Deborah L. Hodge

IL-2 and IL-12 Alter NK Cell Responsiveness to IFN-γ-Inducible Protein 10 by Down-Regulating CXCR3 Expression

Cytokine treatment of NK cells results in alterations in multiple cellular responses that include cytotoxicity, cytokine production, proliferation, and chemotaxis. To understand the molecular mechanisms underlying these responses, microarray analysis was performed and the resulting gene expression patterns were compared between unstimulated, IL-2, IL-2 plus IL-12, and IL-2 plus IL-18-stimulated NK92 cells. RNase protection assays and RT-PCR confirmed microarray predictions for changes in mRNA expression for nine genes involved in cell cycle progression, signal transduction, transcriptional activation, and chemotaxis. Multiprobe RNase protection assay also detected changes in the expression of CCR2 mRNA, a gene that was not imprinted on the microarray. We subsequently expanded our search for other chemokine receptor genes absent from the microarray and found an IL-2- and IL-12-dependent decrease in CXCR3 receptor mRNA expression in NK92 cells. A detailed analysis of CXCR3 expression in primary NK cells revealed that an IL-2 and an IL-12 together significantly decreased the CXCR3 receptor mRNA and receptor surface expression by 6 and 24 h of treatment, respectively. This decrease in receptor expression was associated with a significant reduction in chemotaxis in the presence of IFN-γ-inducible protein-10. The decline in CXCR3 mRNA was due to transcriptional and posttranscriptional mechanisms as the addition of actinomycin D to IL-2- and IL-12-treated NK92 slightly altered the half-life of the CXCR3 mRNA. Collectively, these data suggest that IL-2 and IL-12 directly affect NK cell migratory ability by rapid and direct down-regulation of chemokine receptor mRNA expression.

Regulation of Nuclear Gamma Interferon Gene Expression by Interleukin 12 (IL-12) and IL-2 Represents a Novel Form of Posttranscriptional Control

ABSTRACT Posttranscriptional control of gamma interferon (IFN-γ) gene expression has not been extensively studied and is poorly understood. Our work describes a posttranscriptional mechanism that modulates IFN-γ mRNA expression in stimulated natural killer (NK) cells through nuclear retention of the IFN-γ mRNA. This is evidenced by the elevated and sustained nuclear accumulation of both precursor and processed IFN-γ mRNAs in NK cells stimulated with interleukin-12 (IL-12). The elevated nuclear mRNA accumulation persists long after transcriptional activity has subsided and the rate of cytoplasmic IFN-γ mRNA accumulation has dropped. The IL-12-induced nuclear retention of the IFN-γ mRNA prevails until a secondary cytokine stimulus is received. The secondary stimulus, which is initiated by IL-2, mediates transcription-independent movement of the nuclear IFN-γ mRNA. Concurrent with the nucleocytoplasmic movement of the IFN-γ mRNA, we have observed increases in the amount of processed nuclear IFN-γ mRNA that are greater than that seen for the unprocessed IFN-γ mRNA. The increase in processed IFN-γ mRNA appears to be due to increased mRNA stability which then promotes increased nucleocytoplasmic shuttling of the mature IFN-γ mRNA. These data support a model whereby mobilization of nuclear IFN-γ mRNA stores allows NK cells to rapidly and robustly respond to secondary cytokine activators in a transcription-independent manner, thus shortening the time for overall cellular response to inflammatory signals.

Activating Ly-49 NK Receptors: Central Role in Cytokine and Chemokine Production

In an attempt to understand potential novel functions of receptors in vivo, we evaluated gene expression after cross-linking the activating Ly-49D mouse NK receptor. Gene expression was evaluated using a mouse GEM 2 microarray chip (Incyte Genomics, St. Louis, MO). Each chip displays a total of 8734 elements. The strongly induced genes fell into two categories: 1) soluble factors and 2) apoptotic genes. The majority of the strongly induced mRNAs as analyzed by microarray hybridization were chemokine genes. RNase protection assays and chemokine protein production analysis validated the microarray results, as cross-linking the Ly-49D mouse NK receptor induced high levels of IFN-γ, lymphotactin, macrophage-inflammatory protein (MIP)1α, and MIP1β. This gene expression was specific because other chemokines were not induced by anti-Ly-49D receptors. In addition, a series of pharmacological inhibitors were used to identify the key signaling pathways involved in the cellular response. The primary Ly-49D signaling for IFN-γ production is predominately mediated through Src kinase pathways involving membrane proximal events, whereas MIP1α and MIP1β gene induction is more complex and may involve multiple biochemical pathways. Thus, we conclude that a primary role for the activating NK receptors in vivo may be to trigger soluble factor production and regulation of the immune response. This would place NK cells and their activating Ly-49 receptors as important initiators of microbial immunity and key elements of the innate immune system.

