Cereblon regulates NK cell cytotoxicity and migration via Rac1 activation

Rearrangement of the actin cytoskeleton is critical for cytotoxic and immunoregulatory functions as well as migration of natural killer (NK) cells. However, dynamic reorganization of actin is a complex process, which remains largely unknown. Here, we investigated the role of the protein Cereblon (CRBN), an E3 ubiquitin ligase complex co-receptor and the primary target of the immunomodulatory drugs, in NK cells. We observed that CRBN partially colocalizes with F-actin in chemokine-treated NK cells and is recruited to the immunological synapse, thus suggesting a role for this protein in cytoskeleton reorganization. Accordingly, silencing of CRBN in NK cells results in a reduced cytotoxicity that correlates with a defect in conjugate and lytic synapse formation. Moreover, CRBN depletion significantly impairs the ability of NK cells to migrate and reduces the enhancing effect of lenalidomide on NK cell migration. Finally, we provided evidence that CRBN is required for activation of the small GTPase Rac1, a critical mediator of cytoskeleton dynamics. Indeed, in CRBN-depleted NK cells, chemokine-mediated or target cell–mediated Rac1 activation is significantly reduced. Altogether our data identify a critical role for CRBN in regulating NK cell functions and suggest that this protein may mediate the stimulatory effect of lenalidomide on NK cells.     

Compensation between Vav-1 and Vav-2 in B cell development and antigen receptor signaling

Vav-1 and Vav-2 are closely related Dbl-homology GTP exchange factors (GEFs) for Rho GTPases. Mutation of Vav-1 disrupts T cell development and T cell antigen receptor-induced activation, but has comparatively little effect on B cells. We found that combined deletion of both Vav-1 and Vav-2 in mice resulted in a marked reduction in mature B lymphocyte numbers. Vav-1(-/-)Vav-2(-/-) B cells were unresponsive to B cell antigen receptor (BCR)-driven proliferation in vitro and to thymus-independent antigen in vivo. BCR-stimulated intracellular calcium mobilization was greatly impaired in Vav-1(-/-)Vav-2(-/-) B cells. These findings establish a role for Vav-2 in BCR calcium signaling and reveal that the Vav family of GEFs is critical to B cell development and function.     

IFNalpha2b stimulated release of IFNgamma differentially regulates T cell and NK cell mediated tumor cell cytotoxicity

Interferonalpha2b (IFNalpha2b) augments the suppressed immune functions and peripheral blood mononuclear cell (PBMC) cytotoxicity of head and neck squamous cell carcinoma (HNSCC) patients by differential regulation of IFNgamma, a pleotropic Th1 cytokine. In the present communication, we have examined the role of IFNgamma in IFNalpha2b initiated T and NK cell mediated cytotoxicity of tumor cells. IFNalpha2b activates both T and NK cells to release IFNgamma. IFNgamma plays a crucial role in enhancing tumor cell cytotoxicity by T cells, but not by NK cells, as evidenced by killing of a oral (KB) and breast (MCF7) cancer cells, without affecting the killing of NK sensitive erythroleukemic K562 cells by IFNalpha2b activated PBMC. IFNalpha2b driven tumor cell cytotoxicity is related to the rectification of the downregulated expression of cytotoxic molecules, perforin, granzyme B and FasL in CD8+ T and CD56+ NK cells. Expression of IFNalpha2b mediated perforin and granzyme B is dependent on IFNgamma in T cells, but not in NK cells. However, expression of FasL in both T and NK cells is not dependent on IFNgamma. In conclusion, IFNalpha2b enhances suppressed T cell cytotoxicity of HNSCC patients by stimulating perforin-granzyme B system, which is IFNgamma dependent. IFNalpha2b also induces the expression of perforin-granzyme B system in NK cells, but this NK mediated cytotoxicity is IFNgamma independent.     

