• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 2
  • Tagged with
  • 13
  • 13
  • 5
  • 4
  • 3
  • 3
  • 3
  • 3
  • 3
  • 3
  • 3
  • 3
  • 2
  • 2
  • 2
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

A defective-RNA expression vector for targeted recombination of the coronavirus infectious bronchitis virus

Stirrups, Kathleen Elizabeth January 1999 (has links)
No description available.
2

Isolation and characterisation of genes regulating development in the mosquito Anopheles gambiae

Devenport, Martin Phillip January 1999 (has links)
No description available.
3

Molecular biology of human enteric caliciviruses

Liu, Binlei January 1996 (has links)
No description available.
4

Parasitic influences on the host genome using the molluscan model organism Biomphalaria glabrata

Arican-Goktas, Halime Derya January 2013 (has links)
The freshwater snail Biomphalaria glabrata is an intermediate host for Schistosoma mansoni parasites, causing one of the most prevalent parasitic infections in mammals, known as schistosomiasis (Bilharzia). Due to its importance in the spread of the disease B. glabrata has been selected for whole genome sequencing and is now a molluscan model organism. In order to aid the sequencing project and to understand the structure and organisation of B. glabrata’s genome at the chromosomal level, a G-banded karyotype has been established. Unlike in any other previous reports, two heteromorphic chromosomes have been identified in the genome of B. glabrata and for the first time snail ideograms have been produced. In addition to characterising the snail chromosomes, a methodology for mapping single copy B. glabrata genes onto these chromosomes has also been established, and 4 genes have successfully been mapped using fluorescence in situ hybridisation. In the relationship between a parasite and a host organism, it is of fundamental importance to understand the basic biology and interfere with the life cycle to reveal how the parasite controls and elicits host gene expression for its own benefit. This study is also directly addressing this aspect of host – parasite interactions by investigating the effects of schistosome infection on the genome and cell nuclei of the host snail B. glabrata. Upon infection with S. mansoni miracidia, genes known to be involved in the host response to the parasite are dramatically relocated within the interphase snail nuclei. These events are in conjunction with the up-regulation of gene expression, indicating a parasite induced nuclear event. Moreover, a differential response between the schistosome-resistant and schistosome-susceptible snails is also reported. This is the first time this has been described in a host – pathogen relationship. The precise organisation of the genome is critical for its correct functioning. The genome is non-randomly organised and this level of organisation is very much influenced by the nuclear architecture. Being a molluscan model organism with the availability of a unique cell line, B. glabrata is a remarkable organism for the studies of nuclear and genome biology. For this reason, in this thesis the snail nuclear architecture was also investigated. For the first time PML bodies, transcription factories, and nuclear myosin 1 beta have been visualised in the snail nuclei. A heat shock system was also developed to study the role of these structures in the snail. Upon heat stimuli gene loci were found to reposition and co-localise with transcription factories, which was in parallel with the up-regulation of gene expression. The mechanism of this genome reorganisation was explored by investigating nuclear motor structures in the snail. By using a motor inhibitor on snail cells, gene repositioning and subsequent expression after heat shock was blocked. This is the first time this has been shown in any organism. Thus, due to the ease of use of the snails with respect to maintenance, handling, and treatments, B. glabrata is making a very useful new model organism to study spatial genomic events.
5