Identification of a Novel Ly49 Promoter That Is Active in Bone Marrow and Fetal Thymus

The analysis of several Ly49 genes has identified a tissue-specific promoter adjacent to the previously defined first exon. The current study reveals the presence of an additional Ly49 promoter (Pro-1) and two noncoding exons upstream of the previously defined promoter (Pro-2). DNA sequences homologous to Pro-1 are present 4–10 kb upstream of Pro-2 in all Ly49 genes examined, and Pro-1 transcripts were detected from the Ly49a, e, g, o, and v genes. Pro-1 activity can be detected in bone marrow, embryonic thymus, freshly isolated liver NK cells, and the murine LNK cell line, but it does not function in adult thymus, sorted NK-T cells, spleen NK cells, or the EL-4 T cell line, even though these cells express Ly49 proteins. Luciferase reporter assays identified a Pro-1 core promoter region that functions in the LNK cell line but not EL-4 cells. The novel promoter is not active in mature NK cells, suggesting that Pro-1 represents an early Ly49 promoter.

Interleukin-15 Enhances Proteasomal Degradation of Bid in Normal Lymphocytes: Implications for Large Granular Lymphocyte Leukemias

Large granular lymphocyte (LGL) leukemia is a clonal proliferative disease of T and natural killer (NK) cells. Interleukin (IL)-15 is important for the development and progression of LGL leukemia and is a survival factor for normal NK and T memory cells. IL-15 alters expression of Bcl-2 family members, Bcl-2, Bcl-XL, Bim, Noxa, and Mcl-1; however, effects on Bid have not been shown. Using an adoptive transfer model, we show that NK cells from Bid-deficient mice survive longer than cells from wild-type control mice when transferred into IL-15-null mice. In normal human NK cells, IL-15 significantly reduces Bid accumulation. Decreases in Bid are not due to alterations in RNA accumulation but result from increased proteasomal degradation. IL-15 up-regulates the E3 ligase HDM2 and we find that HDM2 directly interacts with Bid. HDM2 suppression by short hairpin RNA increases Bid accumulation lending further support for HDM2 involvement in Bid degradation. In primary leukemic LGLs, Bid levels are low but are reversed with bortezomib treatment with subsequent increases in LGL apoptosis. Overall, these data provide a novel molecular mechanism for IL-15 control of Bid that potentially links this cytokine to leukemogenesis through targeted proteasome degradation of Bid and offers the possibility that proteasome inhibitors may aid in the treatment of LGL leukemia.

IFN-γ causes aplastic anemia by altering hematopoietic stem/progenitor cell composition and disrupting lineage differentiation.

Aplastic anemia (AA) is characterized by hypocellular marrow and peripheral pancytopenia. Because interferon gamma (IFN-γ) can be detected in peripheral blood mononuclear cells of AA patients, it has been hypothesized that autoreactive T lymphocytes may be involved in destroying the hematopoietic stem cells. We have observed AA-like symptoms in our IFN-γ adenylate-uridylate-rich element (ARE)-deleted (del) mice, which constitutively express a low level of IFN-γ under normal physiologic conditions. Because no T-cell autoimmunity was observed, we hypothesized that IFN-γ may be directly involved in the pathophysiology of AA. In these mice, we did not detect infiltration of T cells in bone marrow (BM), and the existing T cells seemed to be hyporesponsive. We observed inhibition in myeloid progenitor differentiation despite an increase in serum levels of cytokines involved in hematopoietic differentiation and maturation. Furthermore, there was a disruption in erythropoiesis and B-cell differentiation. The same phenomena were also observed in wild-type recipients of IFN-γ ARE-del BM. The data suggest that AA occurs when IFN-γ inhibits the generation of myeloid progenitors and prevents lineage differentiation, as opposed to infiltration of activated T cells. These results may be useful in improving treatment as well as maintaining a disease-free status.

Chronic expression of interferon-gamma leads to murine autoimmune cholangitis with a female predominance

In most autoimmune diseases the serologic hallmarks of disease precede clinical pathology by years. Therefore, the use of animal models in defining early disease events becomes critical. We took advantage of a “designer” mouse with dysregulation of interferon gamma (IFNγ) characterized by prolonged and chronic expression of IFNγ through deletion of the IFNγ 3′‐untranslated region adenylate uridylate‐rich element (ARE). The ARE‐Del‐/‐ mice develop primary biliary cholangitis (PBC) with a female predominance that mimics human PBC that is characterized by up‐regulation of total bile acids, spontaneous production of anti‐mitochondrial antibodies, and portal duct inflammation. Transfer of CD4 T cells from ARE‐Del‐/‐ to B6/Rag1‐/‐ mice induced moderate portal inflammation and parenchymal inflammation, and RNA sequencing of liver gene expression revealed that up‐regulated genes potentially define early stages of cholangitis. Interestingly, up‐regulated genes specifically overlap with the gene expression signature of biliary epithelial cells in PBC, implying that IFNγ may play a pathogenic role in biliary epithelial cells in the initiation stage of PBC. Moreover, differentially expressed genes in female mice have stronger type 1 and type 2 IFN signaling and lymphocyte‐mediated immune responses and thus may drive the female bias of the disease. Conclusion: Changes in IFNγ expression are critical for the pathogenesis of PBC. (Hepatology 2016;64:1189‐1201)

