The Role of ADAM10 in the Immune System: Maintenance of Lymphoid Architecture, MDSC Development and Function, B cell Derived Exosomal Antigen Presentation, and B1 cell IgE Production.

Martin, Rebecca

25 April 2014

ADAM10 is a zinc-dependent metalloprotease. ADAM10 has emerged as a key regulator of cellular processes by cleaving and shedding extracellular domains of multiple transmembrane receptors and ligands. In this study, we examined the role of ADAM10 in the immune system. Here, we show that knocking out ADAM10 on the mature B2 cell causes a defect in the development of secondary lymphoid architecture that becomes more severe post-immunization. We also show that overexpression of ADAM10 leads to a defect in hematopoiesis, which eliminates B2 lymphocyte development. This defect additionally induces accumulation of myeloid derived suppressor cells, MDSCs. ADAM10Tg MDSCs function synonymous to tumor MDSCs. Of the two subpopulations of MDSCs, granulocytic MDSCs increase parasitic clearance in a model of N. brasiliensis. Monocytic MDSCs are more immunosuppressive in regards to tumor. Both subpopulations are dependent on the presence of mast cells for activity. It is thought that this relationship is mediated through histamine and IL-13. During N. brasiliensis infection, ADAM10Tg mice, lacking B2 B cells but having intact B1 B cells, makes increased IgE over WT mice. This production of IgE is thought to be produced by the B1 cells. Of the two types of B1 cells, B1a cells make the majority of the IgE. This IgE production is enhanced by MDSC accumulation and can be induced by MDSC adoptive transfer in a parasite-free mouse. Lastly, ADAM10 is the key sheddase for CD23 on B2 cells. When IgE is bound to its antigen to form an immune complex, IC, it binds CD23 and is internalized. After CD23 bound to IgE ICs is internalized, it is sorted into bexosomes. These bexosomes are transferred to dendritic cells which are responsible for presenting to T cells and inducing an increased antigen-specific immune response. Overall, ADAM10 is important for many aspects of the immune response.

Lymphoid Architecture

B1 cells

Exosomes

IgE

MDSC

Mast Cell

Histamine

Nippostrongylus brasiliensis

Medicine and Health Sciences

Rôle de TLR7 dans la progression tumorale dans le cancer du poumon / Role of TLR7 in tumor progression in lung cancer

Dajon, Marion

02 October 2017

De nombreuses études ont impliqué des TLR dans le développement et la progression tumorale. Précédemment, il a été démontré que les cellules tumorales expriment TLR7, un récepteur à ARNsb, et qu’une forte expression de TLR7 par les cellules tumorales de patients atteints de cancer du poumon est associée à un mauvais pronostic. Dans un modèle murin de cancer du poumon, cet effet pro-tumoral a été reproduit lors de l’injection d’agoniste de TLR7. Mes travaux de thèse ont eu pour objectif de déterminer les mécanismes impliqués dans les effets pro-tumoraux de TLR7. La stimulation de ce récepteur au niveau des cellules tumorales induit une production plus importante de CCL2 et GM-CSF, ainsi qu’un fort recrutement de MDSC au site de la tumeur. Ces MDSC, de par leurs propriétés immunosuppressives sont responsables de l’effet pro-tumoral à la suite de la stimulation de TLR7. Nous avons également mis évidence que la stimulation de TLR7 était pro-métastatique dans un modèle murin de cancer du poumon et que les MDSC étaient également impliquées dans cet effet. Ces effets pro-métastatiques associés au TLR7 ont été confirmés chez l’homme, grâce à l’étude de transcrits de molécules associées à l’invasion, l’angiogénèse, la transition épithélio-mésenchymateuse et les métastases. Enfin nous avons démontré la présence de ligand de TLR7 chez les patients atteints de cancer du poumon et démontré que l’injection intratumorale de virus respiratoires, IAV et RSV, a un effet pro-tumoral dans notre modèle de cancer du poumon. Ces virus respiratoires pourraient donc être à l’origine de la surexpression de TLR7 et du mauvais pronostic associé à ce récepteur chez les patients atteints de cancer du poumon. Ces recherches ont donc permis de mettre en évidence de nouveaux facteurs aggravants dans le cancer du poumon, dont les virus respiratoires, et de découvrir les mécanismes impliqués. / Numerous studies have implicated some TLR in tumor development. Previously, we have demonstrated that lung tumor cells express TLR7, a receptor for ssRNA, and that high TLR7 expression confers to NSCLC patients bad clinical outcome. In mice models of lung cancer, we further demonstrated that the injection of TLR7 agonists led to a pro-tumoral effect.My thesis work has firstly demonstrated the mechanisms involved in the pro-tumoral effects of TLR7 in lung cancer: TLR7 stimulation on tumor cells induces a high production of CCL2 and GM -CSF, as well as a sharp MDSC recruitment within the tumor. These MDSC, by their immunosuppressive properties, are implicated in the pro-tumoral effect upon TLR7 stimulation. We also demonstrated that TLR7 stimulation was pro-metastatic in a mice model of lung cancer and that MDSC were also involved in this effect. These pro-metastatic effects associated with TLR7 have been confirmed in humans through the studies of transcripts and proteins involved in invasion, angiogenesis, Epithelial–mesenchymal transition and metastasis. Finally, we demonstrated that TLR7 ligands are present in tumor microenvironment of lung cancer patients and that intratumoral injection of respiratory viral infections such as IAV and RSV, have a pro-tumoral effect in lung cancer mice model. These respiratory viruses could therefore be at the origin of the overexpression of TLR7 and the poor clinical outcome associated with this receptor in lung cancer patients. This research has thus made possible to highlight new aggravating factors in lung cancer, including respiratory viruses, and to discover the mechanisms involved.