Investigating HLXB9 as a biomarker in cancer

Owoka, Temitayo Olajumoke January 2016 (has links)
A biomarker is a measurable biological characteristic that can be evaluated as an indicator of normal (physiological) or abnormal (pathogenic) processes. In cancer research, there remains a need for the identification of new biomarkers that can be used to close the gaps in the current understanding of cancer development, progression and treatment. HLXB9 is a homeobox gene located at 7q36. It encodes a transcription factor important in embryonic development. Its accurate regulation is significant in the organogenesis of the endodermal germ layer particularly in the development of the pancreas. After development, its expression is downregulated in the majority of adult tissues. Recently, aberrant expression of HLXB9 has been found in certain cancers such as hepatocellular carcinoma, testicular cancer, pancreatic cancer and leukaemia. The location of genes and chromosomes in the nuclei of healthy human cells has been shown to be non-random, therefore understanding the mechanisms that regulate nuclear genome organisation is important in understanding of cancer biology in cases where genes are relocated. The nuclear localisation of genes as a biomarker of tumour development in cancer is a relatively new but promising field in cancer research. Previous research by our group found overexpression of HLXB9 corresponded to an altered positioning of this gene in the nucleus of paediatric leukaemia patients harbouring the translocation t(7;12)(q36;p13). In this project, HLXB9 was evaluated as a biomarker in cancer development. In the first study, a new dual colour probe for the detection of the t(7;12)(q36; p13) was validated by fluorescence in situ hybridisation (FISH) in leukaemia patient samples previously described as harbouring the translocation. The expression of HLXB9 was then analysed by RT-PCR in 48 patients diagnosed with various haematological disorders. 25% of patients analysed expressed HLXB9. Additionally, HLXB9 expression in leukaemia was found in patients with normal copies of chromosome 7 suggesting HLXB9 expression can occur independently of chromosome 7 abnormalities. An attempt was made to evaluate the link between HLXB9 expression and its nuclear localisation in these patients. Four online databases were interrogated to identify cancer types and subtypes that exhibit differential HLXB9 expression. HLXB9 expression was not altered in the majority of cancer cases investigated. However, aberrant HLXB9 expression was found in cancer types not previously reported as showing differential HLXB9 expression such as kidney cancer, lung cancer and endometrial cancer. The identification of aberrant expression of HLXB9 in these cancer types provides a new avenue for research into understanding cancer development and progression in these tumour types. Finally, the expression of HLXB9 was analysed in four breast cancer cell lines by quantitative RT-PCR and immunofluorescence. Additionally, the prognostic significance of HLXB9 expression was evaluated in publicly available breast cancer survival databases (Kaplan Meier plotter and BreastMark). Altogether, the findings emerging from this thesis work show that, although the potential for HLXB9 to be used as biomarker is appealing, further work is required to confirm the value of this biological parameter in the diagnosis, prognosis and progression of cancer.
6

Discovery and restoration of aberrant nuclear structure and genome behaviour in breast cancer cells

Hassan Ahmed, Mai January 2013 (has links)
The eukaryotic interphase nucleus is well organised and the genome positioned non-randomly. Nuclear structure is an important regulator of genome behaviour and function. Genome organisation and nuclear structure are compromised in diseases such as cancer and laminopathies. This study was to find out and to determine if there is any functional relationship between nuclear structure and genome mis-organisation in cancer cells. I have assessed the presence and distribution of specific nuclear structural proteins (A-type, B-type lamins and its receptor LBR, many of their binding proteins such as MAN1, LAP2α, LAP2, and Emerin and other nuclear proteins (PML, Nucleolin, and Ki67) using indirect immunofluorescence. From this study, it is found that the nuclear structure of breast cancer cells is often altered. The most severely affected proteins are the nuclear lamins B1 and B2 and they found as large foci within the nucleoplasm with little LBR expression to localise the lamin B. I also assessed the chromosome positioning (HSA 7, 10, 11, 14 and 17) and gene positioning (AKT1, CCND1, HSP90AA1, EGFR, ERRBB2/HER2 and PTEN) in breast cancer cell lines (T-47D, GI-101, Sk-Br-3 and BT-474) and in normal breast cell lines (MCF-10A) using 2D-FISH technique. I also assessed the position of the genes in nuclei and correlated with gene expression using qRT-PCR. Breast cell lines have treated with a drug named lovastatin and it was found that the cells have restored LBR expression and localisation of lamin B, leading to altered gene positioning and changed expression of breast cancer genes. Since the drug (lovastatin, 12 μM/48 hours) affects the prenylation as a post-translation modification process and lamins B biosythensis, it is found that B-type lamins and its receptor expression and distribution were improved and increased in expression by 2-fold in expression levels in the most affected cells (T-47D, and BT-474) compared to the normal cells (MCF-10A) and these cells also showed abnormal nuclei and dead cells. When analysing the nuclear positioning of the genes (AKT1, HSP90AA1 and ERRBB2/HER2), it is found that AKT1 was positioned periphery in BT-474 and T-47D cells and interiorly in the normal cells (MCF-10A) before treatment whereas the same gene was positioned periphery in T-47D and MCF-10A cells and interiorly in BT-474 after treatment with lovastatin. It is also found that HSP90AA1 was positioned periphery in MCF-10A and T-47D cells and interiorly in BT-474 cells before and after treatment (no change). Moreover, ERRBB2/HER2 gene was positioned periphery in T-47D and BT-474 cells and interiorly in MCF-10A cells before treatment whereas the same gene was positioned periphery in MCF-10A and T-47D cells and interiorly in BT-474 after treatment with the same drug. Regarding LMNB1, LMNB2, and LBR genes, the study focussed only on their expression levels and no work has done on their chromosome positioning as well as gene position before and after treatment. These three genes were over expressed when assessed by measuring the relative and fold changes in expression. Therefore, it is suggestive that 2D-FISH experiment to assess their localisation and their specific chromosome territories is required. The results shown in this thesis demonstrate the importance and roles of nuclear architecture specifically nuclear lamins and the integral nuclear membrane proteins (B-type lamins and LBR) in mediating correct genome organisation and function. The breast normal (immortalised cells) and cancerous cell lines showed different nuclear structures as lamin B affect the position of specific target chromosomes and genes. These results will strength the finding that the nuclear lamina is a significant nuclear structure which associates, organises, and regulates numerous vital nuclear processes and the stability of the genome.
7

