Transfer Of Spleen Cells Research Articles

Which ICU patients need stress ulcer prophylaxis?

Critically ill patients are at an increased risk for developing stress ulcers of the mucosa of the upper gastrointestinal (GI) tract. Bleeding from stress ulcers was previously associated with a longer stay in the intensive care unit and an increased risk of death. Thus, most patients admitted to the intensive care unit receive stress ulcer prophylaxis. However, there is a growing concern that acid-suppression drugs may be associated with increased frequency of nosocomial pneumonia and Clostridioides difficile infection. In this article, the authors address controversies regarding stress ulcer prophylaxis in critically ill patients and provide guidance for its appropriate use in this setting.

CD38 Deficiency Ameliorates Chronic Graft-Versus-Host Disease Murine Lupus via a B-Cell-Dependent Mechanism.

The absence of the mouse cell surface receptor CD38 in Cd38−/− mice suggests that this receptor acts as a positive regulator of inflammatory and autoimmune responses. Here, we report that, in the context of the chronic graft-versus-host disease (cGVHD) lupus inducible model, the transfer of B6.C-H2bm12/KhEg(bm12) spleen cells into co-isogenic Cd38−/− B6 mice causes milder lupus-like autoimmunity with lower levels of anti-ssDNA autoantibodies than the transfer of bm12 spleen cells into WT B6 mice. In addition, significantly lower percentages of Tfh cells, as well as GC B cells, plasma cells, and T-bet+CD11chi B cells, were observed in Cd38−/− mice than in WT mice, while the expansion of Treg cells and Tfr cells was normal, suggesting that the ability of Cd38−/− B cells to respond to allogeneic help from bm12 CD4+ T cells is greatly diminished. The frequencies of T-bet+CD11chi B cells, which are considered the precursors of the autoantibody-secreting cells, correlate with anti-ssDNA autoantibody serum levels, IL-27, and sCD40L. Proteomics profiling of the spleens from WT cGVHD mice reflects a STAT1-driven type I IFN signature, which is absent in Cd38−/− cGVHD mice. Kidney, spleen, and liver inflammation was mild and resolved faster in Cd38−/− cGVHD mice than in WT cGVHD mice. We conclude that CD38 in B cells functions as a modulator receptor that controls autoimmune responses.

Monotherapy With Anti-CD70 Antibody Causes Long-Term Mouse Cardiac Allograft Acceptance With Induction of Tolerogenic Dendritic Cells.

Allograft rejection has been an obstacle for the long-term survival of patients. CD70, a tumor necrosis factor (TNF) family member critically expressed on antigen-presenting cells and strongly but transiently up-regulated during lymphocyte activation, represents an important co-stimulatory molecule that induces effective T cell responses. We used a mouse heterotopic cardiac transplantation model to evaluate the effects of monotherapy with the antibody targeting mouse CD70 (FR70) on transplantation tolerance and its immunoregulatory activity. FR70-treated C3H recipient mice permanently accepted B6 fully mismatched cardiac allografts. Consistent with the graft survival, the infiltration of CD8+ T cells in the graft was reduced, dendritic cells were differentiated into a tolerogenic status, and the number of regulatory T cells was elevated both in the graft and the recipient’s spleen. In addition, naïve C3H given an adoptive transfer of spleen cells from the primary recipients with FR70 treatment accepted a heart graft from a matching B6 donor but not third-party BALB/c mice. Our findings show that treatment with FR70 induced regulatory cells and inhibited cytotoxic T cell proliferation, which led to long-term acceptance of mouse cardiac allografts. These findings highlight the potential role of anti-CD70 antibodies as a clinically effective treatment for allograft rejection.

5-Aminolevulinic acid combined with sodium ferrous citrate (5-ALA/SFC) ameliorated liver injury in a murine acute graft-versus-host disease model by reducing inflammation responses through PGC1-α activation.