Activation of NK cell cytotoxicity

Natural killer (NK) cells are innate effector lymphocytes necessary for defence against stressed, microbe-infected, or malignant cells. NK cells kill target cells by either of two major mechanisms that require direct contact between NK cells and target cells. In the first pathway, cytoplasmic granule toxins, predominantly a membrane-disrupting protein known as perforin, and a family of structurally related serine proteases (granzymes) with various substrate specificities, are secreted by exocytosis and together induce apoptosis of the target cell. The granule-exocytosis pathway potently activates cell-death mechanisms that operate through the activation of apoptotic cysteine proteases (caspases), but can also cause cell death in the absence of activated caspases. The second pathway involves the engagement of death receptors (e.g. Fas/CD95) on target cells by their cognate ligands (e.g. FasL) on NK cells, resulting in classical caspase-dependent apoptosis. The comparative role of these pathways in the pathophysiology of many diseases is being dissected by analyses of gene-targeted mice that lack these molecules, and humans who have genetic mutations affecting these pathways. We are also now learning that the effector function of NK cells is controlled by interactions involving specific NK cell receptors and their cognate ligands, either on target cells, or other cells of the immune system. This review will discuss the functional importance of NK cell cytotoxicity and the receptor/ligand interactions that control these processes.     

Molecular biology of NK T cell specificity and development

NK T cells recognize a glycosphingolipid, alpha -galactosyl ceramide, presented by CD1d. CD1d is capable of binding a variety of lipids, however, and the hydrophilic groups of the antigen contribute relatively little to CD1d binding. Amino acids in the CD1d groove and the top of the alpha helices are involved in lipid antigen presentation, suggesting a conventional mode of presentation and antigen recognition. NK T cells also have unique requirements for their differentiation, as suggested by the analysis of a number of mouse germline mutations. For example, the development of NK T cells, unlike conventional T lymphocytes, is highly lymphotoxin dependent.     

B-Raf-mediated signaling pathway regulates T cell development

The activities of the Raf kinase family proteins control extracellular signal-regulated kinase (ERK) activation in many aspects of cellular responses. However, the relative contributions of individual isozymes to cellular functions including T cell responses are still unclear. In addition to Raf-1, another Raf family kinase, B-Raf, is expressed in murine thymocytes and peripheral T cells, and its activation was induced by TCR stimulation. Here, we investigated the function of B-Raf in development of T cells by generating chimeric mice in which a T cell-compromised host was reconstituted with fetal liver-derived cells from embryonic lethal B-Raf-deficient mice. Although B-Raf was dispensable for normal T cell lineage differentiation at the CD4(-)CD8(-) double-negative stage, thymocytes in the chimeric mice derived from B-Raf(-/-) cells exhibited a drastic arrest of differentiation at the CD4(+)CD8(+) double-positive stage, suggesting that B-Raf is crucial for T cell development, especially for the transition to CD4(+) and CD8(+) single-positive thymocytes. Regarding intracellular signaling, we found that activation of ERK following TCR stimulation was impaired in the thymocytes from the chimeric mice. In conclusion, we present first evidence for the important role of B-Raf-mediated signaling in T cell development.     

Differential regulation of transcription factor T-bet induction during NK cell development and T helper-1 cell differentiation

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The serine kinase phosphoinositide-dependent kinase 1 (PDK1) regulates T cell development

T lymphocyte activation is associated with activation of diverse AGC serine kinases (named after family members protein kinase A, protein kinase G and protein kinase C). It has been difficult to assess the function of these molecules in T cell development with simple gene-deletion strategies because different isoforms of AGC kinases are coexpressed in the thymus and have overlapping, redundant functions. To circumvent these problems, we explored the consequences of genetic manipulation of phosphoinositide-dependent kinase 1 (PDK1), a rate-limiting 'upstream' activator of AGC kinases. Here we analyzed the effect of PDK1 deletion on T lineage development. We also assessed the consequences of reducing PDK1 levels to 10% of normal. Complete PDK1 loss blocked T cell differentiation in the thymus, whereas reduced PDK1 expression allowed T cell differentiation but blocked proliferative expansion. These studies show that AGC family kinases are essential for T cell development.     

