Regulation of gene expression and cell cycle progression by cell shape

Promwikorn, Waraporn

January 2002

No description available.

571

Cell spreading

Kinetics of cell attachment and spreading on hard and soft substrates

Redmann, Anna-Lena

January 2019

A very important aspect for the functioning of an organism is that cells adapt their behaviour to external stimuli. They continuously interact with their environment, and biochemical and physical cues can activate cellular signalling, which leads to changes in cell behaviour such as proliferation and shape. Understanding cells' interactions with their environment is also important for understanding diseases. For example mechanosensing, which is the sensing of the cell's mechanical environment, has been associated with cancer development. In order for a cell to be able to sense its mechanical environment, it needs to form attachments to the environment. In my thesis, I have worked on three different tasks: the development of a new measurement technique and the study of initial cell adhesion and of cell spreading. When a cell from suspension first comes into contact with a substrate, it forms initial attachment bonds with proteins on the substrate surface. These bonds are mediated through integrins, which are transmembrane heterodimers, binding to the cell's environment on one side and to the cell's cytoskeleton on the other side. I study this initial cell attachment by measuring the force needed to detach cells, called cell adhesion strength. For these experiments I built a detachment device, which allows the detachment of cells from a substrate by vibrating the substrate in liquid. The device combines cell incubation, detachment and imaging. I measured the dependence of initial integrin bond formation on external factors such as incubation temperature and substrate stiffness. Once initial integrin bonds are formed, many different proteins are recruited to the adhesion site in order to form stronger adhesions. Amongst these proteins are signalling proteins, which direct the behaviour of the cell as a whole. One of the first cellular reactions to a substrate after initial integrin binding is cell spreading. This can be seen by the cell changing its shape from spherical to dome-like on the substrate. Because cell spreading is a very early response of a cell to a substrate, the onset time of spreading can be used as a quantitative measure for the time it takes the cell to sense a substrate and signal shape change. In my work, I look at the distribution of the time of initial cell spreading in a population of cells. I measure this distribution under different growth conditions such as pH, change of incubation medium from DMEM to PBS, substrate stiffness and incubation temperature. In my detachment experiments, I observe that vibration accelerates cell spreading in those cells which remain on the substrate. This is a connection between the detachment experiments and the cell spreading experiments and it shows how cells react to external forces. By changing the medium temperature in the cell detachment and cell spreading experiments, I am able to analyse the kinetics of these two processes. I use a signalling network model to analyse the internal cellular signalling path that leads from a spherical to a spread cell.

Transglutaminase II: an integrator of fibroblast adhesion pathways in wound healing.

Mearns, Bryony Megan, BABS, UNSW

January 2006

Transglutaminase II (TG2) is a complex protein with five different reported activities. Increases in TG2 expression and TGase activity have previously been observed during wound healing in rat studies; however, it has been unclear whether these phenomena were directly involved in the healing process or if they were simply a by-product of it. The aims of this thesis were, thus, to determine if TG2 plays a role in wound healing in vivo and to elucidate the mechanism of any effects TG2 may have at the cellular level. TG2 ablation resulted in delayed wound healing. To gain mechanistic insight into this abnormality, primary fibroblast cultures from TG2-knockout and wildtype mouse embryos were analysed. TG2-null fibroblasts displayed decreased adhesion and integrin signalling during initial stages of adhesion. Intriguingly, TG2-null cells showed faster activation of Rac1 and RhoA in response to adhesion. Long-term adhesion of TG2-null fibroblasts resulted in increased basal phosphorylation of FAK and number of paxillin-stained focal adhesions, enhanced PI3-kinase signalling, faster actin dynamics and altered activation of p44/42 MAPK. These results are indicative of futile cycling of intracellular signalling pathways resulting from reduced focal adhesion turnover in the TG2-knockout fibroblasts. Rescue experiments demonstrated that TG2-mediated effects on cell adhesion occurred in the extracellular environment and that neither GTP-binding nor TGase activity is required for these effects. Results further showed that a ???compact??? conformation of TG2 was not required for this role of TG2. Interestingly, addition of recombinant TG2 to the extracellular environment increased cell spreading of TG2-null cells to a level far greater than that seen in wildtype cells, which did not increase their spreading in response to exogenous TG2. Demonstration of faster activation of the small GTPases in the TG2-null MEFs, and the apparent inhibition of exogenous TG2???s extracellular effects on cell spreading by endogenous protein in the wildtype cells, provide tantalising evidence for a role for intracellular TG2 in regulating activation of the small GTPases to promote efficient fibroblast migration. This work identifies TG2 as a facilitator of efficient wound closure through extracellular effects on integrin-mediated signalling and intracellular effects on activation of the small GTPases.

