Interaktionen von dendritischen Zellen und Effektorzellen der frühen antitumoralen Immunabwehr

Wehner, Rebekka

18 June 2008

In den letzten Jahren ergaben sich vermehrt Hinweise, dass dendritische Zellen (DCs) zu einer Stimulation von Natürlichen „Killer“ (NK)-Zellen in der Lage sind, die als zytotoxische Effektorzellen des angeborenen Immunsystems Tumorzellen eliminieren. Aus diesem Grund bestand ein wesentliches Ziel dieser Arbeit in der Analyse der Wechselwirkungen zwischen nativen DCs und NK-Zellen. Dazu wurden slanDCs verwendet, welche die größte DC-Subpopulation des Blutes repräsentieren. Zunächst wurde evaluiert, ob slanDCs eine effiziente Aktivierung von NK-Zellen bewirken. Als ein Ergebnis zeigte sich, dass Lipopolysaccharid (LPS)-stimulierte slanDCs sowohl zu einer verstärkten Expression des Aktivierungsmarkers CD69 auf der Oberfläche von NK-Zellen als auch zur Induktion der NK-Zell-Proliferation führen. Darüber hinaus wurde erstmals die slanDC-abhängige Erhöhung der Expression von aktivierenden Rezeptoren (NKp46, NKp44, NKp30) und Korezeptoren (2B4, DNAM-1) auf NK-Zellen demonstriert, welche essentiell für die NK-Zell-vermittelte Erkennung und Lyse von Tumorzellen sind. In weiteren Untersuchungen induzierten LPS-aktivierte slanDCs eine erhebliche Produktion von Interferon (IFN)-gamma in NK-Zellen, welches proliferationshemmend auf Tumorzellen und aktivierend auf T-Lymphozyten wirkt. Funktionelle Analysen ergaben, dass aktivierte slanDCs das zytotoxische Potential von NK-Zellen gegenüber der Tumorzelllinie K-562 deutlich verstärken. Untersuchungen der zugrunde liegenden Mechanismen zeigten die herausragende Bedeutung von IL-12, das sowohl die Steigerung der IFN-gamma-Sekretion als auch die Zunahme der zytolytischen Aktivität von NK-Zellen induzierte. Darüber hinaus konnte erstmals gezeigt werden, dass LPS-aktivierte slanDCs eine Zytotoxizität von NK-Zellen gegenüber frisch etablierten Blasten von Patienten mit akuter myeloischer Leukämie induzieren. In weiteren Untersuchungen wurde evaluiert, ob NK-Zellen ihrerseits die immunstimulatorischen Eigenschaften von slanDCs beeinflussen. Die Analysen zeigten erstmals, dass unstimulierte NK-Zellen die Expression von MHC-Klasse II-Molekülen, kostimulatorischen Molekülen und Adhäsionsmolekülen auf slanDCs deutlich erhöhen und somit ihre Fähigkeit zur Aktivierung von CD8+ T-Lymphozyten sowie CD4+ T-Helferzellen fördern. NK-Zellen führen ebenfalls zu einer deutlichen Verstärkung der Produktion von IL-12 durch LPS-stimulierte slanDCs. Darüber hinaus zeigte sich, dass NK-Zellen die Sekretion des immunsuppressiven Zytokins IL-10 durch LPS-stimulierte slanDCs reduzieren. In weiteren Analysen wurde demonstriert, dass die Interaktionen mit NK Zellen die Fähigkeit von LPS-aktivierten slanDCs zur Programmierung naiver CD4+ T-Lymphozyten in IFN-gamma-produzierende T-Helfer-1-Zellen deutlich verstärken. Diese Ergebnisse zeigten deutlich, dass stimulierte slanDCs und NK-Zellen in der Lage sind, sich wechselseitig zu aktivieren. NKT-Zellen repräsentieren eine weitere bedeutende Effektorzellpopulation der frühen antitumoralen Immunabwehr, die durch Sekretion von Zytokinen und ein ausgeprägtes zytolytisches Potential zur Elimination von Tumorzellen beiträgt. Deshalb wurden im Rahmen dieser Arbeit erstmals die Wechselwirkungen zwischen slanDCs und NKT-Zellen analysiert. Dabei verstärkten LPS-stimulierte slanDCs die Expression des Aktivierungsmarkers CD69 auf NKT-Zellen. Darüber hinaus induzierten LPS-aktivierte slanDCs eine deutliche IFN-gamma-Produktion in NKT-Zellen, wobei erneut die zentrale Rolle von IL-12 gezeigt wurde. Diese Ergebnisse demonstrierten, dass stimulierte slanDCs zu einer effektiven Aktivierung von NKT Zellen in der Lage sind. In abschließenden Untersuchungen wurde die Wirkung von NKT-Zellen auf slanDCs evaluiert. Dabei verstärkten NKT-Zellen die Maturierung von slanDCs erheblich und führten zu einer signifikanten Steigerung der IL-12-Produktion sowie zu einer Reduktion der IL-10-Freisetzung in Abhängigkeit von IFN-gamma. Die gewonnenen Daten demonstrierten, dass NKT-Zellen und slanDCs zu einer gegenseitigen Aktivierung befähigt sind. Die im Rahmen dieser Dissertation gewonnenen Erkenntnisse zu den Interaktionen von slanDCs und NK- bzw. NKT-Zellen können einen wesentlichen Beitrag zum Verständnis der Immunabwehr von Tumoren leisten und die Konzeption neuer antitumoraler Therapiestrategien unterstützen.

