Exosomes and the NKG2D receptor-ligand system in pregnancy and cancer : using stress for survival

Hedlund, Malin

January 2010

Although not obvious at first sight, several parallels can be drawn between pregnancy andcancer. Many proliferative, invasive and immune tolerance mechanisms that supportnormal pregnancy are also exploited by malignancies to establish a nutrient supply andevade or edit the immune response of the host. The human placenta, of crucial importancefor pregnancy success, and its main cells, the trophoblast, share several features withmalignant cells such as high cell proliferation rate, lack of cell-contact inhibition andinvasiveness. Both in cancer and in pregnancy, the immune defense mechanisms,potentially threatening the survival of the tumor or the fetus, are progressively blunted oreven turned into tumor- or pregnancy-promoting players. Amongst immune mechanisms that are meant to protect the host from cancer and can be apotential threat to the fetus, the NKG2D receptor-ligand system stands out as the mostpowerful, stress-inducible “danger detector” system that comprises the activating NK cellreceptor NKG2D and its ligands, the MIC (MHC class I Chain-related proteins A and B)and ULBP (UL-16 Binding Proteins) families. It is the major cytotoxic mechanism in thebody promoting surveillance and homeostasis. In the present thesis we investigate theNKG2D receptor-ligand system in human early normal pregnancy and in theleukemia/lymphoma cell lines Jurkat and Raji and ask the questions “How is the NKG2Dreceptor-ligand system functioning in pregnancy and tumor? How is the danger of cytotoxicattack of the fetus avoided? Why is the immunosurveillance function compromised incancer patients?” We developed a method to isolate and culture villous trophoblast from early human normalplacenta and used it to study the NKG2D receptor-ligand system. We discovered that theNKG2D ligand families of molecules MICA/B and ULBP1-5 are constitutively expressedby the syncytiotrophoblast of the chorionic villi. Using immnunoelectron microscopy, westudied the expression of these molecules at the subcellular level and could show for thefirst time that they are preferably expressed on microvesicles in multivesicular bodies(MVB) of the late endosomal compartment and are secreted as exosomes. Exosomes arenanometer sized microvesicles of endosomal origin, produced and secreted by a great7variety of normal and tumor cells. The exosomes are packages of proteins and ribonucleicacids that function as “mail” or “messengers” between cells conveying different biologicalinformation. We isolated and studied exosomes from placental explant cultures. We foundthat they carry NKG2D ligands on their surface and are able to bind and down-regulate thecognate receptor on NK-, CD8+ and <img src="http://www.diva-portal.org/cgi-bin/mimetex.cgi?%5Cgamma" /><img src="http://www.diva-portal.org/cgi-bin/mimetex.cgi?%5Cdelta" />T cells. The down-regulation selectively causedimpairment of the cytotoxic response of the cells but did not affect their lytic ability asmeasured by perforin content and gene transcription. Thus, the NKG2D ligand-bearingexosomes suppress the cytotoxic activity of the cells in the vicinity of the placenta, leavingtheir cytolytic machinery intact, ready to function when the cognate receptor isrestored/recycled. These findings highlight the role of placental exosomes in the fetalmaternalimmune escape and support the view of placenta as an unique immunomodulatoryorgan. Next, we studied the expression and exosomal release of NKG2D ligands by tumor cellsusing the leukemia cell lines Jurkat and Raji as a tumor model. We found that NKG2Dligand-bearing exosomes with similar immunosuppressive properties as placental exosomesare constitutively secreted by the tumor cells, as a mechanism to blunt the cytotoxicresponse of the immune cells and thus protect themselves from cytotoxic attack by the host.Interestingly, we found that thermal- and oxidative stress up-regulates the exosomesecretion and the amount of exosome-secreted NKG2D ligands. Our results imply thattumor therapies that cause stress-induced damage, such as thermotherapy and stripping ofoxygen supply to the tumor, might have a previously unrecognized side effect causingenhanced exosome production and secretion, which in turn suppresses the natural antitumorimmune response and thus should be taken into account when designing an optimaltherapy of cancer patients. In conclusion, we describe a novel stress-inducible mechanism shared by placenta andtumors as an immune escape strategy. We found that placenta- and tumor-derived NKG2Dligand-bearing exosomes can suppress immune responses to promote the survival and wellbeing of the fetus or the tumor. Our work comprises an important contribution to theelucidation of the NKG2D ligand-receptor system and its mode of operation in the humanbody and opens new perspectives for designing novel therapies for infertility and cancer.

