Browsing by Person "Kienes, Ioannis"

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Bacterial subversion of NLR-mediated immune responses
(2022) Kienes, Ioannis; Johnston, Ella L.; Bitto, Natalie J.; Kaparakis-Liaskos, Maria; Kufer, Thomas A.
Members of the mammalian Nod-like receptor (NLR) protein family are important intracellular sensors for bacteria. Bacteria have evolved under the pressure of detection by host immune sensing systems, leading to adaptive subversion strategies to dampen immune responses for their benefits. These include modification of microbe-associated molecular patterns (MAMPs), interception of innate immune pathways by secreted effector proteins and sophisticated instruction of anti-inflammatory adaptive immune responses. Here, we summarise our current understanding of subversion strategies used by bacterial pathogens to manipulate NLR-mediated responses, focusing on the well-studied members NOD1/2, and the inflammasome forming NLRs NLRC4, and NLRP3. We discuss how bacterial pathogens and their products activate these NLRs to promote inflammation and disease and the range of mechanisms used by bacterial pathogens to evade detection by NLRs and to block or dampen NLR activation to ultimately interfere with the generation of host immunity. Moreover, we discuss how bacteria utilise NLRs to facilitate immunotolerance and persistence in the host and outline how various mechanisms used to attenuate innate immune responses towards bacterial pathogens can also aid the host by reducing immunopathologies. Finally, we describe the therapeutic potential of harnessing immune subversion strategies used by bacteria to treat chronic inflammatory conditions.
Characterization of the role of the NLR proteins NLRC5 and NLRP11 in the immune response
(2021) Kienes, Ioannis; Kufer, Thomas
Recognition of conserved molecular patterns by pattern recognition receptors (PRRs) is crucial for the initiation of an innate immune response. Within PRRs, the NOD-like receptor (NLR) family is, in humans, a group of 22 cytosolic proteins, which function as PRRs of the innate immune system and as regulators of adaptive immune responses. However, it has become evident, that several NLR proteins also function as regulators of innate immune responses. In this thesis the function of human NLR proteins NLRC5 and NLRP11 in immune responses was further characterized. The first part of this thesis was focused on the NOD-like receptor NLRC5. NLRC5 and major histocompatibility complex (MHC) class II transcriptional activator (CIITA) are the master regulators of MHC class I and II transcription, respectively. Both proteins can translocate into the nucleus, where they induce transcription of MHC class I and class II, respectively. As NLRC5 and CIITA do not possess intrinsic DNA binding capacities, they exert their function by binding to a common multiprotein complex, termed MHC enhanceosome and through recruitment of further transcriptional regulators. Although MHC enhanceosome components are, as known thus far, identical, NLRC5 and CIITA are specific for their respective transcriptional targets. In this work we employed several techniques to identify novel interaction partners of NLRC5 to understand the mechanisms behind this specificity. As the N-terminal domain death-domain like fold (DD) of NLRC5 has previously been shown to be involved in conferring specificity, we adapted a protocol for proximal ligation by fusion of the NLRC5 DD to biotin ligase from Aquifex aeolicus (BioID2) to unravel the interactome of this NLRC5 domain. By enrichment of biotinylated proteins through streptavidin-biotin precipitation and analysis of the proteins by LC-MS/MS, we aimed to identify novel putative interactors with functions in transcriptional regulation. Additionally, we used yeast 2 hybrid screening of the NLRC5 DD against a library of human CD4+ and CD8+ T cells for the identification of novel interaction partners. This led to the identification of the paired amphipathic helix protein Sin3A (Sin3A) and the negative elongation factor B (NELFB) as interactors of NLRC5 DD. Characterization of their role in transcriptional regulation of MHC class I revealed an inhibitory role of both proteins. However, as we also observed repression of CIITA-mediated MHC class II transcription, both proteins are likely not involved in determination of target specificity of NLRC5. Translocation of NLRC5 into the nucleus is essential for the induction of MHC class I transcription. It has however previously been shown, that forced nuclear localization of NLRC5 strongly diminishes its transcriptional activity. We therefore employed co-immunoprecipitation of differentially localized NLRC5 constructs to identify interaction partners which might be involved in post translational regulation of NLRC5. Further, to advance our understanding of the NLRC5 DD, we aimed to elucidate its crystal structure. For this, we established a protocol for large-scale recombinant expression and purification of the NLRC5 DD for subsequent crystallization of the recombinant protein. The second part of this thesis was focused on NLRP11. Tight regulation of inflammatory cytokine and interferon (IFN) production in innate immunity is pivotal for optimal control of pathogens and avoidance of immunopathology. NLRP11 has previously been shown to regulate type I IFN and other pro-inflammatory responses. To gain a deeper understanding of the underlying mechanism, we aimed to identify novel NLRP11 interactors, through which the inhibition is conferred. Here we generated cell lines stably expressing NLRP11-eGFP as novel tools to elucidate the functions of NLRP11. We identified the ATP-dependent RNA helicase DDX3X as a novel binding partner of NLRP11 by co immunoprecipitation and LC-MS/MS. DDX3X is known to enhance type I IFN responses and NLRP3 inflammasome activation. We demonstrate that NLRP11 can abolish IKKe-mediated phosphorylation of DDX3X, resulting in lower type I IFN induction upon viral infection. These effects were dependent on the leucine-rich repeat (LRR) domain of NLRP11 that we mapped as the interaction domain for DDX3X. In addition, NLRP11 also suppressed NLRP3-mediated caspase-1 activation in an LRR domain-dependent manner, suggesting, that NLRP11 might sequester DDX3X and prevent it from promoting NLRP3-induced inflammasome activation. Taken together, our data revealed DDX3X as a central target of NLRP11, which can mediate the effects of NLRP11 on type I IFN induction, as well as NLRP3 inflammasome activation. This expands our knowledge of the molecular mechanisms underlying NLRP11 function in innate immunity and suggests that both NLRP11 and DDX3X might be promising targets for modulation of innate immune responses.
Role of NLRs in the regulation of type I interferon signaling, host defense and tolerance to inflammation
(2021) Kienes, Ioannis; Weidl, Tanja; Mirza, Nora; Chamaillard, Mathias; Kufer, Thomas A.
Type I interferon signaling contributes to the development of innate and adaptive immune responses to either viruses, fungi, or bacteria. However, amplitude and timing of the interferon response is of utmost importance for preventing an underwhelming outcome, or tissue damage. While several pathogens evolved strategies for disturbing the quality of interferon signaling, there is growing evidence that this pathway can be regulated by several members of the Nod-like receptor (NLR) family, although the precise mechanism for most of these remains elusive. NLRs consist of a family of about 20 proteins in mammals, which are capable of sensing microbial products as well as endogenous signals related to tissue injury. Here we provide an overview of our current understanding of the function of those NLRs in type I interferon responses with a focus on viral infections. We discuss how NLR-mediated type I interferon regulation can influence the development of auto-immunity and the immune response to infection.