Contrary to short-lived plasma cells, which survive only 3-5 days, long-lived plasma cells (LLPCs) contribute to the humoral memory of the body and thus also to many antibody-related diseases. The ability of plasma cells to persist over months, years, and even a lifetime has been demonstrated in vivo. Yet, the in vitro culture of human primary bone marrow-derived plasma cells has been limited to a few days. Here, we establish culture conditions for human primary bone marrow-derived plasma cells for 21 days. Plasma cells and stromal cells are isolated from human bone marrow and cultured in 2D or a 3D ceramic scaffold. The plasma cells' survival and antibody secretion depend on direct contact with stromal cells. The culture promotes CD19-negative PCs. Inhibition of the PI3K or NF-kappaB pathways using chemical inhibitors reduced the survival of the plasma cells. These results underline the supportive role of the stromal cells for the survival of the LLPC and confirm mechanisms that were identified in mouse LLPCs also for human LLPCs. The culture described here will promote further studies to deepen our understanding of the human LLPC.

Thymic stromal lymphopoietin (TSLP) is an alarmin cytokine activated by allergens, pathogens, and air pollutants. Recent studies suggest TSLP dysregulation in chronic inflammatory diseases. It was highlighted as a key player in the context of asthma-associated mucosal immunity. This study investigated the production and localization of TSLP and its receptors in airway epithelial cells and the related inflammatory response in chronic obstructive pulmonary disease (COPD) and non-COPD patients. TSLP transcripts and proteins were detected in epithelial cells but were not abundant at a steady state. The secretion of airway inflammatory mediators was altered in COPD in association with TSLP production. The cellular and molecular characterization of TSLP signaling may identify COPD patients that could benefit from anti-alarmin therapeutic approaches.

The reasons for the low frequency of anti-Ro/SS-A antibody in patients with HTLV-1-associated myelopathy complicated with Sjögren's syndrome (SS) are unclear. In this study, we investigated whether HTLV-1-infected T cells can act directly on B cells and suppress B cells' production of antibodies, including anti-Ro/SS-A antibody. For this purpose, we established an in vitro T-cell-free B-cell antibody production system. The productions of total IgG and anti-cytomegalovirus IgG in B cells from healthy subjects and those of total IgG and anti-Ro/SS-A IgG in B cells from SS patients were significantly suppressed by the addition of HTLV-1-positive T-cell lines (MT-2 and HCT-5). Our analysis of co-cultured B cells identified no sign of HTLV-1 infection and revealed that MT-2 and HCT-5 cells act on the early stages of B-cell differentiation, not the activation stage. MT-2 and HCT-5 cells constitutively expressed CD70, ICAM-1, LAP (TGF-β), and PD-L1/2, but blocking monoclonal antibodies to these molecules or PD-L1/2 receptor PD-1 had no significant canceling effect on B-cell IgG production regarding their suppressive activity. Importantly, autologous CD4CD25CD127 Treg cells had no inhibitory effect on B-cell IgG production. These results demonstrate that HTLV-1-positive T cells can directly suppress B-cell antibody production through mechanisms that differ from Treg functions.

Many human autoimmune diseases (AIDs) are hallmarked by the presence and persistence of autoreactive B-cells. While autoreactive B-cells may frequently encounter antigens, the signals required to balance and maintain their activation and survival are mostly unknown. Understanding such signals may be important for strategies aimed at eliminating human B-cell autoreactivity. Here, we assessed intracellular signaling pathways in B cells targeting citrullinated protein antigens isolated from patients with rheumatoid arthritis (RA), a common and well-characterized AID. Peripheral blood mononuclear cells of 15 RA patients positive for anti-citrullinated protein antibodies (ACPA) were analyzed directly ex vivo using spectral flow cytometry and B-cell differentiation markers, citrullinated antigen-biotin-streptavidin tetramers, and intracellular (phosphoflow) markers. Tetanus toxoid (TT)-specific B cells served as antigen-specific comparators. In absence of any in vitro BCR stimulation, ACPA-expressing memory B cells (MBCs) displayed enhanced expression of Ki-67 and increased SYK-, BTK-, AKT-, and S6-phosphorylation compared with TT-specific MBCs. We demonstrate the simultaneous detection of B cell antigen-specificity and intracellular protein phosphorylation on the single-cell level. The data reveal that autoreactive B-cells in RA, in contrast to B cells against recall antigens, display enhanced phosphorylation of signaling molecules that point toward continuous, presumably antigen-mediated activation of the autoreactive B-cell compartment.