Cancer du poumon

Tlr7

Mdsc

Virus respiratoire

Iav

Rsv

Lung cancer

TLR7

Respiratory viruses

571.96

Immature Myeloid Cells Promote Tumor Formation Via Non-Suppressive Mechanism

Ortiz, Myrna Lillian

17 February 2014

ABSTRACT Although there is ample evidence linking chronic inflammation with cancer, the cellular mechanisms involved in early events leading to tumor development remain unclear. Myeloid cells are an intricate part of inflammation. They consist of mature cells represented by macrophages, dendritic cells and granulocytes and a population of Immature Myeloid Cells (IMC), which in healthy individuals are cells in transition to mature cells. There is a substantial expansion of IMC in cancer and many other pathological conditions which is associated with pathologic activation of these cells. As a result, these cells acquire the ability to suppress immune responses and are termed Myeloid-derived Suppressor Cells (MDSCs). Although the role of MDSC in immune suppression in cancer and tumor progression is well established, their contribution to tumor development is still uncertain. The fact that cells with MDSC phenotype and function are observed in chronic inflammation raised the possibility that these cells can contribute to initial stages of tumor development. To address this question, we used an experimental system where the number of IMC was regulated by the expression of S100A9 protein. In this project, we used two different models of chronic inflammation in S100A9 transgenic (S100A9tg) and S100A9 knock-out (S100A9KO) mice. In the first model, we created the conditions for topical accumulation of these cells in the skin in the absence of infection or tissue damage using S100A9tg mice. Accumulation of IMC in the skin resulted in a dramatic increase in the formation of skin tumors during epidermal carcinogenesis. Conversely, lack of myeloid cell accumulation in S100A9KO mice substantially reduced the formation of skin papillomas. The effect of IMC was not associated with immune suppression but with the recruitment of CD4+ T cells mediated by CCL4 chemokine released by activated IMC. Elimination of CD4+ T cells or blockade of CCL4 abrogated the increase in tumor formation caused by myeloid cells. Thus, this study implicates the accumulation of IMC as an initial step in facilitating of tumor formation, which can mediate the recruitment of CD4+ T cells via the release of CCL4 chemokine. In the second model, we used inflammation-associated lung cancer caused by the chemical lung carcinogen urethane in combination with exposure to cigarette smoke referred to throughout as CS. Exposure of mice to CS alone resulted in a significant accumulation of cells with typical MDSC phenotype in different organs; however, these cells lacked immune suppressive activity and could not be defined as bona fide MDSC. When CS was combined with the single dose of urethane, it led to the accumulation of immune suppressive cells. The expansion of MDSC followed the onset of lung tumors development. This suggests that MDSC in this model is not the preceding factor but rather a consequence of tumor formation. Further studies are necessary to determine the relevance of targeting these cells for cancer treatment and prevention.

