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DNA Aberrations in Atypical Cancer CohortsLintell, Nicholas Adrian, n/a January 2006 (has links)
The incidence of Squamous Cell Carcinoma is growing in certain populations to the extent that it is now the most common skin lesion in young men and women in high ultraviolet exposure regions such as Queensland. In terms of incidence up to 45% of the Australian population over 40 years of age is thought to possess the precancerous Solar Keratosis lesion and with a small but significant chance of progression into SCC, understanding the genetic events that play a role in this process is essential. The major aims of this study were to analyse whole blood derived samples for DNA aberrations in genes associated with tumour development and cellular maintenance, with the ultimate aim of identifying genes associated with non-melanoma skin cancer development. This study had an explicit emphasis on the mitochondrial genome and nuclear genes that encode for subunits in the mitochondrial regulated energy transducing oxidative phosphorylation pathways. More specifically the first aim of this project was to analyse the NDUFA8, PTCH, NDUFAS, SMOH, SDHD, MMPI2, NDUFV1, EMSI, COXVIIc, and RASAI genes via non-specific fluorophoric Real-Time PCR for genetic aberrations in an affected Solar Keratosis and control cohort. The second aim was to analyse two specific genes, SDHD and MMPI2, for copy number aberrations via Dual-Labelled Probe Real-Time PCR in the same affected Solar Keratosis and control cohort. The third aim was to analyse Mitochondrial DNA Depletion syndrome (MDS) in a chemically exposed RAAF personnel cohort via Dual-Labelled Probe Real-Time PCR. The significance of these studies is in their contribution to the knowledge of the genetic pathways that are malformed in the progression and development of the pre-cancerous skin lesion Solar Keratosis. Furthermore, it would determine whether the genes analysed in this study exist in greater prevalence in the affected Solar Keratosis population compared to the control cohort. With regard to the MDS component, identifying the presence of this disease in these individuals was initially undertaken as part of a study to provide evidence in compensation claims. The diagnosis may assist in their medical therapy, insofar as some of them were now suffering from liver malfunctions and atypical male breast cancer. Another application of this effective and low cost method of diagnosing MDS is in populations with high HTV incidences. This is due to the fact that the most common drug used to treat this disease can give rise to the expression of MDS, thus further complicating the health status of HIV infected individuals. The analysis of this research was accomplished via the Real-Time PCR technique, with a non-specific fluorophore component in addition to specific Dual-Labelled Probe components, to ascertain the general nature of any aberration identified in the sample cohort. This project also employed additional methods of analysis such as DHPLC and DNA sequencing to assist in determining the veracity of its aims, particularly in terms of the precise detection of genetic aberrations via Real-Time PCR. Patients exhibiting male breast cancer and liver malftinctions were also analysed via Dual-Labelled Probe RealTime PCR to ascertain the presence of Mitochondrial DNA Depletion syndrome, a disorder characterised by lactic acidosis, liver failure, seizures, and congestive heart failure. Determining the presence of this syndrome in these patients would assist in their medical treatment, and contribute to the analytical methods available to diagnose this syndrome, which is known to occur in HIV sufferers due to the nucleoside drugs used to combat the disease. Real-Time PCR can adequately gauge the integrity of a genetic area in terms of amplicon malformities (non-specific-fluorophoric) and DNA copy number aberrations (Dual-Labelled Probe) via fluorophore signal differentials compared to wild-type samples and housekeeper profiles. The results of the first component of this project, namely the analysis of five gene pairs by non-specific fluorophoric Real-Time PCR, highlighted that a significantly higher incidence of putative aberrants is evident in the affected population when compared to the control cohort. The genes analysed were NDUFA8, PTCH, NDUFA5, SMOH, SDHD, MMP 12, NDUFVI, EMS 1, COXVIIc, and RASA 1. These ten genes were subdivided into five pairs; one of the pair being a gene associated with the development of a non-melanotic skin cancer (NMSC), the other a gene encoding for a subunit of the Electron Transport Chain (ETC). Each of these pairs exists in close proximity to one another on a particular chromosomal locale. Differences were highlighted in the single gene triplicate run population. The ETC genes (NDUFA8, NDUFA5, SDHD, NIDUFVI, COXVIIc) exhibited 10 / 720 (1.37%) as being putative mutants in the control population, compared to 117 / 675 (17.3%) for the affected population (p value less than 0.0001). The NMSC gene analysis (PTCH, SMOH, MMPI2, EMSI, RASA1) produced a 16 / 720 (2.22%) ratio for the control population, with the affected population having an incidence of 97 / 675 (14.4 %) for putative mutants (p value less than 0.0001). The observance of putative aberrants in the NDUFVI (p less than 0.018), EMS1 (p less than 0.003), COXVTIc (p less than 0.001), and RASA I (p less than 0.009) genes in the affected Solar Keratosis (SK) population was significantly higher than that observed in the control population. The majority of aberrations detected via the non-specific fluorophoric Real-Time PCR technique were small nucleotide base insertions and deletions. The analysis of the SK affected and control cohort via Real-Time PCR proved a cost-effective and reliable method in identifying the presence of DNA aberrations such as non-instructional sites. The results of the second component extended the findings of the non-specific fluorophoric analysis. The SDHD and MMPI 2 genes were analysed for copy number aberrations via Dual-Labelled Probe Real-Time PCR for genetic aberrations the same affected and control Solar Keratosis cohort. It was found that 12 of 279 samples had identifiable copy-number aberrations in either the SDHD or MMPI2 gene (this means that a genetic section of either of these two genes is aberrantly amplified or deleted), with five of the samples exhibiting aberrations in both genes. The MMPI2 gene also had nine samples identified as possessing an intronic heterozygous base-pair substitution anomaly via DNA sequencing. The NDUFA8 gene had 12 samples identified as anomalous via the DHPLC technique, 11 of which were identified