The CD8 co-receptor exists as both an αα homodimer, expressed on subsets of specialized lymphoid cells, and as an αβ heterodimer, which is the canonical co-receptor on cytotoxic T-cells, tuning TCR thymic selection and antigen-reactivity in the periphery. However, the biophysical parameters governing human CD8αβ interactions with classical MHC class I (MHCI) and unconventional MHC-like molecules have not been determined. Using hetero-dimerized Fc-fusions to generate soluble human CD8αβ, we demonstrate similar weak binding affinity to multiple different MHCI alleles compared with CD8αα. We observed that both forms of CD8 bound to certain alleles with stronger affinity than others and found that the affinity of thymically selected TCRs was inversely associated with the affinity of the CD8 co-receptor for the different alleles. We further demonstrated the binding of CD8αα and CD8αβ to the unconventional MHC-like molecule, MHCI-related protein 1, with a similar affinity as for classical MHCI, but no interaction was observed for the other unconventional MHC-like molecules, CD1a, b, c, or d. In summary, this is the first characterization of human CD8αβ binding to MHCI and MHC-like molecules that revealed an intriguing relationship between CD8 binding affinity for different MHCI alleles and the selection of TCRs in the thymus.

P2X7 is an extracellular adenosine 5'-triphosphate (ATP)-gated cation channel that plays various roles in inflammation and immunity. P2X7 is present on peripheral blood monocytes, dendritic cells (DCs), and innate and adaptive lymphocytes. The anti-human P2X7 monoclonal antibody (mAb; clone L4), used for immunolabelling P2X7 or blocking P2X7 activity, is a murine IgG2 antibody, but its ability to mediate complement-dependent cytotoxicity (CDC) is unknown. In this study the functionality of this mAb was confirmed by inhibition of ATP-induced Ca responses in HEK-293 cells expressing P2X7 (HEK-P2X7). Spectrophotometric measurements of lactate dehydrogenase release demonstrated that the anti-P2X7 mAb mediated CDC in HEK-P2X7 but not HEK-293 cells. Further, flow cytometric measurements of the viability dye, 7-aminoactinomycin D, showed that this mAb mediated CDC in human RPMI 8226 but not mouse J774 cells. Immunolabelling with this mAb and flow cytometry revealed that relative amounts of cell surface P2X7 varied between human peripheral blood leukocytes. As such, the anti-P2X7 mAb preferentially mediated CDC of leukocytes that displayed relatively high cell surface P2X7, namely monocytes, DCs, natural killer T cells, myeloid-derived suppressor cells, and T helper 17 cells. Together, this data highlights a novel approach to target cellular P2X7 and to limit unwanted P2X7 functions.

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection in the placenta can lead to fetal distress and demise, characterized by severe trophoblast necrosis, chronic histiocytic intervillositis (CHI), and massive perivillous fibrin deposition. We aimed to uncover spatial immune-related protein changes in SARS-CoV-2 placentitis compared with CHI placentas and uncomplicated pregnancies to gain insight into the underlying pathophysiological mechanisms. Placentas were retrospectively collected from cases with SARS-CoV-2 placentitis resulting in fetal distress/demise (n = 9), CHI (n = 9), and uncomplicated term controls (n = 9). The expression of 53 immune-related proteins was quantified using GeoMx Digital Spatial Profiler in three separate compartments: villi (fetal compartment), intervillous space, and decidua (both maternal compartments). Compared with controls, SARS-CoV-2 placentitis and CHI both displayed differentially expressed proteins in the intervillous space only, including upregulation of myeloid markers (e.g., CD40, CD11c, CD68, CD163). Specifically, SARS-CoV-2 placentitis was associated with reduced expression of multiple apoptotic proteins (e.g., BAD, BIM, BLXL, BCL6). In conclusion, SARS-CoV-2 placentitis and CHI are associated with enhanced myeloid cell infiltration into the intervillous space, but not in the decidua and villi. The more prominently reduced apoptosis-related protein expression in SARS-CoV-2 placentitis may lead to an exaggerated immune response, causing acute placental dysfunction and fetal demise.

This article is part of the Dendritic Cell Guidelines article series, which provides a collection of state-of-the-art protocols for the preparation, phenotype analysis by flow cytometry, generation, fluorescence microscopy, and functional characterization of mouse and human dendritic cells (DC) from lymphoid organs, and various nonlymphoid tissues. Within this article, detailed protocols are presented that allow for the generation of single-cell suspensions from human nonlymphoid tissues including lung, skin, gingiva, intestine as well as from tumors and tumor-draining lymph nodes with a subsequent analysis of dendritic cells by flow cytometry. Further, prepared single-cell suspensions can be subjected to other applications including cellular enrichment procedures, RNA sequencing, functional assays, etc. While all protocols were written by experienced scientists who routinely use them in their work, this article was also peer-reviewed by leading experts and approved by all co-authors, making it an essential resource for basic and clinical DC immunologists.

