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BackgroundTriple negative breast cancer (TNBC) is an aggressive breast cancer subtype characterized with poor prognosis and high metastatic potential. Although traditional chemotherapy, radiation, and surgical resection remain the standard treatment options for TNBC, bispecific antibody-based immunotherapy is emerging as new strategy in TNBC treatment. Here, we found that the receptor tyrosine kinase-like Orphan Receptor 1 (ROR1) was highly expressed in TNBC but minimally expressed in normal tissue. A bispecific ROR1-targeted CD3 T cell engager (TCE) was designed in IgG-based format with extended half-life.MethodThe expression of ROR1 in TNBC was detected by RT-qPCR and immunohistology analysis. The killing of ROR1/CD3 antibody on TNBC cells was determined by the in vitro cytotoxicity assay and in vivo PBMC reconstituted mouse model. The activation of ROR1/CD3 on T cells was analyzed by the flow cytometry and ELISA assay. Pharmacokinetics study of ROR1/CD3 was performed in mouse.ResultsThe ROR1/CD3 TCE triggered T cell activation and proliferation, which showed potent and specific killing to TNBC cells in ROR1-depedent manner. In vivo mouse model indicated that ROR1/CD3 TCE redirected the cytotoxic activity of T cells to lyse TNBC cells and induced significant tumor regression. Additionally, the ROR1/CD3 bispecific antibody exhibited an extended half-life in mouse, which may enable intermittent administration in clinic.ConclusionsCollectively, these results demonstrated that ROR1/CD3 TCE has a promising efficacy profile in preclinical studies, which suggested it as a possible option for the treatment of ROR1-expressing TNBC.Supplementary InformationThe online version contains supplementary material available at 10.1186/s13058-025-02005-w.

ABSTRACTBackgroundIdiopathic pulmonary fibrosis (IPF) is a lethal disease with an unknown etiology and complex pathophysiology that are not fully understood. The disease involves intricate cellular interplay, particularly among various immune cells. Currently, there is no treatment capable of reversing the fibrotic process or aiding lung regeneration. Hepatocyte growth factor (HGF) has demonstrated antifibrotic properties, whereas the adoptive transfer of modified T cells is a well‐established treatment for various malignancies. We aimed to understand the dynamics of T cells in the progression of lung fibrosis and to study the therapeutic benefit of adoptive T cell transfer in a bleomycin‐injured mouse lung (BLM) model.MethodsT cells were isolated from the spleen of naïve mice and transfected in vitro with mouse HGF plasmid and were administered intratracheally to the mice lungs 7 days post‐bleomycin injury to the lung. Lung tissue and bronchoalveolar lavage were collected and analyzed using flow cytometry, histology, qRT‐PCR, ELISA, and hydroxyproline assay.ResultsOur findings demonstrate the successful T cell therapy of bleomycin‐induced lung injury through the adoptive transfer of HGF‐transfected T cells in mice. This treatment resulted in decreased collagen deposition and a balancing of immune cell exhaustion and cytokine homeostasis compared with untreated controls. In vitro testing showed enhanced apoptosis in myofibroblasts induced by HGF‐overexpressing T cells.ConclusionsTaken together, our data highlight the great potential of adoptive T cell transfer as an emerging therapy to counteract lung fibrosis. This study explores the potential of T cells as a therapeutic strategy against idiopathic pulmonary fibrosis (IPF), a progressive lung disease for which there is currently no treatment to reverse fibrosis or restore normal lung function. To investigate an innovative approach using adoptive T cell transfer, T cells isolated from healthy mice were genetically modified to carry a plasmid containing hepatocyte growth factor (HGF). The modified cells were delivered directly into the airways of mice with bleomycin‐induced lung fibrosis. The results showed a significant reduction in fibrotic scarring, improved immune regulation, and increased apoptosis of pathogenic myofibroblasts. These results highlight the potential of HGF‐engineered T cells as a promising therapeutic approach to combat IPF.