via non-specific fluorophoric Real-Time PCR, with the analysis performed to verify the accuracy of the Real-Time technique in identifying DNA aberrations. This study identified DNA aberrations in an affected Solar Keratosis and control cohort and ascertained several particular genomic abnomialities in the SDHD, MMPI2 and NDUFA8 genes, with an emphasis on copy-number aberrations and amplicon abnormalities. In the third component of this study, namely the analysis of Mitochondrial DNA Depletion syndrome (MDS) in a jet-fuel exposed RAAF personnel cohort via Dual-Labelled Probe Real-Time PCR, the results indicated that four of the seven patients were expressing MDS. Of the four patients who exhibited a reduction in mitochondrial copy-number the average decrease was of a four-fold level, or approximately a depletion of mitochondrial copies from 200 plus to ~ 54 (74 % reduction in MtDNA). The patients who contributed DNA for investigation into the presence of MDS were suffering from liver malfunction and atypical male breast cancer. The Dual-Labelled Probe technique proved a reliable and cost effective method in identifying the presence of MDS in these patients, with the DNA extracted from fresh white blood cells that had been isolated using the Ficoll-Hypaque method. The importance of this is that accurate levels of Mitochondrial DNA copy numbers can be ascertained in white blood cells as it removes the presence of platelets, which also contain mitochondria but no nucleus. The analysis of ETC and NMSC associated genes in addition to mitochondrial copy number integrity means that this study investigated two aspects of the carcinogenetic pathway i.e. abnormal energy regulation and the regulation of micromolecular and macromolecular cellular homeostatic mechanisms. The mechanism of programmed cell death or apoptosis is regulated by the mitochondria and the ability of a genetically damaged cell to evade the apoptotic process is directly linked to a cell becoming cancerous. It is only after the evasion of apoptosis and the replication of the damaged cells' DNA into daughter cells that neoplastic events can occur. Thus, this study contributed to the understanding of how neo-plastic lesions may develop and progress into invasive tumours. It additionally assisted in proving the effectiveness of the RealTime PCR technique in detecting DNA aberrations and mitochondrial copy number anomalies.
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Genetic Aberrations in Non-Melanoma Skin CancerAshton, Kevin John, K.Ashton@griffith.edu.au January 2002 (has links)
Genetic changes are hallmarks of cancer development involving the activation and/or inactivation of oncogenes and tumour suppressor genes, respectively. In non-melanoma skin cancer (NMSC) development, the initiation of genetic mutations results from exposure to solar ultraviolet radiation. Non-melanoma skin cancers are comprised of basal cell carcinoma (BCC) and squamous cell carcinoma (SCC). Several related cutaneous lesions also exist, of which solar keratoses (SK) are widely accepted as a precursor dysplasia to SCC development. The study of recurrent genetic changes present within NMSC and SK should help reveal causative mutations in skin cancer development. Such analysis could also elucidate links in the genetic similarity of these dysplasia. The rapid screening of numerical changes in DNA sequence copy number throughout the entire genome has been made possible by the advent of comparative genomic hybridisation (CGH). This technique enables the identification of net gains and loss of genetic material within a tumour DNA sample. Chromosomal regions of recurrent gain or loss identify loci containing putative oncogenes and tumour suppressor genes, respectively with potential roles in NMSC tumourigenesis. Used in conjunction with tissue microdissection and universal degenerate PCR techniques this can enable the elucidation of aberrations in small histologically distinct regions of tumour. Such a technique can utilize archival material such as paraffin embedded tissue, which is the major source of neoplastic material available for cancer research. This study used the CGH technique to investigate aberrations in BCC, SCC and SK samples. The screening of copy number abnormalities (CNAs) in BCC revealed that although these tumours were close to diploid and generally genetically stable, they did contain several recurrent aberrations. The loss of genetic material at 9q was identified in a third of BCC tumours studied. This is characteristic of inactivation of the PTCH tumour suppressor gene, a known attribute in some sporadic BCC development. Validation of this loss was performed via loss of heterozygosity, demonstrating good concordance with the CGH data. In addition the over-representation of the 6p chromosome arm was revealed in 47% of biopsies. This novel CNA is also commonly observed in other cutaneous neoplasias, including Merkel cell carcinoma and malignant melanoma. This suggests a possible common mechanism in development and or promotion in these cutaneous dysplasias, the mechanisms of which have yet to be clearly defined. In contrast to BCC, numerical genetic aberrations in SCC and SK were much more frequent. Several regions of recurrent gain were commonly shared between both dysplasias including gain of 3q, 4p, 5p, 8q, 9q, 14q, 17p, 17q and 20q. Common chromosomal regions of loss included 3p, 8p, 9p, 11p, 13q and 17p. In addition loss of chromosome 18 was significantly observed in SCC in comparison to SK, a possible defining event in SK progression to SCC. The identification of shared genetic aberrations suggests a clonal and genetic relationship between the two lesions. This information further supports the notion for re-classification of SK to an SCC in situ or superficial SCC. Finally, the CNAs detected have been similarly observed in other squamous cell-derived tumours, for example cervical and head and neck SCC. This provides further evidence to common mechanisms involved in the initiation, development and progression of SCC neoplasia. This study has identified a number of recurrent chromosomal regions, some of which are novel in NMSC development. The further delineation of these loci should provide additional evidence of their significance and degree of involvement in NMSC tumourigenesis. The identification of the cancer-causing genes mapped to these loci will further demarcate the genetic mechanisms of BCC and SCC progression. An understanding of the events involved in skin cancer formation and progression should shed additional light on molecular targets for diagnostics, management and therapeutic treatment.
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