技术资料

Uveal melanoma (UM) is the most common intraocular cancer in adults,with metastatic disease (mUM) occurring in approximately half of the patients. Tebentafusp,an immune-mobilizing monoclonal T cell receptor against cancer (ImmTAC),is a therapeutic shown to improve overall survival (OS) in HLA-A*02:01+ adult patients with mUM. Here we investigate the impact of tumor-associated macrophages (TAM) on ImmTAC activity. In vitro,M2 macrophages inhibit ImmTAC-mediated tumor-killing in a dose-dependent and contact-dependent manner. Accordingly,high baseline intratumoral TAM-to-T cell ratios correlate with shorter OS (HR = 2.09,95% CI,1.31–3.33,p = 0.002) in tebentafusp-treated mUM patients from a phase 2 trial. By contrast,IL-2 conditioning of T cells overcomes M2 macrophage-mediated suppression in vitro,while ImmTAC treatment leads to M2-to-M1 macrophage reprogramming both in vitro and in tebentafusp-treated mUM patients. Overall,we show that tebentafusp reshapes the tumor microenvironment to enhance anti-tumor T cell activity,whilst combining tebentafusp with IL-2 may enhance benefit in patients with high levels of TAM. ‘T cell engagers promote antitumor immunity,but how macrophage modulates this activity in tumor is still unclear. Here the authors show,using biopsies from patients with uveal melanoma and single cell analyses,that a T cell engager,tebentafusp,reprograms tumor-associated macrophages and ameliorates,in synergy with IL-2,immunosuppression to cancer. View Publication

Immune evasion by cancer cells involves reshaping the tumor microenvironment (TME) via communication with non-malignant cells. However,resistance-promoting interactions during treatment remain lesser known. Here we examine the composition,communication,and phenotypes of tumor-associated cells in serial biopsies from stage II and III high-risk estrogen receptor positive (ER+ ) breast cancers of patients receiving endocrine therapy (letrozole) as single agent or in combination with ribociclib,a CDK4/6-targeting cell cycle inhibitor. Single-cell RNA sequencing analyses on longitudinally collected samples show that in tumors overcoming the growth suppressive effects of ribociclib,first cancer cells upregulate cytokines and growth factors that stimulate immune-suppressive myeloid differentiation,resulting in reduced myeloid cell- CD8 + T-cell crosstalk via IL-15/18 signaling. Subsequently,tumors growing during treatment show diminished T-cell activation and recruitment. In vitro,ribociclib does not only inhibit cancer cell growth but also T cell proliferation and activation upon co-culturing. Exogenous IL-15 improves CDK4/6 inhibitor efficacy by augmenting T-cell proliferation and cancer cell killing by T cells. In summary,response to ribociclib in stage II and III high-risk ER +  breast cancer depends on the composition,activation phenotypes and communication network of immune cells. The CDK4/6 inhibitor ribociclib holds promise in cancer therapy but how cell cycle inhibitory drugs affect the anti-tumor immune response remains a question. Here authors show that poor response of early-stage estrogen receptor positive breast cancers to ribociclib is caused by changes in the immune cell composition and cancer-cell-immune-cell communication in the tumors rather than intrinsic cancer cell resistance to cell cycle inhibition. View Publication