ABSTRACTImmune checkpoint inhibitors (ICIs) have provided new hope for melanoma patients, however, not all patients benefit. Furthermore, ICI‐related therapies cause significant immune‐related adverse events that adversely affect patient outcomes. Therefore, there is a pressing need for reliable biomarkers to identify patients most likely to benefit from these treatments. In this study, we employed an extracellular vesicles (EVs) protein expression array to explore the longitudinal membrane protein profiles of plasma‐derived EVs from 32 melanoma patients receiving anti‐PD‐1 and anti‐angiogenesis therapy at baseline and early treatment. We found that the dynamic changes in PD‐L2 on the EV membrane were associated with treatment response and patient survival. The dynamic change of EV PD‐L2 as an indication of treatment efficacy was validated in an independent cohort of melanoma patients treated with anti‐PD‐1 monotherapy. Plasma‐derived PD‐L2+ EVs from patients with mucosal melanoma significantly reduced the frequency of granzyme B+ CD8 T cells within the peripheral blood mononuclear cells (PBMCs) of healthy individuals. The inhibitory effect of PD‐L2+ EVs on CD8 T cells was further validated using human melanoma cell lines and the B16‐F10 mouse model. Although intratumoural injection of PD‐L2+ EVs could promote melanoma growth in vivo, tumours with PD‐L2+ EVs showed a higher response to anti‐PD‐1 than those without PD‐L2+ EVs. Collectively, our study demonstrates that PD‐L2+ EVs inhibit CD8 T cell activation and promote melanoma growth, and changes in PD‐L2 on circulating EVs during early treatment could serve as a biomarker for ICI‐based therapy.

AbstractThe landscape of cancer treatment has been transformed by immune checkpoint inhibitors; however, the failure to benefit a large number of patients with cancer has underlined the need to identify promising targets for more effective interventions. In this study, we leverage 23andMe, Inc.’s large-scale human germline genetic and health database to uncover the previously unknown role of UL16-binding protein 6 (ULBP6), a high-affinity NK group 2D (NKG2D) ligand, in cancer and its promise as an immuno-oncology therapeutic target. We confirm ULBP6 expression in human tumors and demonstrate that soluble ULBP6 shed from tumors circumvents NKG2D activation provided by membrane-anchored NKG2D ligands to inhibit immune cell activation and tumor cell killing. Based on these findings, we developed 23ME-01473, a humanized Fc effector–enhanced antibody that binds to ULBP6 and its closely related family members, ULBP2 and ULBP5. 23ME-01473 effectively blocks soluble ULBP6-mediated immunosuppression to restore the NKG2D axis on NK and T cells to elicit tumor growth control. Moreover, the Fc effector–enhanced design of 23ME-01473 increases its binding affinity to fragment crystallizable gamma receptor IIIa, which, together with 23ME-01473’s binding to membrane-anchored ULBP6/2/5 on cancer cells, allows for augmented antibody-dependent cellular cytotoxicity induction, providing a second activation node for NK cells. Our studies demonstrate the therapeutic potential of an Fc effector–enhanced anti-ULBP6/2/5 antibody to reinvigorate NK cell and T-cell activation and cytotoxicity for the treatment of cancer.Significance:This study emphasizes the utility of population-based genome-wide assessments for discovering naturally occurring genetic variants associated with lifetime risks for cancer or immune diseases as novel drug targets. We identify ULBP6 as a potential keystone member of the NKG2D pathway, which is important for antitumor immunity. Targeting ULBP6 may hold therapeutic promise for patients with cancer.

