Interleukin -3 receptor expression and function in now-hemopoietic cells / Eija Korpelainen.

Korpelainen, Eija

January 1995

Errata inserted on back end papers. / Includes bibliographical references. / 99 leaves, [9] leaves of plates : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Identifies a novel site of action for IL-3, and suggests that it can influence immune and inflammatory responses and hemopoiesis by acting not only on hemopoietic cells but also on vascular endothelium. / Thesis (Ph.D.)--University of Adelaide, Dept. of Medicine, 1996?

616.079 20

Interleukin 3 Physiological effect.

Interleukin 3 Therapeutic use.

Hematopoietic growth factors.

Transcriptional regulation of the GM-CSF gene in T lymphocytes / Cameron Stuart Osborne.

Osborne, Cameron Stuart

January 1996

Addendum pasted on front end papers. / Includes bibliographies. / 109, [99] leaves, [5] leaves of plates : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Describes the investigation as to whether the mouse granulocyte-macrophage colony-stimulating factor and interleukin-3 genes are regulated in a similar manner as those of the human, focussing on regulation through an enhancer. / Thesis (Ph.D.)--University of Adelaide, Dept. of Microbiology and Immunology, 1996

616.079 21

Interleukin-3.

Cytokines Physiological effect.

Hematopoietic growth factors.

Characterization and purification of insulin-like growth factor-binding proteins of human fibroblasts / by Briony Evelyn Forbes.

Forbes, Briony E.

January 1991

Bibliography: leaves 105-136. / vi, 136, [73] leaves, [13] leaves of plates : ill. (some col) ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Biochemistry, 1992

574.1927 20

Fibroblast growth factors.

Effect of growth factors on the osteoinductive potential of Hydroxyapatite β-Tricalcium Phosphate (HA-TCP).

Chan, Raymond Chun Wai

January 2010

The replacement of missing teeth by osseointegrated dental implants is a commonly utilised treatment option in dentistry. However, successful treatment outcomes are dependent on sufficient bone quantity in the proposed surgical site for implant placement (Buser et al., 2004). Surgical augmentation of bone defects is commonly performed prior to or during implant placement. Bone augmentation procedures of the maxillary sinus or guided bone regeneration (GBR) procedures of alveolar ridge defects have utilised a variety of bone graft materials in block or particulate form, either alone or in combination with resorbable or non-resorbable barrier membranes. Objective: The aim of this study was to determine whether Hydroxyapatite β-Tricalcium Phosphate (HA-TCP) either alone or combined with Enamel Matrix Derivative (EMD) or recombinant human Platelet Derived Growth Factor-BB (rhPDGF-BB) is osteoinductive when implanted into a nonosseous site. Methods: Twenty CD-1 adult male mice underwent intramuscular implantation into both hindlimbs of an empty gelatine capsule or a gelatine capsule containing one of the following: 10 mg of uncoated particulate HA-TCP, (Straumann Bone Ceramic®, HA-TCP), EMD coated HA-TCP, (Emdogain®, HATCP + EMD) or rhPDGF-BB coated HA-TCP (HA-TCP + PDGF). Ten animals were sacrificed at four and eight weeks with five specimens from each group retrieved at each time point. The area of graft placement was radiographed and after graft retrieval, a semi-quantitative histological examination was performed with the aim of assessing the inflammatory changes, reparative processes and osteoinduction within the graft site. Results: At both 4 and 8 weeks, histological analysis failed to demonstrate any osteoinductive activity in any of the specimens from the three experimental groups. A minimal chronic inflammatory response and foreign body reaction was seen in the experimental groups which reduced over time. The particles were embedded within fibrous connective tissue and were encapsulated by a dense cellular layer consisting of active fibroblasts and occasional macrophages with the thickness of this layer decreasing over time. At 4 weeks, a greater density of the fibrous connective tissue was demonstrated in the HA-TCP + EMD group (P<0.001) while a greater thickness in the capsule thickness was seen in the HA-TCP group (P=0.022) although no differences were seen after 8 weeks. Greater neovascularisation was seen in the HA-TCP + PDGF group after 8 weeks (P=0.043) while greater amounts of adipose tissue surrounding the particles were detected in the HA-TCP + PDGF group at 4 weeks (P=0.002) and in the HA-TCP + EMD group at eight weeks (P=0.002). Conclusions: The results of this study suggest that the use of commercially available HA-TCP alone or in combination with EMD or rhPDGF-BB is biocompatible but not osteoinductive in the murine model. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1522641 / Thesis (D.Clin.Dent.) -- University of Adelaide, School of Dentistry, 2010

Insulin-like growth factor receptors in colorectal cancer.