GLUT1 deficiency prevents glucose uptake in T cells resulting in lower intracellular ATP generation and IFNy production.

Ulcerative colitis (UC) is an inflammatory bowel disease (IBD) often associated with a Type 2 immune response. Although previous reports hint at a role for signal transducer and activator of transcription (STAT) 6 signaling in non-immune cells, the contribution of STAT6-activation particularly in intestinal epithelial cells (IECs) is still unknown. Dextran sodium sulfate (DSS)-induced colitis is a model for UC in mice that we applied here on animals with expression of a constitutively active version of STAT6 in IECs (VillinCre_STAT6vt mice). We report increased pathology and mortality due to enhanced and systemic inflammation in these mice. Bulk RNA sequencing of colonic tissue from naïve VillinCre_STAT6vt mice showed differential expression of more than 140 genes compared to control mice. Gene set enrichment analysis revealed STAT6-regulated expression of the unfolded protein response, MTORC- and MYC-signaling, and protein secretion pathways. A comparison of gene expression in the colon of naïve VillinCre_STAT6vt mice and a human single-cell RNA sequencing dataset of a patient cohort with IBD revealed overlapping changes in the epithelial and macrophage compartment compared to corresponding controls. In conclusion, we found that activation of STAT6 in the intestinal epithelium predisposes to exacerbated colitis and gut inflammation.

The human fetal immune system starts to develop in the first trimester and likely plays a crucial role in fetal development and maternal-fetal tolerance. Innate lymphoid cells (ILCs) are the earliest lymphoid cells to arise in the human fetus. ILCs consist of natural killer (NK) cells, ILC1s, ILC2s, and ILC3s that all share a common lymphoid origin. Here, we studied fetal ILC subsets, mainly NK cells and ILC3s and their potential progenitors, across human fetal tissues. Our results show that fetal ILC subsets have distinct distribution, developmental kinetics, and gene expression profiles across human fetal tissues. Furthermore, we identify CD34RORγtEomes and CD34RORγtEomes cells in the fetal intestine, indicating that tissue-specific ILC progenitors exist already during fetal development.

The immune system undergoes profound dysregulation in sepsis, characterized by hyperinflammation in the acute phase followed by long-lasting immunosuppression. T-cell exhaustion has been proposed as one facet of sepsis-related immunosuppression, which is characterized by impaired effector function and continuous expression of PD1. However, the current analysis of T-cell exhaustion in the post-sepsis is inadequate. Our current study has identified a progressive increase in the frequency of CD44CD11a memory T cells during the post-sepsis phase, accompanied by the upregulation of exhaustion markers (PD-1, Lag3, and Tim3) and functional impairments in these cells. TOX is traditionally recognized as a key regulator driving CD8 T-cell exhaustion in cancer and chronic infection. However, we demonstrate that TOX does not play a critical role in T-cell exhaustion during chronic sepsis but rather is involved in T-cell effector function. Both knockout and "knockdown" of TOX failed to alleviate sepsis-induced T-cell exhaustion. Instead, deletion of TOX impaired the effector function of T cells in chronic sepsis, contradicting its impact on short-term TCR engagement. Our study provides a novel insight into sepsis-induced T-cell exhaustion, highlighting the distinct characteristics of T-cell exhaustion programmed by sepsis.

Mast cell (MC)-driven allergic diseases are constantly expanding and require the development of novel pharmacological MC stabilizers. Allergen/antigen (Ag)-triggered activation via crosslinking of the high-affinity receptor for IgE (FcεRI) is fundamentally regulated by SRC family kinases, for example, LYN and FYN, exhibiting positive and negative functions. We report that KIRA6, an inhibitor for the endoplasmic reticulum stress sensor IRE1α, suppresses IgE-mediated MC activation by inhibiting both LYN and FYN. KIRA6 attenuates Ag-stimulated early signaling and effector functions such as degranulation and proinflammatory cytokine production/secretion in murine bone marrow-derived MCs. Moreover, Ag-triggered bronchoconstriction in an ex vivo model and IgE-mediated stimulation of human MCs were repressed by KIRA6. The interaction of KIRA6 with three MC-relevant tyrosine kinases, LYN, FYN, and KIT, and the potential of KIRA6 structure as a pharmacophore for the development of respective single-, dual-, or triple-specificity inhibitors, was evaluated by homology modeling and molecular dynamics simulations. We found that KIRA6 particularly strongly binds the inactive state of LYN, FYN, and KIT with comparable affinities. In conclusion, our data suggest that the chemical structure of KIRA6 as a pharmacophore can be further developed to obtain an effective MC stabilizer.