Acute graft-versus-host disease (aGvHD) remains lethal as a life-threatening complication after allogeneic hematopoietic stem cell transplantation (HSCT). Inflammatory responses play an important role in aGvHD. 5-Aminolevulinic acid combined with sodium ferrous citrate (5-ALA/SFC) has been widely reported to have a major effect on the anti-inflammatory response; however, these effects in aGvHD models have never been reported. In this study, a murine aGvHD model was developed by transferring spleen cells from donor B6/N (H-2kb) mice into recipient B6D2F1 (H-2kb/d) mice. In addition to evaluating manifestations in aGvHD mice, we analyzed the serum ALT/AST levels, liver pathological changes, infiltrating cells and mRNA expression of inflammation-related cytokines and chemokines. 5-ALA/SFC treatment significantly ameliorated liver injury due to aGvHD and decreased the population of liver-infiltrating T cells, resulting in a reduced expression of pro-inflammatory cytokines and chemokines. Furthermore, the mRNA expression proliferator-activated receptor-γcoactivator (PGC-1α) was enhanced, which might explain why 5-ALA/SFC treatment downregulates inflammatory signaling pathways. Our results indicated that 5-ALA/SFC can ameliorate liver injury induced by aGvHD through the activation of PGC-1α and modulation of the liver mRNA expression of inflammatory-related cytokines and chemokines. This may be a novel strategy for treating this disease.

Abstract P5-04-15: An immunogenic mouse model using BALB.B-MMTV-neuT breast cancers reveals spontaneous protective humoral immunity

Abstract The BALB/c-neuT mouse has been a faithful model for investigating metastatic breast cancer. Spontaneous breast tumors from BALB/c-neuT mice are readily transplantable orthotopically into syngeneic or rat neuT negative BALB/c WT hosts facilitating controlled studies of developing breast cancers. When introduced into the breast ducts of BALB/c WT hosts, lung metastases form similarly to how they appear in mice with spontaneous tumors. Tumor grafts grow out with comparable kinetics and induce similar systemic immune abnormalities in the spleens and lymph nodes of both lines of mice as seen in mice with spontaneous tumors. Factors inducing these abnormal immune cell configurations are not yet known. Immunization of BALB/c WT mice against the rat Her2 antigen can induce both T cell and antibody mediated rejection of the transplanted tumors, but these approaches have not been equally successful in syngeneic, rat neuT+ positive hosts, indicating tolerance to rat Her2 is a significant barrier to the induction of immunity against these breast tumors. The MHC encodes class I and class II antigen presenting molecules which are known to be highly polymorphic in both structure and function. We introduced the H-2b MHC haplotype into the MMTV-NeuT model to assess the influence of a different set of antigen presenting molecules on tumor biology. In BALB.B-neuT mice spontaneous tumors appeared with frequencies and in numbers similar to those seen in the BALB/c model. In anything, lung metastases are more frequent and more aggressive in BALB.B-neuT mice. Again, the tumors were readily transplantable into the breast fat pads of syngeneic BALB.B-neuT hosts which developed systemic immune abnormalities very similar to those observed in BALB/c -neuT or BALB/c WT mice. However, BALB.B WT hosts initially accepted the grafts, but subsequently rejected them after they were established. Mice that were in the process of rejecting the tumors retained normal cellularity within their spleens and lymph nodes indicating the importance of an ongoing immune response and/or tumor rejection in shaping the microenvironment in secondary lymphoid organs. Adoptive transfer of spleen cells from BALB.B WT mice which had rejected established tumor conferred resistance to the tumor grafts as long as B cells were included (P<0.01), indicating active humoral immunity was important to tumor rejection. A mechanistic understanding or how antibody-mediated immunotherapy works in patients is incomplete. This new model provides an opportunity to address this question. The Her2 ecto-domain is known to be shed from tumor cells. We propose a model in which the ecto-domain of rat neuT is shed, but is insufficiently immunogenic in BALB/c (H-2d) hosts, but highly immunogenic in BALB.B (H-2b) mice. Consistent with this model is the prediction using the Immune Epitope and Data Base Resource of the presence of a potentially immunogenic IAb-restricted class II epitope within the ecto-domain of rat Her2 neuT oncogene, but no such epitope restricted by IAd or IEd was identified. This provides a compelling hypothesis explaining why grafted spontaneous tumors grow in BALB/c, but not in BALB.B WT mice. An important prediction from this model is that linkage of a potent class II epitope to the Erbb2-encoded ecto-domain may provide a basis for a potent vaccine against Her2 positive breast tumors which should be a strategy adaptable to any MHC genotype. It also will be of interest to determine whether the presence of an antibody reactive against established tumor restores the normal cellular composition of secondary lymphoid organs which have been perturbed by established breast tumors. Citation Format: Sarah Anne Castro, Alvaro Pena, Khashayarsha Khazaie, Larry R. Pease. An immunogenic mouse model using BALB.B-MMTV-neuT breast cancers reveals spontaneous protective humoral immunity [abstract]. In: Proceedings of the 2019 San Antonio Breast Cancer Symposium; 2019 Dec 10-14; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2020;80(4 Suppl):Abstract nr P5-04-15.