AbstractBackgroundHypoxia is associated with the evasion of triple-negative breast cancer (TNBC) from immune surveillance. Hypoxia increases the subpopulation of putative TNBC stem-like cells (TNBCSCs) through activating Wnt/β-Catenin signaling. The shedding of MHC class I-related chain A (MICA) is particularly noteworthy in cancer stem cells (CSCs),promoting the resistance of CSCs to natural killer (NK) cell cytotoxicity. To reestablish MICA/NKG2D-mediated immunosurveillance,we proposed the design of a fusion protein (SHH002-hu1-MICA) which consists of Frizzled-7 (Fzd7)-targeting antibody and MICA,serving as an engager retargeting NK cells against TNBCs,especially TNBCSCs.MethodsOpal multicolor immunohistochemistry staining was used to validate the expression of membrane MICA (mMICA) and existence of NK cells in TNBC tumors; flow cytometry (FCM) assay was used to detect the expression of Fzd7/mMICA on TNBCs. Biolayer interferometry (BLI) and surface plasmon resonance (SPR) assays were executed to assess the affinity of SHH002-hu1-MICA towards rhFzd7/rhNKG2D; near-infrared imaging assay was used to evaluate the targeting capability. A cytotoxicity assay was conducted to assess the effects of SHH002-hu1-MICA on NK cell-mediated killing of TNBCs,and FCM assay to analyze the effects of SHH002-hu1-MICA on the degranulation of NK cells. Finally,TNBC cell-line-derived xenografts were established to evaluate the anti-tumor activities of SHH002-hu1-MICA in vivo.ResultsThe expression of mMICA is significantly downregulated in hypoxic TNBCs and TNBCSCs,leading to the evasion of immune surveillance exerted by NK cells. The expression of Fzd7 is significantly upregulated in TNBCSCs and exhibits a negative correlation with the expression of mMICA and infiltration level of NK cells. On accurate assembly,SHH002-hu1-MICA shows a strong affinity for rhFzd7/rhNKG2D,specifically targets TNBC tumor tissues,and disrupts Wnt/β-Catenin signaling. SHH002-hu1-MICA significantly enhances the cytotoxicity of NK cells against hypoxic TNBCs and TNBCSCs by inducing the degranulation of NK cells and promotes the infiltration of NK cells in CD44high regions within TNBC xenograft tumors,exhibiting superior anti-tumor activities than SHH002-hu1.ConclusionsSHH002-hu1-MICA maintains the targeting property of SHH002-hu1,successfully activates and retargets NK cells against TNBCs,especially TNBCSCs,exhibiting superior antitumor activities than SHH002-hu1. SHH002-hu1-MICA represents a promising new engager for NK cell-based immunotherapy for TNBC. View Publication

ABSTRACTCell therapy based on chimeric antigen receptor (CAR) T cells has represented a revolutionary new approach for treating tumors,especially hematological diseases. Complete remission rates (CRR) > 80%–97% and 50%–90% overall response rates (ORR) have been achieved with a treatment based on CAR‐T cells in patients with malignant B‐cell tumors that have relapsed or are refractory to previous treatments. Toxicity remains the major problem. Most patients treated with CAR‐T cells develop high‐grade cytokine release syndrome (CRS) and immune effector cell‐associated neurotoxicity syndrome (ICANS). However,the unprecedentedly high CRR and ORR have led to the approval of six CAR‐T cell therapeutics by the Food and Drug Administration (FDA) and the European Medicines Agency (EMA),prompting researchers to improve existing products and develop new ones. By now,around 1000 clinical trials based on CAR‐T cells are registered at ClinicalTrials.gov: 82% are for hematological diseases,while the remaining 16% are for solid tumors. As a result of this increased research,an enormous amount of conflicting information has been accumulated in the literature,and each group follows its manufacturing protocols and performs specific in vitro testing. This review aimed to combine and compare clinical and preclinical information,highlighting the most used protocols to provide a comprehensive overview of the in vitro world of CAR‐T cells,from manufacturing to their characterization. The focus is on all steps of the CAR‐T cell manufacturing process,from the collection of patient or donor blood to the enrichment of T cells,their activation with anti‐CD3/CD28 beads,interleukin‐2 (IL‐2) or IL‐7 and IL‐15 (induction of a more functional memory phenotype),and their transfection (viral or non‐viral methods). Automation is crucial for ensuring a standardized final product. View Publication

