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Calcium Regulates Cyclic Compression-induced Early Changes In Chondrocytes During In Vitro Tissue FormationRaizman, Igal 15 February 2010 (has links)
A single application of cyclic compression to bioengineered cartilage improves tissue formation through cell shape changes that are mediated by α5β1 integrin and membrane-type metalloprotease (MT1-MMP). To determine if this response is controlled by calcium, we investigated how calcium regulated cell shape changes, MT1-MMP and integrin activity in response to stimulation. Stimulation-induced changes in cell shape and MT1-MMP expression were abolished with chelation of extracellular calcium, and reinstated with its re-introduction. Spreading and retraction were inhibited by blocking the stretch-activated and L-Type voltage-gated channels, respectively; channel blocking also inhibited MT1-MMP upregulation. Channels’ role was confirmed through treatment with calcium A23187 ionophore, which alleviated the effects of channel blocking. Calcium regulated the integrin-mediated signalling pathway, which was facilitated through the kinase Src. Both calcium- and integrin-mediated pathways converged on activating ERK in response to stimulation. Understanding the molecular mechanisms regulating chondrocyte mechanotransduction may lead to the development of improved bioengineered cartilage.
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Calcium Regulates Cyclic Compression-induced Early Changes In Chondrocytes During In Vitro Tissue FormationRaizman, Igal 15 February 2010 (has links)
A single application of cyclic compression to bioengineered cartilage improves tissue formation through cell shape changes that are mediated by α5β1 integrin and membrane-type metalloprotease (MT1-MMP). To determine if this response is controlled by calcium, we investigated how calcium regulated cell shape changes, MT1-MMP and integrin activity in response to stimulation. Stimulation-induced changes in cell shape and MT1-MMP expression were abolished with chelation of extracellular calcium, and reinstated with its re-introduction. Spreading and retraction were inhibited by blocking the stretch-activated and L-Type voltage-gated channels, respectively; channel blocking also inhibited MT1-MMP upregulation. Channels’ role was confirmed through treatment with calcium A23187 ionophore, which alleviated the effects of channel blocking. Calcium regulated the integrin-mediated signalling pathway, which was facilitated through the kinase Src. Both calcium- and integrin-mediated pathways converged on activating ERK in response to stimulation. Understanding the molecular mechanisms regulating chondrocyte mechanotransduction may lead to the development of improved bioengineered cartilage.
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The Role of Wnt Signaling in Bone MechanotransductionBullock, Whitney Ann 11 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The aging US population is experiencing a growing incidence of osteoporosis,
characterized by increased fracture risk and low bone mass. In skeletal tissue, canonical
Wnt signaling is a critical regulator of bone mass, and dysregulation of the Wnt pathway
has been implicated in numerous skeletal displasias. Some components of the Wnt
signaling pathway have a clear role in bone homeostasis, particularly in the response of
bone to altered mechanical environment. Other pathway components are more poorly
defined. One important intracellular signal transduction node in the Wnt cascade is β-
catenin, which modulates gene expression and cell-cell junctions, among other functions.
During periods of disuse, β-catenin is degraded, leading to inhibition of Wnt targets.
Here, I characterize the role of β-catenin in bone during a disuse challenge, using a
genetic mouse model expressing an inducible constitively-active mutant form of β-
catenin in the osteocyte population. I hypothesize that prevention of β-catenin
degradation during disuse will prevent the bone wasting effects of mechanodeprivation.
As a second goal, I focus on upstream (membrane-bound) modulation of Wnt. Here, I
investigate the low-density lipoprotein receptor-related receptor 4 (Lrp4), in the
regulation of bone mass and mechanotransduction. I generated an Lrp4 knockin mouse
model harboring a missense mutation found among human patients with abnormally high
bone mass. I hypothesize that the mutation compromises sclerostin action on bone cells.
Understanding how each of these components of the Wnt signaling pathway interact, may
lead to novel therapeutic targets for treatment of bone diseases.
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Mechanotransduction of subcellular AMPK and its role in breast cancer cell migrationSteele, Hannah E. 04 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The biophysical microenvironment of the tumor site has significant impact on breast cancer progression and metastasis. The importance of altered mechanotransduction in cancerous tissue through the integrin-mediated signaling axis has been documented, yet its role in the regulation of cellular metabolism and the potential link between cellular energy and cell migration remain poorly understood.