Immune Reaction to Type XVII Collagen Induces Intramolecular and Intermolecular Epitope Spreading in Experimental Bullous Pemphigoid Models.

Bullous pemphigoid (BP), the most common autoimmune blistering disease, is induced by autoantibodies to type XVII collagen (COL17). Previous studies demonstrated that COL17 harbors several epitopes targeted by autoreactive T and B cells and that the target epitopes change sequentially during the disease course. To elucidate the details of the humoral immune response to COL17, we used an active BP mouse model in which BP is induced by the adoptive transfer of spleen cells from wild-type mice immunized with human COL17-expressing skin grafting to immunodeficient COL17-humanized (Rag-2−/−, mouse Col17−/−, human COL17+) mice. By immunoblot analysis, antibodies to the NC16A domain and other extracellular domains (ECDs) of COL17 were detected earlier than antibodies to intracellular domains (ICDs) in the active BP model. Time course analysis by enzyme-linked immunosorbent assay demonstrated a delayed peak of antibodies to ICD epitopes in active BP model. The blockade of CD40–CD40 ligand interaction soon after the adoptive transfer suppressed the production of antibodies to the non-collagenous 16A (NC16A) domain but not to an ICD epitope, suggesting the sequential activation from T and B cells against the ECD epitopes including the NC16A domain to those against ICD epitopes in vivo. Both wild-type mice immunized with a fragment of the NC16A domain and the recipients of those spleen cells produced IgG antibodies to ICD and ECD epitopes, showing intramolecular epitope spreading from the NC16A domain to other epitopes of COL17. Furthermore, we found that a portion of the active BP model mice show intermolecular epitope spreading from human COL17 to murine BP230. The appearance of antibodies to ICD epitopes of COL17 or of antibodies to murine BP230 did not correlate with the skin changes in the mice, suggesting that those antibodies have low pathogenicity. These results suggest that the immune response to the ECD epitopes of COL17, especially to the NC16A domain, triggers intramolecular, and intermolecular epitope spreading to ICD epitopes of COL17 and to murine BP230. These novel findings provide insight into the mechanism of epitope spreading in organ-specific, antibody-mediated autoimmune disorders.

Effect of Immune Responses Against Hydatid Cyst Antigens on Growth of Melanoma Tumor

Background: Hydatid cyst is the larval stage of the tape worm parasite, Echinococcus granulosus. Human is infected by ingestion of parasite ova excreted in dog feces. The anticancer activity of different antigens of hydatid cyst has been reported in the previous works. In this research, the role of immune system in induction of this anticancer activity has been investigated.Materials and Methods: Spleen cells of mice immunized with hydatid cyst antigens were transferred to the recipient mice that had already been challenged with melanoma cells. Also, mice with melanoma cancer were injected with antisera raised against hydatid cyst antigens. In all above mice, tumor growth was measured using a caliper. Results: Passive transfer of spleen cells resulted in significant inhibition of melanoma cancer growth. However passive transfer of antisera did not affect cancer growth in the recipient mice.Conclusion: According to the results of this work, cellular immunity but not humoral immunity may be involved in induction of anticancer activities of hydatid cyst.

