Cbx4 regulates the proliferation of thymic epithelial cells and thymus function.

Liu, B., Liu, Y.F., Du, Y.R., Mardaryev, Andrei N., Yang, W., Chen, H., Xu, Z.M., Xu, C.Q., Zhang, X.R., Botchkarev, Vladimir A., Zhang, Y., Xu, G.L.

January 2013

no / Thymic epithelial cells (TECs) are the main component of the thymic stroma, which supports T-cell proliferation and repertoire selection. Here, we demonstrate that Cbx4, a Polycomb protein that is highly expressed in the thymic epithelium, has an essential and non-redundant role in thymic organogenesis. Targeted disruption of Cbx4 causes severe hypoplasia of the fetal thymus as a result of reduced thymocyte proliferation. Cell-specific deletion of Cbx4 shows that the compromised thymopoiesis is rooted in a defective epithelial compartment. Cbx4-deficient TECs exhibit impaired proliferative capacity, and the limited thymic epithelial architecture quickly deteriorates in postnatal mutant mice, leading to an almost complete blockade of T-cell development shortly after birth and markedly reduced peripheral T-cell populations in adult mice. Furthermore, we show that Cbx4 physically interacts and functionally correlates with p63, which is a transcriptional regulator that is proposed to be important for the maintenance of the stemness of epithelial progenitors. Together, these data establish Cbx4 as a crucial regulator for the generation and maintenance of the thymic epithelium and, hence, for thymocyte development.

REF 2014

Critical characteristics for corticosteroid solution metered dose inhaler bioequivalence

Grainger, C.I., Saunders, M., Buttini, F., Telford, Richard, Merolla, L.L., Martin, G.P., Jones, S.A., Forbes, B.

15 October 2019

No / Determining bioequivalence for solution pressurized metered dose inhalers (pMDI) is difficult because the critical characteristics of such products are poorly defined. The aim of this study was to elucidate the non-aerodynamic properties of the emitted aerosol particles from two solution pMDI products that determine their biopharmaceutical differences after deposition. Novel particle capture and analysis techniques were employed to characterize the physicochemical and biopharmaceutical properties of two beclomethasone dipropionate (BDP) products: QVAR and Sanasthmax. The BDP particles emitted from the Sanasthmax inhaler were discernibly different those emitted from QVAR in terms of size (50% larger, less porous), solid state (less crystalline) and dissolution (20-fold slower). When deposited onto the surface of respiratory epithelial cell layers, QVAR delivered ∼50% more BDP across the cell layer in 60 min than Sanasthmax. Biopharmaceutical performance was not attributable to individual particle properties as these were manifold with summative and/or competing effects. The cell culture dissolution− absorption model revealed the net effect of the particle formed on drug disposition and was predictive of human systemic absorption of BDP delivered by the test inhalers. This illustrates the potential of the technique to detect the effect of formulation on the performance of aerosolized particles and contribute to assessment of bioequivalence. / This work was in part funded by a grant from the Safety and Environmental Assurance Centre, Unilever Colworth, U.K. Particle sizing was performed by Steve Ingham, Institute of Pharmaceutical Science, King’s College London.

Aerosol deposition

Aerosol formulation

Airway epithelial cell

Inhaled corticosteroids

Pressurized metered dose inhalers

THE ROLE OF SEMEN TRANSFORMING GROWTH FACTOR BETA 1 IN MODULATING IMMUNE RESPONSES DURING HIV-1 INFECTION / IMMUNE RESPONSES TO SEMINAL TGF-BETA 1