Prednisolone suppresses NK cell cytotoxicity in vitro in women with a history of infertility and elevated NK cell cytotoxicity

PROBLEM: To evaluate the effect of prednisolone on NK cell cytotoxicity in vitro environment and also to compare the effect of prednisolone versus immunoglobulin-G (IVIG) on NK cell cytotoxicity using in vitro co-culture with K562 cells. METHOD OF STUDY: The following is a prospective observational study, between August 2006 and February 2007, was carried out on blood samples from 110 patients with a history of recurrent miscarriage or recurrent failed implantation. Peripheral blood mononuclear cells containing NK cells were isolated and co-cultured with target cell K562 in three different effector-to-target (E:T) ratios of 50:1, 25:1 and 12.5:1. Prednisolone or IVIG was then added to the tube with E:T ratio of 50:1 to assess suppressive effect. The percentage killing was recorded and statistical analysis performed using Student's t-test. RESULTS: In the experiments with an E:T ratio of 50:1 without prednisolone or IVIG in the co-culture, the mean target cell killing percentage was 26.4%. In cultures using the same E:T ratio, this killing percentage was significantly reduced in the presence of IVIG (9.9%) or prednisolone (13.6%), (P<0.001 in both analyses). On comparing the reduction in killing percentage of target cells by prednisolone versus IVIG, a slightly lower reduction in the prednisolone co-culture was noted but this was not statistically significant (P>0.05). CONCLUSION: The results of this study show that prednisolone is able to suppress the cytolytic activity of the NK cell. Prednisolone and IVIG are almost equally effective in suppressing in vitro NK cell cytolytic activity.     

Redundant functions of TCF-1 and LEF-1 during T and NK cell development,but unique role of TCF-1 for Ly49 NK cell receptor acquisition

Members of the TCF/LEF (T cell factor / lymphoid enhancer factor) family of DNA-binding factors play important roles during embryogenesis, the establishment and/or maintenance of self-renewing tissues such as the immune system and for malignant transformation. Specifically, it has been shown that TCF-1 is required for T cell development. A role for LEF-1 became apparent when mice harbored two hypomorphic TCF-1 alleles and consequently expressed low levels of TCF-1. Here we show that NK cell development is similarly regulated by redundant functions of TCF-1 and LEF-1, whereby TCF-1 contributes significantly more to NK cell development than LEF-1. Despite this role for NK cell development, LEF-1 is not required for the establishment of a repertoire of MHC class I-specific Ly49 receptors on NK cells. The proper formation of this repertoire depends to a large extent on TCF-1. These findings suggest common and distinct functions of TCF-1 and LEF-1 during lymphocyte development.     

The adaptor SAP controls NK cell activation by regulating the enzymes Vav-1 and SHIP-1 and by enhancing conjugates with target cells

The adaptor SAP, mutated in X-linked lymphoproliferative disease, has critical roles in multiple immune cell types. Among these, SAP is essential for the ability of natural killer (NK) cells to eliminate abnormal hematopoietic cells. Herein, we elucidated the molecular and cellular bases of this activity. SAP enhanced NK cell responsiveness by a dual molecular mechanism. It coupled SLAM family receptors to the kinase Fyn, which triggered the exchange factor Vav-1 and augmented NK cell activation. SAP also prevented the inhibitory function of SLAM family receptors. This effect was Fyn independent and correlated with uncoupling of SLAM family receptors from the lipid phosphatase SHIP-1. Both mechanisms cooperated to enable conjugate formation with target cells and to stimulate cytotoxicity and cytokine secretion by NK cells. These data showed that SAP secures NK cell activation by a dichotomous molecular mechanism, which is required for conjugate formation. These findings may have implications for the role of SAP in other immune cell types.     

EphrinB1-EphB signaling regulates thymocyte-epithelium interactions involved in functional T cell development