Co-stimulatory molecules are imperative for CD8+ T cells to eliminate target cell and maintain sustained cytotoxicity. Despite an advanced understanding of the co-stimulatory molecules deficiency that results in tumor escape,the tumor cell-intrinsic mechanisms that regulate co-stimulatory molecules remain enigmatic,and an in-depth dissection could facilitate the improvement of treatment options. To this end,in this study,we report that the deficiency of the critical costimulatory molecule CD58,mediated by the expression of ATF4 in tumor cells,impairs the formation of immunological synapses (IS) and leads to the deterioration of antitumor immune function of CD8+ T cells. Mechanistically,ATF4 transcriptionally upregulated dynamin 1 (DNM1) expression leading to DNM1-dependent endocytosis (DDE)-mediated degradation of CD58. Furthermore,administration of DDE inhibitor prochlorperazine or ATF4 knockdown effectively restored CD58 expression,boosting CD8+ T cell cytotoxicity and immunotherapy efficiency. Thus,our study reveals that ATF4 in tumor cells weakens CD58 expression to interfere with complete IS formation,and indicates potential approaches to improve the cytolytic function of CD8+ T cell in tumor immunotherapy.Supplementary InformationThe online version contains supplementary material available at 10.1186/s12967-025-06245-4. View Publication

Background/Objectives: The SARS-CoV-2’s high mutations and replication rates contribute to its high infectivity and resistance to current vaccinations and treatments. The primary cause of resistance to most current treatments aligns within the coding regions for the spike S protein of SARS-CoV-2 that has mutated. As a potential novel immunotherapy,we generated a novel fusion protein composed of a soluble ACE2 (sACE2) linked to llama-derived anti-CD16 that targets different variants of spike proteins and enhances natural killer cells to target infected cells. Methods: Here,we generated a novel sACE2-AntiCD16VHH fusion protein using a Gly4Ser linker,synthesized and cloned into the pLVX-EF1alpha-IRES-Puro vector,and further expressed in ExpiCHO-S cells and purified using Ni+NTA chromatography. Results: The fusion protein significantly blocked SARS-CoV-2 alpha,beta,delta,gamma,and omicron S-proteins binding and activating angiotensin-converting enzyme receptor-2 (ACE2) on ACE2-expressing RAW-Blue macrophage cells and the secretion of several key inflammatory cytokines,G-CSF,MIP-1A,and MCP-1,implicated in the cytokine release storm (CRS). The sACE2-Anti-CD16VHH fusion protein also bridged NK cells to ACE2-expressing human lung carcinoma A549 cells and significantly activated NK-dependent cytotoxicity. Conclusions: The findings show that a VHH directed against CD16 could be an excellent candidate to be linked to soluble ACE2 to generate a bi-specific molecule (sACE2-AntiCD16VHH) suitable for bridging effector cells and infected target cells to inhibit SARS-CoV-2 variant spike proteins binding to the ACE2 receptor in the RAW-Blue cell line and pro-inflammatory cytokines and to activate natural killer cell cytotoxicity. View Publication

Current clinical strategies for the delivery of pulmonary therapeutics to the lung are primarily targeted to the upper portions of the airways,such as treatment with nebulized instillation and inhalation. However,targeted delivery to the lower regions of the lung is necessary for the treatment of parenchymal lung injury and disease. Here,we show the development of an mRNA therapeutic for the lower lung in mice using one-component Ionizable Amphiphilic Janus Dendrimers as a delivery vehicle. We deliver an anti-inflammatory cytokine mRNA,transforming growth factor-beta,to produce transient protein expression in the lower regions of the lung. This study highlights a method for precise,effective,and safe delivery of TGF-β mRNA to the lung in mice. This delivery system offers a promising approach for targeting therapeutics to the specific tissues,a strategy necessary to fill the current clinical gap in treating parenchymal lung injury and disease. Targeted delivery to the lower regions of the lung is necessary for the treatment of parenchymal lung injury and disease but is challenging. Here,the authors develop an mRNA delivery platform to treat acute lung injury in mice and demonstrate that it can reach the lower regions of the lung. View Publication