KAFKA, JESSICA KATHERINE

08 May 2015

Thirty five million people are currently living with HIV-1 today with women accounting for half of infected individuals globally. Sexual transmission is the main route of HIV transmission with approximately 40% of HIV infections occurring when the mucosal lining of the female genital tract (FGT) is exposed to HIV in semen from an infected male partner. Seminal plasma (SP), the fluid portion of semen, is a complex fluid which plays an immunomodulatory role in the FGT for successful conception, largely due to its high concentrations of TGF-β1. Several factors in SP from HIV-uninfected men have been shown to either inhibit or enhance HIV infection in target cells, however it is not clear how SP from HIV infected men would modulate genital epithelial cells (GECs), the first cells that encounter HIV in the FGT. The overall goals of this thesis were to compare inflammatory and regulatory cytokine concentrations in SP from HIV-uninfected and infected men, and subsequently compare GEC cytokine responses following exposure to SP from HIV-uninfected and HIV-infected men. I also investigated how SP and TGF-β regulated cytokine production and barrier function in GECs in the presence of HIV. The results summarized in this thesis demonstrated that HIV infection leads to different cytokine profiles in SP, based on stage of HIV-1 infection. HIV-infected men in acute stage contained higher levels of proinflammatory cytokines in their SP compared to HIV-uninfected and chronically infected men (CI men) which subsequently lead to higher levels of proinflammatory cytokines from GECs compared to CI men. In the follow up to this study we found that active TGF-β, which was found in higher concentrations in SP from CI men and led to decreased inflammatory response from GECs, was compartmentalized between blood plasma and seminal plasma. Higher levels of active TGF-β in SP correlated with decreased semen viral load and the immune activation marker sCD14 leading us to believe that ART-naive CI men in our cohort were naturally controlling their immune activation status, as active TGF-β levels were lower in ART-treated men. Short-term exposure of GECs to SP from CI men or TGF-β at comparable concentrations to SP protected the GEC barrier against HIV by decreasing inflammatory cytokines and preventing tight junction breakage. However, long-term exposure to TGF-β in the presence of HIV further increased inflammation in GECs suggesting a biphasic role for TGF-β in the FGT. This body of work summarized in this thesis demonstrates for the first time how semen from HIV-infected men modulates FGT epithelial cell cytokine responses and barrier function, an important consideration in the design of local therapeutic strategies to protect the FGT against HIV infection. / Thesis / Doctor of Philosophy (Medical Science)

Semen

TGF-Beta 1

HIV-1

Female Genital Tract

Male Genital Tract

Epithelial Cell

Mucosal Immunity

Mechanisms of Particulate Matter-Induced Experimental Asthma

Saunders, Vanessa C.

13 April 2010

No description available.

Immunology

Asthma

Particulate Matter

Lung

T Cell

Dendritic Cell

Epithelial Cell

The Novel Inhibitory Role of CCL20 in Allergic Asthma

Phelan, Jordan D.

11 September 2015

No description available.

Immunology

Allergic asthma

CCL20

epithelial cell

immune regulation

DNA

dendritic cell

Laminar Inflammation and the Equine Epidermal Epithelial Cell: Determining the Role in Laminar Failure

Leise, Britta S.

January 2010

No description available.

Veterinary Services

laminitis

horse

equine

inflammation

keratinocyte

laminar epithelial cell

gene expression

Lens Epithelial Cell Migrational Model: Understanding Motile Behaviour During Posterior Capsule Opacification on Natural and Synthetic Substrates

Marshall, Meghan

12 1900

Cataract surgery is currently the most common surgical procedure done in the world. However, within 5 years, approximately half of these patients will develop posterior capsule opacification (PCO). In cataract surgery, the biological lens is replaced with an intraocular lens (IOL). PCO is caused by migration and transformation of residual lens epithelial cells (LEC) that remain in the capsule following the surgery. LECs which have migrated to the posterior capsule within the first month of surgery are thought to be the major contributors to PCO since after this time, the capsule completely seals. A mathematical model has been developed in order to better understand the process of LEC migration during PCO. The model addresses the impact of substrate and substrate modification as well as the presence and absence of the growth factors transforming growth factor beta (TGF(beta)) and fibroblast growth factor (FGF2). It was developed from a first order rate of decay model taken from process control. If the cell speed is divided by the distance travelled by the cell up to the point of posterior capsule breach, the time for the LECs to breach the capsule posterior can be calculated. The model was tested with literature data and was able to predict the effects of cell speed on the presence of various extracellular matrix components and growth factors. It was determined that potentially modification with fibronectin may be useful for the prevention of PCO Preliminary experimental validation of the model was performed by modifying silicone substrates with various extracellular matrix derived peptides. Results demonstrate that peptide modified surfaces may be more resistant to EMT by increasing cell adhesion and decreasing cell migration. Therefore, this LEC migrational model will be a useful tool in the development of superior IOLs and materials. / Thesis / Master of Applied Science (MASc)

epithelial cell

migration

opacity

lens

behaviour

motile behaviour

natural substrate

synthetic substrate

THE ROLE OF INTESTINAL EPITHELIAL CELLS AND THE REGULATION OF THE POLYMERIC IMMUNOGLOBULIN RECEPTOR IN HOMEOSTASIS AND INFLAMMATION

