Browsing by Author "Lunec, Joseph"

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    The effect of oxidation on the stability of G-quadruplex DNA : implications for oncogene expression
    (Cranfield University, 2011-10) Stebbeds, William Joshua David; Larcombe, Lee; Lunec, Joseph
    G-quadruplexes (G4-DNA) are a class of secondary structures formed from Guanine rich sequences. In recent years these structures have been implicated in both telomere maintenance and oncogene expression, and have been shown to be abundant in upstream promoter regions and at telomeric ends. The mutagenic properties of oxidative stress on DNA have been widely studied, as has the association with carcinogenesis. The oxidation of deoxyguanosine to 8-oxo-2’deoxyguanosine (8-oxo-dG) is the most common result when DNA is under oxidative stress and as such, the G-rich sequences that form G-quadruplexes can be viewed as potential “hot-spots” for DNA oxidation. We propose that oxidation may destabilise the G-quadruplex structure, leading to its unfolding into the duplex structure, affecting gene expression. This would imply a possible mechanism by which oxidation may impact on oncogene expression. This project used both in silico and in vitro methods to observe the effect of oxidation on the G-quadruplex structure and the consequences in oncogene expression, using two biologically relevant G-quadruplex structures, those found in the promoter regions of the proto-oncogenes c-Myc and c-Kit as proof of concept. Molecular dynamics (MD) simulations were performed (isothermic, isobaric 500ns unrestrained simulation in explicit solvent and counterions) on the c-Kit and c-Myc G-quadruplex structures with and without 8-oxo-dG incorporated into the central tetrad. FRET experiments were performed on these same structures, observing the conformation of sequences known to form G-quadruplexes under near physiological conditions and subjected to oxidative stress, through Fenton chemistry. Gene expression data analyses were also performed to evaluate the prevalence of different G-quadruplex forming motifs (GQMs) in genes affected by oxidation.Although no relevant information was gained from the FRET experiments, the MD results constitute the longest simulations of this type performed on the c-Myc and c-Kit G-quadruplex structures published to date and predict the high stability of these structures under normal physiological conditions. They also clearly demonstrate a destabilising effect of oxidation on G-quadruplex structures, with the extent of the effect dependent on the structure oxidised. Furthermore, gene expression data analysis showed that genes whose expression is significantly altered when subjected to oxidative stress are statisticallymore likely to contain a GQM than the remainder of the genome, through the use of significance testing. These findings demonstrate a differential effect of oxidation on G-quadruplexes, likely dependent on other known characteristics affecting G4 stability such as loop length and sequence. Results also point towards this mechanism affecting gene expression. This is suggestive of a novel route for oxidation mediated carcinogenesis, through upregulation of oncogene expression or possibly downregulation of tumour suppression genes.
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    An in silico study of the differential effect of oxidation on two biologically relevant G-quadruplexes: Possible implications in oncogene expression
    (PLOS (Public Library of Science), 2012-08-22T00:00:00Z) Stebbeds, William Joshua David; Lunec, Joseph; Larcombe, L. D.
    G-quadruplex structures, formed from guanine rich sequences, have previously been shown to be involved in various physiological processes including cancer-related gene expression. Furthermore, G-quadruplexes have been found in several oncogene promoter regions, and have been shown to play a role in the regulation of gene expression. The mutagenic properties of oxidative stress on DNA have been widely studied, as has the association with carcinogenesis. Guanine is the most susceptible nucleotide to oxidation, and as such, G-rich sequences that form G-quadruplexes can be viewed as potential "hot-spots" for DNA oxidation. We propose that oxidation may destabilise the G-quadruplex structure, leading to its unfolding into the duplex structure, affecting gene expression. This would imply a possible mechanism by which oxidation may impact on oncogene expression. This work investigates the effect of oxidation on two biologically relevant G-quadruplex structures through 500 ns molecular dynamics simulations on those found in the promoter regions of the c-Kit and c-Myc oncogenes. The results show oxidation having a detrimental effect on stability of the structure, substantially destabilising the c-Kit quadruplex, and with a more attenuated effect on the c-Myc quadruplex. Results are suggestive of a novel route for oxidation-mediated oncogenesis and may have wider implications for genome stability.
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    Toxicity evaluation and medical application of multi-walled carbon nanotubes
    (Cranfield University, 2015-01) Zhou, Lulu; Ge, Yi; Lunec, Joseph
    Carbon nanotubes (CNTs) are of special interest to industry and they have been increasingly utilised as advanced nanovectors in drug/gene delivery systems. They possess significant advantages including high surface area, welldefined morphologies, unique optical property, superior mechanical strength and thermal conductivity. However, despite their unique and advanced physicochemical properties, the low compatibility of some of those materials [e.g. multiwalled CNTs (MWCNTs)] in most biological and chemical environments has also generated some serious health and environment concerns. Chemical functionalization broadens CNT applications, conferring new functions, and at the same time was found potentially altering toxicity. Although considerable experimental data related to functionalised CNT toxicity, at the molecular and cellular levels, have been reported, there is very limited information available for the corresponding mechanism involved (e.g. cell apoptosis, genotoxicity. The toxicity of carbon nanotubes has been confirmed on many cell lines including A549 (lung cancer cell line) and MRC-5 (lung fibroblasts). However, the sensitivity of each cell line in terms of cellular morphology, apoptosis and DNA damage are still unknown. In this report the different levels of cellular response to oxidative stress and phagocytosis have been investigated in A549, MCF-7 and MRC-5 cell lines to better understand the mechanisms of the toxicity pathway. siRNA as an ideal personalized therapeutics can specifically regulate gene expression, but efficient delivery of siRNA is difficult while it has been shown that MWCNTs protect siRNA, facilitate entry into cells. In this study, we comprehensively evaluated the in vitro cytotoxicity of pristine and functionalized (-OH, -COOH) multi-wall carbon nanotubes (MWCNTs), via cell viability test, reactive oxygen species (ROS) generation test, cell apoptosis and DNA mutation detection, to investigate the non-toxic dose and influence of functional group in A549, MCF-7 and MRC-5 cells exposed to 1-1000 μg/mL MWCNTs from 6 to 72 hours. In addition, 84 toxicity related genes have been detected to investigate the change of RNA regulation after treatment with MWCNTs. The research findings suggest that functionalized MWCNTs are more genotoxic compared to their pristine form, and the level of both dose and dispersion in the matrix used should be taken into consideration before applying further clinical applications of MWCNTs. Among all three cell lines, MCF-7 was the most sensitive to cell death and DNA damage induced by pristine carbon nanotubes. The majority of MCF-7 cell death was in necrotic. In A549 cells, apoptosis played a notable role in cytotoxicity. MRC-5 didn’t show significant cell loss or membrane damage, which might be explained by its low cell growth rate, notably however, a great reduction of the F-actin and attachment points was observed after treatment which indicates that MRC-5 cells are under very unhealthy condition and less attached to the bottom of flasks. Despite their toxicity, which is still being researched, carbon nanotubes have a great potential in clinical medicine. Thus, understanding the sensitivity of different cell lines could offer a more individualized approach for future treatment regimes. In regards to gene delivery, MWCNTs were found to be less toxic than chemical agents (positive control) without weakening the delivery efficiency, which proves that MWCNTs have a good potential in medicine area.