info:eu-repo/classification/ddc/570

ddc:570

Výzkum vzájemné interakce membránových receptorů NKR-P1D a Clrb / Studies on interactions between NKR-P1D and Clrb membrane receptors

Hanč, Pavel

January 2011

Studies on interactions between NKR-P1D and Clrb membrane receptors Interaction between murine NKR-P1D and Clrb receptors was originally described as a novel type of "MHC class-I independent missing-self recognition" and was shown to confer protection from killing by natural killer cells.[1] However, further study brought conflicting results suggesting that NKR-P1D does not binds Clrb strongly if it does at all.[2] In order to address the issues arising from these conflicting results, we have recombinantly expressed the extracellular domains of both receptors in E. coli cells and refolded the proteins in vitro. The quality of refolding was confirmed both by determining the disulphide bonding pattern using FTMS and measuring 1 H/15 N-HSQC spectra. By means of size exclusion chromatography and analytical ultracentrifuge we were unable to provide convincing results for the interaction itself. However, using SPR technique, a weak, specific, pH-dependent interaction was observed. Interaction between the proteins in solution was immobilized using chemical cross-linking technique. Three cross-linking reagents, EDC, DSG and DSS were used. The reaction mixture was separated by means of SDS-PAGE and protein bands corresponding to dimers were digested in gel. Using FT-MS we were able to find peptides from both...

Exploitation du potentiel thérapeutique des cellules Natural Killer pour traiter les cancers