transglutaminase

adhesion

cell spreading

wound healing

Disruption of Cell Spreading by the Activation of MEK/ERK Pathway is Dependent on AP-1 Activity

Xu, Feng, Ito, Satoko, Hamaguchi, Michinari, Senga, Takeshi

08 1900

No description available.

MEK

ERK

AP-1

BATF

Cell spreading

Transglutaminase II: an integrator of fibroblast adhesion pathways in wound healing.

Mearns, Bryony Megan, BABS, UNSW

January 2006

Transglutaminase II (TG2) is a complex protein with five different reported activities. Increases in TG2 expression and TGase activity have previously been observed during wound healing in rat studies; however, it has been unclear whether these phenomena were directly involved in the healing process or if they were simply a by-product of it. The aims of this thesis were, thus, to determine if TG2 plays a role in wound healing in vivo and to elucidate the mechanism of any effects TG2 may have at the cellular level. TG2 ablation resulted in delayed wound healing. To gain mechanistic insight into this abnormality, primary fibroblast cultures from TG2-knockout and wildtype mouse embryos were analysed. TG2-null fibroblasts displayed decreased adhesion and integrin signalling during initial stages of adhesion. Intriguingly, TG2-null cells showed faster activation of Rac1 and RhoA in response to adhesion. Long-term adhesion of TG2-null fibroblasts resulted in increased basal phosphorylation of FAK and number of paxillin-stained focal adhesions, enhanced PI3-kinase signalling, faster actin dynamics and altered activation of p44/42 MAPK. These results are indicative of futile cycling of intracellular signalling pathways resulting from reduced focal adhesion turnover in the TG2-knockout fibroblasts. Rescue experiments demonstrated that TG2-mediated effects on cell adhesion occurred in the extracellular environment and that neither GTP-binding nor TGase activity is required for these effects. Results further showed that a ???compact??? conformation of TG2 was not required for this role of TG2. Interestingly, addition of recombinant TG2 to the extracellular environment increased cell spreading of TG2-null cells to a level far greater than that seen in wildtype cells, which did not increase their spreading in response to exogenous TG2. Demonstration of faster activation of the small GTPases in the TG2-null MEFs, and the apparent inhibition of exogenous TG2???s extracellular effects on cell spreading by endogenous protein in the wildtype cells, provide tantalising evidence for a role for intracellular TG2 in regulating activation of the small GTPases to promote efficient fibroblast migration. This work identifies TG2 as a facilitator of efficient wound closure through extracellular effects on integrin-mediated signalling and intracellular effects on activation of the small GTPases.

