Signaling Pathways Involved in Mechanical Stimulation and ECM Geometry in Bone Cells

Jiang, Chang

27 July 2010

Indiana University-Purdue University Indianapolis (IUPUI) / The proliferation and differentiation of osteoblasts are influenced by mechanical and geometrical growth environments. A specific aim of my thesis was the elucidation of signaling pathways involved in mechanical stimulation and geometric alterations of the extracellular matrix (ECM). A pair of questions addressed herein was (a) Does mechanical stimulation modulate translational regulation through the phosphorylation of eukaryotic initiation factor 2 (eIF2)? (b) Do geometric alterations affect the phosphorylation patterns of mitogen-activated protein kinase (MAPK) signaling? My hypothesis was mechanical stress enhances the proliferation and survival of osteoblasts through the reduction in phosphorylation of eIF2, while 3-dimensional (3D) ECM stimulates differentiation of osteoblasts through the elevation of phosphorylation of p38 MAPK. First, mechanical stimulation reduced the phosphorylation of eIF2. Furthermore, flow pre-treatment reduced thapsigargin-induced cell mortality through suppression of phosphorylation of protein kinase RNA-like ER kinase (Perk). However, H2O2-driven cell mortality, which is not mediated by Perk, was not suppressed by mechanical stimulation. Second, in the ECM geometry study, the expression of the active (phosphorylated) form of p130Cas, focal adhesion kinase (FAK) and extracellular signal-regulated protein kinase (ERK) was reduced in cells grown in the 3D matrix. Conversely, phosphorylation of p38 MAPK was elevated in the 3D matrix and its up-regulation was linked to an increase in mRNA levels of dentin matrix protein 1 and bone sialoprotein. In summary, our observations suggest the pro-survival role of mechanical stimulation and the modulation of osteoblastic fates by ECM geometry.

Mechanical Stimulation; Osteoblast; ECM

Extracellular matrix

Bone cells

Phosphorylation

Study of Pulse Electrochemical Micromachining using Cryogenically Treated Tungsten Microtools

Balsamy Kamaraj, Abishek

January 2012

No description available.

Mechanics

Electrochemical micromachining

ECM

Cryogenic treatment

Corrosion

Cavitation

Tungsten

Fabrication of 3D hybrid scaffold by combination technique of electrospinning-like and freeze-drying to create mechanotransduction signals and mimic extracellular matrix function of skin

Aghmiuni, A.I., Heidari Keshel, S., Sefat, Farshid, AkbarzadehKhiyavi, A.

21 February 2021

Yes / Fabrication of extracellular matrix (ECM)-like scaffolds (in terms of structural-functional) is the main challenge in skin tissue engineering. Herein, inspired by macromolecular components of ECM, a novel hybrid scaffold suggested which includes silk/hyaluronan (SF/HA) bio-complex modified by PCP: [polyethylene glycol/chitosan/poly(ɛ-caprolactone)] copolymer containing collagen to differentiate human-adipose-derived stem cells into keratinocytes. In followed by, different weight ratios (wt%) of SF/HA (S1:100/0, S2:80/20, S3:50/50) were applied to study the role of SF/HA in the improvement of physicochemical and biological functions of scaffolds. Notably, the combination of electrospinning-like and freeze-drying methods was also utilized as a new method to create a coherent 3D-network. The results indicated this novel technique was led to ~8% improvement of the scaffold's ductility and ~17% decrease in mean pore diameter, compared to the freeze-drying method. Moreover, the increase of HA (>20wt%) increased porosity to 99%, however, higher tensile strength, modulus, and water absorption% were related to S2 (38.1, 0.32 MPa, 75.3%). More expression of keratinocytes along with growth pattern similar to skin was also observed on S2. This study showed control of HA content creates a microporous-environment with proper modulus and swelling%, although, the role of collagen/PCP as base biocomposite and fabrication technique was undeniable on the inductive signaling of cells. Such a scaffold can mimic skin properties and act as the growth factor through inducing keratinocytes differentiation.

Composite scaffolds

ECM components

Skin tissue engineering

Fabrication techniques

Keratinocytes

Specific ECM Engagement Differentially Modulates T Cell Cytoskeletal Reorganization By Rho GTPases

Xue, Feng

January 2009

No description available.

Integrins

ECM

fibronectin

CELL

PBT

RHO GTPASES

GTPASES

Tyramine Substituted-Hyaluronan Enriched Fascia for Rotator Cuff Tendon Repair

Chin, LiKang

07 July 2011

No description available.

Biomedical Engineering

ECM (extracellular matrix)

hyaluronan

biocompatibility

macrophage

tendon

Effect of alpha 2,6 Sialylation and Ionizing Radiation on Integrin-mediated Cell Adhesion and Cell Cycle Arrest

Yuan, Ye

January 2016

No description available.