Vitamin A deficiency provokes aberrant T cell responses and exacerbates liver injury in LCMV-infected mice

Abstract Vitamin A deficiency (VAD) is a public health problem worldwide; however, its role and underlying mechanisms in viral infection are not entirely understood. In this study, we detected elevated LCMV-specific T cell responses in VAD mice at the acute stage (7 dpi). These VAD mice exhibited higher serum ALT levels and increased liver permeability. Consistently, enhanced antiviral T cell responses were observed in VAD mice in persistent infection (30 dpi), as evidenced by decreased PD-1 expression and increased cytokine production. To investigate whether VAD causes an intrinsic abnormality of T cells during animal development and growth, we transferred spleen cells from control and VAD mice into CD45.1 recipient mice, followed by LCMV infection, and found that antiviral T cell responses were comparable between control and VAD donor cells. However, when CD45.1 cells were transferred into control and VAD recipient mice, they showed a highly activated phenotype in VAD mice. These results suggest that vitamin A or its metabolites restrict T cell activation through an extrinsic way. Retinoic acid (RA) is considered one of the important metabolites of vitamin A. We found that RA administration inhibited excessive T cell responses in VAD mice. To dissect the mechanism of RA, we treated splenocytes and purified CD8+ T cells with RA, followed by PMA stimulation. RA treatment reduced the phosphorylation of AKT, p38, ERK, and S6, as well as the abundance of transcriptional factor NFATc1. Together, our study demonstrated that VAD caused an aberrant T cell response to viral infection, and RA may have the potential to serve as a therapeutic agent for excessive immune responses and tissue injury in VAD patients.

Donor bone marrow cells are essential for iNKT cell‐mediated Foxp3+ Treg cell expansion in a murine model of transplantation tolerance

Mixed chimerism induction is the most reliable method for establishing transplantation tolerance. We previously described a novel treatment using a suboptimal dose of anti-CD40 ligand (anti-CD40L) and liposomal formulation of a ligand for invariant natural killer Tcells administered to sub-lethally irradiated recipient mice after donor bone marrow cell (BMC) transfer. Recipient mice treated with this regimen showed expansion of a Foxp3-positive regulatory T(Treg) cell phenotype, and formation of mixed chimera. However, the mechanism of expansion and bioactivity of Treg cells remains unclear. Here, we examine the role of donor BMCs in the expansion of bioactive Treg cells. The mouse model was transplanted with a heart allograft the day after treatment. The results showed that transfer of spleen cells in place of BMCs failed to deplete host interferon (IFN)-γ-producing CD8+ Tcells, expand host Ki67+ CD4+ CD25+ Foxp3+ Treg cells, and prolong graft survival. Severe combined immunodeficiency mice who received Treg cells obtained from BMC-recipients accepted skin grafts in an allo-specific manner. Myeloid-derived suppressor cells, which were a copious cell subset in BMCs, enhanced the Ki67 expression of Treg cells. This suggests that donor BMCs are indispensable for the expansion of host bioactive Treg cells in our novel treatment for transplant tolerance induction.

Local Microenvironment Controls the Compartmentalization of NK Cell Responses during Systemic Inflammation in Mice

Systemic inflammatory response syndrome is a whole-body reaction to a triggering insult that often results in life-threatening illness. Contributing to the development of this inflammatory cascade are numerous cellular partners, among which NK cells were shown to play a key role. Accumulating evidence points to organ-specific properties of systemic inflammation and NK cells. However, little is known about compartment-specific activation of NK cells during systemic inflammatory response syndrome or the relative contribution of NK cell-intrinsic properties and microenvironmental cues. In this study, we undertook a sequential characterization of NK responses in the spleen, lungs, bone marrow, peritoneum, and blood using a mouse model of endotoxemia. We report that, despite similar systemic dynamics of NK cell responses, expression of activation markers (CD69 and CD25) and effector molecules (IFN-γ, granzyme B, and IL-10) display organ-specific thresholds of maximum activation. Using adoptive transfers of spleen and lung NK cells, we found that these cells have the capacity to quickly adapt to a new environment and adjust their response levels to that of resident NK cells. This functional adaptation occurs without significant alterations in phenotype and independently of subpopulation-specific trafficking. Thus, using a dynamic in vivo-transfer system, to our knowledge our study is the first to report the compartmentalization of NK cells responses during systemic inflammation and to show that NK cell-intrinsic properties and microenvironmental cues are involved in this process, in a sequential manner.

The spleen dictates platelet destruction, anti-platelet antibody production, and lymphocyte distribution patterns in a murine model of immune thrombocytopenia.

