The role of sodium butyrate and transforming growth factor #beta#1 in growth control in colorectal carcinogenesis

Butt, Alison J.

January 1996

No description available.

572.8

Colonic growth control

A novel human stress response gene with a potential role in induced radioprotection and cell cycle control

McKeen, Hayley

January 2003

No description available.

616.0796

Tumour growth control

Amino acid oxidation and protein metabolism in animals

Hawkey, Robin Keith

January 1993

No description available.

590

Animal growth control

The molecular biology of plant growth control

Ryan, Lucy Anne

January 1988

No description available.

572.8

Genetics/plant growth control

Additives and control of grain growth in barium titanate ceramics

Xue, L. A.

January 1987

No description available.

666

Ceramics grain growth control

The synthesis of indole containing anticancer compounds

Roffey, Jonathan R. A.

January 1996

The concept of bioreductive prodrug chemotherapy is introduced in chapter 1. Tumour cell hypoxia is a significant factor in limiting tumour growth control with conventional radiotherapy and some chemotherapeutic agents. Following therapy these cells can repopulate and cause a relapse of the cancer. On the other hand, hypoxia is unique to tumours, and is therefore potentially exploitable. Bioreductive prodrugs are compounds in which a oxygen inhibited redox-based bioactivation step triggers a reaction leading to a lethal intermediate. The concept of bioreductive DNA alkylators and DNA topoisomerase 11 inhibitors is discussed. The synthesis of model thiazolylindole compounds based on the natural product BE \0988 are discussed in chapter 2. Two strategies were employed for the construction of the thiazolylindoles: the Hantzsch reaction; and nucleophilic substitution on 2-bromothiazole by an indolyl anion. The synthesis of thiazolylindolequinone compounds are discussed in chapter 3. The quinone C(5) position of the thiazolylindolequinone analogues was elaborated to provide a series of cyclic and acyclic C(5)-amino derivatives. Synthetic strategies towards the synthesis of indole-2-carboxylates are discussed in chapter 4. The Moody-Rees and Cadogan-Sundberg reactions were employed to provide a synthesis of the useful highly substituted indole [154]. The Brederek imidazole reaction (i.e., the reaction of a amidine and a-halo ketone) is discussed in chapter 5. Application of the Brederek reaction was employed towards the construction of the bisindole imidazole natural compounds, the nortopsentins. The biological properties of the compounds of the compounds synthesised are discussed in chapter 6. The compounds were tested for DNA topoisomerase 11 inhibitory activity and cytotoxicity under a hypoxic environment.

615.1

Identification of Essential Functions of GRP94 in Metazoan Growth Control and Epithelial Homeostasis

Maynard, Jason Christopher

January 2009

<p>GRP94, the endoplasmic reticulum Hsp90, is a metazoan-restricted chaperone essential for early development in mammals, yet dispensable for mammalian cell viability. These data suggest that GRP94 is required for important developmental processes relying on cell-cell communication and cell-cell interaction. Consistent with this hypothesis, loss of GRP94 expression in mouse is embryonic lethal yet tissue culture cells expressing no GRP94 are viable. To date, functional studies of GRP94 have relied on cell-autonomous model systems, the use of which has lead to discoveries of proteins that GRP94 chaperones also called client proteins. These systems give limited insight into the essential role(s) played by GRP94 in metazoan biology. The dichotomy that GRP94 is necessary for metazoan life, but dispensable for cellular viability suggests that the chaperone is required for the functional expression of secretory and/or membrane proteins that enable cells to function in the context of tissues.</p><p>To explore this hypothesis, the <italic>Drosophila</italic> ortholog of <italic>GRP94</italic>, <italic>Gp93</italic>, was identified and <italic>Gp93</italic> mutants were created using imprecise P-element excision. <italic>Gp93</italic> was found to be an essential gene in <italic>Drosophila</italic>. Loss of zygotic <italic>Gp93</italic> expression is late larval lethal and causes prominent defects in the larval midgut, the sole endoderm-derived larval tissue. <italic>Gp93</italic> mutant larvae display pronounced defects in the midgut epithelium, with aberrant copper cell structure, markedly reduced gut acidification, atypical septate junction structure, depressed gut motility, and deficits in intestinal nutrient uptake. The metabolic consequences of the loss of <italic>Gp93</italic>-expression are profound; <italic>Gp93</italic> mutant larvae exhibit a starvation-like metabolic phenotype, including suppression of insulin signaling and extensive mobilization of amino acids and triglycerides. The defects in copper cell structure/function accompanying loss of <italic>Gp93</italic> expression resemble those reported for mutations in <italic>labial</italic>, an endodermal homeotic gene required for copper cell specification, and &alpha;-spectrin, thus suggesting an essential role for Gp93 in the functional expression of secretory/integral membrane protein-encoding labial protein target genes and/or integral membrane protein(s) that interact with the spectrin cytoskeleton.</p><p>The creation of <italic>Gp93</italic> mutant <italic>Drosophila</italic> has allowed for the study of GRP94 function <italic>in vivo</italic> and will be of upmost importance to future studies examining the function of this chaperone in all aspects of metazoan biology. This dissertation focuses on the morphological and physiological defects that accompany loss of <italic>Gp93</italic> expression in <italic>Drosophila</italic> larvae. It will also outline future studies utilizing this model.</p> / Dissertation