MCP-1/CCR2 interactions direct migration of peripheral B and T lymphocytes to the thymus during acute infectious/inflammatory processes

Mature lymphocyte immigration into the thymus has been documented in mouse, rat, and pig models, and highly increases when cells acquire an activated phenotype. Entrance of peripheral B and T cells into the thymus has been described in healthy and pathological situations. However, it has not been proposed that leukocyte recirculation to the thymus could be a common feature occurring during the early phase of a Th1 inflammatory/infectious process when a large number of peripheral cells acquire an activated phenotype and the cellularity of the thymus is seriously compromised. The data we present here demonstrate that in well‐established Th1 models triggered by different types of immunogens, for example, LPS treatment (a bacterial product), Candida albicans infection (a fungus), and after Trypanosoma cruzi infection (a parasite), a large number of mature peripheral B and T cells enter the thymus. This effect is dependent on, but not exclusive of, the available space in the thymus. Our data also demonstrate that MCP‐1/CCR2 (where MCP‐1 is monocyte chemoattractant protein‐1) interaction is responsible for the infiltration of peripheral cells to the thymus in these Th1‐inflammatory/infectious situations. Finally, systemic expression of IL‐12 and IL‐18 produced during the inflammatory process is ultimately responsible for these migratory events.

Hematopoiesis and Thymic Apoptosis Are Not Affected by the Loss of Cdk2

ABSTRACT Cell cycle regulation is essential for proper homeostasis of hematopoietic cells. Cdk2 is a major regulator of S phase entry, is activated by mitogenic cytokines, and has been suggested to be involved in antigen-induced apoptosis of T lymphocytes. The role of Cdk2 in hematopoietic cells and apoptosis in vivo has not yet been addressed. To determine whether Cdk2 plays a role in these cells, we performed multiple analyses of bone marrow cells, thymocytes, and splenocytes from Cdk2 knockout mice. We found that Cdk2 is not required in vivo to induce apoptosis in lymphocytes, a result that differs from previous pharmacological in vitro studies. Furthermore, thymocyte maturation was not affected by the lack of Cdk2. We then analyzed the hematopoietic stem cell compartment and found similar proportions of stem cells and progenitors in Cdk2−/− and wild-type animals. Knockouts of Cdk2 inhibitors (p21, p27) affect stem cell renewal, but a competitive graft experiment indicated that renewal and multilineage differentiation are normal in the absence of Cdk2. Finally, we stimulated T lymphocytes or macrophages to induce proliferation and observed normal reactivation of Cdk2−/− quiescent cells. Our results indicate that Cdk2 is not required for proliferation and differentiation of hematopoietic cells in vivo, although in vitro analyses consider Cdk2 to be a major player in proliferation and apoptosis in these cells and a potential target for therapy.

Differential inducibility of the transcriptional repressor ICER and its role in modulation of Fas ligand expression in T and NK lymphocytes.

The engagement of antigen receptor can initiate apoptosis of T lymphocytes through the induced expression of Fas ligand (FasL). Forskolin, an activator of the cAMP/PKA pathway, results in antagonism of Fas‐dependent, activation‐induced cell death (AICD) by suppressed expression of the FasL. We report that forskolin‐mediated induction of inducible cAMP early repressor (ICER) correlates with transcriptional attenuation of FasL expression in the AICD model 2B4 T cell hybridoma. ICER is inducible in human peripheral blood CD3+ T cells, but in CD19+ B cells, its induction is less responsive to forskolin treatment. Increased expression of ICER correlates with decreased FasL expression in both T and NK cells. ICER binds specifically to the proximal DNA binding siteof the nuclear factor of activated T cells (NFAT) in the FasL promoter and in the presence of the minimal NFAT DNA‐binding domain, the proximal NFAT motif allows ICER and NFAT to form an NFAT/ICER ternary complex in vitro. Moreover, in the activated 2B4 T cell hybridoma, the proximal NFAT motif participates in the down‐regulation of the FasL promoter mediated by ICER. These findings provide further insight into the mechanism involved in cAMP‐mediated transcriptional attenuation of FasL expression in T and NK lymphocytes.