transglutaminase

adhesion

cell spreading

wound healing

Involvement of CD45 in early thymocyte development

Lai, Jacqueline Cheuk-Yan

05 1900

CD45 is a protein tyrosine phosphatase that is expressed on all nucleated hematopoietic cells. The major substrates of CD45 in thymocytes and T cells are the Src family kinases Lck and Fyn. The role of CD45 in thymocyte development and T cell activation via its regulation of Src family kinases in T cell receptor signaling has been studied extensively. However, the role of CD45 in processes that affect thymocyte development prior to the expression of the T cell receptor has not been explored. The overall hypothesis of this study was that CD45 is a regulator of spreading, migration, proliferation, and differentiation of early thymocytes during development in the thymus and the absence of CD45 would alter the outcome of thymocyte development. The first aim was to determine how CD45 regulates CD44-mediated signaling leading to cell spreading. The interaction between CD44 and Lck was first examined. CD44 associated with Lck in a zinc-dependent and a zinc-independent manner. Mutation analysis localized the zinc-dependent interaction to the membrane proximal region of CD44, but did not involve individual cysteine residues on CD44. CD44 and Lck co-localized in microclusters upon CD44-mediated cell spreading. CD45 co-localized with Lck and CD44 in microclusters and with F-actin in ring structures. The recruitment of CD45 to microclusters may be a mechanism of how CD45 negatively regulates CD44-mediated spreading. The second specific aim was to determine the role of CD45 in migration, proliferation, and progression and differentiation of early thymocytes. CD45 negatively regulated CXCL12-mediated migration, and positively regulated the proliferation and progression of CD117- DN1 thymocytes. Absence of CD45 led to an altered composition of thymic subsets. The CD45-/- thymus contained decreased numbers of ETPs and an aberrant CD117- DN1 population that lacked CD24, TCRbeta, and CCR7 expression. There were also increased thymic NK and gamma/delta T cells, but decreased NKT cells. In addition, a novel intermediate between DN1 and DN2 that required Notch for progression was identified. Overall, this study identified new roles for CD45 in early thymocytes and provided a better picture of how the development of T cells, a central component of the immune system, is regulated.

CD45

T cell development

Thymocyte

Migration

Cell spreading

CD44

Lck

Involvement of CD45 in early thymocyte development

Lai, Jacqueline Cheuk-Yan

05 1900

CD45 is a protein tyrosine phosphatase that is expressed on all nucleated hematopoietic cells. The major substrates of CD45 in thymocytes and T cells are the Src family kinases Lck and Fyn. The role of CD45 in thymocyte development and T cell activation via its regulation of Src family kinases in T cell receptor signaling has been studied extensively. However, the role of CD45 in processes that affect thymocyte development prior to the expression of the T cell receptor has not been explored. The overall hypothesis of this study was that CD45 is a regulator of spreading, migration, proliferation, and differentiation of early thymocytes during development in the thymus and the absence of CD45 would alter the outcome of thymocyte development. The first aim was to determine how CD45 regulates CD44-mediated signaling leading to cell spreading. The interaction between CD44 and Lck was first examined. CD44 associated with Lck in a zinc-dependent and a zinc-independent manner. Mutation analysis localized the zinc-dependent interaction to the membrane proximal region of CD44, but did not involve individual cysteine residues on CD44. CD44 and Lck co-localized in microclusters upon CD44-mediated cell spreading. CD45 co-localized with Lck and CD44 in microclusters and with F-actin in ring structures. The recruitment of CD45 to microclusters may be a mechanism of how CD45 negatively regulates CD44-mediated spreading. The second specific aim was to determine the role of CD45 in migration, proliferation, and progression and differentiation of early thymocytes. CD45 negatively regulated CXCL12-mediated migration, and positively regulated the proliferation and progression of CD117- DN1 thymocytes. Absence of CD45 led to an altered composition of thymic subsets. The CD45-/- thymus contained decreased numbers of ETPs and an aberrant CD117- DN1 population that lacked CD24, TCRbeta, and CCR7 expression. There were also increased thymic NK and gamma/delta T cells, but decreased NKT cells. In addition, a novel intermediate between DN1 and DN2 that required Notch for progression was identified. Overall, this study identified new roles for CD45 in early thymocytes and provided a better picture of how the development of T cells, a central component of the immune system, is regulated.