Lemieux, William

12 1900

Malgré le succès de l’utilisation des lymphocytes T modifiées par des récepteur antigéniques chimériques (CAR) contre les leucémies, celles-ci présentent des limites comme leur risque de CRS et leur inefficacité dans les tumeurs solides. Plusieurs autres immunothérapies cellulaires ont été proposées pour pallier à ces inconvénients. Les cellules natural killer (NK) ont plusieurs propriétés qui en font une alternative avantageuse aux cellules T dans les immunothérapies. Cependant, les cellules NK restent difficiles à modifier avec les outils actuels et leur efficacité reste limitée par les mécanismes immunosuppresseurs des tumeurs. Nous avons réussi à augmenter l’efficacité de transduction avec une nouvelle glycoprotéine, le BaEVRless. Nous avons aussi démontré que cette enveloppe ne provoque pas de modification du phénotype ou de l’activité intrinsèque des cellules NK. Dans un modèle de leucémie, nous avons déterminé que l’utilisation du BaEVRless permet la production de cellules CAR-NK fonctionnelles. Les cellules NK peuvent aussi être transduites efficacement par des constructions lentivirales portant les séquences codant pour deux constructions CAR simultanément. Nous avons aussi démontré que l’édition génomique des NK par la technologie Clustered Regularly Interspersed Short Palindromic Repeats (CRISPR) est possible en utilisant une livraison non-virale. Avec cette méthode, nous avons pu réduire l’expression de NKG2A. Les cellules NK avec une expresssion réduite de NKG2A étaient résistantes à l’inhibition par HLA-E, exprimé sur des lignées de cancer du sein et du colon. Cet effet a été confirmé in vivo dans un modèle préclinique xenogénique. Ces résultats montrent deux stratégies qui pourraient permettre d’améliorer les immunothérapies à base de cellules NK. / Despite the overwhelming success of chimeric antigen receptor (CAR)-modified T lymphocytes against leukemias, some limitations have been observed, such as the risk of developing CRS and the lack of efficiency in solid tumor settings. Many other cell-based immunotherapies have been explored to circumvent those caveats. Natural killer (NK) cells present many advantageous properties that could make them a very promising alternative to T cells in immunotherapies. However, NK cells have some caveats, mainly they are hard to modify using conventional tools and they are sensitive to many inhibitory signals expressed by cancer cells. We managed to greatly improve the efficiency of transduction using a novel viral glycoprotein, BaEVRless. In the process, we determined that this novel enveloppe glycoprotein did not modify the phenotype or intrinsic activity of the transduced NK cells. In a leukemia model, we also showed that the BaEVRless can be used to generate functionnal CAR-NK cells. Moreover, the NK cells can be transduced with larger lentiviral constructions bearing two simultaneous CAR-coding sequences. We also demonstrated that Clustered Regularly Interspersed Short Palindromic Repeats (CRISPR) modification of NK cells using a non-viral approach was possible. Using this approach, we generated NK cells with lower NKG2A expression, that were resistant to the inhibitory effects of HLA-E. This affect was seen in a breast cancer model and a colon cancer model. The in vitro results were confirmed in an in vivo preclinical xenogeneic model. Together, those results represent two improvements applicable to NK cell-based immunotherapies.

Immunothérapie

Cellules NK

Récepteurs antigéniques chimériques

Transduction

HLA-E

NKG2A

Immunotherapy

NK cells

Chimeric antigen receptors

Cryopreservation of Induced Pluripotent Stem Cell Derived Neurons and Primary T-Cells and Natural Killer Cells Using Ice Recrystallization Inhibitor Technology

