The Role of IκB kinase β in Redox Modulation

Peng, Zhimin

20 April 2009

No description available.

Toxicology

IKK&946

NF-&954

B

oxidative stress

arsenic

glutathione

TGF&946

Role of the EGFR Pathway in Lung Remodeling and Disease

Kramer, Elizabeth L.

January 2009

No description available.

Biology

EGFR

TGF-alpha

Egr-1

lung remodeling

house dust mite

airway smooth muscle remodeling

IkappaB Kinase beta in the Regulation of Cell Migration, Senescence and Fibrosis

Chen, Liang

19 April 2012

No description available.

Environmental Health

IKK&946

TGF&946

ROS

cornea

wound healing

fibrosis

A Study of Breast Cancer Cell Adhesion to Endothelium in Response to Cytokine Stimulus

Henson, Karissa A.

26 July 2010

No description available.

Biomedical Research

Breast Cancer

Cancer Stem Cells

Metastasis

E-selectin

Cell Adhesion

SDF-1

TGF-beta

Generation and utilization of knockout mice to elucidate the functions of the TGF-β pathway in mammalian endodermal specification and placental development

Liu, Ye

22 September 2006

No description available.

Biology, Genetics

TGF-&946

Generation of novel conditional and hypomorphic alleles of the Smad2 gene and the effects of Smad2 removal in environments with elevated retinoid signaling

Festing, Maria H.

25 June 2007

No description available.

Biology, Genetics

Smad2 null allele

HPE

Retinoid Signaling

TGF-beta signaling

Effector Th1 cells demonstrate self-regulation in a mouse model of Multiple Sclerosis

Huss, David J.

21 July 2011

No description available.

Immunology

Immune regulation

effector-memory T cell

EAE

MS

TGF-beta

IL-10

The Intricate Role of Connective Tissue Growth Factor (CTGF/CCN2) in Prenatal Osteogenesis: A Heretofore Oversimplified Dogma of the CCN Field

Lambi, Alex G.

January 2015

Connective tissue growth factor (CTGF/CCN2) is axiomatically necessary for proper skeletal development and function. We need not look further than the studies that have been done to date utilizing mice genetically engineered to lack CTGF production. These CTGF null or knockout (KO) mice fail to form a normal murine skeleton and instead yield one littered with bony dysmorphisms, including incompetent craniofacial development, kinked limb bones, and misshapen ribs that are not conducive to proper respiratory function. As a result, the global lack of CTGF is incompatible with postnatal life. A closer look at several sites demonstrated defects in physiologic processes necessary for bone formation - angiogenesis, chondrogenesis, and osteogenesis. Therefore, the dogma in the CCN protein field to date has been that systemic ablation of CTGF production in vivo results in global defects in bone development. We believe this dogma is an oversimplification of the role of CTGF on skeletal development. Our initial impetus leading us to this belief was the gross identification of the specific skeletal sites malformed in CTGF KO mice, in particular the bones of the limbs. While in the lower limb of CTGF KO mice the tibiae and fibulae are misshapen, the adjacent femora and digits are phenotypically normal. The same is true for the upper limb, in which the radii and ulnae are phenotypically abnormal while the humeri and digits are normal. Therefore, we believe that the role of CTGF in skeletogenesis is site-specific such that its loss affects local skeletal patterning and/or mechanobiological cues resulting in the unique phenotype seen in CTGF KO mice. The research of this dissertation constitutes a comprehensive skeletal analysis of CTGF KO mice and in so doing we determined the extent and location of skeletal abnormalities. We found skeletal site-specific changes in growth plate organization, bone microarchitecture and shape and gene expression levels in CTGF KO compared to wild-type (WT) mice. Growth plate malformations included reduced proliferation zone and increased hypertrophic zone lengths. Appendicular skeletal sites demonstrated decreased metaphyseal trabecular bone, while having increased mid-diaphyseal bone and osteogenic expression markers. Axial skeletal analysis showed decreased bone in caudal vertebral bodies, mandibles, and parietal bones in CTGF KO mice, with decreased expression of osteogenic markers. Analysis of skull phenotypes demonstrated global and regional differences in CTGF KO skull shape resulting from allometric (size-based) and non-allometric shape changes. Localized differences in skull morphology included increased skull width and decreased skull length. We further continued the skeletal characterization of CTGF KO bones with an analysis of bone cell ultrastructure and matrix composition. These studies demonstrated that, while CTGF is not necessary for complete morphologic maturation of bone cells, global ablation results in ultrastructural features not commonly seen in WT bones. Our findings include drastically dilated rough endoplasmic reticulum (RER) in osteoblasts of the tibial diaphyseal region, comprising the phenotypic kink in CTGF KO mice and ultrastructural dysmorphologies of CTGF KO osteoclasts including multi-layered, membranous inclusions, decreased vacuolization and ruffled border extents, and disproportionately large clear zones. Lastly, FT-IR analysis demonstrated heterogeneity in CTGF KO bone composition. The results of this dissertation have revealed a more complex role for CTGF in osteogenesis and have identified potential mechanisms and future research directions to fully understand this intricate story. / Cell Biology