In this study, we investigated the role of mechanotransduction (via Src and FAK) in AMP-activated protein kinase (AMPK) activation in breast cancer cells in response to interstitial fluid flow. Additionally, we explored the involvement of AMPK in breast cancer cell migration. An in-vitro three-dimensional (3D) cell culture model utilizing collagen-Matrigel matrices was used. Interstitial fluid flow was applied to the 3D cell-matrix construct inside a flow chamber. The sub-cellular signaling activity of Src, FAK, and AMPK was visualized in real-time using fluorescent resonance energy transfer (FRET). We observed that breast cancer cells (MDA-MB-231) are more sensitive to interstitial fluid flow than normal epithelial cells (MCF-10A) in the regulation of FAK and Src. AMPK was activated in the mitochondria of MDA-MB-231 cells by interstitial fluid flow, but not in other subcellular domains (i.e., cytosol, plasma membrane, and nucleus). Subcellular AMPK in MCF-10A cells did not respond to interstitial fluid flow. The inhibition of FAK or Src abolished flow-induced AMPK activation in the mitochondria of MDA-MB-231 cells. We also observed that global AMPK activation reduced MDA-MB-231 cell migration. Interestingly, specific AMPK inhibition in the mitochondria reduced cell migration and blocked interstitial fluid flow-induced cell migration.
Our results suggest the linkage of FAK/Src and mitochondria-specific AMPK in mechanotransduction and the dual role of AMPK in breast cancer cell migration depending on its subcellular activation. Therefore, subcellular AMPK activation may play an important and distinct role in cancer invasion and progression.
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Mechanisms of E-cadherin mechanotransductionBays, Jennifer McQuown 01 January 2017 (has links)
Cells experience force throughout their lifetimes. Cells sense force via adhesion receptors, such as the cadherins, which anchor cells to neighboring cells, and integrins, which tether cells to the underlying matrix. Both adhesion receptors respond to force by activating signaling pathways inside the cell. These pathways trigger growth of adhesion complexes and reinforcement of the cytoskeleton in order to resist the force. These activities are energetically costly. Thus, mechanisms are needed to couple force transmission and energy production.
In this thesis, I demonstrated force on cadherins activates a master regulator of energy homeostasis known as AMP-activated kinase (AMPK). In response to force, AMPK was recruited to the cadherins. AMPK promoted growth of the adhesion complex and cytoskeletal reinforcement by stimulating energy production in the cell. Additionally, AMPK formed a complex with vinculin—a protein that is recruited to both cadherins and integrins. I observed AMPK activation of vinculin dictates whether vinculin joins the cadherin complex. Conversely, AMPK activation has no bearing on vinculin recruitment to integrins.
This work provides three novel contributions: (1) the first link between energy production and force transmission, (2) a molecular mechanism for how AMPK increases adhesion complex growth, and (3) an explanation for how vinculin discriminates between cadherins and integrins.
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Role of Mechanical Strain on the Cardiomyogenic Differentiation of Periodontal Ligament Derived Stem CellsPelaez, Daniel 08 April 2011 (has links)
The application of cellular therapies for the treatment of myocardial infarction has provided encouraging evidence for the possibility of cellular therapies to restore normal heart function. However, questions still remain as to the optimal cell source, pre-conditioning methods and delivery techniques for such an application. Here I propose the use of a unique population of stem cells arising from the embryonic neural crest. These cells were shown to express neural crest markers as well as pluripotency-associated markers. Furthermore, the cells were shown to express proteins essential to the formation of gap junctions and to possess a cardiomyogenic differentiation potential by several means. Furthermore, I explore the use of mechanical strain as an inducer of cardiomyogenesis and possibly pre-conditioning stimulus for the better engraftment of the cells while in the heart. Mechanical strain was shown to elicit a cardiomyogenic response from the cells following just a couple of hours of stimulation. The mode in which mechanical strain elicited these responses was demonstrated to be via the mediation of the reactive oxygen species (ROS) pathways. Given the results presented here, the use of these periodontal ligament-derived stem cells (PDLSC) in combination with mechanical strain preconditioning of the cells prior to their delivery into the heart may pose a valuable alternative for the treatment of myocardial infarction and merits further exploration for its capacity to augment the already observed beneficial effects of cellular therapies.