For many years, splenectomy has been used to treat immune thrombocytopenia (ITP), and this procedure benefits approximately two-thirds of the treated patients. Although splenectomy may raise platelet counts, antibody-coated platelets and cytotoxic T lymphocytes appear to persist or can change over time. To better understand how the spleen may affect anti-platelet immune responses, we used a murine model of ITP demonstrating both antibody-mediated and T lymphocyte-mediated thrombocytopenia. Mice with severe combined immunodeficiency (SCID) were either splenectomized or not and transfused with splenocytes from CD61 (GPIIIa) knockout mice immunized against CD61(+) platelets. Platelet counts and anti-platelet antibody levels were performed weekly. After 4weeks, the mice were sacrificed, and lymphoid organs were harvested and examined by flow cytometry to quantify CD4(+)CD25(+)FoxP3(+) Tregs and conventional cross-presenting XCR1(+) and tolerizing SIRPα+ dendritic cells. The results indicate that compared with control non-splenectomized mice, thrombocytopenia was improved and anti-platelet antibody production was significantly diminished in all splenectomized mice that received immune splenocytes. Splenectomized SCID mice also had a marked reduction in Tregs in the thymus together with an increased proportion of both thymic dendritic cell subsets that correlated with increased platelet counts. Of interest, although splenectomy diminished anti-platelet antibody production and raised platelet counts, marrow megakaryocyte densities were still significantly reduced in mice that received immune splenocytes. These results suggest that the spleen in murine ITP not only is the primary site responsible for platelet destruction, but it also controls, to a significant extent, the antibody response against platelets and the migration patterns of lymphocyte subsets.

B cells establish, but do not maintain, long-lived murine anti-peanut IgE(a).

Peanut allergy (PNA) has been reported to be transferred to tolerant recipients through organ and bone marrow (BM) transplantation. The roles T and B cells play in establishing, and the roles B cell subsets play in maintaining lifelong anti-peanut IgE levels are unknown. To determine the cellular requirements for the transfer of murine PNA and to determine the role CD20(+) cells play in maintaining long-lived anti-peanut IgE levels. We developed a novel adoptive transfer model to investigate the cellular requirements for transferring murine PNA. We also treated peanut-allergic (PA) mice with anti-CD20 antibody and measured IgE levels throughout treatment. Purified B220(+) cells from PA splenocytes and purified CD4(+) cells from naïve (NA) splenocytes are the minimal requirements for the adoptive transfer of PNA. Prolonged treatment of allergic mice with anti-CD20 antibody results in significant depletion of B cell subsets but does not affect anti-peanut IgE levels, symptoms, or numbers of IgE antibody secreting cells (ASCs) in the BM. Adoptive transfer of BM and spleen cells from allergic donors treated with anti-CD20 antibody does not result in the transfer of PNA in NA recipients, demonstrating that anti-CD20 antibody treatment depletes B cells capable of differentiating into peanut-specific IgE ASCs. Peanut allergy can be established in a NA hosts with B220(+) cells from PA donors and CD4(+) cells from peanut-NA donors. However, long-term depletion of B220(+) cells with anti-CD20 antibody does not affect anti-peanut IgE levels. These results highlight a novel role for B cells in the development of PNA and provide evidence that long-lived anti-peanut IgE levels may be maintained by long-lived ASCs.

Effect of Passive Transfer of Spleen Cells from Immunized Mice with Hydatid Cyst Antigens on the Growth of Melanoma Cancer in C57/Black Mice

Effect of Passive Transfer of Spleen Cells from Immunized Mice with Hydatid Cyst Antigens on the Growth of Melanoma Cancer in C57/Black Mice

Administration of sulfosuccinimidyl-4-[N-maleimidomethyl] cyclohexane-1-carboxylate conjugated GP10025–33 peptide-coupled spleen cells effectively mounts antigen-specific immune response against mouse melanoma

