Toshiya Inoue

The Production of IL-10 by Human Regulatory T Cells Is Enhanced by IL-2 through a STAT5-Responsive Intronic Enhancer in the IL-10 Locus

STAT5 molecules are key components of the IL-2 signaling pathway, the deficiency of which often results in autoimmune pathology due to a reduced number of CD4+CD25+ naturally occurring regulatory T (Treg) cells. One of the consequences of the IL-2-STAT5 signaling axis is up-regulation of FOXP3, a master control gene for naturally occurring Treg cells. However, the roles of STAT5 in other Treg subsets have not yet been elucidated. We recently demonstrated that IL-2 enhanced IL-10 production through STAT5 activation. This occurred in two types of human Treg cells: a novel type of umbilical cord blood-derived Treg cell, termed HOZOT, and Tr1-like Treg cells, IL-10-Treg. In this study, we examined the regulatory mechanisms of IL-10 production in these Treg cells, focusing specifically on the roles of STAT5. By performing bioinformatic analysis on the IL-10 locus, we identified one STAT-responsive element within intron 4, designated I-SRE-4, as an interspecies-conserved sequence. We found that I-SRE-4 acted as an enhancer element, and clustered CpGs around the I-SRE-4 were hypomethylated in IL-10-producing Treg cells, but not in other T cells. A gel-shift analysis using a nuclear extract from IL-2-stimulated HOZOT confirmed that CpG DNA methylation around I-SRE-4 reduced STAT5 binding to the element. Chromatin immunoprecipitation analysis revealed the in situ binding of IL-2-activated STAT5 to I-SRE-4. Thus, we provide molecular evidence for the involvement of an IL-2-STAT5 signaling axis in the expression of IL-10 by human Treg cells, an axis that is regulated by the intronic enhancer, I-SRE-4, and epigenetic modification of this element.

Identification of a vascular endothelial growth factor (VEGF) antagonist, sFlt-1, from a human hematopoietic cell line NALM-16

An antagonistic activity against vascular endothelial growth factor (VEGF) was identified in the culture supernatants of certain human hematopoietic cell lines and the antagonistic protein was purified from NALM‐16 (B cell) culture supernatant. Amino acid sequencing of the N‐terminus and Western blot analysis confirmed that the antagonist was identical to a soluble truncated form of Flt‐1 (sFlt‐1). Seventeen of 52 leukemia and lymphoma cell lines investigated expressed sFlt‐1 mRNA, and 16 of the sFlt‐1 expressing cells also expressed VEGF and membrane‐bound Flt‐1 (mFlt‐1). This report is the first showing that sFlt‐1 can be produced by malignant hematopoietic cells, suggesting that the production of VEGF antagonist by hematopoietic cells may play some role in the regulation of VEGF activity in normal and malignant hematopoietic cell proliferation.

Cell-in-cell Structures Formed between Human Cancer Cell Lines and the Cytotoxic Regulatory T-cell Line HOZOT

We previously established a novel cell line, termed HOZOT, derived from umbilical cord blood mononuclear cells that is characterized as a human cytotoxic regulatory T (Treg) cell line with a FOXP3(+)CD4(+)CD8(+)CD25(+) phenotype. Here, we describe a new property of HOZOT cells: they actively penetrate into a variety of human cancer cell lines, but not into normal cell lines, and form apparent cell-in-cell structures. In the process of cell penetration, we observed that HOZOT cells adhered to target cells seemed to first insert their nuclei into the cytoplasm of target cells, distinct from the process of phagocytosis. In addition, blocking experiments showed that major histocompatibility complex class I is one of the target cell recognition molecules for HOZOT cells. Furthermore, we propose that cell-in-cell structures between HOZOT cells and target cancer cells could be one of the cytotoxic mechanisms of HOZOT cells.

Interleukin-8 and RANTES are signature cytokines made by HOZOT, a new type of regulatory T cells

Distinct cytokine production profiles define the effector functions of both helper and regulatory T cells. Recently, we established novel cytotoxic regulatory T (Treg) cell lines, HOZOT, which have been characterized as IL-10-producing T cells. In this study, we further characterized HOZOT by performing comprehensive analyses of cytokines produced by HOZOTs in order to identify a signature cytokine profile. Using DNA microarrays, we compared the gene expression profiles of HOZOT-4, a representative HOZOT cell line, under three different conditions. Seven genes, including IL-8, IL-10, IL-13, MIP-1alpha, and MIP-1beta, were identified as inducible cytokines when stimulated with stromal cells or anti-CD3/CD28 antibodies. Twelve genes, including IL-2, IL-3, IL-4, IL-22, CCL1, and lymphotactin, were categorized as antibody stimulation-responsive but stromal cell-non-responsive. Three genes, IL-32, RANTES, and CCL23, were constitutively expressed irrespective of stimulation condition. Among these cytokines, we focused on two chemokines, IL-8 and RANTES for further studies, and found that only HOZOT produced both of them at considerable levels whereas other T cell subsets, including Tregs and helper T cells, did not. Kinetic and inhibition experiments revealed contrasting properties for the two chemokines. IL-8 was induced only after stimulation, whereas RANTES mRNA and protein accumulated to high levels even before stimulation. Interestingly, IL-8 mRNA was induced by cycloheximide treatment and RANTES showed reduced mRNA but increased protein expression by antibody stimulation. As a whole, the unique cytokine signature profile consisting of Th1, Th2, and cytolytic T cell cytokines as well as Treg cytokines reflect the multifunctional nature of HOZOT. In particular, the dual production of IL-8 and RANTES by distinct mechanisms is a hallmark of HOZOT.

Potent anti-tumor killing activity of the multifunctional Treg cell line HOZOT against human tumors with diverse origins.

The T cell line HOZOT has a unique FOXP3+CD4+ CD8+CD25+ phenotype, exhibits suppressive activity in allogeneic mixed lymphocyte reactions (MLR), and produces IL-10, defining HOZOT as regulatory T cells (Tregs). Interestingly, in addition to possessing a suppressive Treg ability, HOZOT was also found to show cytotoxicity against certain representative human cancer cell types. In order to disclose the range of anti-tumor activity by HOZOT, we screened it by using a panel of twenty human tumor cell lines with different origins. Consequently, HOZOT showed potent cytocidal effects against a wide spectrum of neoplastic cells including carcinomas, sarcomas, mesotheliomas and glioblastomas except for hematopoietic malignancies. Its anti-tumor activity was strong enough with an E:T ratio of 4:1, which is considered to be more effective than that by conventional CTLs. Furthermore, an in vivo representative mouse tumor model by implanting human colon adenocarcinoma cells revealed that adoptive transfer of HOZOT almost completely eradicated disseminated lesions on peritoneum, markedly reduced metastases in lung and liver, and dramatically decreased bloody ascites caused by peritoneal carcinomatosis. Treatment of the tumor model mice by HOZOT with an E:T ratio of 2:1 even indicated the prolongation of their survival, although not reaching obvious statistical significance. In vitro blocking experiments using antibodies and inhibitors suggested that the cytotoxic mechanism of HOZOT against tumors is different from conventional cytotoxic cells such as CTL, NK or NKT cells. Altogether, our studies demonstrated the potent killing activity of HOZOT against a broad range of human malignancies, which indicates that HOZOT is a powerful tool in immunotherapy for advanced stage tumors.