Biochemistry

cell adhesion

integrins

sialylation

ECM

ionizing radiation

cell cycle

The Larval Requirement for Matrix Metalloproteinase-Mediated Remodelling of the Cardiac Extracellular Matrix in Drosophila melanogaster / Matrix Metalloproteinase Remodelling of the Extracellular Matrix

Hughes, Chris

06 1900

The Drosophila heart is a tubular vessel surrounded by a dynamic scaffold of extracellular matrix (ECM) proteins. Heart development and function rely upon protease-mediated remodelling and turnover of the ECM, and changes in ECM composition correlate with age and cardiac disease. Previous research has shown that a family of proteases called matrix metalloproteinases (MMPs), and their inhibitors (TIMPs), are necessary for normal cardiac cell migration and lumenogenesis. The Drosophila heart expands considerably throughout growth, but the role of MMP activity has not been elucidated at this time. I examine the role of the two Drosophila MMPs, MMP1 and MMP2, as well as TIMP, in defining larval heart structure and ECM protein distribution. I observe heart phenotypes via immunofluorescence labelling and confocal microscopy using loss-of-function mutants, gene over-expression, and gene knock-down techniques. Reduced MMP1 function during embryogenesis correlates with myofibrillar disorganisation, whereas reduced MMP2 function or TIMP over-expression both result in cardia bifida as well as increased density and ectopic localisation of Collagen-IV and Pericardin. Post-embryonic MMP reduction compromises cardiac structural integrity but does not affect Pericardin localisation. Live imaging of the larval heart with optical coherence tomography (OCT) and light microscopy reveals that reduced MMP2 function correlates with decreased heart rate but not impaired dilation or contraction. These data suggest that MMP2 activity during embryogenesis is critical for larval heart development. In contrast, post-embryonic protease function appears to have a less pronounced effect on ECM protein distribution throughout larval development. / Thesis / Master of Science (MS) / The fruit fly (Drosophila) heart undergoes significant changes in organisation and size throughout development and growth. The heart is surrounded and supported by a network of extracellular matrix (ECM) proteins, which is regulated by proteases, including matrix metalloproteinases (MMPs). Previous research has shown that MMPs are required for normal heart formation. I demonstrate that a reduction in MMP activity during embryonic development results in larval heart defects and an increase in the disorganisation of ECM proteins around the heart, whereas reduction during larval development results in less pronounced protein mislocalisation. These findings are corroborated via over-expression of an MMP inhibitor.

ECM

Drosophila

MMP

heart

TIMP

remodelling

Collagen

Pericardin

Effects of mechanical stimulation on fibroblast-guided microstructural and compositional remodeling

De Jesús, Aribet M.

01 May 2016

Many physiological and pathological processes, such as wound healing and tissue remodeling, are heavily influenced by continuous mechanical cell-cell and cell-ECM communication. Abnormalities that may compromise the biomechanical communication between the cells and the ECM can have significant repercussions on these physiological and pathological processes. The state of the mechanical environment and the reciprocal communication of mechanical signals between the ECM and the cell during wound healing and aged dermal tissue regeneration may be key in controlling the quality of the structure and physical properties of regenerated tissue. This dissertation encompasses a series of studies developed for characterizing the effects of mechanical cues on altering and controlling tissue remodeling, and regeneration in the context of controlling scar formation during wound healing, and the maintenance and regeneration of the dermal extracellular matrix (ECM) during aging. In order to achieve this goal, in vitro models that contained some features of the provisional ECM, and the ECM of the dermis were developed and subjected to an array of quantifiable mechanical cues. Wound models were studied with different mechanical boundary conditions, and found to exhibit differences in initial short-term structural remodeling that lead to significant differences in the long-term synthesis of collagen after four weeks in culture. Dermal models seeded with fibroblasts from individuals of different ages were treated with a hyaluronic acid (HA)-based dermal filler. Changes in the mechanical environment of the dermal models caused by swelling of the hydrophilc HA, resulted in changes in the expression of mechanosensitive, and ECM remodeling genes, essential for the maintenance and regeneration of dermal tissue. Taken together, these data provide new insights on the role of mechanical signals in directing tissue remodeling.

publicabstract

Aging

ECM remodeling

Fibroblast-ECM interactions

In vitro tissue models

Multi-scale mechanical interactions

Wound healing

Framgångsfaktorer vid implementering av Enterprise Content Management / Success factors when implementing Enterprise Content Management

