Investigating the Interplay between Inflammation and Matrix Stiffness: Evaluation of Cell Phenotype and Cytoplasmic Stiffness In Vitro

Ford, Andrew Joseph

13 August 2018

The cellular microenvironment in vivo consists of both mechanical and chemical signals, which drive cell function and fate. These signals include the composition, architecture, and mechanical properties of the extracellular matrix (ECM), signaling molecules secreted by cells into their surroundings, as well as physical interactions between neighboring cells. Cells are able to interact with their surroundings through a number of different mechanisms such as remodeling of the ECM through adhesion, contraction, degradation, and deposition of proteins, as well as the secretion of pro- or anti-inflammatory molecules. In diseased states, where homeostasis has been perturbed, inflammatory signals are secreted which can modify the cellular microenvironment. Diseased states such as cancer and fibrosis are often associated with the excessive production of ECM proteins that subsequently lead to an increase in tissue stiffness and changes to ECM architecture. Such changes to the mechanical properties of the cellular microenvironment affect the cytoskeletal arrangement, migration and adhesion of both the parenchymal cells, as well as immune response cells, which migrate to the sites of injury. Further understanding of the inflammatory responses and their relationships to tissue stiffness and ECM architecture could aid in the development of novel strategies to predict diseases as well as to target and monitor therapies. Since inflammation and mechanical properties of the affected tissue are closely interlinked, obtaining a detailed understanding of the interplay between the properties of the microenvironment and the cells that reside within it will be very beneficial to obtain physiologically relevant information. We have investigated the combinatorial effects of matrix stiffness, and architecture in the presence of co-cultures of cells to determine the overall effect on cellular responses and phenotypes. We have conducted studies on co-cultures of cells in 2D and 3D environments to identify how cellular behavior is affected by dimensionality. / PHD / The cellular microenvironment in vivo consists of both mechanical and chemical signals, which drive cell function and fate. These signals include the composition and organization of the extracellular matrix (ECM), signaling molecules secreted by cells into their surroundings, as well as physical interactions between neighboring cells. Cells are able to interact with their surroundings through reorganization of the ECM and secretion of pro- or anti-inflammatory molecules. In diseased states, inflammatory signals are secreted which can modify the cellular microenvironment. Diseased states such as cancer and fibrosis are often associated with the excessive production of ECM proteins that subsequently lead to an increase in tissue stiffness and changes to ECM architecture. Such changes to the mechanical properties of the cellular microenvironment affect the function and behavior of cells within a given tissue. Further understanding of the inflammatory responses and their relationships to tissue stiffness and ECM architecture could aid in the development of novel strategies to predict diseases as well as to target and monitor therapies. Since inflammation and mechanical properties of the affected tissue are closely interlinked, obtaining a detailed understanding of the interplay between the properties of the microenvironment and the cells that reside within it will be very beneficial to obtain physiologically relevant information. We have investigated the combinatorial effects of matrix stiffness, and architecture in the presence of co-cultures of cells to determine the overall effect on cellular responses and phenotypes. We have conducted studies on co-cultures of cells in 2D and 3D environments to identify how cellular behavior is affected by dimensionality.

inflammation

ECM remodeling

liver fibrosis

liver sinusoidal endothelial cells

cytoplasmic stiffness

macrophage fibroblast co-culture

Modulation der gewebespezifischen Migration von CD4+ T-Zellen durch das Lebersinusendothel