It remains a top research priority to develop immunotherapeutic approaches to induce potent antigen-specific immune responses against tumors. However, in spite of some promising results, most strategies are ineffective because they generate low numbers of tumor-reactive cytotoxic T lymphocytes (CTLs). Here we designed a strategy to enhance antigen-specific immune response via administering sulfosuccinimidyl-4-[N-maleimidomethyl] cyclohexane-1-carboxylate (sulfo-SMCC)-conjugated melanoma tumor antigen GP10025–33 peptide-coupled syngeneic spleen cells in a mouse model of melanoma. We found that infusion of GP10025–33 peptide-coupled spleen cells significantly attenuated the growth of melanoma in prophylactic and therapeutic immunizations. Consistent with these findings, the adoptive transfer of spleen cells from immunized mice to naïve syngeneic mice was able to transfer anti-tumor effect, suggesting that GP10025–33 peptide-specific immune response was induced. Further studies showed that, CD8+ T cell proliferation and the frequency of interferon (IFN)-γ-producing CD8+ T cells upon ex vivo stimulation by GP10025–33 were significantly increased compared to control groups. Tumor antigen, GP10025–23 specific immune response was also confirmed by ELISpot and GP100-tetramer assays. This approach is simple, easy-handled, and efficiently delivering antigens to lymphoid tissues. Our study offers an opportunity for clinically translating this approach into tumor immunotherapy.

Splenic monocytes traffic to the thyroid and produce a novel TSHβ splice variant during acute Listeria infection in mice (INC4P.334)

Abstract It has been known for over three decades that thyroid stimulating hormone (TSH) is produced by cells of the immune system; however, the functional role of that TSH has remained obscure. We recently identified a novel splice variant of the thyroid stimulating hormone β-subunit (TSHβv) that is primarily produced by cells of the immune system, in particular by myeloid cells in the bone marrow (BM) and spleen. During acute infection with virulent L. monocytogenes, TSHβv synthesis increased in CD14+, F4/80+ BM cells and spleen cells. In vitro culture of the mouse AM macrophage cell line with LPS or zymosan, or following stimulation with anti-CD14 or anti-TLR2 antibodies, resulted in increased synthesis of TSHβv. Three days post-infection with Listeria, there was an infiltration of CD14+, F4/80+ cells into the thyroid that was followed by an increase in intrathyroidal TSHβv gene expression on days 4 and 5 compared to non-infected mice. Following in vivo transfer of CFSE-labeled spleen cells from infected mice into normal non-infected mice, CFSE+ cells were present throughout the thyroid, demonstrating an active process of trafficking of TSHβv-producing spleen cell into the thyroid during an acute infection. These findings point to a novel mechanism of host metabolic regulation by the immune system during systemic bacterial infection, and they define a functional role for TSHβv in that process.

Zfra activates memory Hyal-2+ CD3- CD19- spleen cells to block cancer growth, stemness, and metastasis in vivo.

Zfra is a 31-amino-acid zinc finger-like protein, which participates in the tumor necrosis factor signaling. Here, we determined that when nude mice and BALB/c mice were pre-injected with nanogram levels of a synthetic Zfra1-31 or truncated Zfra4-10 peptide via tail veins, these mice became resistant to the growth, metastasis and stemness of melanoma cells, and many malignant cancer cells. The synthetic peptides underwent self-polymerization in phosphate-buffered saline. Alteration of the Ser8 phosphorylation site to Gly8 abolished Zfra aggregation and its-mediated cancer suppression in vivo. Injected Zfra peptide autofluoresced due to polymerization and was trapped mainly in the spleen. Transfer of Zfra-stimulated spleen cells to naïve mice conferred resistance to cancer growth. Zfra-binding cells, designated Hyal-2+ CD3- CD19- Z cells, are approximately 25-30% in the normal spleen, but are significantly downregulated (near 0-3%) in tumor-growing mice. Zfra prevented the loss of Z cells caused by tumors. In vitro stimulation or education of naïve spleen cells with Zfra allowed generation of activated Z cells to confer a memory anticancer response in naïve or cancer-growing mice. In particular, Z cells are abundant in nude and NOD-SCID mice, and can be readily activated by Zfra to mount against cancer growth.