Background and aimsMortality rates for hepatocellular carcinoma (HCC) remain high, while multimodal treatment approaches offer new perspectives. Here, we investigated the association of extracellular nicotinamide adenine dinucleotide (eNAD+) on ecto-nucleotide pyrophosphatase/phosphodiesterase 1 (CD203a, ENPP1 or PC-1) on Th17 cells in relation to the likelihood of HCC recurrence following liver resection.MethodThe study compared heparinized blood plasma samples from 95 patients who underwent liver resection, including 25 patients with HCC and 24 control patients without liver disease. Plasma eNAD+ concentrations were determined using a heat-based dichotomous pH extraction method, followed by enzymatic cycling and a colorimetric assay for quantification. Fibrosis was graded histologically using the Desmet score (F0–F4). Surface expression analysis was performed using flow cytometry.ResultsWith increasing grades of liver fibrosis predominant in HCC patients, a significant reduction in plasma eNAD+ concentrations was measured (p < 0.05). Further, a significant correlation was found between HCC patients and CD203a expression on CD4+, CCR4+ as well as CCR6+ T cells (p < 0.05). Patients who exhibited high proportions of CD203a expressing Th17 cells (CD4+, CCR6+ CCR4+) post surgery were found to be at a sixfold increased risk (HR 6.38, 95% Cl 1.51–27.00) of HCC recurrence and had a median recurrence-free survival of 233 days (p < 0.05), compared to patients with low CD203a expressing Th17 cells (CD4+ CCR6+ CCR4+). Similarly, patients who had a high proportion of CD203a expressing Th17 cells (CD4+ CCR6+) following surgery had a fivefold increased risk (HR 5.56, 95% Cl 1.58–19.59) of HCC recurrence and a median recurrence-free survival of 334 days (p < 0.05) compared to those with low CD203a expressing Th17 cells (CCR6+).ConclusionThe data indicates that eNAD+ levels are decreased in patients with liver fibrosis or cirrhosis. Strikingly, patients with high CD203a expression on Th17 cells had a significantly increased likelihood of recurrence, highlighting its potential as a valuable prognostic marker and a possible therapeutic target.Supplementary InformationThe online version contains supplementary material available at 10.1007/s00432-025-06155-4.

BackgroundMyeloid-derived suppressor cells (MDSCs) in tumor microenvironment reduce the efficacy of immunotherapy. PKN2 plays a role in colon cancer, but its function in esophageal cancer (EC) remains unclear. This study investigated PKN2 expression in MDSCs derived from EC tissues and determined whether PKN2 regulates immunosuppressive activity of MDSCs by mediating fatty acid oxidation (FAO).Materials and methodsPKN2 expression was determined in GEO database, EC patients, and 4-NQO-induced EC mice, as well as in different types of immune cells. The effect of PKN2 on the function of polymorphonuclear myeloid-derived suppressor cells (PMN-MDSCs) was investigated by co-culture of PMN-MDSCs and CD4+/CD8+ T cells. The co-culture of patient-derived organoids and autologous immune cells was performed to observe the effect of PKN2 on the immunosuppressive function of PMN-MDSCs.ResultsPKN2 is highly expressed in EC tumor tissues compared to normal tissues, especially in tumor-infiltrated PMN-MDSCs. Overexpressing PKN2 in PMN-MDSCs contributes to the immunosuppressive activity of PMN-MDSCs in vitro. PKN2-overexpressing PMN-MDSCs inhibited the killing ability of cytotoxic T lymphocytes and promoted EC organoid growth. PKN2 promotes FAO in PMN-MDSCs via CPT1B (a key enzyme of FAO). Mechanistically, PKN2 promotes CPT1B transcription by upregulating STAT3 phosphorylation.ConclusionsPKN2 expression was increased in PMN-MDSCs derived from human and mouse EC tissues. PKN2 plays a role in enhancing the immunosuppressive activity of PMN-MDSCs by facilitating STAT3 phosphorylation and CPT1B transcription, which in turn leads to increased CPT1B-mediated FAO in PMN-MDSCs. Targeted inhibition of PKN2 is expected to improve immunotherapeutic efficacy in EC patients.Supplementary InformationThe online version contains supplementary material available at 10.1186/s10020-025-01132-6.

This protocol offers an ex vivo method for screening host-targeting antivirals (HTAs) using human peripheral blood mononuclear cells (PBMCs) or plasmacytoid dendritic cells (pDCs). Unlike virus-targeting antivirals (VTAs), HTAs provide advantages in overcoming drug resistance and offering broad-spectrum protection, especially against rapidly mutating or newly emerging viruses. By focusing on PBMCs or pDCs, known for their high production of humoral factors such as Type I interferons (IFNs), the protocol enables the screening of antivirals that modulate immune responses against viruses. Targeting host pathways, especially innate immunity, allows for species-independent antiviral activity, reducing the likelihood of viral escape mutations. Additionally, the protocol's versatility makes it a powerful tool for testing potential antivirals against various viral pathogens, including emerging viruses, positioning it as an essential resource in both pandemic preparedness and broad-spectrum antiviral research. This approach differentiates itself from existing protocols by focusing on host immune modulation through pDCs, offering a novel avenue for HTA discovery. Key features • Optimized protocol for screening HTAs against dengue virus (DENV), chikungunya virus (CHIKV), and Zika virus (ZIKV).• This protocol is ideal for screening soluble or intravenous-formulated compounds for evaluating their efficacy in experimental settings.• This protocol builds upon the method developed by Tsuji et al. [1] and extends its application to PBMCs and testing against DENV, CHIKV, and ZIKV.

