress histone protein H4, a major protein involved in chromatin assembly, and down-regulate components involved in protein synthesis. Our results show that electroporation does not significantly change expression profile of major tumour suppressor genes or oncogenes of cell cycle. Moreover, electroporation also does not changes the expression of genes involved in stability of DNA, supporting the current evidence that electroporation is a safe method that does not promote tumorigenesis. However, in spite of being considered an isothermal method it does to some extent induce stress that resulted in expression of environmental stress response mechanism, HSP70.

Project description:Electroporation is a versatile method for in vitro or in vivo delivery of different molecules into cells. However, no study so far has analysed the effects of electric pulses used in electrochemotherapy (ECT pulses) or electric pulses used in electrogene therapy (EGT pulses) on malignant cells. We studied the effect of ECT and EGT pulses in human malignant melanoma cells in vitro in order to understand and predict possible effect of electric pulses on gene expression and their possible effect on cell behaviour. We used microarrays with 2698 different oligonucleotides to obtain expression profile of genes involved in apoptosis and development of cancer in a malignant melanoma cell line (SK-MEL28) exposed to ECT pulses and EGT pulses. Cells exposed to ECT pulses showed 68.8% average survival rate and 31.4% average survival rate in cells exposed to EGT pulses. Only seven common genes were found differentially expressed in cells 16 h after exposure to ECT and EGT pulses. We found that ECT and EGT pulses induce HSP70 stress response mechanism, repress histone protein H4, a major protein involved in chromatin assembly, and down-regulate components involved in protein synthesis. Our results show that electroporation does not significantly change expression profile of major tumour suppressor genes or oncogenes of cell cycle. Moreover, electroporation also does not changes the expression of genes involved in stability of DNA, supporting the current evidence that electroporation is a safe method that does not promote tumorigenesis. However, in spite of being considered an isothermal method it does to some extent induce stress that resulted in expression of environmental stress response mechanism, HSP70. The difference in expression of genes involved in development of cancer was obtained by comparison of malignant melanoma cells exposed to EGT or ECT pulses against the same untreated malignant melanoma cells. In our experimental design, microarrays with 2698 different genes were used as a dual colour system in which exposed and non-exposed cells’ mRNA were separately labelled, mixed and hybridised together on each array. Only microarrays expressing at least 50% of genes were used for further analysis. All oligonucleotides on the same array were spotted in quadruplicates and each microarray analysis was performed in duplicates, therefore obtaining eight measurements of the same oligonucleotide. The acquired data were analysed with Acuity 4.0 to select reliable signals. Only genes, present in both duplicated microarrays were considered for further processing.

Project description:In the last few years, pulsed electric fields have emerged as promising clinical tools for tumor treatments. This study highlights the distinct impact of a specific pulsed electric field protocol named PEF-5 (0.3 MV/m, 40 µs, 5 pulses) on astrocytes (NHA), medulloblastoma (D283) and gli-oblastoma (U87 NS) cancer stem-like cells. We pursued this goal performing ultrastructural analyses corroborated by molecular/omics approaches to understand the vulnerability or re-sistance mechanisms triggered by PEF-5 exposure in the different cell types. Electron microscopic analyses showed that, independently of exposed cells, the main targets of PEF-5 were the cell membrane and the cytoskeleton, presenting indiscriminate filopodia disappearance on the cell surface accompanied by a rapid cell swelling. Nevertheless, cells activated different responses stemming from intracellular organelles. NHA triggered a protective mechanism to recover from the damaged membranes and eliminated the detrimental ROS to maintain cell vital functions. Conversely, PEF-5 induced a different action on mitochondria of cancer stem-like cells, more prominent on D283 compared to U87 NS cells, in correlation with a higher basal level of CD133 protein in D283 cells. In this case, a complete mitochondrial dysfunction was demonstrated, inhibiting the recovery of D283 vital processes, while a mild perturbation was observed in mito-chondria of U87 NS cells, not sufficient to impair their cell functions. Altogether, these results suggest the possibility to use PEF-based technology as a novel strategy to target selectively mi-tochondria of CSCs, preserving healthy cells. Ultrastructural analysis, supported by transcriptomic characterization in microsecond pulsed electric field exposed normal brain and brain tumor cells