Brierley, Gemma Victoria

January 2008

The IGF system is a crucial regulator of normal growth and development, however dysregulation of the system on multiple levels is associated with the incidence of a wide variety of malignancies including the breast, thyroid, lung, and colon, making the IGF system an important anti-cancer therapeutic target. Due to its role in mediating cellular proliferation, protection from apoptosis, and metastasis, traditional focus has been set on examining the role of the type 1 IGF receptor [IGF1R] in cancer. However there is mounting evidence to suggest the insulin receptor [IR] may also be involved in the potentiation and pathogenesis of cancers. The observation that IGF-II is overexpressed, compared to normal tissues, by cancers suggests signaling via target receptors by this ligand has important implications on cancer pathogenesis. Indeed, both the IGF1R and IR have been demonstrated to be up-regulated in a variety of malignancies. In regards to IR isoform, the IGF-II binding IR-A is preferentially expressed by a number of cancer cell types. Together with the observation that an autocrine proliferative loop exists between IGF-II and the IR-A in malignant thyrocytes and cultured breast cancer cells, suggests signaling via the IR-A may play a role in cancer cell growth and survival. However, very few studies on the IR-A have been conducted in cells co-expressing the IGF1R. This is mainly due to the difficulties associated with discrimination between signaling arising from IGF1R homodimers, IR-A homodimers, and IGF1R/IR-A hybrid receptors. It is not known how the IR-A interacts, and functions in conjunction with the other receptors of the IGF system to signal biologically relevant outcomes, especially in terms of anti-cancer therapeutics that aim to block and down-regulate the IGF1R. Current anti-cancer therapies targeting the IGF system have concentrated on blocking IGF signaling via the IGF1R, due mostly to the functional properties of the receptor, but also in part due to the metabolic consequences associated with blockade and inhibition of the IR. This individual targeting of the IGF1R potentially leaves a pathway by which IGF-II secreted by the tumour can circumvent current IGF1R based therapies. Consequently, this thesis investigated whether the IR-A could compensate for the targeted loss of the IGF1R and how the IR-A interacts with the IGF1R in cells co-expressing these two receptors. In addition, the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation was assessed. The main experimental techniques used throughout this body of work included; assessment of protein expression and activation by Western blot, siRNA mediated gene silencing, and measures of cell proliferation, survival, and migration. The key areas of investigation included: 1. Investigation of the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation 2. Identification of an appropriate cell line model in which to investigate the interactions between the IR-A and IGF1R 3. Optimisation of siRNA mediated knock-down of the IR-A and IGF1R in SW480 colorectal adenocarcinoma cells 4. Determination of the biological role of the IR-A in SW480 cells co-expressing the IGF1R The key findings from this work included: 1. The IR-A could not compensate for IGF1R depletion in SW480 cells 2. Dual silencing of the IR-A and IGF1R indicated signaling via the IGF1R was dominant to signaling via the IR-A in SW480 cells 3. Signaling via IR-A/IGF1R hybrid receptors may not be as potent as signaling via IGF1R homodimers 4. IGF-I at physiological concentrations can stimulate biological responses via both isoforms of the IR. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1337339 / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2008

Cell receptors.

Colon (Anatomy) Cancer.

Rectum Cancer.

Insulin-like growth factor receptors in colorectal cancer.