CCL4

inflammation

MDSC

S100A9

T helper Cells

Cell Biology

Immunology and Infectious Disease

Molecular Biology

Europium and samarium doped fluorochlorozirconate (FCZ) glasses for optoelectronics applications: thermal and optical properties

Panigrahi, Sujata

23 August 2011

<p>Fluorochlorozirconate (FCZ) glasses are a member of heavy metal fluoride glasses, and are derived from a well known ZBLAN glass. In this work, halogen salts of europium (Eu²⁺) and samarium (Sm³⁺) are used as dopants in FCZ glasses. FCZ glasses doped with Eu²⁺ and Sm³⁺ can be used in high resolution x-ray imaging for tissue scanning, and have been shown to behave as storage phosphors and/or x-ray scintillators.</p> <p>Glass transition (T_g), heat capacity (C_p) and glass crystallization (T_c) properties of Eu²⁺ and Sm³⁺ doped and undoped FCZ glasses with different amounts of relative Cl concentration, that is, with respect to the total Cl and F concentration have been investigated by conventional differential scanning calorimetry (DSC) and modulated differential scanning calorimetry (MDSC) techniques. MDSC experiments were performed at different heating rates to analyze the complex transitions and to get a better resolution of any overlapping transitions. The crystallization kinetics have also been studied by applying the Kissinger technique to multiple DSC scans in order to determine the thermal stability of FCZ glass samples used in this work. The apparent activation energy for the crystallization process was obtained by the crystallization peak temperature shift method in the conventional DSC mode. The specific heat capacity (C_p) has been measured as a function of composition, and the glass transition temperature (T_g) is evaluated from the smooth change in the heat capacity curve during the glass transformation. The observation of two possible glass transitions points to the presence of two phases in these FCZ glasses with higher relative Cl content.</p> <p>Optical transmission spectra of both doped and undoped FCZ glass samples have been measured by infrared spectroscopy and optical band gaps corresponding to an absorption coefficient of 10³ cm^-1 have been determined. A good correlation between X-ray luminescence and the glass structure is observed. While the integrated photoluminescence intensity increases linearly with the Sm³⁺ concentration, the integrated X-ray luminescence increases sublinearly. The importance of appropriate annealing conditions, such as temperature, time and ambient atmosphere, and their effect on the X-ray luminescence of rare earth (RE) doped FCZ glass samples have been investigated. Annealing conditions influence the formation of BaCl₂ nanocrystals in the glass and the properties of the resulting FCZ glass ceramics.</p>

RE doped FCZ.

DSC

infrared spectroscopy

FCZ glass

MDSC

Europium and samarium doped fluorochlorozirconate (FCZ) glasses for optoelectronics applications: thermal and optical properties

Panigrahi, Sujata

23 August 2011

<p>Fluorochlorozirconate (FCZ) glasses are a member of heavy metal fluoride glasses, and are derived from a well known ZBLAN glass. In this work, halogen salts of europium (Eu²⁺) and samarium (Sm³⁺) are used as dopants in FCZ glasses. FCZ glasses doped with Eu²⁺ and Sm³⁺ can be used in high resolution x-ray imaging for tissue scanning, and have been shown to behave as storage phosphors and/or x-ray scintillators.</p> <p>Glass transition (T_g), heat capacity (C_p) and glass crystallization (T_c) properties of Eu²⁺ and Sm³⁺ doped and undoped FCZ glasses with different amounts of relative Cl concentration, that is, with respect to the total Cl and F concentration have been investigated by conventional differential scanning calorimetry (DSC) and modulated differential scanning calorimetry (MDSC) techniques. MDSC experiments were performed at different heating rates to analyze the complex transitions and to get a better resolution of any overlapping transitions. The crystallization kinetics have also been studied by applying the Kissinger technique to multiple DSC scans in order to determine the thermal stability of FCZ glass samples used in this work. The apparent activation energy for the crystallization process was obtained by the crystallization peak temperature shift method in the conventional DSC mode. The specific heat capacity (C_p) has been measured as a function of composition, and the glass transition temperature (T_g) is evaluated from the smooth change in the heat capacity curve during the glass transformation. The observation of two possible glass transitions points to the presence of two phases in these FCZ glasses with higher relative Cl content.</p> <p>Optical transmission spectra of both doped and undoped FCZ glass samples have been measured by infrared spectroscopy and optical band gaps corresponding to an absorption coefficient of 10³ cm^-1 have been determined. A good correlation between X-ray luminescence and the glass structure is observed. While the integrated photoluminescence intensity increases linearly with the Sm³⁺ concentration, the integrated X-ray luminescence increases sublinearly. The importance of appropriate annealing conditions, such as temperature, time and ambient atmosphere, and their effect on the X-ray luminescence of rare earth (RE) doped FCZ glass samples have been investigated. Annealing conditions influence the formation of BaCl₂ nanocrystals in the glass and the properties of the resulting FCZ glass ceramics.</p>

RE doped FCZ.