NETS coordinate genome organisation and gene expression changes in T-cells and during myogenesis

Robson, Michael Ian January 2015 (has links)
Gene positioning changes with respect to the nuclear periphery correlate with their activation in a number of tissues during development. However, the determination of the function this serves or the mechanism through which this was achieved has been remarkably difficult to resolve. It may now be possible to address these questions due to the recent identification of a number of tissue-specific nuclear envelope transmembrane proteins (NETs) which are capable of promoting the repositioning of specific subsets of chromosomes and concomitantly inducing changes to gene expression (Zuleger et al,. 2013). In this thesis I describe the role of NETs in the positioning of genes to the nuclear envelope (NE) during muscle differentiation and the role this activity plays in the optimisation of myogenic gene expression in as myoblasts (MTs) differentiate to myotubes (MTs). To do this I identified four NETs with the capacity to reposition a chromosome to the periphery that are present specifically in the NEs of skeletal muscle. Using a combination of genome-wide gene expression analysis and DamID I determined that depletion of these NETs disrupted myogenic gene expression and, more significantly, prevented the targeting to and silencing of normally repressed genes at the NE. I also investigated an analogous role for the blood-specific NET TAPBPL in the regulation of the critical T-cell regulator interleukin 2 (IL-2) at the NE in T-cells. Depletion of this NET caused release of the IL2 locus from the periphery and promoted its inappropriate and long-term activation. Interestingly, depletion of TAPBPL also prevented IL2 silencing following the end of T-cell activation, suggesting this genome organisation activity is critical for the maintenance of normal T-cell function. Collectively, the results discussed herein describe a new role for NETs in the regulation of gene expression through the manipulation of spatial genome organisation and may serve as an additional layer of higher order tissue-specific gene regulation in higher organisms.
8

Epigenetic regulation of skin development and postnatal homeostasis : the role of chromatin architectural protein Ctcf in the control of keratinocyte differentiation and epidermal barrier formation

Malashchuk, Ogor January 2016 (has links)
Epigenetic regulatory mechanisms play important roles in the control of lineage-specific differentiation during development. However, mechanisms that regulate higher-order chromatin remodelling and transcription of keratinocyte-specific genes that are clustered in the genome into three distinct loci (Keratin type I/II loci and Epidermal Differentiation Complex (EDC)) during differentiation of the epidermis are poorly understood. By using 3D-Fluorescent In Situ Hybridization (FISH), we determined that in the epidermal keratinocytes, the KtyII and EDC loci are located closely to each other in the nuclear compartment enriched by the nuclear speckles. However, in KtyII locus knockout mice, EDC locus moved away from the KtyII locus flanking regions and nuclear speckles towards the nuclear periphery, which is associated with marked changes in gene expression described previously. Chromatin architectural protein Ctcf has previously been implicated in the control of long-range enhancer-promoter contacts and inter-chromosomal interactions. Ctcf is broadly expressed in the skin including epidermal keratinocytes and hair follicles. Conditional Keratin 14-driven Ctcf ablation in mice results in the increase of the epidermal thickness, proliferation, alterations of the epidermal barrier and the development of epidermal pro-inflammatory response. Epidermal barrier defects in Krt14CreER/Ctcf fl/fl mice are associated with marked changes in gene expression in the EDC and KtyII loci, which become topologically segregated in the nucleus upon Ctcf ablation. Therefore, these data suggest that Ctcf serves as critical determinant regulating higher-order chromatin organization in lineage-specific gene loci in epidermal keratinocytes, which is required for the proper control of gene expression, maintenance of the epidermal barrier and its function.
9