Alasmar, Salma

14 November 2022

Given the rising demand for diverse cell types in regenerative and transfusion medicines, such as human induced pluripotent stem cell-derived neurons (iPSC-Ns), human T/chimeric antigen receptor (CAR) T cells, and human natural killer (NK) cells, the ability to cryopreserve cells has become increasingly important. In regenerative medicine, iPSC-Ns are powerful tools for treating and modelling neurodegenerative diseases. Moreover, transplants/transfusions of T/CAR T cells or NK cells offer promising treatment for numerous types of tumors, such as leukemia and multiple myeloma. Cryopreservation of cells at sub-zero temperatures (-80 to -196 °C) allows for the development of master cell banks that can be used for clinical applications. Conventional cryoprotective agents (CPAs), such as dimethylsulfoxide (DMSO) and glycerol, are utilized to protect cells from cryoinjuries associated with the freezing process. However, the use of high concentrations of DMSO (i.e., 10 to 20%) has been shown to be accompanied with toxic effects on patients receiving cell therapies if it is not removed or diluted prior to transfusion. Moreover, DMSO does not prevent the occurrence of the cryoinjury associated with ice recrystallization, which is one of the major causes of cell death/damage during cryopreservation. As a result, there is a surge of attention toward developing new non-toxic cryo-additives that inhibit ice recrystallization during cryopreservation to permit future advancement in regenerative and transfusion medicines. Moreover, the use of ice recrystallization inhibitors (IRIs) as novel CPAs has become a promising strategy to improve cell viability and function post-thaw. The Ben laboratory heavily invested in synthesizing several classes of carbohydrate-based small molecule IRIs (i.e., O-linked alkyl and aryl glycosides, and N-aryl-D-gluconamides), and studying the correlation between their IRI activity and molecular properties, such as polar surface area to molecular surface area (PSA/MSA) ratio. Moreover, compounds that belong to the O-linked aryl glycosides and N-aryl-D-gluconamides classes of IRIs have been shown to enhance the viability and functionality of red blood cells (RBCs), hematopoietic stem cells (HSCs), and induced pluripotent stem cells (iPSCs) after thawing. Part of the research presented throughout this thesis focuses on structure-activity relationship (SAR) studies of alkyl pyranoses with modified alkyl chain lengths to explore any correlations between the IRI activity and the net polarity (i.e., PSA/MSA ratio) of the IRI candidates. O- and C-linked alkyl pyranose derivatives with different alkyl chain lengths were synthesized and their IRI activity was assessed using the modified splat cooling assay. While the IRI activity of the O- and C-linked alkyl glucosides did differ as the length of the alkyl chain increased, no correlation between the PSA/MSA ratios and their IRI activity was observed. In addition, this work allowed for investigation into the effect of the type of the glycosidic bond (i.e., C-O and C-C bonds) at the anomeric position, on the IRI activity of the different compounds. The O-linked alkyl glucosides appeared to be more IRI active than the C-linked compounds, suggesting the nature of the glycosidic bond is important for IRI activity. The second part of the research presented in this thesis focuses on examining the potential for IRIs to cryopreserve iPSC-Ns, T/CAR T cells, and NK cells. 2-fluorophenyl-D-gluconamides (2FA), which is one of the most active IRIs from the N-aryl-Dgluconamides, has shown promising results in maintaining a high number of viable and functional HSCs and iPSCs post-thaw, and therefore it was employed in the cryopreservation protocol of iPSC-Ns, human-derived T/CAR T cells, and human-derived NK cells. The efficacy of the cryopreservation protocol being constructed was evaluated by assessing the post-thaw viability and recovery rate, as well as the functionality of iPSCNs, T/CAR T cells, and NK cells post-thaw. These studies showed that protecting against ice recrystallization during cryopreservation with IRIs increases the number of viable and functional iPSC-Ns, and T/CAR T cells. It was also observed that employing IRI technology in the cryopreservation protocol of NK cells does not compromise their functionality compared to fresh, non-frozen NK cells. Overall, inhibition of ice recrystallization using IRIs appeared to enhance the cryopreservation outcomes of the different cell types, which will allow for the development of off-the-shelf cell therapy products and improvement of the delivery of efficacious cell products to clinics and hospitals.

Cryopreservation

Ice recrystallization inhibitors

Cellular therapy

Stem cells

T/CART cells

Natural killer (NK) cells

Stem cells

glucosides

aldonamide

Étude du rôle de la conformation des glycoprotéines de l'enveloppe du VIH-1 dans la réponse cytotoxique cellulaire dépendante des anticorps