Helicobacter infection is a key cause of gastric B cell mucosa-associated lymphoid tissue (MALT) lymphoma. This study examined the role of B cell-activating factor (BAFF), a major driver of B cell proliferation and many B cell disorders, in this malignancy using a model in which conditional knockout mice for NOD-like receptor family CARD domain-containing 5 (Nlrc5) are infected with Helicobacter felis. Gastric BAFF production was significantly increased in H. felis-infected Nlrc5 mice compared to wild-type. Blocking BAFF signalling, before or after the onset of Helicobacter-induced gastritis, significantly reduced MALT development, with fewer gastric B cell follicles and reduced gland hyperplasia. BAFF blockade also reshaped the immune cell landscape in the stomach, resulting in fewer CD4 T cells, Tregs, macrophages and dendritic cells. Using a cell culture model, we identified the protein-coding BAFF transcripts that are upregulated in NLRC5-deficient macrophages stimulated with either H. felis or the NLRC5 agonist, lipopolysaccharide. Among the upregulated variants, TNFSF13B (BAFF)-206 acts as a transcription factor and is reported to enhance BAFF production in autoimmune diseases and cancer. Altogether, these findings implicate the NLRC5-BAFF signalling axis in Helicobacter-induced B cell MALT lymphoma, highlighting BAFF inhibition as a potential therapeutic approach.

Chimeric antigen receptor-T cell (CAR-T) immunotherapy has shown remarkable results for the treatment of certain hematologic malignancies. A redirection strategy that utilizes clinically relevant CAR-T cells in combination with adapter proteins may be an effective strategy to target other hematologic and solid cancers. We established a fusion antibody-based strategy with flexibility to target multiple tumor types in combination with a novel anti-leukocyte immunoglobulin-like receptor-B 4 (LILRB4) CAR-T cell. Specifically, we engineered switch protein (SwP) adapters containing the LILRB4 extracellular domain fused to either an anti-CD19 or anti-CD20 single-chain variable fragment (scFv). These SwPs were sufficient to stimulate anti-LILRB4 CAR-T cells against SwP-tagged LILRB4CD19 and LILRB4CD20 cancers in vitro and in vivo. This strategy may allow CAR-T cells to be redirected against a variety of tumor antigens and cancer types and become a valuable approach to expand the impact of cellular immunotherapy.

B cells with low or absent expression of CD21 (CD21 B cells) gained attention due to their expansion in the peripheral blood of patients with immune-mediated, rheumatic diseases. This is not only observed in typical autoimmune diseases like systemic lupus erythematosus and Sjögren's disease (SjD) but also in radiographic axial spondyloarthritis (r-axSpA), which is considered an autoinflammatory disease. To gain more insight into the origins of the heterogeneous CD21 B-cell population, and its relation to the plasmablast (PB) compartment, we profiled the B-cell-receptor (BCR) repertoire in CD27 and CD27 fractions of CD21 B cells and early PBs using next-generation sequencing. Populations were sorted from peripheral blood of healthy individuals, SjD patients, and r-axSpA patients (n = 10 for each group). In healthy individuals and both patient groups, our findings indicate that CD27CD21 B cells, which exhibit few mutations in their BCR, may develop into CD27CD21 B cells and PBs, both marked by considerably more mutations. Given the known expansion of circulating CD27CD21 B cells in SjD and r-axSpA patients and clonal relationships with both CD27CD21 B cells and early PBs, these cells might actively contribute to (pathological) immune responses in rheumatic diseases with autoimmune and/or autoinflammatory characteristics.

Tumor cell-intrinsic ubiquitin-conjugating enzyme Ubc13 promotes tumorigenesis, yet how Ubc13 in immune cell compartments regulates tumor progression remains elusive. Here, we show that myeloid-specific deletion of Ubc13 (Ubc13Lyz2) leads to accelerated transplanted lung tumor growth in mice. Compared with their littermate controls, tumor-bearing Ubc13Lyz2 mice had lower proliferation and effector function of CD8 T lymphocytes, accompanied by increased infiltration of myeloid-derived suppressor cells within the tumor microenvironment. Mechanistically, Ubc13 deficiency leads to upregulation of Arg1 and PD-L1, the latter is modulated by reduced Ubc13-mediated K63-linked polyubiquitination and increasing activation of Akt, thereby inducing skewness to protumoral polarization and immunosuppressive manifestation. Taken together, we reveal that macrophage-intrinsic Ubc13 restrains lung tumor progression, indicating that activating Ubc13 in macrophages could be an effective immunotherapeutic regimen for lung cancer.