Brierley, Gemma Victoria

January 2008

The IGF system is a crucial regulator of normal growth and development, however dysregulation of the system on multiple levels is associated with the incidence of a wide variety of malignancies including the breast, thyroid, lung, and colon, making the IGF system an important anti-cancer therapeutic target. Due to its role in mediating cellular proliferation, protection from apoptosis, and metastasis, traditional focus has been set on examining the role of the type 1 IGF receptor [IGF1R] in cancer. However there is mounting evidence to suggest the insulin receptor [IR] may also be involved in the potentiation and pathogenesis of cancers. The observation that IGF-II is overexpressed, compared to normal tissues, by cancers suggests signaling via target receptors by this ligand has important implications on cancer pathogenesis. Indeed, both the IGF1R and IR have been demonstrated to be up-regulated in a variety of malignancies. In regards to IR isoform, the IGF-II binding IR-A is preferentially expressed by a number of cancer cell types. Together with the observation that an autocrine proliferative loop exists between IGF-II and the IR-A in malignant thyrocytes and cultured breast cancer cells, suggests signaling via the IR-A may play a role in cancer cell growth and survival. However, very few studies on the IR-A have been conducted in cells co-expressing the IGF1R. This is mainly due to the difficulties associated with discrimination between signaling arising from IGF1R homodimers, IR-A homodimers, and IGF1R/IR-A hybrid receptors. It is not known how the IR-A interacts, and functions in conjunction with the other receptors of the IGF system to signal biologically relevant outcomes, especially in terms of anti-cancer therapeutics that aim to block and down-regulate the IGF1R. Current anti-cancer therapies targeting the IGF system have concentrated on blocking IGF signaling via the IGF1R, due mostly to the functional properties of the receptor, but also in part due to the metabolic consequences associated with blockade and inhibition of the IR. This individual targeting of the IGF1R potentially leaves a pathway by which IGF-II secreted by the tumour can circumvent current IGF1R based therapies. Consequently, this thesis investigated whether the IR-A could compensate for the targeted loss of the IGF1R and how the IR-A interacts with the IGF1R in cells co-expressing these two receptors. In addition, the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation was assessed. The main experimental techniques used throughout this body of work included; assessment of protein expression and activation by Western blot, siRNA mediated gene silencing, and measures of cell proliferation, survival, and migration. The key areas of investigation included: 1. Investigation of the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation 2. Identification of an appropriate cell line model in which to investigate the interactions between the IR-A and IGF1R 3. Optimisation of siRNA mediated knock-down of the IR-A and IGF1R in SW480 colorectal adenocarcinoma cells 4. Determination of the biological role of the IR-A in SW480 cells co-expressing the IGF1R The key findings from this work included: 1. The IR-A could not compensate for IGF1R depletion in SW480 cells 2. Dual silencing of the IR-A and IGF1R indicated signaling via the IGF1R was dominant to signaling via the IR-A in SW480 cells 3. Signaling via IR-A/IGF1R hybrid receptors may not be as potent as signaling via IGF1R homodimers 4. IGF-I at physiological concentrations can stimulate biological responses via both isoforms of the IR. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1337339 / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2008

Cell receptors.

Colon (Anatomy) Cancer.

Rectum Cancer.

Insulin-like growth factor receptors in colorectal cancer.

Brierley, Gemma Victoria

January 2008

The IGF system is a crucial regulator of normal growth and development, however dysregulation of the system on multiple levels is associated with the incidence of a wide variety of malignancies including the breast, thyroid, lung, and colon, making the IGF system an important anti-cancer therapeutic target. Due to its role in mediating cellular proliferation, protection from apoptosis, and metastasis, traditional focus has been set on examining the role of the type 1 IGF receptor [IGF1R] in cancer. However there is mounting evidence to suggest the insulin receptor [IR] may also be involved in the potentiation and pathogenesis of cancers. The observation that IGF-II is overexpressed, compared to normal tissues, by cancers suggests signaling via target receptors by this ligand has important implications on cancer pathogenesis. Indeed, both the IGF1R and IR have been demonstrated to be up-regulated in a variety of malignancies. In regards to IR isoform, the IGF-II binding IR-A is preferentially expressed by a number of cancer cell types. Together with the observation that an autocrine proliferative loop exists between IGF-II and the IR-A in malignant thyrocytes and cultured breast cancer cells, suggests signaling via the IR-A may play a role in cancer cell growth and survival. However, very few studies on the IR-A have been conducted in cells co-expressing the IGF1R. This is mainly due to the difficulties associated with discrimination between signaling arising from IGF1R homodimers, IR-A homodimers, and IGF1R/IR-A hybrid receptors. It is not known how the IR-A interacts, and functions in conjunction with the other receptors of the IGF system to signal biologically relevant outcomes, especially in terms of anti-cancer therapeutics that aim to block and down-regulate the IGF1R. Current anti-cancer therapies targeting the IGF system have concentrated on blocking IGF signaling via the IGF1R, due mostly to the functional properties of the receptor, but also in part due to the metabolic consequences associated with blockade and inhibition of the IR. This individual targeting of the IGF1R potentially leaves a pathway by which IGF-II secreted by the tumour can circumvent current IGF1R based therapies. Consequently, this thesis investigated whether the IR-A could compensate for the targeted loss of the IGF1R and how the IR-A interacts with the IGF1R in cells co-expressing these two receptors. In addition, the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation was assessed. The main experimental techniques used throughout this body of work included; assessment of protein expression and activation by Western blot, siRNA mediated gene silencing, and measures of cell proliferation, survival, and migration. The key areas of investigation included: 1. Investigation of the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation 2. Identification of an appropriate cell line model in which to investigate the interactions between the IR-A and IGF1R 3. Optimisation of siRNA mediated knock-down of the IR-A and IGF1R in SW480 colorectal adenocarcinoma cells 4. Determination of the biological role of the IR-A in SW480 cells co-expressing the IGF1R The key findings from this work included: 1. The IR-A could not compensate for IGF1R depletion in SW480 cells 2. Dual silencing of the IR-A and IGF1R indicated signaling via the IGF1R was dominant to signaling via the IR-A in SW480 cells 3. Signaling via IR-A/IGF1R hybrid receptors may not be as potent as signaling via IGF1R homodimers 4. IGF-I at physiological concentrations can stimulate biological responses via both isoforms of the IR. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1337339 / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2008