Prévost, Jérémie

06 1900

En l'absence d'un vaccin efficace et avec des thérapies antirétrovirales incapables d'éradiquer le virus, le VIH-1 reste un problème de santé publique mondial. Des immunothérapies à base d'anticorps sont à l'étude pour éliminer les réservoirs cellulaires, qui représentent un obstacle incontournable à la guérison du VIH-1. Les glycoprotéines d'enveloppe du VIH-1 (Env) représentent le seul antigène du virus exposé à la surface des cellules infectées et constituent donc la principale cible des anticorps. L’Env non-liée adopte sa conformation « fermée », reconnue préférentiellement par les anticorps neutralisants. L'interaction avec CD4 fait passer Env dans sa conformation « ouverte », exposant des épitopes conservés reconnus par les anticorps non-neutralisants (nnAbs) présents dans le sérum d’individus infectés par le VIH-1 (sérums VIH+). Les nnAbs peuvent éliminer les cellules infectées par la cytotoxicité cellulaire dépendante des anticorps (ADCC). Cependant, les protéines accessoires Nef et Vpu diminuent l’expression de surface de CD4 et BST-2 afin d’évader à la reconnaissance et l'élimination des cellules infectées par les nnAbs. Dans cette thèse, nous caractérisons en détail la contribution d’Env, Nef et Vpu pour échapper aux réponses humorales et explorons de nouvelles stratégies pour sensibiliser les cellules infectées à l’ADCC. Pour quantifier plus adéquatement la réponse ADCC, nous avons identifié des biais dans les tests largement utilisés, notamment pour évaluer les corrélats de protection vaccinale. Il s'agit de l'incapacité à faire la distinction entre l'élimination des cellules infectées et des cellules non-infectées, et l'utilisation de constructions virales comportant un gène rapporteur empêchant l’expression de Nef. En utilisant un nouveau marquage intracellulaire, nous avons confirmé l’effet protecteur de Nef et Vpu contre l’ADCC. Ensuite, nous avons étudié les déterminants d’Env et Vpu modulant la susceptibilité des cellules infectées à l’ADCC médiée par les nnAbs. Certaines caractéristiques structurelles d'Env modulent ses transitions conformationnelles, incluant le domaine d'association du trimère, le site de clivage de la furine et la cavité Phe43. L’altération de ces composantes augmente la sensibilité des cellules infectées à l'ADCC par les sérums VIH+. Outre l’inhibition de CD4 et BST-2, Vpu cible également NTB-A et PVR, des ligands de récepteurs activateurs des cellules NK. Cependant, la polyfonctionnalité de Vpu est compromise par l’augmentation de BST-2 par les interférons de type I (IFN-I), sensibilisant ainsi les cellules infectées aux réponses NK. En utilisant un modèle de souris humanisée, nous validons l'importance de Vpu pour échapper à la pression immunitaire des nnAbs in vivo. Enfin, nous avons exploré de nouvelles stratégies pour sensibiliser les cellules infectées à l'ADCC en modulant la conformation d’Env avec des mimétiques moléculaires de CD4 (CD4mc). Nous avons identifié des résidus bordant la cavité Phe43 modulant la sensibilité au CD4mc. L’accumulation d’Env induite par les IFN-I augmente la capacité du CD4mc à sensibiliser les cellules infectées à l'ADCC par les sérums VIH+. Globalement, cette thèse dévoile une caractérisation approfondie des déterminants viraux et cellulaires modulant la susceptibilité des cellules infectées par le VIH-1 aux réponses humorales. Une meilleure compréhension