Haematology and Cell Biology
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Browsing Haematology and Cell Biology by Advisor "Louw, V. J."
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Item Open Access The application of high-resolution melting curve analysis for the detection of mutations in the MCR-ABL kinase domain of patients with chronic myeloid leukaemia(University of the Free State, 2011-12) Wienand, Kirsty; Viljoen, C. D.; Louw, V. J.CML is a haematological malignancy that is characterized by the BCR-ABL fusion oncogene that encodes a constitutively active tyrosine kinase. The treatment of choice for CML is a tyrosine kinase inhibitor and molecular monitoring of patients forms an integral part of disease management. When the expected response to tyrosine kinase inhibitor is not achieved within internationally accepted time frames, acquired resistance to tyrosine kinase inhibitors is suspected. Acquired resistance to tyrosine kinase inhibitors is primarily due to mutations in the BCR-ABL kinase domain. Types of mutations include single base mutations, insertions, deletions as well as duplications. Characterization of these mutations is important for treatment, since the type and position of the mutation may have an effect on how the patient responds to treatment. Although several methods have been described for detecting mutations, DNA sequencing is mostly used. Sequencing is currently the only technique that can simultaneously detect single base mutations, insertions and deletions in the BCR-ABL kinase domain. However, sequencing is costly as some patient samples do not have mutations and the lack of response to treatment is due to non-compliance. Thus, a screening method to exclude samples without mutations would make mutational analysis more cost-effective. High resolution melting (HRM) is a relatively new technique that is being used to screen for mutations, prior to sequencing. HRM has recently been used to screen the region of BCR-ABL encoding for the kinase domain for single base mutations. However, it was unknown whether HRM could be used to identify insertions, deletions or duplications in the kinase domain. This study has shown that HRM can be used to screen for mutations including insertions, deletions and duplications the region of BCR-ABL encoding for the kinase domain, prior to sequencing. HRM was performed on 40 patient samples, 10 of which had confirmed mutations in BCR-ABL in the region of the kinase domain. Of the 10 samples with mutations, three had single base mutations, one with a previously described insertion, seven had novel deletion variants. Furthermore, HRM detected a tandem duplication of the kinase domain in two patient samples that was not previously been possible with sequencing. There was 100% congruency between the detection of mutations using HRM and sequencing results, indicating similar sensitivity. HRM proved successful to indicate the presence of deletion variants. However, the deletion variants were detected in the HRM region preceding the area affected by the deletion. It was confirmed that the detection of the deletion variants was due to the PCR extension of HRM 1 amplicon into the HRM area of the deletion. It has been suggested that the insertion, deletions and duplications detected in this study may result in acquired resistance to tyrosine kinase inhibitor. In conclusion, this was the first study to use high-resolution melting to detect insertions, deletions and duplications in the region of BCR-ABL encoding for the kinase domain, indicating the suitability of the assay for screening for mutations prior to sequencing.Item Open Access The application of real-time quantitative PCR in the diagnostics of chronic myeloid leukaemia(University of the Free State, 2009-05) Van Deventer, Jacob Jacobus; Viljoen, C. D.; Louw, V. J.English: CML is a cancer of the white blood cells and it effects on average one individual in every 100,000. Since it was first described in 1845 by John Hughes Bennett and the subsequent discovery of the Philadelphia chromosome by Nowell and Hungerford in 1960, this hematopoietic malignancy has received much attention in terms of scientific study. Elucidating the pathogenic pathway has lead to the development of targeted therapy. In 2001 imatinib mesylate was introduced as first line therapy for CML. The success of imatinb was illustrated during the IRIS trial by Real-time quantification of BCR-ABL mRNA. BCR-ABL expression levels are correlated to disease stage and progression. BCR-ABL mRNA quantification is therefore the most accurate and sensitive prognostic marker to monitor CML patients. Hence, Real-time PCR for BCRABL has been introduced in many international laboratories to allow for accurate and reliable monitoring to improve and manage patient treatment. Standardization became problematic due to the ease of method development and robustness for Real-time quantification of BCR-ABL mRNA by different laboratories. As a result a plethora of methods for Real-time quantification of BCR-ABL mRNA have been published. This is especially problematic for laboratories with limited means undertaking to develop and implement such a method. Since there are no standardized guidelines, in-house development is required. Furthermore, availability of commercial copy number standards for control and target genes makes it difficult to implement any one method from the literature especially since there is criticism for the genes where standards are commercially available. From a thorough analysis of the literature, problem areas considering RNA extraction, the choice of priming for cDNA synthesis, primers and probes for Real-time PCR as well as a specific control gene together with copy number standards and reference material were clearly defined. Based on this information, best laboratory practice regarding common methodology from literature was established. Only recently through an initiative known as Europe Against Cancer (EAC) has there been a concerted effort to facilitate regional standardization of Real-time quantification of BCR-ABL mRNA. During this study a modified EAC method for Real-time quantification of BCRABL mRNA was developed and validated with the emphasis to improve reproducibility. Instead of ABL or BCR, GUS was used as control gene based on recommendations from literature. Based on statistical analysis it was concluded that the modifications did not bias the percentage BCR-ABL result. It cannot be emphasised enough that standardization for Real-time monitoring of BCR-ABL is most crucial as it will ultimately facilitate molecular laboratories to develop this diagnostic with much greater ease. In order for standardization to be realized, copy number standards as well as reference material for quality control purposes needs to become more readily available. In addition to that, specific guidelines for assay criteria such as appropriate Ct values and analysis of data must also be developed. By streamlining Real-time quantification of BCR-ABL the treatment and monitoring of CML patients can be improved on a global scale.Item Open Access Prevalence of helicobacter pylori and its relation to cytotoxin-associated gene a status in HIV positive and negative haematology patients(University of the Free State, 2007-10) Abbott, Tanya Claire; Louw, V. J.; Badenhorst, P. N.; Meiring, S. M.Abstract not available