AbstractIn this work,we have generated bispecific interleukin (IL)‐12 surrogate agonists based on camelid‐derived single‐domain antibodies (sdAbs) targeting the IL‐12 receptor (IL‐12R) subunits IL‐12Rβ1 and IL‐12Rβ2. Following immunization and antibody display‐based paratope isolation,respective sdAbs were combinatorially reformatted into a monovalent bispecific architecture by grafting resulting paratopes onto the hinge region of a heterodimeric Fc region. Functional characterization using NK‐92 cells enabled the identification of multiple different sdAb‐based bispecifics displaying divergent IL‐12R agonism capacities as analyzed by STAT4 phosphorylation. Further investigations by harnessing peripheral blood mononuclear cells (PBMCs) from healthy donors revealed attenuated pSTAT4 activation compared to recombinant human (rh) wild‐type IL‐12 regarding both natural killer (NK)‐cell and T‐cell activation but robust IL‐12R agonism on stimulated T cells. While several sdAb‐based IL‐12 mimetics were nearly inactive on NK cells as well as T cells obtained from PBMCs,they elicited significant STAT4 phosphorylation and interferon (IFN)‐γ release on stimulated T cells as well as an IL‐12‐like transcriptional signature. Furthermore,we demonstrate that the activity of receptor agonism of generated bispecific IL‐12 mimetics can also be biased towards stimulated T cells by changing the spatial orientation of the individual sdAbs within the molecular design architecture. Taken together,we present an alternative strategy to generate IL‐12‐like biologics with tailor‐made characteristics. View Publication

The persistence of HIV-1 latency reservoirs in CD4+ T cells is a significant obstacle for curing HIV-1. Shock-and-kill strategies,which aim to reactivate latent HIV-1 followed by cytotoxic clearance,have shown limited success in vivo due to insufficient efficacy of latency reversal agents (LRAs) and off-target effects. Natural killer (NK) cells,with their ability to mediate cytotoxicity independent of antigen specificity,offer a promising avenue for enhancing the shock-and-kill approach. Previously,we observed that pan-caspase inhibitors induce NK cells to secrete an LRA in vitro. Here,we aimed to identify this LRA using a targeted proteomic approach. We identified lymphotoxin-α (LTα) as the key LRA secreted by NK cells following pan-caspase inhibitor treatment. LTα was shown to significantly induce HIV-1 LTR promoter activity,a hallmark of viral reactivation. Neutralization of LTα effectively abolished the observed LRA activity,confirming its central role. Moreover,cytokine-primed but not resting human primary NK cells exhibited LRA activity that could be neutralized with LTα neutralizing antibodies. Finally,pan-caspase inhibitor treatment did not decrease the ability of the cytokine-primed NK cells to kill target cells. These findings demonstrate that cytokine-primed NK cells,through LTα secretion,can effectively reactivate latent HIV-1 following pan-caspase inhibitor treatment,without compromising NK cell cytotoxicity. This highlights a potential enhancement strategy utilizing NK cells for shock-and-kill approaches in HIV-1 cure research. View Publication