DSC

infrared spectroscopy

FCZ glass

MDSC

The Effects of Nanoparticle Augmentation of Nitrate Thermal Storage Materials for Use in Concentrating Solar Power Applications

Betts, Matthew

2011 May 1900

The Department of Energy funded a project to determine if the specific heat of thermal energy storage materials could be improved by adding nanoparticles. The standard thermal energy storage materials are molten salts. The chosen molten salt was a sodium nitrate and potassium nitrate eutectic, commercially called Hitec Solar Salt. Two nanoparticle types were chosen, alumina and silica. The nanoparticle composite materials were fabricated by mixing the components in an aqueous solution, mixing that solution for a set amount of time using a sonic mixer, then removing the water from the aqueous solution, leaving the composite molten salt behind as a fine white powder. The thermal properties of the composite and plain material were measured using two techniques: American Society for Testing and Materials (ASTM) 1269E and Modulating Differential Scanning Calorimetry (MDSC). These two techniques measured the specific heat and the heat of fusion of the plain and composite materials. The results of all the ASTM and MDSC measurements suggest that the addition of the nanoparticles using the given manufacturing technique increased the specific heat of the molten salt by approximately 20 percent, with both measurement techniques showing approximately the same level of increase. The silica and the alumina improved the specific heat by nearly the same amount over the base material. The heat of fusion did not seem to be significantly altered compared to the observed heat of fusion value of the unmodified material. It was also observed that the nitrate and silica composite material's specific heat decreased if the material was raised to a temperature above 400C. The specific heat was observed to decrease over time, even when the temperature was well below 400C. It is unknown why this occurred. The nitrate plus alumina composite and the plain nitrate were stable to a temperature of 450C for the test duration.

Molten Salt

Concentrating Solar Power

Specific Heat

Nanoparticles

Differential Scanning Calorimetry

DSC

MDSC

FORMATION AND DISSOCIATION OF CO2 AND CO2 – THF HYDRATES COMPARED TO CH4 AND CH4 - THF HYDRATES

Giavarini, Carlo, Maccioni, Filippo, Broggi, Alessandra, Politi, Monia

07 1900

This work is part of a research project sponsored by the Italian Electricity Agency for CO2 disposal in form of hydrate. The dissociation behavior of CH4 hydrate was taken as a reference for the study of the CO2 hydrate preservation. The formation and dissociation of CO2 and CO2–THF mixed hydrates, compared to CH4 and CH4 – THF mixed hydrates, has been considered. The experimental tests were performed in a 2 liter reaction calorimeter at pressures between 0.1 and 0.3 MPa. The dissociation has been followed at temperatures from -3 °C to 0 °C for CO2 and CH4 hydrates, and from -3 °C to 10 °C for THF mixed hydrates. More than pressure, which is very important for methane hydrates, temperature affects the preservation of CO2 and CO2–THF mixed hydrates. Subcooling after formation is important for methane hydrate preservation, but it does not substantially affect CO2 hydrate stability. In the studied P, T range, CO2 hydrate does not present any anomalous self-preservation effect. The mixtures containing more ice show a slower dissociation rate. Methane hydrate requires less energy to dissociate than CO2 hydrate and, therefore, is less stable. On the contrary, the mixed CO2 – THF hydrates are less stable than the mixed methane hydrates. Modulated differential scanning calorimetry (MDSC) has been used for hydrate characterization: both CH4 and CO2 hydrates include two decomposition peaks, the first due to the melting of the ice and the second to the decomposition of the hydrate. The higher temperature of the decomposition peak of CO2 hydrate confirms its higher stability respect to CH4 hydrate.

CO2

THF

CH4

Dissociation rate

MDSC

ICGH 2008

Epoxy/Clay Nanocomposites: Effect of Clay and Resin Chemistry on Cure and Properties