Neumann, Katrin

20 September 2012

Die Einwanderung von T-Zellen in ein Gewebe wird durch selektive Wechselwirkungen mit vaskulären Endothelzellen kontrolliert. In der vorliegenden Arbeit wurde der Frage nachgegangen, ob Interaktionen zwischen Lebersinusendothelzellen (LSEC) und CD4+ T-Zellen die gewebespezifische Migration von CD4+ T-Zellen beeinflussen und damit Relevanz für den Verlauf spezifischer Immunantworten haben. Die Präsentation von Antigenen durch zytokinaktivierte LSEC erhöhte die Adhäsion und Transmigration antigenspezifischer CD4+ T-Zellen. Die Daten deuten auf eine Rolle des Lebersinusendothels bei der entzündungsinduzierten, antigenabhängigen Rekrutierung von CD4+ T-Zellen in das Lebergewebe hin. Eine antigenabhängige Aktivierung naiver CD4+ T-Zellen durch LSEC sowie deren Bereitstellung von Retinolsäure induzierte die Expression von darmspezifischen Homingrezeptoren auf CD4+ T-Zellen. LSEC-aktivierte CD4+ T-Zellen migrierten in das Darmgewebe von C57BL/6-Mäusen. Die Ergebnisse legen den Schluss nahe, dass LSEC einen darmspezifischen Homingphänotyp und damit die Migration von in der Leber aktivierten CD4+ T-Zellen in den Darm induzieren. Die Bereitstellung von Chemokinen durch LSEC mittels Transzytose und Immobilisierung verstärkte die Transmigration von CD4+ T-Zellen durch das Endothel. Die Gabe eines Inhibitors der endothelialen Chemokintranszytose während einer Concanavalin A-induzierten Autoimmunhepatitis supprimierte den Verlauf der Hepatitis und führte zu einer verminderten Migration von aktivierten CD4+ T-Zellen in das Lebergewebe. Diese Daten weisen dem Lebersinusendothel eine aktive Beteiligung in der chemokinabhängigen Rekrutierung von CD4+ T-Zellen in die Leber zu. In der vorliegenden Arbeit wurde die Modulation der gewebespezifischen Migration von CD4+ T-Zellen über Antigenpräsentation und Chemokinbereitstellung durch das Lebersinusendothel gezeigt und damit weitere spezifische Aspekte in der Funktion der Leber als immunologisches Organ beschrieben. / T-cell immigration into a tissue is controlled by selective interactions with vascular endothelial cells. The present study addressed the question if interactions between liver sinusoidal endothelial cells (LSEC) and CD4+ T cells influence the tissue-specific migration of CD4+ T cells and thus have relevance for the course of specific immune responses. Antigen presentation by cytokine-activated LSEC increased adhesion and transmigration of antigen-specific CD4+ T cells. These results indicate an involvement of LSEC in the inflammation-induced, antigen-specific migration of CD4+ T cells into the liver tissue. Antigen-specific activation of naive CD4+ T cells by LSEC and their supply of retinoic acid induced expression of gut-specific homing receptors on CD4+ T cells. LSEC-activated CD4+ T cells migrated into the intestine of C57BL/6 mice. The findings presented here imply that LSEC induce a gut-specific homing phenotype resulting in migration of liver-activated CD4+ T cells into the intestine. The active supply of chemokines by LSEC via transcytosis and immobilization enhanced transmigration of CD4+ T cells. Administration of an inhibitor of the endothelial chemokine transcytosis during Concanavalin A-induced autoimmune hepatitis suppressed hepatitis and resulted in reduced migration of activated CD4+ T cells into the liver tissue. The data show the impact of LSEC on the chemokine-dependent recruitment of CD4+ T cells into the liver. In the present study the modulation of the tissue-specific migration of CD4+ T cells by LSEC via antigen presentation and supply of chemokines was demonstrated. Thus, additional functional aspects concerning the immunologic functions of the liver were described.