Biology, Cell

copper cell

Drosophila

Gp93

growth control

GRP94

Hsp90

Exploring molecular mechanisms controlling skin homeostasis and hair growth : microRNAs in hair-cycle-dependent gene regulation, hair growth and associated tissue remodelling

Ahmed, Mohammed Ikram

January 2010

The hair follicle (HF) is a cyclic biological system that progresses through stages of growth, regression and quiescence, each being characterized by unique patterns of gene activation and silencing. MicroRNAs (miRNAs) are critically important for gene silencing and delineating their role in hair cycle may provide new insights into mechanisms of hair growth control and epithelial tissue remodelling. The aims of this study were: 1) To define changes in the miRNA profiles in skin during hair cycle-associated tissue remodelling; 2) To determine the role of individual miRNAs in regulating gene expression programs that drive HF growth, involution and quiescence; 3) and to explore the role of miRNAs in mediating the effects of BMP signalling in the skin. To address Aims 1 & 2, global miRNA expression profiling in the skin was performed and revealed marked changes in miRNAs expression during distinct stages of the murine hair cycle. Specifically, miR-31 markedly increased during anagen and decreased during catagen and telogen. Administration of antisense miR-31 inhibitor into mouse skin during the early- and mid-anagen phases of the hair cycle resulted in accelerated anagen development, and altered differentiation of hair matrix keratinocytes and hair shaft formation. Microarray, qRT-PCR and Western blot analyses revealed that miR-31 negatively regulates expression of Fgf10, the components of Wnt and BMP signalling pathways Sclerostin and BAMBI, and Dlx3 transcription factor, as well as selected keratin genes. Luciferase reporter assay revealed that Krt16, Krt17, Dlx3, and Fgf10 serve as direct miR-31 targets. In addition, miR-214 was identified as a potent inhibitor of the Wnt signalling pathway in the keratinocytes. Mutually exclusive expression patterns of miR-214 and β-catenin was observed during HF morphogenesis. MiR-214 decreases the expression of β-catenin and other components of Wnt signalling pathways c-myc, cyclin D1, and Pten in the keratinocytes. Luciferase reporter assay proved that β-catenin serves as a direct target of miR-214. In addition, miR-214 prevented translocation of β-catenin into the nucleus in response to the treatment with an activator of the Wnt signalling pathway lithium chloride, and abrogated the lithium-induced increase of the expression of the Wnt target gene VI Axin2. This suggests that miR-214 may indeed be involved in regulation of skin development and regeneration at least in part, by controlling the expression of β-catenin and the activity of the Wnt signalling pathway. To address Aim 3, the role of miRNAs in mediating the effects of the bone morphogenetic protein (BMP) signalling in the skin was explored. MiRNAs were isolated from the primary mouse keratinocytes treated with BMP4 and processed for analysis of global miRNA expression using the microarray approach. Microarray and real-time PCR analysis revealed BMP4-dependent changes in the expression of distinct miRNAs, including miR-21, which expression was strongly decreased in the keratinocytes after BMP4 treatment. In contrast, miR-21 expression was substantially higher in the skin of transgenic mice over-expressing BMP antagonist Noggin. Transfection of the keratinocytes with miR-21 mimic revealed existence of two groups of the BMP target genes, which are differentially regulated by miR-21. Thus, this suggests a novel mechanism controlling the effects of BMP signalling in the keratinocytes. Thus, miRNAs play important roles in regulating gene expression programs in the skin during hair cycle. By targeting a number of growth regulatory molecules, transcription factors and cytoskeletal proteins, miRNAs are involved in establishing an optimal balance of gene expression in the keratinocytes required for the HF and skin homeostasis.