Pettersson, Emelie

January 2016

Enterprise Content Managment (ECM) är ett relativt nytt forskningsområde som fortfarande saknar vetenskaplig forskning (Alalwan & Weistroffer, 2012). Det finns ett uttryckt behov av att veta hur ECM system kan implementeras effektivt i verksamheter och detta har lett till att forskningsfrågan ” Vilka framgångsfaktorer finns vid implementering av Enterprise Content Management (ECM) system?” har formulerats. Genom en kvalitativ metodansats genomsöks tidigare publicerad litteratur som behandlar fältstudier för implementering av ECM system. I analyskapitlet presenteras två tabeller med de identifierade framgångsfaktorerna. Dessa har delats upp i två kategorier, organisatoriska och tekniska framgångsfaktorer, som kan resultera i en lyckad implementering av ECM system. Slutligen förs en diskussion som reflekterar över resultatet, vilka konsekvenser som framkommit från denna studie och var framtida forskning fortfarande behövs. / Enterprise Content Management (ECM) is a relatively new research area, which still lacks research (Alalwan & Weistroffer, 2012). There is an expressed need to know how ECM systems can be implemented effectively in organisations, and this has formulated the research question: “Which success factors can be found when implementing Enterprise Content Management (ECM) systems?”. By analysing previously published literature, to identify and compile the success factors that can be found in connection with implementation of ECM systems within organisations, a qualitative research method is used. In the analysis section two tables of identified success factors are presented. These have been divided in two categories, organizational and technological success factors, which can result in a successful implementation of an ECM system. Lastly, a discussion reflects upon the findings, on the implications this study brings into light and where future research is still needed.

Enterprise Content Management

ECM

success factors

information management

Enterprise Content Management

ECM

framgångsfaktorer

informationshantering

Information Systems

Two new distinct mechanisms drive epithelial folding in Drosophila wing imaginal discs

Sui, Liyuan

22 March 2018

Epithelial folding is an important morphogenetic process that is essential in transforming simple sheets of cells into complex three-dimensional tissues and organs during animal development (Davidson, 2012). Epithelial folding has been shown to rely on constriction forces generated by the apical actomyosin network (Martin et al., 2009; Roh-Johnson et al., 2012; Sawyer et al., 2010). However, the contributions of mechanical forces acting along lateral and basal cell surfaces to epithelial folding remain poorly understood. Here we combine live imaging with force measurements of epithelial mechanics to analyze the formation of two epithelial folds in the Drosophila larval wing imaginal disc. We show that these two neighboring folds form via two distinct mechanisms. These two folds are driven either by decrease of basal tension or increase of lateral tension, none of them depends on apical constriction. In the first fold, a local decrease in extracellular matrix (ECM) density in prefold cells results in a reduction of mechanical tension on the basal cell surface, leading to basal expansion and fold formation. Consistent with that, a local reduction of ECM by overexpression of Matrix metalloproteinase II is sufficient to induce ectopic folding. In the second fold a different mechanism is at place. Here basal tension is not different with neighboring cells, but pulsed dynamic F-actin accumulations along the lateral interface of prefold cells lead to increased lateral tension, which drives cell shortening along the apical-basal axis and fold formation. In this thesis I described two distinct mechanisms driving epithelial folding, both basal decrease and lateral increase in tension can generate similar morphological changes and promote epithelial folding in the Drosophila wing discs. / Die Faltung von Epithelien ist ein wichtiger morphogenetischer Prozess, der die Entstehung komplexer, dreidimensionaler Gewebe und Organe aus einfachen Zellschichten ermöglicht (Davidson, 2012). Es ist bekannt, dass Kräfte erzeugt durch das apikale Aktomyosin-Netzwerk wichtig sind für die erfolgreiche Faltung von Epithelien (Martin et al., 2009; Roh-Johnson et al., 2012; Sawyer et al., 2010). Die Rolle von mechanischen Kräften, die entlang der lateralen und basalen Seite wirken, ist jedoch kaum verstanden. Wir verbinden Lebendmikroskopie mit der Messung von mechanischen Eigenschaften, um die Entstehung von 2 Epithelfalten in den Imaginalscheiben von Drosophila zu verstehen. Wir können dadurch zeigen, dass die beiden Falten durch unterschiedliche Mechanismen entstehen. Sie entstehen entweder durch eine Verringerung der Spannung auf der basalen Seite oder durch eine Erhöhung der Spannung auf der lateralen Seite, aber keine von beiden entsteht durch zusammenziehende Kräfte auf der apikalen Seite. Die erste Falte entsteht durch eine lokale Verringerung der extrazellulären Matrix in den Vorläuferzellen, was zu einer Reduktion der Spannung auf der basalen Seite und zur Ausbildung der Falte führt. Die zweite Falte wird durch einen anderen Mechanismus ausgebildet. Hier ist nicht die Spannung auf der basalen Seite reduziert sondern dynamische Anreicherungen von F-Aktin auf der lateralen Seite resultieren in einer erhöhten lateralen Spannung, die zu einer Verkürzung der Zellen und damit zur Ausbildung einer Falte führt. In meiner Arbeit zeige ich 2 neue Mechanismen zur Entstehung von Epithelfalten auf, durch Absenken der Spannung auf der basalen oder Erhöhen auf der lateralen Seite.

info:eu-repo/classification/ddc/570

ddc:570