技术资料

Trogocytosis is an underappreciated phenomenon that shapes the immune microenvironment surrounding many types of solid tumors. The consequences of membrane-bound proteins being deposited from a donor immune cell to a recipient cancer cell via trogocytosis are still unclear. Here,we report that human clear cell renal carcinoma tumors stably express the lymphoid markers CD45,CD56,CD14,and CD16. Flow cytometry performed on fresh kidney tumors revealed consistent CD45 expression on tumor cells,as well as varying levels of the other markers mentioned previously. These results were consistent with our immunofluorescent analysis,which also revealed colocalization of lymphoid markers with carbonic anhydrase 9,a standard kidney tumor marker. RNA analysis showed a significant upregulation of genes typically associated with immune cells by tumor cells. Finally,we show evidence of chromosomal DNA being transferred from immune cells to tumor cells through physical contact. This horizontal gene transfer has transcriptional consequences in the recipient tumor cell,resulting in a fusion phenotype that expresses both immune and cancer specific proteins. This work demonstrates a novel mechanism by which tumor cell protein expression is altered through the acquisition of surface membrane fragments and genomic DNA from infiltrating lymphocytes. These results alter the way in which we understand tumor-immune cell interactions and may reveal new insights into the mechanisms by which tumors develop. Additionally,further studies into trogocytosis and other mechanisms of contact-mediated cellular transfer will help push the field towards the next generation of immunotherapies and biomarkers for treating renal cell carcinoma and other cancers. View Publication

This study investigates the impact of minimal residual disease (MRD) on relapse in patients with acute myeloid leukemia (AML),focusing on its interaction with immune cells function. A total of 49 AML patients were enrolled in this prospective study and categorized into four groups: MRD − positive with relapse,MRD − positive without relapse,MRD − negative with relapse,and MRD − negative without relapse. Peripheral blood T lymphocyte subpopulations were analyzed using ten-color flow cytometry. CD4 + T cells were co-cultured with leukemia cell lines to assess the impact of CD4 + T cells on leukemia cell proliferation,apoptosis,and cytokine release. In MRD − positive patients,relapsed individuals exhibited significantly higher levels of CD4 + T cells,regulatory T (Treg) cells,and CD4 + CD45RA + naïve T cells compared to non-relapsed patients ( P < 0.0001,P = 0.0016,and P = 0.0066,respectively). Conversely,in MRD − negative patients,relapsed individuals showed a significantly lower percentage of Treg cells ( P = 0.0068). Furthermore,we observed that CD4 + T cells were associated with enhanced leukemia cell proliferation and reduced apoptosis,along with markedly increased IL-10 expression. The available data raise the possibility that CD4 + T cell-derived IL-10 participates in immune microenvironment regulation,a process that may have implications for MRD maintenance and disease recurrence in AML. View Publication

The selection of genetically engineered immune or hematopoietic cells in vivo after gene editing remains a clinical problem and requires a method to spare on-target toxicity to normal cells. Here,we develop a base editing approach exploiting a naturally occurring CD33 single nucleotide polymorphism leading to removal of full-length CD33 surface expression on edited cells. CD33 editing in human and nonhuman primate hematopoietic stem and progenitor cells protects myeloid progeny from CD33-targeted therapeutics without affecting normal hematopoiesis in vivo,thus demonstrating potential for improved immunotherapies with reduced off-leukemia toxicity. For broader application to gene therapies,we demonstrate highly efficient (>70%) multiplexed adenine base editing of the CD33 and gamma globin genes,resulting in long-term persistence of dual gene-edited cells with HbF reactivation in nonhuman primates. Using the CD33 antibody-drug conjugate Gemtuzumab Ozogamicin,we show resistance of engrafted,multiplex edited human cells in vivo,and a 2-fold enrichment for edited cells in vitro. Together,our results highlight the potential of adenine base editors for improved immune and gene therapies. Subject terms: Haematopoietic stem cells,Bone marrow transplantation,Cell biology View Publication

Prenatal alcohol exposure (PAE) affects embryonic development,causing a variable fetal alcohol spectrum disorder (FASD) phenotype with neurodevelopmental disorders and birth defects. To explore the effects of PAE on gastrulation,we used an in vitro model with subchronic moderate (20 mM) and severe (70 mM) ethanol exposures during the differentiation of human embryonic stem cells into germ layer cells. We analyzed genome-wide gene expression (mRNA sequencing),DNA methylation (EPIC Illumina microarrays) and metabolome (non-targeted LC-MS) of the endodermal,mesodermal and ectodermal cells. The largest number of ethanol-induced alterations were observed in endodermal cells,whereas the most prominent changes were in ectodermal cells. Methionine metabolism and genes of the main signaling pathways involved in gastrulation and body patterning were affected by ethanol in all germ layers. Many of the altered genes,including BMP4,FGF8,SIX3 and LHX2,have previously been associated with PAE and phenotypes of FASD,like defects in heart and corpus callosum development as well as holoprosencephaly. Our findings support the early origin of alcohol-induced developmental disorders and strengthen the role of methionine cycle in the etiology of FASD. View Publication