Natural killer (NK) cells are innate immune cells that are crucial for anticancer activity and have been developed as an immune cell therapy for leukemia. However, their limited effectiveness against solid tumors has prompted research into methods to enhance NK cell activity through combination therapies. Health supplements capable of boosting immune surveillance against tumor cells are gaining attention owing to their potential benefits. Resveratrol, a stilbenoid produced by several plants including peanuts and grapes, reportedly exerts anticancer effects and can activate immune cells. The peanut sprout extract cultivated with fermented sawdust medium (PSEFS) is rich in resveratrol, leveraging its health benefits in terms of the dry weight of herbal products, thus maximizing the utilization of resveratrol’s beneficial properties. Our study compared the efficacy of resveratrol and PSEFS and revealed that PSEFS significantly enhanced NK cell activation compared with an equivalent dose of resveratrol. We investigated the ability of PSEFS to potentiate NK cell anticancer activity, focusing on NK cell survival, tumor cell lysis, and NK cell activation in PSEFS-administered mice. Our findings suggest that PSEFS could be a potential NK cell booster for cancer immunotherapy.

BACKGROUNDSepsis is a severe illness characterized by systemic and multiorgan reactive responses and damage. However, the impact of sepsis on the bone marrow, particularly on bone marrow mesenchymal stem cells (BMSCs), is less reported. BMSCs are critical stromal cells in the bone marrow microenvironment that maintain bone stability and hematopoietic homeostasis; however, the impairment caused by sepsis remains unknown.AIMTo investigate the effects of sepsis on BMSCs and the underlying mechanisms.METHODSBMSCs were obtained from healthy donors and patients with sepsis. We compared the self-renewal capacity, differentiation potential, and hematopoietic supportive ability in vitro. Senescence of septic BMSCs was assessed using β-galactosidase staining, senescence-associated secretory phenotype, intracellular reactive oxygen species levels, and the expression of P16 and P21. Finally, the changes in septic BMSCs after nicotinamide adenine dinucleotide (NAD) treatment were evaluated.RESULTSSeptic BMSCs showed decreased proliferation and self-renewal, bias towards adipogenic differentiation, and weakened osteogenic differentiation. Additionally, hematopoietic supportive capacity declines in sepsis. The levels of aging markers were significantly higher in the septic BMSCs. After NAD treatment, the proliferation capacity of septic BMSCs showed a recovery trend, with increased osteogenic and hematopoietic supportive capacities. Sepsis resulted in decreased expression of sirtuin 3 (SIRT3) in BMSCs, whereas NAD treatment restored SIRT3 expression, enhanced superoxide dismutase enzyme activity, reduced intracellular reactive oxygen species levels, maintained mitochondrial stability and function, and ultimately rejuvenated septic BMSCs.CONCLUSIONSepsis accelerates the aging of BMSCs, as evidenced by a decline in self-renewal and osteogenic capabilities, as well as weakened hematopoietic support functions. These deficiencies can be effectively reversed via the NAD/SIRT3/superoxide dismutase pathway.