CD45

T cell development

Thymocyte

Migration

Cell spreading

CD44

Lck

Involvement of CD45 in early thymocyte development

Lai, Jacqueline Cheuk-Yan

05 1900

CD45 is a protein tyrosine phosphatase that is expressed on all nucleated hematopoietic cells. The major substrates of CD45 in thymocytes and T cells are the Src family kinases Lck and Fyn. The role of CD45 in thymocyte development and T cell activation via its regulation of Src family kinases in T cell receptor signaling has been studied extensively. However, the role of CD45 in processes that affect thymocyte development prior to the expression of the T cell receptor has not been explored. The overall hypothesis of this study was that CD45 is a regulator of spreading, migration, proliferation, and differentiation of early thymocytes during development in the thymus and the absence of CD45 would alter the outcome of thymocyte development. The first aim was to determine how CD45 regulates CD44-mediated signaling leading to cell spreading. The interaction between CD44 and Lck was first examined. CD44 associated with Lck in a zinc-dependent and a zinc-independent manner. Mutation analysis localized the zinc-dependent interaction to the membrane proximal region of CD44, but did not involve individual cysteine residues on CD44. CD44 and Lck co-localized in microclusters upon CD44-mediated cell spreading. CD45 co-localized with Lck and CD44 in microclusters and with F-actin in ring structures. The recruitment of CD45 to microclusters may be a mechanism of how CD45 negatively regulates CD44-mediated spreading. The second specific aim was to determine the role of CD45 in migration, proliferation, and progression and differentiation of early thymocytes. CD45 negatively regulated CXCL12-mediated migration, and positively regulated the proliferation and progression of CD117- DN1 thymocytes. Absence of CD45 led to an altered composition of thymic subsets. The CD45-/- thymus contained decreased numbers of ETPs and an aberrant CD117- DN1 population that lacked CD24, TCRbeta, and CCR7 expression. There were also increased thymic NK and gamma/delta T cells, but decreased NKT cells. In addition, a novel intermediate between DN1 and DN2 that required Notch for progression was identified. Overall, this study identified new roles for CD45 in early thymocytes and provided a better picture of how the development of T cells, a central component of the immune system, is regulated. / Science, Faculty of / Microbiology and Immunology, Department of / Graduate

CD45

T cell development

Thymocyte

Migration

Cell spreading

CD44

Lck

Murine Guanylate-Binding Protein-2: An interferon-induced GTPase that inhibits cell adhesion, cell spreading and MMP-9 expression

Messmer-Blust, Angela F.

27 January 2010

No description available.

Cellular Biology

GBP

IFN

MMP

cytoskeleton

TNF

cell spreading

Development of a Novel Single-Cell Attachment and Spreading Platform Utilizing Fused-Fiber Nanonets

Gill, Amritpal Singh

04 June 2015

Initial attachment to the extracellular matrix (ECM) and consequent spreading is a necessary process in the cell cycle of which little is known. Cell spreading has been well-recognized in 2D systems, however, the native fibrous ECM presents cells with 3D biophysical cues. Thus, using suspended fibers as model systems, we present the development of a novel platform (Cell-STEPs) capable of capturing cell attachment dynamics and forces from the moment a cell in suspension contacts the fiber. Cell-STEPs comprises of a custom glass-bottom petri dish with a lid to deliver a constant supply of CO2 to maintain pH. Fibrous scaffolds are attached in the dish to allow cellular investigations over extended periods of time. We find that cell-fiber attachment occurs in three progressive phases: initial attachment of cell to fiber (phase 0), rapid drop in circularity (phase 1), and increase in cell spread area (phase 2). Furthermore, using iterative inverse methods, forces involved in cell spreading through deflection of fibers were estimated. Our findings provide new insights in attachment biomechanics, including initial sensing and latching of cell to fiber with a negligible or protrusive force, followed by rapid loss in circularity through protrusion sensing at nearly constant spread area and minimal force generation, transitioning to a final phase of increased contractile forces until spread area and force saturation is observed. Also, anisotropic spreading of cells on single and two-fibers are closely related, while cells attached to several fibers take longer and spread isotropically. The Cell-STEPs platform allows, for the first time, detailed interrogations in the discrete and orchestrated adhesion steps involved in cell-fibrous matrix recognition and attachment along with simultaneous measurements of forces involved in cell attachment. / Master of Science

nanofiber

attachment

cell force

cell spreading

single-cell