Cellular Biology

Developmental Biology

Bone

Ccn2

Ctgf

Osteogenesis

Skull

Tgf-beta

Effects of different transforming growth factor beta (TGF-β) isomers on wound closure of bone cell monolayers

Sefat, Farshid, Denyer, Morgan C.T., Youseffi, Mansour

12 May 2014

no / This study aimed at determining the role of the transforming growth factor-beta (TGF-β) isomers and their combinations in bone cell behaviour using MG63 cells. The work examined how TGF-β1, 2 and 3 and their solvent and carrier (HCl and BSA, respectively) effected cell morphology, cell proliferation and integrin expression. This study also aimed at examining how the TGF-βs and their solvent and carrier influenced wound closure in an in vitro wound closure model and how TGF-βs influence extracellular matrix (ECM) secretion and integrin expression. The wound healing response in terms of healing rate to the TGF-βs and their solvent/carrier was investigated in 300 μm ± 10–30 μm SD wide model wounds induced in fully confluent monolayers of MG63 bone cells. The effect of different TGF-β isomers and their combinations on proliferation rate and cell length of human bone cells were also assessed. Immunostaining was used to determine if TGF-βs modifies integrin expression and ECM secretion by the bone cells. Imaging with WSPR allowed observation of the focal contacts without the need for immunostaining. The wound healing results indicated that TGF-β3 has a significant effect on the wound healing process and its healing rate was found to be higher than the control (p < 0.001), TGF-β1 (p < 0.001), TGF-β2 (p < 0.001), BSA/HCl (p < 0.001) and HCl (p < 0.001) in ascending order. It was also found that TGF-β1 and TGF-β2 treatment significantly improved wound closure rate in comparison to the controls (p < 0.001). All TGF-β combinations induced a faster healing rate than the control (p < 0.001). It was expected that the healing rate following treatment with TGF-β combinations would be greater than those healing rates following treatments with TGF-β isomers alone, but this was not the case. The results also suggest that cell morphological changes were observed significantly more in cells treated with TGF-β(2 + 3) and TGF-β(1 + 3) (p < 0.001). Any cell treated with TGF-β1, TGF-β(1 + 2) and TGF-β(1 + 2 + 3) showed significantly less elongation compared to the control and other TGF-β isomers. In terms of proliferation rate, TGF-β3 and TGF-β(2 + 3) increased cell numbers more than TGF-β1, TGF-β2 and other combinations. TGF-β1 and its combinations did not show significant proliferation and attachment compared to the control. Immunostaining indicated that treatment with TGF-β3 significantly enhanced the secretion of collagen type I, fibronectin and integrins α3 and β1. The WSPR experiments also indicated that TGF-βs influenced the distribution of focal contacts. In conclusion, combining TGF-β3 with any other TGF-β isomer resulted in a faster model wound closure rate (p < 0.001), while treatment with TGF-β1 in any TGF-β combination reduced the healing rate (p < 0.001). It can therefore be concluded that the presence of TGF-β1 has an inhibitory effect on bone wound healing while TGF-β3 had the opposite effect and increased the rate of wound closure in a 2 dimensional cell culture environment. / Emailed Mansour for final draft 27/06/2016

Effect of Transforming Growth Factor-β3 on mono and multilayer chondrocytes

Sefat, Farshid, Youseffi, Mansour, Khaghani, Seyed A., Soon, Chin Fhong, Javid, Farideh A.

22 April 2016

Yes / Articular cartilage is an avascular and flexible connective tissue found in joints. It produces a cushioning effect at the joints and provides low friction to protect the ends of the bones from wear and tear/damage. It has poor repair capacity and any injury can result pain and loss of mobility. Transforming growth factor-beta (TGF-β), a cytokine superfamily, regulates cell function, including differentiation and proliferation. Although the function of the TGF-βs in various cell types has been investigated, their function in cartilage repair is as yet not fully understood. The effect of TGF-β3 in biological regulation of primary chondrocyte was investigated in this work. TGF-β3 provided fibroblastic morphology to chondrocytes and therefore overall reduction in cell proliferation was observed. The length of the cells supplemented with TGF-β3 were larger than the cells without TGF-β3 treatment. This was caused by the fibroblast like cells (dedifferentiated chondrocytes) which occupied larger areas compared to cells without TGF-β3 addition. The healing process of the model wound closure assay of chondrocyte multilayer was slowed down by TGF-β3, and this cytokine negatively affected the strength of chondrocyte adhesion to the cell culture surface.