Frantz, Aubrey Leigh

01 January 2012

The mammalian intestine harbors an estimated 100 trillion microorganisms, which normally maintain a mutually beneficial relationship with the host. The intestinal epithelium consists of a single layer of intestinal epithelial cells (IECs) that provides a physical barrier as well as innate immune defense, preventing this vast community of microbes from entering host tissues. Secretory immunoglobulin A (SIgA) acts as the first line of antigen-specific immunity at the interface between the gut microbiota and the intestinal epithelium. Polymeric IgA secreted by plasma cells in the intestinal lamina propria is transported across IECs by the polymeric immunoglobulin receptor (pIgR). Defects in epithelial barrier and immune functions can lead to infections with opportunistic and pathogenic microbes and contribute to the etiology of inflammatory bowel disease (IBD). Here we investigate the ability of IEC biomarkers to define the mechanism and severity of intestinal inflammation, as well as provide insight into the function of IEC in regulating intestinal homeostasis and inflammation. Importantly, down-regulation of pIgR expression was a common feature in human IBD and mouse models of experimental colitis. One molecule of pIgR is consumed for every molecule of SIgA transported, thus high expression of pIgR is required to maintain sufficient supply of SIgA. Accordingly, we investigate the mechanisms by which IECs regulate pIgR expression in response to colonic bacteria. Cross-talk between the microbiota and IECs is mediated by pattern recognition receptors, including Toll-like receptors (TLR), leading to expression of gene products that enhance epithelial barrier function and innate immunity. The cytoplasmic adaptor protein MyD88 transduces signals from TLRs that recognize bacterial products. We show that pIgR induction by colonic bacteria is dependent on TLR4-MyD88 activation of NF-κB signaling. We examined the role of epithelial-specific MyD88 signaling in antibacterial immunity and epithelial expression of key gene products that participate in innate immunity in the gut by generating mice with an IEC-targeted deletion of the Myd88 gene (MyD88ΔIEC). MyD88ΔIEC mice display immunological and antimicrobial defects resulting in increased susceptibility to experimental colitis. We conclude that cross-talk between bacteria and IECs via MyD88-dependent signaling is crucial for maintenance of gut homeostasis.

Intestinal epithelial cell (IEC)

polymeric immunoglobulin receptor (pIgR)

MyD88

IgA

Inflammatory Bowel Disease (IBD)

Immunology and Infectious Disease

Characterization of the Sterile20 kinase Slik : A regulator of growth in Drosophila

Nath, Apurba

02 1900

La prolifération cellulaire et la croissance tissulaire sont étroitement contrôlées au cours du développement. Chez la Drosophila melanogaster, ces processus sont régulés en partie par la kinase stérile-20 Slik (SLK et LOK chez les mammifères) et le suppresseur de tumeur Hippo (Hpo, MST1/2 chez les mammifères) dans les cellules épithéliales. La surexpression de la kinase Slik augmente la taille des tissus chez les mouches adultes. Cependant, les mutants slik-/- meurent avant d'avoir terminé leur développement. Lorsqu’elle est surexprimée dans les cellules épithéliales des ailes en voie de développement, cette protéine favorise la prolifération cellulaire. En outre, l'expression de Slik dans une population de cellules conduit à une surprolifération des cellules voisines, même quand elles sont physiquement séparées. Ceci est probablement dû à la sécrétion de facteurs de croissance qui stimulent la prolifération de manière paracrine. En utilisant des méthodes génétiques et transcriptomiques, nous essayons de déterminer les molécules et les mécanismes impliqués. Contrairement à ce qui a été publié, nous avons constaté que Slik ne transmet pas de signal prolifératif en inhibant le suppresseur de tumeur Merlin (Mer, NF2 chez les mammifères), un composant en amont de la voie Hippo. Plutôt, elle favorise la prolifération non-autonome et la croissance des tissus en signalisation par la kinase dRaf (la seule kinase de la famille Raf chez la drosophile). Nous prouvons que dRaf est nécessaire chez les cellules voisines pour conduire la prolifération chez ces cellules. De plus, nous avons utilisé le séquençage du transcriptome pour identifier de nouveaux effecteurs en aval de Slik. Ce qui permettra de mieux comprendre les effets de SLK et LOK chez les humains. / Cell proliferation and tissue growth are tightly controlled during development. In epithelial tissues in Drosophila melanogaster, these processes are regulated in part by the Sterile-20 kinase Slik (SLK and LOK in mammals) and the tumor suppressor Hippo (Hpo, MST1/2 in mammals). Slik overexpression leads to an increase in tissue size in flies, whereas, slik-/- mutants die before completing development. Overexpressing this protein in the developing wing disc epithelium promotes cell proliferation, consistent with the overgrown wing phenotype in the adults. Moreover, expression of Slik in one population of cells leads to an overproliferation of neighboring cells, even when they are physically separated by a central lumen. This can be explained by secretion of paracrine growth factors, stimulating non-autonomous proliferation that is specific to Slik. We used genetic and transcriptomic assays to define the molecules and mechanism involved in Slik-mediated signaling. Contrary to what has been suggested, we found that Slik does not promote proliferation through the tumor suppressor Merlin (Mer, NF2 in mammals), an upstream component of the Hippo pathway, nor through other components of the Hippo pathway. Rather, Slik promotes non-autonomous proliferation and tissue growth signaling through dRaf (the single Raf family kinase orthologue in Drosophila). We found that dRaf is required in the signal receiving cells to stimulate proliferation. We performed RNA-seq to identify novel downstream effectors of Slik. Characterizing the signaling pathway downstream of Slik in Drosophila will shed light on how SLK and LOK function in mammals, and provide insights into their potential involvement during development and in cancer.