132 A novel anti-PDL1 antibody-based bifunctional protein with enhanced immunological activity

Zfra is a 31-amino-acid zinc finger-like protein, which participates in tumor necrosis factor signaling. Here, we determined that synthetic full-length Zfra1−31 peptide selfpolymerized in degassed buffers without catalytic enzymes. When nude mice and BALB/c mice were pre-injected with micromolar levels of Zfra1−31 or truncated Zfra4−10 via tail veins, these mice became resistant to the growth, metastasis and stemness of prostate, breast, and lung cancer cells, melanoma cells, and many malignant cancer cells. Alteration of the Ser8 phosphorylation site to Gly8 abolished Zfra polymerization and cancer suppression in vivo. Injected Zfra was deposited mainly in the spleen. Transfer of Zfra-stimulated spleen cells to naive mice conferred resistance to cancer growth. Mechanistically, Zfra bound membrane hyaluronidase Hyal-2 and suppressed the TGF-b/Hyal-2/WWOX/Smad4 signaling, via down-regulation of Hyal-2 and activated WWOX (with Y33 phosphorylation), in the spleen for generating novel non-T/non-B memory cells, designated Hyal2+ CD3−CD19− cells. Transfer of these cells to naive mice also induced anticancer response. Similarly, agonist anti-Hyal-2 antibody mimicked the effect of Zfra in causing cancer suppression. In conclusion, Zfra self-polymerizes in the spleen to activate Hyal2+ CD3− CD19− cells for blocking cancer growth, stemness and metastasis in vivo. Supported in part by NSC and NHRI, Taiwan, and DoD, USA

Aromatase Controls Sjögren Syndrome–Like Lesions through Monocyte Chemotactic Protein-1 in Target Organ and Adipose Tissue–Associated Macrophages

Several autoimmune diseases are known to develop in postmenopausal women. However, the mechanism by which estrogen deficiency influences autoimmunity is unknown. Aromatase is an enzyme that converts androgens to estrogens. Herein, we used female aromatase gene knockout (ArKO) mice as a model of estrogen deficiency to investigate the molecular mechanism that underlies the onset and development of autoimmunity. Histological analyses showed that inflammatory lesions in the lacrimal and salivary glands of ArKO mice increased with age. Adoptive transfer of spleen cells or bone marrow cells from ArKO mice into recombination activating gene 2 knockout mice failed to induce the autoimmune lesions. Expression of mRNA encoding proinflammatory cytokines and monocyte chemotactic protein-1 increased in white adipose tissue of ArKO mice and was significantly higher than that in wild-type mice. Moreover, an increased number of inflammatory M1 macrophages was observed in white adipose tissue of ArKO mice. A significantly increased monocyte chemotactic protein-1 mRNA expression of the salivary gland tissue in ArKO was found together with adiposity. Furthermore, the autoimmune lesions in a murine model of Sjögren syndrome were exacerbated by administration of an aromatase inhibitor. These results suggest that aromatase may play a key role in the pathogenesis of Sjögren syndrome-like lesions by controlling the target organ and adipose tissue-associated macrophage.

The discovery of T cell-B cell cooperation.

The discovery of T cell-B cell cooperation.

Effects of Preexisting Autoimmunity on Heart Graft Prolongation After Donor-Specific Transfusion and Anti-CD154

Alloreactive memory T cells prevent costimulatory blockade-induced heart graft survival in mice, but whether and how preexisting autoreactive T cells affect solid-organ transplants under these conditions is unknown. We tested the impact of preexisting cardiac myosin (CM)-specific immunity on murine heart transplant recipients treated with donor-specific transfusion (DST) plus anti-CD154 monoclonal antibody MR1. Preimmunization with CM but not control ovalbumin abrogated the graft prolonging effects of DST/MR1, whether administered 2 weeks or more than 6 weeks before transplantation. Adoptive transfer of spleen cells from CM-immunized mice into naïve recipients had similar effects. CM-specific immunity did not cross-react with donor antigens and preimmunization with CM had no impact on the survival or histology of DST/MR1-treated syngeneic heart grafts, the latter indicating that persistent autoimmunity is insufficient to cause rejection in the context of costimulatory blockade. We observed that the CM preimmunized mice produced higher frequencies of donor-reactive T cells with higher ratios of CD8/CD4Foxp3 cells, suggesting that the autoreactive memory T cells provide help for activation of alloreactive T cells despite the costimulatory blockade. These mechanistic insights linking autoimmunity and alloimmunity in a model of murine heart transplantation have clinical relevance to the known association between autoimmunity and an elevated risk of acute and chronic heart transplant injury in humans.