Immune dysregulation-induced inflammation serves as a driving force in the progression of metabolic dysfunction-associated steatohepatitis (MASH), while the underlying cellular and molecular mechanisms remain largely uncharted. A Western diet (WD) is employed to construct mouse models of metabolic dysfunction associated steatotic liver disease (MASLD) or MASH. Mass cytometry identifies a c-kit+ cDC1 subset whose frequency is reduced in the livers of mice and patients with MASH compared with healthy controls. Adoptive cell transfer of c-kit+ cDC1 protects the progression of MASH. Moreover, analysis of gut microbe sequence shows that WD-fed mice and MASLD/MASH patients exhibit gut microbiota dysbiosis, with an elevated abundance of H2S-producing Desulfovibrio_sp. Transplanting of MASH-derived fecal flora, Desulfovibrio_sp., or injecting H2S intraperitoneally into MASLD mice decreases the c-kit+cDC1 population and exacerbates liver inflammation. Mechanistically, H2S induces autophagic cell death of cDC1 in a c-kit-dependent manner in cDC-specific c-kit-/- and Atg5-/- mice. We thus uncover that microbiota-derived H2S triggers the autophagic cell death of c-kit+ cDC1 and ignites the liver inflammatory cascade in MASH. The immune regulatory mechanism for metabolic dysfunction-associated steatohepatitis (MASH) remains elusive. Here, the authors identify a c-kit+ cDC1 subset, which can be depleted by Desulfovibrio_sp.-induced H2S via autophagic cell death and contributing to uncontrolled inflammation for MASH progression.

Characterizing the HIV-1 reservoir in blood and tissues is crucial for the development of curative strategies. Using an HIV Tat mRNA-containing lipid nanoparticle (Tat-LNP) in combination with panobinostat, we show that p24+ cells from blood and lymph nodes exhibit distinct phenotypes. Blood p24+ cells are found in both central/transitional (TCM/TTM) and effector memory subsets, mostly lack CXCR5 expression and are enriched in GZMA+ cells. In contrast, most lymph node p24+ cells display a TCM/TTM phenotype, with approximately 50% expressing CXCR5 and nearly all lacking GZMA expression. Furthermore, germinal center T follicular helper cells do not appear to harbor the translation-competent reservoir in long-term suppressed individuals. Near full-length HIV-1 sequencing in longitudinal samples from matched blood, lymph nodes, and gut indicates that clones of infected cells, including those carrying an inducible provirus, persist and spread across various anatomical compartments. Finally, uniform genetic diversity across sites suggests the absence of ongoing replication in tissues under treatment. Here, Pardons and Lambrechts et al show that HIV-1 reservoirs in blood and lymph nodes differ phenotypically. Furthermore, germinal center T follicular helper cells do not harbor the inducible reservoir in long-term suppressed individuals. Infected clones can spread across tissues and persist without active replication.

Tissue-repair regulatory T cells (trTregs) comprise a specialized cell subset essential for tissue homeostasis and repair. While well-studied in sterile injury models, their role in infection-induced tissue damage and antimicrobial immunity is less understood. We investigated trTreg dynamics during acute Trypanosoma cruzi infection, marked by extensive tissue damage and strong CD8+ immunity. Unlike sterile injury models, trTregs significantly declined in secondary lymphoid organs and non-lymphoid target tissues during infection, correlating with systemic and local tissue damage, and downregulation of function-associated genes in skeletal muscle. This decline was linked to decreased systemic IL-33 levels, a key trTreg growth factor, and promoted by the Th1 cytokine IFN-γ. Early recombinant IL-33 treatment increased trTregs, type 2 innate lymphoid cells, and parasite-specific CD8+ cells at specific time points after infection, leading to reduced tissue damage, lower parasite burden, and improved disease outcome. Our findings not only provide novel insights into trTregs during infection but also highlight the potential of optimizing immune balance by modulating trTreg responses to promote tissue repair while maintaining effective pathogen control during infection-induced injury. Author summaryDuring Chagas’ disease, caused by the protozoan Trypanosoma cruzi, severe organ damage is generated by the interplay between the parasite and the immune response. In our investigation, we examined the role of tissue-repair regulatory T cells (trTregs) during the acute phase of T. cruzi infection in mice. Surprisingly, we observed a reduction in trTregs at the peak of tissue damage, contrary to their usual accumulation after injury in other contexts. This decline aligned with decreased levels of interleukin-33, a critical factor for trTreg survival, and was promoted by the effector cytokine IFN-γ. Administering interleukin-33 at early infection times not only boosted trTregs but also expanded other reparative and antiparasitic immune cells. Consequently, these treated mice exhibited reduced damage and lower parasite levels in tissues. Our findings provide new insights into how trTreg function during infection-related injury, paving the way for strategies that balance the immune response to support tissue repair without weakening the body’s ability to fight the infection. This approach could have broader implications for treating infectious diseases and conditions involving tissue damage.