Study of 3D genome organisation in budding yeast by heterogeneous polymer simulations

Fahmi, Zahra January 2019 (has links)
Investigating the arrangement of the packed DNA inside the nucleus has revealed the essential role of genome organisation in controlling genome function. Furthermore, genome architecture is highly dynamic and significant chromatin re-organisation occurs in response to environmental changes. However, the mechanisms that drive the 3D organisation of the genome remain largely unknown. To understand the effect of biophysical properties of chromatin on the dynamics and structure of chromosomes, I developed a 3D computational model of the nucleus of the yeast S. cerevisiae during interphase. In the model, each chromosome was a hetero-polymer informed by our bioinformatics analysis for heterogeneous occupancy of chromatin-associated proteins across the genome. Two different conditions were modelled, normal growth (25°C) and heat shock (37°C), where a concerted redistribution of proteins was observed upon transition from one temperature to the other. Movement of chromatin segments was based on Langevin dynamics and each segment had a mobility according to their protein occupancy and the expression level of their corresponding genes. The model provides a significantly improved match with quantitative microscopy measurements of telomere positions, the distributions of 3D distances between pairs of different loci, and the mean squared displacement of a labelled locus. The quantified contacts between chromosomal segments were similar to the observed Hi-C data. At both 25°C and 37°C conditions, the segments that were highly occupied by proteins had high number of interactions with each other, and the highly transcribed genes had lower contacts with other segments. In addition, similar to the experimental observations, heat-shock genes were found to be located closer to the nuclear periphery upon activation in the simulations. It was also shown that the determined distribution of proteins along the genome is crucial to achieve the correct genome organisation. Hence, the heterogeneous binding of proteins, which results in differential mobility of chromatin segments, leads to 3D self-organisation.
10

Epigenetic Regulation of Skin Development and Postnatal Homeostasis The role of chromatin architectural protein Ctcf in the control of Keratinocyte Differentiation and Epidermal Barrier Formation

Malashchuk, Igor January 2016 (has links)
Epigenetic regulatory mechanisms play important roles in the control of lineage-specific differentiation during development. However, mechanisms that regulate higher-order chromatin remodelling and transcription of keratinocyte-specific genes that are clustered in the genome into three distinct loci (Keratin type I/II loci and Epidermal Differentiation Complex (EDC) during differentiation of the epidermis are poorly understood. By using 3D-Fluorescent In Situ Hybridization (FISH), we determined that in the epidermal keratinocytes, the KtyII and EDC loci are located closely to each other in the nuclear compartment enriched by the nuclear speckles. However, in KtyII locus knockout mice, EDC locus moved away from the KtyII locus flanking regions and nuclear speckles towards the nuclear periphery, which is associated with marked changes in gene expression described previously. Chromatin architectural protein Ctcf has previously been implicated in the control of long-range enhancer-promoter contacts and inter-chromosomal interactions. Ctcf is broadly expressed in the skin including epidermal keratinocytes and hair follicles. Conditional Keratin 14-driven Ctcf ablation in mice results in the increase of the epidermal thickness, proliferation, alterations of the epidermal barrier and the development of epidermal pro-inflammatory response. Epidermal barrier defects in Krt14CreER/Ctcf fl/fl mice are associated with marked changes in gene expression in the EDC and KtyII loci, which become topologically segregated in the nucleus upon Ctcf ablation. Therefore, these data suggest that Ctcf serves as critical determinant regulating higher-order chromatin organization in lineage-specific gene loci in epidermal keratinocytes, which is required for the proper control of gene expression, maintenance of the epidermal barrier and its function.

Page generated in 0.1296 seconds