de ces mécanismes est nécessaire pour développer des nouvelles stratégies capables d’éradiquer les réservoirs viraux. / In the absence of an effective vaccine and with antiretroviral therapies unable to eradicate the virus, HIV-1 remains a global public health problem. Antibody-based immunotherapies are currently being investigated to eliminate cellular reservoirs, which represent a major obstacle towards an HIV-1 cure. HIV-1 envelope glycoproteins (Env) represent the only virus-specific antigen exposed at the surface of infected cells and therefore is the main target for antibodies. In its unliganded form, Env samples a ‘closed’ conformation, preferentially recognized by neutralizing antibodies. Interaction with CD4 drives Env into its ‘open’ conformation, exposing conserved epitopes recognized by non-neutralizing antibodies (nnAbs) present in sera from HIV-1 infected individuals (HIV+ sera). NnAbs can eliminate infected cells by antibody-dependent cellular cytotoxicity (ADCC). However, HIV-1 encodes for the accessory proteins Nef and Vpu which decrease cell surface levels of CD4 and BST-2, thus avoiding recognition and elimination of infected cells by nnAbs. In this thesis, we characterize in detail the contribution of Env, Nef, and Vpu to evade humoral responses and explore new strategies for sensitizing infected cells to ADCC. In an effort to develop a more adequate quantification of ADCC responses, we identified major biases in widely used assays, including the ones used to assess correlates of vaccine protection. These include the inability to distinguish between the elimination of infected and uninfected cells and the use of viral constructs coding for a reporter gene that prevents Nef expression. Using a novel intracellular staining, we confirmed the protective effect of Nef and Vpu against ADCC responses. Next, we studied the different Env and Vpu determinants modulating the susceptibility of infected cells to nnAbs-mediated ADCC responses. Certain Env structural features modulate its conformational transitions, including the trimer association domain, the furin cleavage site and the Phe43 cavity. Alterations of these components increase the susceptibility of HIV-1-infected cells to ADCC mediated by HIV+ sera. In addition to inhibiting CD4 and BST-2, Vpu also targets NTB-A and PVR, which act as ligands for NK cell activating receptors. However, we found that the polyfunctionality of Vpu can be compromised by the upregulation of BST-2 by type I interferons (IFN-I), thereby sensitizing infected cells to NK cell responses. Using a humanized mouse model, we validate the importance of Vpu to escape the immune pressure of nnAbs in vivo. Finally, we explored new strategies to bypass the protective effect of Vpu and Nef and sensitize HIV-1-infected cells to ADCC by modulating Env conformation using small CD4-mimetic compounds (CD4mc). We identified a network of residue lining the Phe43 cavity that modulates Env sensitivity to CD4mc. The enhanced surface expression of Env by type I IFNs boosts the ability of CD4mc to sensitize HIV-1-infected cells to ADCC by HIV+ sera. Overall, this thesis sheds light on a thorough characterization of viral and cellular determinants modulating the susceptibility of HIV-1-infected cells to humoral responses. A better understanding of these mechanisms is needed to develop new strategies able to eradicate viral reservoirs.