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Force Transduction and Strain Dynamics through Actin Stress Fibres of the CytoskeletonGuolla, Louise 29 September 2011 (has links)
It is becoming clear that mechanical stimuli are critical in regulating cell biology; however, the short-term structural response of a cell to mechanical forces remains relatively poorly understood. We mechanically stimulated cells expressing actin-EGFP with controlled forces (0-20nN) in order to investigate the cell’s structural response. Two clear force dependent responses were observed: a short-term local deformation of actin stress fibres and a long-term force-induced remodelling of stress fibres at cell edges, far from the point of contact. We were also able to quantify strain dynamics occurring along stress fibres. The cell exhibits complex heterogeneous negative and positive strain fluctuations along stress fibres, indicating localized dynamic contraction and expansion. A ~50% increase in myosin contractile activity is apparent following application of 20nN force. Directly visualizing force-propagation and stress fibre strain dynamics has revealed new information about the pathways involved in mechanotransduction which ultimately govern the downstream response of a cell.
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Effects of Cyclic Hydraulic Pressure on OsteocytesLiu, Chao 10 January 2011 (has links)
Bone changes composition and structure to adapt to its mechanical environment. Osteocytes are putative mechanosensors responsible for orchestrating the bone remodeling process. Recent in vitro studies showed that osteocytes could sense and respond to substrate strain and fluid shear. However the capacity of osteocytes to sense cyclic hydraulic pressure (CHP) associated with physiological mechanical loading is not well understood. In this study, osteocyte-like MLO-Y4 cells were subjected to CHP of 68 kPa at 0.5 Hz, and the effects of CHP on intracellular calcium concentration, cytoskeleton organization, mRNA expression of genes related to bone remodeling, and osteocyte apoptosis were investigated. The results indicate that osteocytes could sense CHP and respond by increased intracellular calcium concentration, altered microtubule organization, an increase in COX-2 mRNA level and RANKL/OPG mRNA ratio, and decreased apoptosis. Therefore cyclic hydraulic pressure in bone a mechanical stimulus to osteocytes and may play a role in regulating bone remodeling.
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Effects of Cyclic Hydraulic Pressure on OsteocytesLiu, Chao 10 January 2011 (has links)
Bone changes composition and structure to adapt to its mechanical environment. Osteocytes are putative mechanosensors responsible for orchestrating the bone remodeling process. Recent in vitro studies showed that osteocytes could sense and respond to substrate strain and fluid shear. However the capacity of osteocytes to sense cyclic hydraulic pressure (CHP) associated with physiological mechanical loading is not well understood. In this study, osteocyte-like MLO-Y4 cells were subjected to CHP of 68 kPa at 0.5 Hz, and the effects of CHP on intracellular calcium concentration, cytoskeleton organization, mRNA expression of genes related to bone remodeling, and osteocyte apoptosis were investigated. The results indicate that osteocytes could sense CHP and respond by increased intracellular calcium concentration, altered microtubule organization, an increase in COX-2 mRNA level and RANKL/OPG mRNA ratio, and decreased apoptosis. Therefore cyclic hydraulic pressure in bone a mechanical stimulus to osteocytes and may play a role in regulating bone remodeling.
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Force Transduction and Strain Dynamics through Actin Stress Fibres of the CytoskeletonGuolla, Louise 29 September 2011 (has links)
It is becoming clear that mechanical stimuli are critical in regulating cell biology; however, the short-term structural response of a cell to mechanical forces remains relatively poorly understood. We mechanically stimulated cells expressing actin-EGFP with controlled forces (0-20nN) in order to investigate the cell’s structural response. Two clear force dependent responses were observed: a short-term local deformation of actin stress fibres and a long-term force-induced remodelling of stress fibres at cell edges, far from the point of contact. We were also able to quantify strain dynamics occurring along stress fibres. The cell exhibits complex heterogeneous negative and positive strain fluctuations along stress fibres, indicating localized dynamic contraction and expansion. A ~50% increase in myosin contractile activity is apparent following application of 20nN force. Directly visualizing force-propagation and stress fibre strain dynamics has revealed new information about the pathways involved in mechanotransduction which ultimately govern the downstream response of a cell.
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