IgE-mediated stimulation of monocytes regulates multiple cellular functions including cellular maturation, cytokine release, antiviral responses, and T-cell differentiation. Expression of the high-affinity IgE receptor, FcεRI, is closely linked to serum IgE levels and atopic disease. The signaling molecules regulating FcεRI effector functions have been well studied in mast cells and basophils; however, less is known about the signaling and regulatory mechanisms in monocytes. This study sought to identify regulators of IgE-mediated cytokine release in human monocytes. SHIP-1 was identified as a negative regulator of IgE-induced IL-10 production. It was also determined that IgE-mediated stimulation and SHIP-1 inhibition decreased antiviral IP-10 production after liposomal poly(I:C) stimulation, indicating differential regulation by SHIP-1 in IgE-driven and antiviral response pathways. SHIP-1 and NF-κB were activated following IgE-mediated stimulation of monocytes, and NF-κB activation was related to both SHIP-1 and FcεRIα cellular expression levels. To our knowledge, this is the first study to identify a role for SHIP-1 in regulating IgE-mediated and antiviral responses in human monocytes. Given the importance of monocytes in inflammation and immune responses, a better understanding of the signaling and regulatory mechanisms downstream of the FcεRI receptor could lead to new therapeutic targets in allergic disease.

Imlifidase (IdeS) is a bacterial protease that hydrolyzes human IgG in their hinge region, decreasing their half-life and abrogating their Fc-mediated properties. It is now successfully used in therapy to prevent graft rejection during kidney transplants and is being clinically evaluated in several IgG-mediated autoimmune diseases. IdeS short half-life however limits its clinical use, particularly in the case of chronic diseases that would request repeated administrations. Here, we developed IdeS-Fc fusion proteins as a divalent homodimer (IdeS-Fc) or a monovalent heterodimer (IdeS-Fc), in order to extend the IgG-depleting action of IdeS over time. Both IdeS-Fc efficiently separated monoclonal and polyclonal human IgG into F(ab') and Fc fragments, although with slower kinetics than their native counterpart. IdeS-Fc exhibited a seven-fold half-life extension in vivo as compared with IdeS, and a significantly better residual cleavage of human IgG at later time points after injection. Our results provide proof of concept for the use of an IdeS with extended IgG-hydrolyzing functions in vivo that could rapidly translate to the clinic.

Identifying activated T lymphocytes and differentiating antigen-specific from bystander T cells is crucial for understanding adaptive immune responses. This study investigates the efficacy of activation-induced markers (AIMs) in distinguishing these cell populations. We measured the expression of commonly used AIMs (CD25, CD38, CD40L, CD69, CD137, HLA-DR, ICOS, and OX40) in an in vitro T-cell activation system and evaluated their sensitivity, specificity, and positive predictive value. We demonstrated that individual AIMs, while specific in detecting activated CD4 T cells, poorly discriminate between antigen-specific and bystander activation, as assessed by a discriminative capacity (DC) score we developed. Our analysis revealed that dual AIM combinations significantly enhanced the ability to distinguish antigen-specific from bystander-activated T cells, achieving DC scores above 90%. These combinations also improved positive predictive value and specificity with a modest reduction in sensitivity. The CD25/ICOS combination emerged as the most efficient, with an average sensitivity of 84.35%, specificity of 99.7%, and DC score of 90.12%. Validation through T-cell cloning and antigen re-stimulation confirmed the robustness of our predictions. This study provides a practical framework for researchers to optimize strategies for identifying and isolating antigen-specific human CD4 T lymphocytes and studying their phenotype, function, and T-cell receptor repertoire.

Genetic engineering of regulatory T cells (Tregs) presents a promising avenue for advancing immunotherapeutic strategies, particularly in autoimmune diseases and transplantation. This study explores the modification of Tregs via mRNA electroporation, investigating the influence of T-cell activation status on transfection efficiency, phenotype, and functionality. For this CD45RA Tregs were isolated, expanded, and modified to overexpress brain-derived neurotrophic factor (BDNF). Kinetics of BDNF expression and secretion were explored. Treg activation state was assessed by checking the expression of activation markers CD69, CD71, and CD137. Our findings show that only activated Tregs secrete BDNF post-genetic engineering, even though both activated and resting Tregs express BDNF intracellularly. Notably, the mTOR pathway and CD137 are implicated in the regulation of protein secretion in activated Tregs, indicating a complex interplay of signalling pathways. This study contributes to understanding the mechanisms governing protein expression and secretion in engineered Tregs, offering insights for optimizing cell-based therapies and advancing immune regulation strategies.