616.5

Optimal multi-drug chemotherapy control scheme for cancer treatment : design and development of a multi-drug feedback control scheme for optimal chemotherapy treatment for cancer : evolutionary multi-objective optimisation algorithms were used to achieve the optimal parameters of the controller for effective treatment of cancer with minimum side effects

Algoul, Saleh

January 2012

Cancer is a generic term for a large group of diseases where cells of the body lose their normal mechanisms for growth so that they grow in an uncontrolled way. One of the most common treatments of cancer is chemotherapy that aims to kill abnormal proliferating cells; however normal cells and other organs of the patients are also adversely affected. In practice, it's often difficult to maintain optimum chemotherapy doses that can maximise the abnormal cell killing as well as reducing side effects. The most chemotherapy drugs used in cancer treatment are toxic agents and usually have narrow therapeutic indices, dose levels in which these drugs significantly kill the cancerous cells are close to the levels which sometime cause harmful toxic side effects. To make the chemotherapeutic treatment effective, optimum drug scheduling is required to balance between the beneficial and toxic side effects of the cancer drugs. Conventional clinical methods very often fail to find drug doses that balance between these two due to their inherent conflicting nature. In this investigation, mathematical models for cancer chemotherapy are used to predict the number of tumour cells and control the tumour growth during treatment. A feedback control method is used so as to maintain certain level of drug concentrations at the tumour sites. Multi-objective Genetic Algorithm (MOGA) is then employed to find suitable solutions where drug resistances and drug concentrations are incorporated with cancer cell killing and toxic effects as design objectives. Several constraints and specific goal values were set for different design objectives in the optimisation process and a wide range of acceptable solutions were obtained trading off among different conflicting objectives. Abstract v In order to develop a multi-objective optimal control model, this study used proportional, integral and derivative (PID) and I-PD (modified PID with Integrator used as series) controllers based on Martin's growth model for optimum drug concentration to treat cancer. To the best of our knowledge, this is the first PID/I-PD based optimal chemotherapy control model used to investigate the cancer treatment. It has been observed that some solutions can reduce the cancer cells up to nearly 100% with much lower side effects and drug resistance during the whole period of treatment. The proposed strategy has been extended for more drugs and more design constraints and objectives.

616.99

Interação funcional entre hormônios glicocorticóides e o gene supressor de tumor TP53 em um modelo celular de glioma de rato / Functional Link Between Glucocorticoid Hormones and the TP53 Tumor Suppressor Gene in a Rat Glioma Cell Model

Macedo, Antero Ferreira de Almeida

02 October 2007

Tanto hormônios glicocorticóides (GCs) como o gene supressor de tumor TP53, medeiam a resposta celular a uma diversidade de condições fisiológicas de estresse, sendo reguladores fundamentais do processo de vida/morte de diversos tipos celulares. A interação funcional entre estes fatores vem sendo explorada, recentemente, revelando que GCs exercem um efeito dual sobre p53. O modelo celular ST1/P7 de glioma de rato é particularmente interessante para investigar o papel de p53 na ação de GCs, já que estas linhagens apresentam respostas distintas a GCs. O tratamento com Hidrocortisona (Hy) leva as células ST1 a uma complexa reversão fenotípica tumoral&#8594;normal, enquanto as células P7 são altamente resistentes ao tratamento. Foi possível observar que a ativação de p53 por Hy ocorre apenas em células ST1, mas não em P7. Esta ativação é mediada pela indução de fosforilação da Ser15 de p53 e seu acúmulo nuclear, o que resulta no aumento de sua ligação a elementos responsivos a p53 no DNA e na sua capacidade de transativação de p53, levando a um aumento da expressão de alguns de seus genes-alvo. Contudo, o bloqueio de p53 através de siRNA não foi suficiente para alterar a resposta de células ST1 a GCs, indicando que a regulação positiva de p53 por GCs pode ser um evento secundário, mas não essencial, para a resposta anti-tumoral exercida por estes hormônios em células ST1. / Both glucocorticoid hormones (GCs) and the TP53 tumor suppressor gene mediate cellular responses to a diversity of physiological stress conditions, acting as crucial regulators of the life/death process in a wide variety of cell types. The ST1/P7 rat glioma model cell system is particularly interesting to investigate the role of p53 in the action of GCs, since these cell lines display opposite responses to GCs. Treatment with Hydrocortisone (Hy) leads ST1 cells to a complete tumoral&#8594;normal phenotypic reversion, while P7 cells are highly resistant to this treatment. It was possible to observe that activation of p53 by Hy occurs only in ST1 cells, but not in GC-resistant P7 cells. This activation is mediated by induction of phosphorylation of the Ser15 residue of p53 and its accumulation in the nucleus, resulting in increased binding of p53 to its responsive elements on the DNA and in activation of its transactivating potential, leading to increased expression of some of its target genes. However, blocking of p53 through siRNA was not sufficient to alter ST1 cells response to GCs, indicating that the positive regulation of p53 by GCs may be a secondary, non-essential, event for the anti-tumor response exerted by these hormones in ST1 cells.

Cell growth control

Controle da proliferação celular

Glicocorticóides

Glioma

Glioma

Glucocorticoid

Oncogene

p53

P53

siRNA

siRNA