CD4+ T-Zellen

gewebespezifische Migration

Lebersinusendothel

CD4+ T cells

tissue-specific migration

liver sinusoidal endothelial cells

570 Biowissenschaften, Biologie

32 Biologie

WF 9895

ddc:570

Rôle des cellules endothéliales dans l’immunité innée précoce induite lors d’infections par des coronavirus murins

Bleau, Christian

08 1900

Les cellules endothéliales (EC) constituent une première barrière physique à la dissémination de virus pléiotropiques circulant par voie hématogène mais leur contribution à la défense innée anti-virale est peu connue. Des dysfonctions des EC de la barrière hémato-encéphalique (BMEC) et des sinusoïdes hépatiques (LSEC) ont été rapportées dans des neuropathologies et des hépatites aiguës ou chroniques d’origine virale, suggérant que des atteintes à leur intégrité contribuent à la pathogenèse. Les sérotypes de coronavirus de l’hépatite murine (MHV), se différenciant par leur capacité à induire des hépatites et des maladies neurologiques de sévérité variable et/ou leur tropisme pour les EC, représentent des modèles viraux privilégiés pour déterminer les conséquences de l’infection des EC sur la pathogenèse virale. Lors d’infection par voie hématogène, le sérotype MHV3, le plus virulent des MHV, induit une hépatite fulminante, caractérisée par une réponse inflammatoire sévère, et des lésions neurologiques secondaires alors que le sérotype moins virulent, MHV-A59, induit une hépatite modérée sans atteintes secondaires du système nerveux central (SNC). Par ailleurs, le sérotype MHV3, à la différence du MHV-A59, démontre une capacité à stimuler la production de cytokines par la voie TLR2. Les variants atténués du MHV3, les virus 51.6-MHV3 et YAC-MHV3, sont caractérisés par un faible tropisme pour les LSEC et induisent respectivement une hépatite modérée et subclinique. Compte tenu de l’importance des LSEC dans le maintien de la tolérance hépatique et de l’élimination des pathogènes circulants, il a été postulé que la sévérité de l’hépatite et de la réponse inflammatoire lors d’infections par les MHV est associée à la réplication virale et à l’altération des propriétés tolérogéniques et vasculaires des LSEC. Les désordres inflammatoires hépatiques pourraient résulter d’une activation différentielle du TLR2, plutôt que des autres TLR et des hélicases, selon les sérotypes. D’autre part, compte tenu du rôle des BMEC dans la prévention des infections du SNC, il a été postulé que l’invasion cérébrale secondaire par les coronavirus est reliée à l’infection des BMEC et le bris subséquent de la barrière hémato-encéphalique (BHE). À l’aide d’infections in vivo et in vitro par les différents sérotypes MHV, chez des souris ou des cultures de BMEC et de LSEC, nous avons démontré, d’une part, que l’infection in vitro des LSEC par le sétotype MHV3, à la différence des variants 51.6- et YAC-MHV3, altérait la production du facteur vasodilatant NO et renversait leur phénotype tolérogénique en favorisant la production de cytokines et de chimiokines inflammatoires. Ces dysfonctions se traduisaient in vivo par une réponse inflammatoire incontrôlée et une dérégulation du recrutement intrahépatique de leucocytes, favorisant la réplication virale et les dommages hépatiques. Nous avons aussi démontré, à l’aide de souris TLR2 KO et de LSEC dont l’expression du TLR2 a été abrogée par des siRNA, que la sévérité de l’hépatite et de la réponse inflammatoire induite par le sérotype MHV3, dépendait en partie de l’induction et de l’activation préférentielle du TLR2 par le virus dans le foie. D’autre part, la sévérité de la réplication virale au foie et des désordres dans le recrutement leucocytaire intrahépatique induits par le MHV3, et non par le MHV-A59 et le 51.6-MHV3, corrélaient avec une invasion virale subséquente du SNC, au niveau de la BHE. Nous avons démontré que l’invasion cérébrale du MHV3 était associée à une infection productive des BMEC et l’altération subséquente des protéines de jonctions serrées occludine, VE-cadhérine et ZO-1 se traduisant par une augmentation de la perméabilité de la BHE et l’entrée consécutive du virus dans le cerveau. Dans l’ensemble, les résultats de cette étude mettent en lumière l’importance du maintien de l’intégrité structurale et fonctionnelle des LSEC et des BMEC lors d’infections virales aigües par des MHV afin de limiter les dommages