VIH-1

ADCC

Env

glycoprotéine

Vpu

Nef

CD4

BST-2

anticorps

cellules NK

HIV-1

glycoprotein

antibody

NK cells

Virology / Virologie (UMI : 0720)

Engineering hematopoietic and immune cells from human pluripotent stem cells for fundamental and therapeutic applications

Juhyung Jung (17045163)

27 September 2023

<p dir="ltr">Hematopoietic stem cells (HSCs) originating from aorta-gonad-mesonephros (AGM) could self-renew and develop into various immune cells, such as T cells, neutrophil and natural killer (NK) cells, rendering them as a promising cell source for immunotherapy. NK cells belong to the family of the innate lymphoid cells, and are employed as one of immunotherapy to cure solid and hematological malignancies including leukemia. Neutrophils are one of the granulocytes, and they are emerging as a new therapeutic target in various cancers. Due to the lack of reliable sources for the amounts of HSCs and immune cells required for clinical infusions (~10⁹ cells/patient), it remains as a major challenge to realize their full potential in targeted cell and immunotherapy. While substantial efforts have been made to generate native cell-like HSPCs and immune cells from human pluripotent stem cells (hPSCs), intricate molecular process governing the differentiation of HSCs and immune cells remain elusive, preventing the development of robust strategies for HSC and immune cell productions.</p><p dir="ltr">In this study, we first demonstrated that critical role of temporally regulating Wnt signaling in initiating AGM-like hematopoiesis across 11 hPSC lines. By inhibiting TGFβ at the stage of aorta-like CD34+SOX17⁺ hemogenic endothelium, which led to the downregulation of Wnt signaling, we established a chemically defined, feeder-free culture system that efficiently produced robust AGM-like hematopoietic cells. Furthermore, we investigated how hypoxia affects the <i>in vitro</i> hPSC differentiation into HSPCs, which resulted in a hypoxia-enhanced HSPC differentiation platform.</p><p dir="ltr">Next, the temporal roles of transcription factors (TFs), including <i>NFIL3</i>, <i>ID2</i>,<i> </i>and <i>SPI1</i>, in regulating and promoting NK cell differentiation from hPSCs are determined. <i>NFIL3</i> and <i>SPI1</i> have been reported to influence the early stages of NK cell development, while <i>ID2</i> has an impact on the generation of NK cells throughout the early and intermediate stage. We genetically modified hPSCs with doxycycline-inducible expression of <i>NFIL3</i>, <i>ID2</i>,<i> </i>and <i>SPI1</i>, and investigated their roles in NK cell induction from hPSCs. Among these three TFs, forced expression of <i>ID2</i> yielded the highest percentage of NK cells under a chemically defined, feeder-free monolayer culture condition, demonstrating that forced expression of NK-specific TFs improves the efficiency of NK cell differentiation from hPSCs.</p><p dir="ltr">Chimeric antigen receptor (CAR) is an artificial cell receptor expressed on immune T or NK cells that has been engineered to allow T or NK cells to re-target cancer cells by exclusively binding to a cancer-specific protein. CAR engineering has significantly improved the anti-tumor efficacy of NK cell therapy, resulting in 6 FDA-approved CAR-T therapies and many other ongoing clinical trials. Recently, a chlorotoxin (CLTX)-based CAR was developed and shown to specifically bind to a variety of heterogenous glioblastoma (GBM) cell lines. To test whether CLTX-CAR could improve the anti-tumor cytotoxicity of hPSC-derived NK cells, hPSCs were engineered with CLTX-CAR for stable and homogenous CAR expression via Cas9-mediated homologous recombination. The expression of CLTX-CAR did not affect the pluripotency and NK cell differentiation potential of hPSCs, and CLTX-CAR significantly improved the cytotoxicity of hPSC-derived NK cells against GBM cells.</p><p dir="ltr">Finally, we implemented a GBM-on-a-chip microfluidic model to interrogate the tumor microenvironment (TME). Microfluidics are an emerging device for investigating cancer biology with spatiotemporal control over signaling modulators by using a small volume. The interaction between hPSC-drived neutrophils and GBM was explored in this microfluidic device. GBM TME is very complex and involves many cell types, including neurons, microglia, immune T and NK cells. In the future, microfluidic models with isogenic cell components will be designed and implemented to better model GBM TME.</p><p dir="ltr">In summary, these discoveries confirm the pivotal role of Wnt signaling in guiding hPSCs towards hematopoietic lineages, while also highlighting <i>ID2</i> as a potent enhancer of NK cell differentiation from hPSC-derived hematopoietic progenitor cells. Additionally, CAR engineering enhances the anti-tumor capabilities of hPSC-derived NK cells. Furthermore, microfluidic models are employed to interrogate GBM TME.</p>

Haematology

Cellular immunology

Pluripotent stem cells (PSC)

Natural killer cell (NK cells)

hematopoietic (stem) cells

IL-7-MEDIATED CD56BRIGHT NK CELL FUNCTION IS IMPAIRED IN HCV IN PRESENCE AND ABSENCE OF CONTROLLED HIV INFECTION, WHILE CD14BRIGHTCD16- MONOCYTES NEGATIVELY CORRELATE WITH CD4 MEMORY T CELLS AND HCV DECLINE DURING HCV-HIV CO-INFECTION

Judge, Chelsey J.

08 February 2017

No description available.

Immunology

Functional Characterization Of Human IkappaBzeta In Modulating Inflammatory Responses

Kannan, Yashaswini

20 October 2011

No description available.

