| 1. |
- Zeller, Kathrin Stephanie
(författare)
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Integrin Signaling in Cell Adhesion and Mechanotransduction : Regulation of PI3K, AKT, and ROS
- 2012
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Integrins are a family of conserved cell surface receptors found throughout the animal kingdom. They comprise 24 dimers in mammals, and regulate a number of processes including cell survival, differentiation, and migration. These complex cellular responses involve processes such as cell attachment, spreading, and various signaling pathways, which in turn depend on the composition of the extracellular environment, on its mechanical properties, and involved integrin types. This thesis focuses on identifying molecules that signal downstream of integrins and how integrin-induced signals may differ dependent on the type of mechanical stimulus that is given. In Paper I, we show that cell spreading and the activation of AKT is regulated by the catalytic PI3K isoform p110α. An intact β1 integrin cytoplasmic tail and actin polymerization was needed for spreading, whereas the presence of FAK or SRC, or the interaction between p110α and RAS was dispensable. Paper II reports that the RICTOR-mTOR complex (TORC2) acts as the kinase downstream of β1 integrins in order to phosphorylate AKT on Ser473, which was functionally linked to cell survival. β1 integrins activated both AKT1 and AKT2, but seemed to prefer AKT2. The investigation of several receptor types with regard to their requirement of TORC2, PAK, and ILK for AKT Ser473 phosphorylation revealed that different kinds of receptors engage specific enzyme combinations depending on cell type and context. In the third paper, we demonstrate that adhesion- and mechanical stretch-induced integrin signaling lead to divergent protein phosphorylation patterns, and that most signals from cell adhesion were not dependent on intracellular contractility. This indicates that integrin ligand binding and mechanical stretch induce signaling via distinct mechanisms. Reactive oxygen species (ROS) derived from different cellular sources modulated these responses. Stretching primarily induced phosphorylation of ERK1/2, and this signal was markedly increased by a derivative of the antioxidant ascorbate and extracellularly administered catalase. The robust AKT phosphorylation in response to adhesion was almost completely abolished with an inhibitor targeting mitochondrial ROS, whereas phosphorylation levels were only marginally affected in stretch assays. Similar results were obtained with siRNA knock-down of a critical subunit of ROS-producing NADPH oxidases.
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| 2. |
- van Wieringen, Tijs, 1979-
(författare)
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Intra- and Extracellular Modulation of Integrin-directed Connective Tissue Cell Contraction
- 2009
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- All blood vessels in the microvasculature are embedded in loose connective tissue, which regulates the transport of fluid to and from tissues. The intersti-tial fluid pressure (IFP) is one of the forces that control this transport. A lowering of IFP in vivo results in an increased transport of fluid from the circulation into the underhydrated connective tissues, resulting in edema formation. During homeostasis, contractile connective tissue cells exert a tension on the connective tissue fibrous network by binding with β1 in-tegrins, thereby actively controlling IFP. During inflammation, the IFP is lowered but platelet-derived growth factor (PDGF)-BB induces an IFP nor-malization dependent on integrin αVβ3. We demonstrate that extracellular proteins from Streptococcus equi subspecies equi modulated cell-mediated and integrin αVβ3-directed collagen gel contraction in vitro. One of these proteins, the collagen- and fibronectin binding FNE, stimulated contraction by a process dependent on fibronectin synthesis. This study identified a pos-sible novel virulence mechanism for bacteria based on the ability of bacteria to modulate the edema response. Another protein, the collagen-binding pro-tein CNE, inhibited contraction and this led to the identification of sites in collagen monomers that potentially are involved in connecting αVβ3 to the collagen network. PDGF-BB and prostaglandin E1 (PGE1) stimulate and inhibit collagen gel contraction in vitro and normalize and lower IFP, respec-tively. We showed that these agents affected both similar and different sets of actin-binding proteins. PDGF-BB stimulated actin cytoskeleton dynamics whereas PGE1 inhibited processes dependent on cytoskeletal motor and adhesive functions, suggesting that these different activities may partly ex-plain the contrasting effects of PGE1 and PDGF-BB on contraction and IFP. Mutation of the phosphatidylinositol 3’-kinase (PI3K), but not phospholipase C (PLC)γ activation site, rendered cells unable to respond to PDGF-BB in contraction and in activation of the actin binding and severing protein cofilin. Ability to activate cofilin after PDGF-BB stimulation correlated with ability to respond to PDGF-BB in contraction, suggesting a role for cofilin in this process downstream of PDGF receptor-activated PI3K. Many proteins can modulate contraction either by affecting the extracellular matrix and cell adhesions or by altering cytoskeletal dynamics. Knowledge on how these proteins might influence IFP is likely to be of clinical importance for treat-ment of inflammatory conditions including anaphylaxis, septic shock and also carcinoma growth.
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| 3. |
- Reyhani, Vahid
(författare)
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Extracellular Matrix and Actin Cytoskeleton - the Control Unit of Interstitial Fluid Volume
- 2014
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- The regulation of fluid (water) volume in the body is crucial for tissue homeostasis. The interstitial fluid, which comprises almost 20% of the body fluid, is stored in the loose connective tissue and its volume is actively regulated by components of this tissue. The loose connective tissue provides a path for fluid flow from capillaries to the tissue and lymphatics. This fluid is partially stored in the interstitium and the remainder is directed to the lymphatics. The fibroblasts in the loose connective tissue actively compact the fibrous extracellular matrix (ECM) through mechanotransduction via integrins. This in turn, maintains the interstitial fluid pressure and keeps the ground substance underhydrated. The interstitial fluid pressure is part of the forces that regulate the efflux of fluid from capillaries and keep the ground substance underhydrated. The underhydrated ground substance has a potential to take up fluid 3-fold the plasma volume. Therefore, the active contraction of the ECM via fibroblasts is crucial to prevent the risk of evacuation of fluid from capillaries. During pathologies, such as inflammation and carcinogenesis, the interstitial fluid pressure and hence the interstitial fluid volume is altered.The results presented in this thesis show that the signaling events downstream of αVβ3 integrin, collagen-binding β1 integrins, and platelet-derived growth factor receptor β, that induce cell-mediated matrix contraction, included paired function of PI3K and PLCγ, cofilin activation, actin turnover, and generation of actomyosin forces. Furthermore, the results highlight new potential roles for fibrin and αVβ3 integrins, for instance during clearance of edema. Notably, fibrin extravasation at inflammatory sites induced αVβ3 integrin-dependent matrix contraction, leading to normalization of the altered interstitial fluid volume. It also reprograms the expression of ECM-related genes and hence induces ECM turnover. Taken together, these results provide further insight into the regulatory mechanism through which the loose connective tissue actively regulates the interstitial fluid volume.
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