IntroductionThe role of miRNAs in regulating variable molecular functions has been sought by scientists for its promising utility in regulating the immune response and,hence,in treating various diseases. In hepatocellular carcinoma (HCC) specifically,a reduction in the number and efficiency of circulating and intrahepatic natural killer (NK) cells has been reported. Our project aims to investigate the role of miR-216a-3p in the regulation of NK cell cytotoxicity,especially since it plays a tumor suppressor role in the context of HCC.MethodsTo achieve our aim,we isolated NK cells from the whole blood of 86 patients with HCC and 23 healthy controls. We assessed the expression profile of miR-216a-3p in NK cells of patients and controls. Furthermore,we induced the expression of miR-216a-3p in NK cells isolated from healthy controls,followed by measuring the release of interferon-gamma (IFN-γ),tumor necrosis factor-alpha (TNF-α),perforins (PRF) and granzyme B (GrB) using ELISA as well as NK cells cytolytic activity against Huh7 cells using lactate dehydrogenase (LDH) cytotoxicity assay. After that,we performed an in silico analysis to understand the mechanistic regulation imposed by miR-216a-3p on NK cells to study its impact on one of its potential downstream targets.ResultsOur results have indicated that miR-216a-3p has higher expression in NK cells of patients with HCC,and simulating this elevated expression pattern via forcing miR-216a-3p expression in normal NK cells has negatively impacted the release of TNF- α,IFN- γ,GrB,and PRF. Consequently,a decrease in cell cytolysis was observed. Our in silico analysis revealed that the predicted downstream targets of miR-216a-3p are enriched in the FOXO-signaling pathway. Among those targets is FOXO-1,which has been reported to play a role in NK cell maturation. Thus,we evaluated FOXO-1 expression upon mimicking miR-216a-3p in control NK cells that showed significant downregulation of FOXO-1 on both RNA and protein levels.ConclusionIn conclusion,we report miR-216-3p as a negative regulator of NK cell cytotoxicity. View Publication

GATA2 germline mutations lead to a syndrome characterized by immunodeficiency,vascular disorders and myeloid malignancies. To elucidate how these mutations affect hematopoietic homeostasis,we created a knock-in mouse model expressing the recurrent Gata2 R396Q missense mutation. Employing molecular and functional approaches,we investigated the mutation’s impact on hematopoiesis,revealing significant alterations in the hematopoietic stem and progenitor (HSPC) compartment in young age. These include increased LT-HSC numbers,reduced self-renewal potential,and impaired response to acute inflammatory stimuli. The mature HSPC compartment was primarily affected at the CMP sub-population level. In the mutant LT-HSC population,we identified an aberrant subpopulation strongly expressing CD150,resembling aging,but occurring prematurely. This population showed hyporesponsiveness,accumulated over time,and exhibited allele-specific expression (ASE) favoring the mutated Gata2 allele,also observed in GATA2 mutated patients. Our findings reveal the detrimental impact of a Gata2 recurrent missense mutation on the HSC compartment contributing to its functional decline. Defects in the CMP mature compartment,along with the inflammatory molecular signature,explain the loss of heterogeneity in HPC compartment observed in patients. Finally,our study provides a valuable model that recapitulates the ASE-related pathology observed in GATA2 deficiency,shedding light on the mechanisms contributing to the disease’s natural progression. View Publication

Gene enhancers often form long-range contacts with promoters,but it remains unclear if the activity of enhancers and their chromosomal contacts are mediated by the same DNA sequences and recruited factors. Here,we study the effects of expression quantitative trait loci (eQTLs) on enhancer activity and promoter contacts in primary monocytes isolated from 34 male individuals. Using eQTL-Capture Hi-C and a Bayesian approach considering both intra- and inter-individual variation,we initially detect 19 eQTLs associated with enhancer-eGene promoter contacts,most of which also associate with enhancer accessibility and activity. Capitalising on these shared effects,we devise a multi-modality Bayesian strategy,identifying 629 “trimodal QTLs” jointly associated with enhancer accessibility,eGene promoter contact,and gene expression. Causal mediation analysis and CRISPR interference reveal causal relationships between these three modalities. Many detected QTLs overlap disease susceptibility loci and influence the predicted binding of myeloid transcription factors,including SPI1,GABPB and STAT3. Additionally,a variant associated with PCK2 promoter contact directly disrupts a CTCF binding motif and impacts promoter insulation from downstream enhancers. Jointly,our findings suggest an inherent genetic coupling of enhancer activity and connectivity in gene expression control relevant to human disease and highlight the regulatory role of genetically determined chromatin boundaries. Here,the authors study the effects of expression quantitative trait loci on enhancer activity and promoter contacts in primary monocytes isolated from male individuals,suggesting an inherent genetic link between the activity of enhancers,their contacts to target gene promoters and gene expression. View Publication