Cell receptors.

Colon (Anatomy) Cancer.

Rectum Cancer.

Insulin-like growth factor receptors in colorectal cancer.

Brierley, Gemma Victoria

January 2008

The IGF system is a crucial regulator of normal growth and development, however dysregulation of the system on multiple levels is associated with the incidence of a wide variety of malignancies including the breast, thyroid, lung, and colon, making the IGF system an important anti-cancer therapeutic target. Due to its role in mediating cellular proliferation, protection from apoptosis, and metastasis, traditional focus has been set on examining the role of the type 1 IGF receptor [IGF1R] in cancer. However there is mounting evidence to suggest the insulin receptor [IR] may also be involved in the potentiation and pathogenesis of cancers. The observation that IGF-II is overexpressed, compared to normal tissues, by cancers suggests signaling via target receptors by this ligand has important implications on cancer pathogenesis. Indeed, both the IGF1R and IR have been demonstrated to be up-regulated in a variety of malignancies. In regards to IR isoform, the IGF-II binding IR-A is preferentially expressed by a number of cancer cell types. Together with the observation that an autocrine proliferative loop exists between IGF-II and the IR-A in malignant thyrocytes and cultured breast cancer cells, suggests signaling via the IR-A may play a role in cancer cell growth and survival. However, very few studies on the IR-A have been conducted in cells co-expressing the IGF1R. This is mainly due to the difficulties associated with discrimination between signaling arising from IGF1R homodimers, IR-A homodimers, and IGF1R/IR-A hybrid receptors. It is not known how the IR-A interacts, and functions in conjunction with the other receptors of the IGF system to signal biologically relevant outcomes, especially in terms of anti-cancer therapeutics that aim to block and down-regulate the IGF1R. Current anti-cancer therapies targeting the IGF system have concentrated on blocking IGF signaling via the IGF1R, due mostly to the functional properties of the receptor, but also in part due to the metabolic consequences associated with blockade and inhibition of the IR. This individual targeting of the IGF1R potentially leaves a pathway by which IGF-II secreted by the tumour can circumvent current IGF1R based therapies. Consequently, this thesis investigated whether the IR-A could compensate for the targeted loss of the IGF1R and how the IR-A interacts with the IGF1R in cells co-expressing these two receptors. In addition, the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation was assessed. The main experimental techniques used throughout this body of work included; assessment of protein expression and activation by Western blot, siRNA mediated gene silencing, and measures of cell proliferation, survival, and migration. The key areas of investigation included: 1. Investigation of the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation 2. Identification of an appropriate cell line model in which to investigate the interactions between the IR-A and IGF1R 3. Optimisation of siRNA mediated knock-down of the IR-A and IGF1R in SW480 colorectal adenocarcinoma cells 4. Determination of the biological role of the IR-A in SW480 cells co-expressing the IGF1R The key findings from this work included: 1. The IR-A could not compensate for IGF1R depletion in SW480 cells 2. Dual silencing of the IR-A and IGF1R indicated signaling via the IGF1R was dominant to signaling via the IR-A in SW480 cells 3. Signaling via IR-A/IGF1R hybrid receptors may not be as potent as signaling via IGF1R homodimers 4. IGF-I at physiological concentrations can stimulate biological responses via both isoforms of the IR. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1337339 / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2008

Cell receptors.

Colon (Anatomy) Cancer.

Rectum Cancer.

Insulin-like growth factor receptors in colorectal cancer.