Slik

Hippo

Merlin

Raf

Prolifération

Croissance

Cellules épithéliales

Proliferation

Growth

Epithelial cell

A numerical study of periciliary liquid depth in MDCT-based human airway models

Wu, Dan

01 May 2015

Periciliary liquid (PCL) is a critical component of the respiratory system for maintaining mucus clearance. As PCL homeostasis is affected by evaporation and mechanical forces, which are in turn affected by various breathing conditions, lung morphology and ventilation distribution, the complex process of PCL depth regulation in vivo is not fully understood. We propose an integrative approach to couple a thermo-fluid computational fluid dynamics (CFD) model with an epithelial cell model to study the dynamics of PCL depth using subject-specific human airway models based on multi-detector row computed-tomography (MDCT) volumetric lung images. The thermo-fluid CFD model solves three-dimensional (3D) incompressible Navier-Stokes and transport equations for temperature and water vapor concentration with a realistic energy flux based boundary condition imposed at airway wall. A corresponding one-dimensional (1D) thermo-fluid CFD model is also developed to provide necessary information to the 3D model. Both 1D and 3D models are validated with experimental measurements, and the temperature and humidity distributions in the airways are investigated. Correlations for the dimensionless parameters of Nusselt number and Sherwood number are proposed for characterizing heat and mass transfer in the airways. As one of the key applications of the thermo-fluid CFD model, the water loss rates in the both 1D and 3D airway models are studied. It is found that the secondary flows formed at the bifurcations elevate the regional heat and mass transfer during inspiration and hence the water loss rate, which can only be observed in the 3D models. Among the three human airway models studied in both 1D and 3D, little inter-subject variability is observed for the distributions of temperature and humidity. However, the inter-subject variability could be dramatic for the distribution of water loss rate, as it is greatly affected by airway diameter and regional ventilation. A method is proposed to construct an ion-channel conductance model for both normal and cystic fibrosis (CF) epithelial cells, which couples an existing fluid secretion model with an existing nucleotide and nucleoside metabolism model (collectively named epithelial cell model). The epithelial cell models for both normal and CF are capable of predicting PCL depth based on mechanical stresses and evaporation, and are validated with a wide range of experimental data. With these two models separately validated and tested, the integrated model of the thermo-fluid CFD model and epithelial cell model is applied to MDCT-based human airway models of three CF subjects and three normal subjects to study and compare PCL depth regulation under regular breathing conditions. It is found that evaporative water loss is the dominant factor in PCL homeostasis. Between three types of mechanical forces, cyclic shear stress is the primary factor that triggers ATP release and increases PCL depth. In addition, it is found that that greater diameters of the airways in the 4th-7th generations in CF subjects decrease evaporative water loss, resulting in similar PCL depth as normal subjects. Under regular breathing conditions, the average PCL depths of normal and CF is around 6 to 7 µm, with mechanical forces play a greater role in regulating CF PCL depth. Comparing to 7.68 µm normal base level (considered as optimum PCL depth), this average PCL depth is about 8 to 21% lower. This might suggest that mechanical forces alone cannot entirely balance evaporative water loss, and other mechanisms might be involved.

airway epithelial cell

airways

computational fluid dynamics

heat and mass transfer

Multiple detector computed tomography

Periciliary liquid depth

Mechanical Engineering