Biochemistry

Biology

Biophysics

Cellular Biology

Molecular Biology

IkappaBzeta

Pro-inflammatory response

Innate Immunity

TLRs

Monocytes

NK cells

IL-6

IL-1beta

IFN-gamma

Post-transcriptional regulation

Atherosclerosis

oxLDL

Repeated lipoprotein apheresis and immune response: Effects on different immune cell populations

Walther, Romy, Wehner, Rebekka, Tunger, Antje, Julius, Ulrich, Schatz, Ulrike, Tselmin, Sergey, Bornstein, Stefan R., Schmitz, Marc, Graessler, Juergen

11 June 2024

Background: Atherosclerosis is considered a chronic inflammation of arterial vessels with the involvement of several immune cells causing severe cardiovascular diseases. Lipoprotein apheresis (LA) improves cardiovascular conditions of patients with severely disturbed lipid metabolism. In this context, little is known about the impact of LA on various immune cell populations, especially over time. Methods: Immune cells of 18 LA-naïve patients starting weekly LA treatment were analyzed before and after four apheresis cycles over the course of 24 weeks by flow cytometry. Results and Conclusions: An acute lowering effect of LA on T cell and natural killer (NK) cell subpopulations expressing CD69 was observed. The nonclassical and intermediate monocyte subsets as well as HLA-DR+ 6-sulfo LacNAc+ monocytes were significantly reduced during the apheresis procedure. We conclude that LA has the capacity to alter various immune cell subsets. However, LA has mainly short-term effects than long-term consequences on proportions of immune cells.

info:eu-repo/classification/ddc/610

ddc:610

Novel approaches to enhance the protective immune responses of vaccines against Porcine Reproductive and Respiratory Syndrome Virus

Cao, Qian

08 February 2018

Since late 1980s, porcine reproductive and respiratory syndrome virus (PRRSV) has emerged as the most economically important swine pathogen affecting pig industries worldwide. Vaccination is the principal means that have been used for prevention of PRRSV infection. However, the currently available vaccines for PRRSV are generally considered as not very effective. One of the major obstacles for developing an effective modified live-attenuated vaccine (MLV) with broad protection is the delayed and insufficient immune responses mounted by PRRSV, and the problem is further exacerbated by the antigenic variations of the constantly-evolving field strains of PRRSV. In order to boost the immune response induced by the MLV vaccine virus, we evaluated the immunogenicity and vaccine efficacy of recombinant PRRSV MLVs expressing porcine IL-15 or IL-18 as adjuvants. The cytokine genes were fused with a GPI modification signal so that they are anchored onto the cell surface upon infection with the recombinant MLV. Both cytokines are successfully expressed on the cell membrane of porcine alveolar macrophage (PAMs) after recombinant MLVs infection in vitro. Subsequently, pigs vaccinated with cytokine-expressing recombinant PRRSV MLVs had an improved antiviral response of cytotoxic lymphocytes including natural killer (NK) cells and T cells, characterized by increased IFN-γ secretion and/or enhanced CD107a expression. The results offer a novel strategy to incorporate cytokine genes into PRRSV genome as potent bio-active adjuvants expressed by the vaccine virus itself. Since we showed that PRRSV VR2385 down-regulated swine leukocyte antigen class I surface expression, naturally the next logical question is which viral protein is responsible for this down-regulation. To answer the question, we cloned and expressed all known PRRSV structural and non-structural proteins and examined which protein(s) is involved in SLA-I downregulation. Our results identified the newly-discovered nonstructural protein Nsp2TF of PRRSV as the main mediator in down-regulating SLA-I expression. We also demonstrated that the Nsp2TF-knockout mutant virus lost its function of negatively modulating SLA-I presentation compared to the wild-type virus. The results suggest that disruption of the Nsp2TF's ability to down-regulate SLA-I expression may improve the existing PRRSV vaccines towards a better CMI response against the virus. / PHD

vaccine

adjuvant

cytokine

porcine immunology

T cell and NK cells

swine leukocyte antigen class I (SLA-I)

Nsp2TF