Brierley, Gemma Victoria

January 2008

The IGF system is a crucial regulator of normal growth and development, however dysregulation of the system on multiple levels is associated with the incidence of a wide variety of malignancies including the breast, thyroid, lung, and colon, making the IGF system an important anti-cancer therapeutic target. Due to its role in mediating cellular proliferation, protection from apoptosis, and metastasis, traditional focus has been set on examining the role of the type 1 IGF receptor [IGF1R] in cancer. However there is mounting evidence to suggest the insulin receptor [IR] may also be involved in the potentiation and pathogenesis of cancers. The observation that IGF-II is overexpressed, compared to normal tissues, by cancers suggests signaling via target receptors by this ligand has important implications on cancer pathogenesis. Indeed, both the IGF1R and IR have been demonstrated to be up-regulated in a variety of malignancies. In regards to IR isoform, the IGF-II binding IR-A is preferentially expressed by a number of cancer cell types. Together with the observation that an autocrine proliferative loop exists between IGF-II and the IR-A in malignant thyrocytes and cultured breast cancer cells, suggests signaling via the IR-A may play a role in cancer cell growth and survival. However, very few studies on the IR-A have been conducted in cells co-expressing the IGF1R. This is mainly due to the difficulties associated with discrimination between signaling arising from IGF1R homodimers, IR-A homodimers, and IGF1R/IR-A hybrid receptors. It is not known how the IR-A interacts, and functions in conjunction with the other receptors of the IGF system to signal biologically relevant outcomes, especially in terms of anti-cancer therapeutics that aim to block and down-regulate the IGF1R. Current anti-cancer therapies targeting the IGF system have concentrated on blocking IGF signaling via the IGF1R, due mostly to the functional properties of the receptor, but also in part due to the metabolic consequences associated with blockade and inhibition of the IR. This individual targeting of the IGF1R potentially leaves a pathway by which IGF-II secreted by the tumour can circumvent current IGF1R based therapies. Consequently, this thesis investigated whether the IR-A could compensate for the targeted loss of the IGF1R and how the IR-A interacts with the IGF1R in cells co-expressing these two receptors. In addition, the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation was assessed. The main experimental techniques used throughout this body of work included; assessment of protein expression and activation by Western blot, siRNA mediated gene silencing, and measures of cell proliferation, survival, and migration. The key areas of investigation included: 1. Investigation of the individual ability of the IR isoforms to signal biological outcomes in response to IGF stimulation 2. Identification of an appropriate cell line model in which to investigate the interactions between the IR-A and IGF1R 3. Optimisation of siRNA mediated knock-down of the IR-A and IGF1R in SW480 colorectal adenocarcinoma cells 4. Determination of the biological role of the IR-A in SW480 cells co-expressing the IGF1R The key findings from this work included: 1. The IR-A could not compensate for IGF1R depletion in SW480 cells 2. Dual silencing of the IR-A and IGF1R indicated signaling via the IGF1R was dominant to signaling via the IR-A in SW480 cells 3. Signaling via IR-A/IGF1R hybrid receptors may not be as potent as signaling via IGF1R homodimers 4. IGF-I at physiological concentrations can stimulate biological responses via both isoforms of the IR. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1337339 / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2008

Cell receptors.

Colon (Anatomy) Cancer.

Rectum Cancer.

The production and characterisation of transgenic disease models for retinal ocular neovascularisation

May, Leigh A.

January 2004

[Truncated abstract] One of the barriers to understanding and preventing proliferative diabetic retinopathy in humans has been the lack of an appropriate animal model. Historically dog, rat and mouse models of diabetic retinopathy have been studied but none of these exhibit the later changes of proliferative diabetic retinopathy. Animals can be rendered diabetic by surgical pancreatectomy or the use of chemicals such as allozan or streptozotocin or by feeding of a high galactose diet. Alternatively, spontaneous rodent models of diabetes have been examined such as the BB rat, KK mouse or NOD mouse. However, in each case the retinal vascular changes observed are those of early nonproliferative diabetic retinopathy comprising at most saccular microaneurysms, increased thickness of the capillary basement membrane, acellular capillaries and pericyte ghosts. … Fluorecein angiography of this transgenic line clearly demonstrates the presence of leaky new vessels, by the appearance of leakage spots scattered throughout the retina from 1 month of age. These mice constitute a valuable model of diabetic retinopathy. Neovascularization in this animal model is induced by VEGF as in human diabetic retinopathy. The source of VEGF in human diabetic retinopathy is the ischemic inner retina. In this transgenic model the source of VEGF are the photoreceptor cells, which are situated just underneath the inner retina. The neovascularization is not dependent on a particular developmental stage and there is no spontaneous regression of new vessels. Thus any results generated in this model are highly relevant to human diabetic retinopathy.

Diabetic retinopathy -- Animal models

Neovascularization -- Animal models

Vascular endothelial growth factors

Transgenic mice