Siddans, Bradley

January 2005

Polymer/clay nanocomposites consisting of an epoxy resin matrix filled with organoclays have been investigated. The main objective of this study was to determine which combination of components led to the greatest enhancement in properties of the epoxy resin. Exfoliation of the clay was desired, as exfoliated nanocomposites are known to exhibit great improvements in mechanical properties [1]. The epoxy resins studied were di-functional DGEBA and tetra-functional TGDDM. The epoxy resin was cured with three different hardeners, these included: the high functionality amine hardener, TETA, and two anhydride hardeners, accelerated MTHPA and pure HHPA. The three organoclays used, contained alkylammonium cations and were also compared to the unmodified clay. Morphology was investigated by XRD and TEM, and the flexural properties of the resulting nanocomposites were studied. The effect that the addition of an organoclay has on the cure of the epoxy resin was investigated using MDSC. Both the temperatures required to cure the resin with, and without, the clay, and any changes in the total heat flow that occurred were studied. The Tg++ of the cured nanocomposites was also measured using MDSC. The heat flow results indicated that the clays added to the epoxy resins act as a physical barrier, which prevents the resin from reaching full cure. In the higher functional resin, the addition of clay resulted in a significant decrease in the total heat flow, suggesting that a large amount of epoxy remains uncured, and, as a result, there should be a reduction in the amount of cross-linking. The lower cross-link density led to a significantly lower Tg and the mechanical properties were also poorer. The reactivity of the hardener towards the resin was found to have the greatest impact on the cured nanocomposite morphology. Intragallery polymerisation occurring at a faster rate than the extragallery polymerisation causes exfoliation. In order to achieve a balance that favours intragallery polymerisation, it was found that the curing reaction was required to be catalysed by the alkylammonium cation of the organoclay, and not catalysed by other means. The DGEBA cured with HHPA provided the largest layer expansion in the clay structure due to the alkylammonium cation catalysing the anhydride ring-opening reaction. The effect was not seen with TGDDM due to the tertiary amine in its structure. The accelerator within the MTHPA assisted extragallery polymerisation of the resin and the TETA cured readily without additional catalysis.

Polymer

Clay

nanocomposites

epoxy resin

organoclays

DGEBA

TGDDM

MTHPA

HHPA

TETA

XRD

TEM

MDSC

polymerisation

Rôles des cellules myéloïdes suppressives et des lymphocytes Th17 dans le cancer / Roles of myeloïd derived suppressor cells and Th17 lymphocytes in cancer

Chalmin, Fanny

04 July 2012

Le système immunitaire joue un double rôle dans le cancer: il peut non seulement supprimer la croissance tumorale en détruisant les cellules cancéreuses, mais aussi promouvoir la progression de la tumeur en sélectionnant les cellules tumorales ou en créant un microenvironnement tumoral immunosuppresseur. Au cours de ma thèse, je me suis intéressée à deux populations du système immunitaire : les MDSC (Myeloïd Derived Suppressor Cells) et les lymphocytes Th17. Dans ce travail, nous avons exploré les mécanismes impliqués dans l’activation et dans les fonctions suppressives de ces deux populations cellulaires au cours de la croissance tumorale. Tout d’abord, nous avons montré que les cellules tumorales activaient les MDSC en libérant des exosomes exprimant HSP72 à leur surface. HSP72 à la surface des exosomes permet l’activation de STAT3 via la voie de signalisation TLR2/Myd88 dans les MDSC et favorise leur fonction suppressive. Le facteur de transcription STAT3 joue aussi un rôle fondamental dans la différenciation des lymphocytes Th17. Le rôle des lymphocytes Th17 est controversé dans la croissance tumorale. Nous avons découvert que les lymphocytes Th17 exprimaient les ectonucléotidases CD39 et CD73 soutenant ainsi leur fonction suppressive. L'expression des ectonucléotidases est dépendante de l’activation de STAT3 par l’IL-6 et de l’inhibition de Gfi-1 par le TGFβ lors de leur différenciation. / Immune system plays a dual role in cancer: it can not only suppress tumor growth by destroying cancer cells, but also promote tumor progression by selecting immunoresistant tumor cells or by establishing an immunosuppressive microenvironment.During my thesis, I focused on two populations of the immune system: MDSC (myeloid derived suppressor cells) and Th17 lymphocytes. In this work, we explored the mechanisms involved in the activation of suppressive functions of these two cell populations during tumor growth. First, we showed that tumor cells activated MDSC by releasing exosomes that express HSP72 on their surface. HSP72 on exosomes surface induces STAT3 activation via Myd88/TLR2 signaling pathway in MDSC and promotes their suppressive function. The transcription factor STAT3 also plays a fundamental role in Th17 cells differentiation. The role of Th17 cells is controversial in tumor growth. We reported that Th17 cells express CD39 and CD73 ectonucleotidases and thereby supporting their suppressive function. The expression of ectonucleotidases is dependent on the activation of STAT3 by IL-6 and inhibition of Gfi-1 by TGFβ during their differentiation.

Immunosurveillance

MDSC

Th17

Cancer

STAT3

HSP72

Exosome

Ectonucleotidase

No english keywords

616

616.9

571.6

Organoid Models of Digestive Diseases

Holokai, Loryn

14 October 2019

No description available.

Molecular Biology

organoids

Helicobacter pylori

Pancreatic Ductal Adenocarcinoma

PD-L1

SPEM

MDSC