hépatiques associés à l’induction d’une réponse inflammatoire exagérée et de prévenir le passage des virus au cerveau suite à une dissémination par voie hématogène. Ils révèlent en outre un nouveau rôle aggravant pour le TLR2 dans l’évolution de l’hépatite virale aigüe ouvrant la voie à de nouvelles avenues thérapeutiques visant à moduler l’activité inflammatoire du TLR2. / Endothelial cells (EC) act as a physical barrier against invasion by pleiotropic blood borne viruses but their contribution in innate antiviral defense is poorly known. Dysfunctions in blood-brain barrier EC (BMECs) and liver sinusoidal EC (LSECs) have been reported in viral neuropathologies and hepatitis, suggesting that loss of ECs integrity may contribute to the pathogenesis. Mouse hepatitis coronaviruses (MHV), differing in their ability to induce severe to subclinical hepatitis and neurological diseases and / or their tropism for ECs, are relevant viral models to study the consequences of EC infection in viral pathogenesis. Following hematogenous infection, the MHV3 serotype, the most virulent MHV, induces fulminant hepatitis, characterized by severe inflammatory response, followed by neurological damage whereas the less virulent MHV-A59 serotype induces milder hepatitis but does not invade the central nervous system (CNS). In addition, MHV3, in contrast to MHV-A59, shows ability to induce TLR2-dependent cytokine response. The attenuated MHV3 variants, 51.6-MHV3 and YAC-MHV3, are characterized by a weak tropism for LSECs and induce moderated and subclinical hepatitis respectively. Given the importance of LSECs in hepatic tolerance and the elimination of circulating pathogens, it has been postulated that the severity of hepatitis and inflammatory response induced by MHVs correlates with infection and alterations in vascular and tolerogenic properties of LSECs. Hepatic inflammatory disorders may result from differential activation of TLR2, rather than other TLRs and helicases, according to serotypes. Moreover, given the role of BMECs in preventing CNS infections, it has been postulated that secondary cerebral invasion by coronaviruses is related to infection of BMECs and subsequent breakdown of the blood-brain barrier (BBB). Through in vitro and in vivo infections of isolated BMECs, LSECs or mice with the different MHVs, we demonstrated, first, that in vitro productive infection of LSECs by the highly virulent MHV3 serotype, in contrast to 51.6- et YAC-MHV3 variants, altered their production of vasoactive factors and overthrew their intrinsic tolerogenic properties by promoting inflammatory cytokines and chemokines production. These disturbances were reflected in vivo by an uncontrolled inflammatory response and a deregulation of intrahepatic leukocyte recruitment, favoring viral replication and liver damages. We demonstrated, using TLR2 KO mice and LSECs treated with siRNA for TLR2 that the abnormal inflammatory response induced by MHV3 depended in part on preferential induction and activation of TLR2 by the virus on the surface of hepatic cells. Moreover, the severity of the primary viral replication in the liver and disorders in intrahepatic leucocyte recruitment induced by MHV3, but not by MHV-A59 and 51.6-MHV3, correlated with a subsequent brain invasion at the BBB level. Such invasion was related to productive infection of BMECs and subsequent IFN--dependent disruption of tight junction proteins occludin, VE-cadherin and ZO-1, resulting in an increase of BBB permeability and further viral entry into the CNS. Overall, the results of this study highlight the importance of structural and functional integrity of LSECs and BMECs during acute viral infections by MHVs to limit liver damages associated with viral-induced exacerbation of inflammatory response and prevent brain invasion by MHVs following viral spread through the bloodstream. They also reveal a new worsening role for TLR2 in the evolution of acute viral hepatitis paving the way for new therapies targeting TLR2-induced inflammatory activity.

Coronavirus

Virus de l’hépatite murine (MHV)

Inflammation

Hépatite aiguë

Réponse immune innée

TLR2

Cytokines

Chimiokines

Innate immune response

Mouse hepatitis viruses (MHV)

Chemokines

Acute hepatitis

Liver sinusoidal endothelial cells

Brain microvascular endothelial cells

Interferon-beta