The Eph and ephrin families are involved in numerous developmental processes. Recently, an increasing body of evidence has related these families with some aspects of T cell development. In the present study, we show that the addition of either EphB2-Fc or ephrinB1-Fc fusion proteins to fetal thymus organ cultures established from 17-day-old fetal mice decreases the numbers of both double-positive (CD4(+)CD8(+)) and single-positive (both CD4(+)CD8(-) and CD4(-)CD8(+)) thymocytes, in correlation with increased apoptosis. By using reaggregate thymus organ cultures formed by fetal thymic epithelial cells (TEC) and CD4(+)CD8(+) thymocytes, we have also demonstrated that ephrinB1-Fc proteins are able to disorganize the three-dimensional epithelial network that in vivo supports the T cell maturation, and to alter the thymocyte interactions. In addition, in an in vitro model, Eph/ephrinB-Fc treatment also decreases the formation of cell conjugates by CD4(+)CD8(+) thymocytes and TEC as well as the TCR-dependent signaling between both cell types. Finally, immobilized EphB2-Fc and ephrinB1-Fc modulate the anti-CD3 antibody-induced apoptosis of CD4(+)CD8(+) thymocytes in a process dependent on concentration. These results therefore support a role for Eph/ephrinB in the processes of development and selection of thymocytes as well as in the establishment of the three-dimensional organization of TEC.     

T and NK cell peripheral tumors

Peripheral T lymphomas are formed by cells with CD3 antigen which contain TCR alpha/beta. A minor part of the non-tumourous population contains TCR gamma/delta. The position is similar in T cell tumours. In the tumours however TCR may be lacking .NK ("natural killer") cells are CDR3 negative, rearrangement of the gene TCR does not occur and they are TCR alpha/beta and TCR gamma/delta negative. Contrary to T cells they contain antigen CD56 ("NK-associated antigen"). In these cells and in tumours cytotoxic proteins are usually present: TIA-1, granzyme-B, perforin. There is a continuous transition between T and NK cells. The prognosis of T cell tumours cannot be assessed from the cell size. T/NK small cell lymphomas are highly aggressive tumours. The prognosis of patients is very bad. From the morphological aspect they can resemble very much non-tumorous lymphocytes. Conversely, large cell T lymphomas of the skin which are CD30 positive take a very mild course and their prognosis is favourable. The author mentions also some more recent entities of extra-nodular T lymphomas: angiocentric NK/T lymphoma of the nose (and other regions), malignant T cell lymphoma in enteropathies, T cell lymphoma resembling subcutaneous panniculitis, hepatosplenic gamma/delta T lymphoma. These tumours are rare in this country and some, e.g. T/NK lymphoma of the nose, are found usually only in certain regions of the world. They may be however encountered also in Europe, in particular in immunosuppressed subjects and patients after organ transplantation.     

Divergent effects of thyroid HLA-antigens on T and natural killer (NK) cell cytotoxicity.

We have used non-autoimmune non-neoplastic human thyroid cells to explore the role of surface class I and DR antigens on these cells' sensitivity towards T and Natural Killer (NK) cell cytotoxicity. Non-treated thyrocytes expressed class I but no DR antigens. Following incubation with gamma-interferon (gamma-IFN) class I antigens were markedly elevated and DR expression was induced. Whereas non-treated thyrocytes were minimally lysed by sensitized T cells, they served as appropriate targets for NK cells. Following incubation with gamma-IFN, the thyroid cells became highly sensitive to T cell lysis, with no significant reduction in their vulnerability to NK cell killing. The addition of monoclonal anti class I or DR antigens, or brief acid treatment which specifically eliminates class I molecules, inhibited T cell cytotoxicity but enhanced the sensitivity to lysis by NK cells. Thus, the presence of HLA antigens on the same thyroid cells have an opposite effect on two major cytotoxi mechanisms. Our findings are relevant within the context of recent suggestions of intervening with target HLA antigens for the management of autoimmune and malignant diseases.     

Notch 1 signaling regulates peripheral T cell activation

Notch signaling has been identified as an important regulator of leukocyte differentiation and thymic maturation. Less is known about the role of Notch signaling in regulating mature T cells. We examined the role of Notch 1 in regulating peripheral T cell activity in vitro and in vivo. Coligation of Notch 1 together with TCR and CD28 resulted in a dramatic inhibition of T cell activation, proliferation, and cytokine production. This effect was dependent on presenilin activity and induced the expression of HES-1, suggestive of Notch 1 signaling. Biochemical analysis demonstrated an inhibition of AKT and GSK3beta phosphorylation following Notch 1 engagement while other biochemical signals such as TCR and ERK phosphorylation remained intact. Similar effects were observed in vivo in an adoptive transfer model. Therefore, Notch 1 signaling may play an important role in regulating naive T cell activation and homeostasis.