Exsosomes

NKG2D

MICA

MICB

ULBP

human placenta

trophoblast

syncytiotrophoblast

thermal stress

oxidative stress

leukemia

lymphoma

In silico transcriptional regulation and functional analysis of dengue shock syndrome associated SNPs in PLCE1 and MICB genes

Taqi, M.M., Waseem, D., Ismatullah, H., Haider, S.A., Faisal, Muhammad

01 April 2016

Yes / Single nucleotide polymorphisms (SNPs) in PLCE1 and MICB genes increase risk for the development of dengue shock syndrome (DSS). We used Bioinformatics tools to predict alterations at the transcriptional and posttranslational levels driven by PLCE1 and MICB SNPs associated with DSS. Functional and phenotypic analysis conducted to determine deleterious SNPs and impact of amino acid substitution on the structure and function of proteins identified rs2274223 (H1619R) as deleterious to protein coding as it induces structural change in the C2 domain of PLCε, with the mutant residue more positively charged than the wild-type residue (RMSD score, 1.75 Å).Moreover, rs2274223 condenses the chromatinrepressing PLCε expression in DSS. Briefly, this study presents the impact of a single nucleotide transition at SNPs associated with DSS on differential protein binding patterns with PLCE1 and MICB genes and on protein structure modification and their possible role in the pathogenesis of DSS.

Phospholipase C epsilon (PLCE1)

MICB

Transcription factors

Dengue-associated SNPs

Mutated PLCε protein

Subversion of Natural Killer Cell Defenses Induced by a Deadly Zoonotic Virus

Vasireddi, Mugdha

01 December 2009

B virus (Macacine herpesvirus 1, Cercopithecine herpesvirus 1, herpes B virus) is an Old World monkey simplex virus endemic in macaques. B virus infection in its natural host, macaque, is very similar to HSV-­‐1 infection in humans causing mild or asymptomatic infection. On the other hand, zoonotic infection in humans results in death in the absence of early initiation of antiviral drugs. Viruses evade host immune responses in order to survive and propagate. Most herpes viruses including HSV-­‐1 down-­‐regulate major histocompatibility complex class I (MHC class I) surface expression on infected cells in order to prevent CD8+ T-­‐cell recognition and subsequent cell lysis. MHC class I molecules bind to the inhibitory receptors of NK cells and prevent NK cell activity. Thus, this mechanism protects HSV-­‐1 infected cells from CD8+ T-­‐cell lysis, making them sensitive to natural killer (NK) cell cytotoxicity. To investigate if B virus pathogenicity is a result of novel immune evasion mechanisms employed by B virus, we determined NK cell regulation during B virus infection. To this end, our experiments demonstrate that B virus does not down-­‐ regulate MHC I expression as effectively as HSV-­‐1, leading us to hypothesize that B virus in-­‐ fected cells are resistant to NK cell activity. We examined the expression of MHC I chain related genes (MICA/ MICB), which are activation ligands to NKG2D receptors on NK cells. Our results show that there is no significant difference in MICA and MICB expression between HSV-­‐1 and B virus infected cells. Furthermore, we tested for the up-­‐regulation of cytokines and chemokines responsible for NK cell activation and migration. Our results indicate a significant up-­‐regulation of IFN-­‐α from PBMCs co-­‐cultured with HSV-­‐1 infected cells, which plays an important role in activating NK cells. NK cells within these PBMCs up-­‐regulate perforin release indicative of NK cell activity. PBMCs co-­‐cultured with B virus infected cells do not up-­‐regulate any cytokines or chemokines responsible for NK cell activity. As a result the NK cells within these PBMCs do not significantly up-­‐regulate perforin release. These results demonstrate that B virus employs a novel immune evasion mechanism to subvert NK cell activity.

B virus

MHC I

HLA-­A

-­B

-­C

-­E

-­G

MICA

MICB

HSV-­1

NK cells

PBMC

IFN-­ and IP-­10

Perforin

Granzyme B

Biology, general