Bats can host viruses of pandemic concern without developing disease. The mechanisms underlying their exceptional resilience to viral infections are largely unresolved,necessitating the development of physiologically relevant and genetically tractable research models. Here,we developed respiratory and intestinal organoids that recapitulated the cellular diversity of the in vivo epithelium present in Rousettus aegyptiacus,the natural reservoir for the highly pathogenic Marburg virus (MARV). In contrast to human counterparts,bat organoids and mucosal tissue exhibited elevated constitutive expression of innate immune effectors,including type I interferon-ε (IFNε) and IFN-stimulated genes (ISGs). Upon infection with diverse zoonotic viruses,including MARV,bat organoids strongly induced type I and III IFN responses,which conferred robust antiviral protection. Type III IFNλ3 additionally displayed virus-independent self-amplification,acting as an ISG to enhance antiviral immunity. Our organoid platform reveals key features of bat epithelial antiviral immunity that may inform therapeutic strategies for viral disease resilience. Subject terms: Mucosal immunology,Viral infection View Publication

The intestinal epithelium of human infants is developmentally immature compared to that of adults. Exactly how this immaturity affects key epithelial functions and their interactions with nearby immune cells remains an understudied area of research,partly due to limited access to non-diseased infant gut tissues. Human intestinal organoids,or “mini guts” generated from tissue stem cells,are promising models for investigating intestinal biology and disease mechanisms. These three-dimensional structures closely mimic their tissue of origin,including cellular physiology and genetics. We have also previously shown that neonatal Th17 cells represent a distinct cell population with a cytokine profile skewed toward IL-22 production rather than IL-17A,as seen in adult Th17 cells. In this study,we sought to model the impact of neonatal-derived Th17 cytokine,namely IL-22 and the intestinal epithelium using infant-derived ileal enteroids. We generated enteroids from ileal biopsies from infants (< 6 months old) and cultured them for seven days with standard organoid growth media,organoid media supplemented with conditioned media from cord-blood-derived Th17 cells,or media supplemented with recombinant IL-22. We assessed morphological changes and conducted transcriptomics profiling via RNAseq. Exposing enteroids to neonatal Th17-cells-derived conditioned media led to enhanced growth,maturation,and differentiation as compared to control media. These effects were ablated when an IL-22 neutralizing antibody was used,while conversely,supplementing with recombinant IL-22 mimicked the Th17 effects,increasing intestinal epithelial cell proliferation and inducing marked differentiation of secretory cells. Our transcriptomic profiling similarly demonstrated significant changes in response to IL-22 with downregulation of Wnt and Notch signaling and upregulation of immune pathways,particularly interferon signaling. The transcriptomic data also suggested that IL-22 treatment led to changes in cell type composition with an increase in stem- and progenitor cells at the expense of enterocytes. Taken together,our data suggests that early-life intestinal development is likely influenced by IL-22-dependent crosstalk between the infant epithelium and exposure to neighboring Th17 cells. This promotes epithelial cell maturation and immune readiness,reflected at both the morphological and molecular levels. Our work also provides a relevant framework for studying healthy infant gut development,which can be further leveraged to examine early-life gastrointestinal disorders,model complex human disease,and therapeutic testing while reducing reliance on animal models. View Publication

Hematologic adverse events are common dose-limiting toxicities in drug development. Classical animal models for preclinical safety assessment of immunotherapies are often limited due to insufficient cross-reactivity with non-human homologous proteins,immune system differences,and ethical considerations. Therefore,we evaluate a human bone marrow (BM) microphysiological system (MPS) for its ability to predict expected hematopoietic liabilities of immunotherapeutics. The BM-MPS consists of a closed microfluidic circuit containing a ceramic scaffold covered with human mesenchymal stromal cells and populated with human BM-derived CD34+ cells in chemically defined growth factor-enriched media. The model supports on-chip differentiation of erythroid,myeloid and NK cells from CD34+ cells over 31 days. The hematopoietic lineage balance and output is responsive to pro-inflammatory factors and cytokines. Treatment with a transferrin receptor-targeting IgG1 antibody results in inhibition of on-chip erythropoiesis. The immunocompetence of the chip is established by the addition of peripheral blood T cells in a fully autologous setup. Treatment with T cell bispecific antibodies induces T cell activation and target cell killing consistent with expected on-target off-tumor toxicities. In conclusion,this study provides a proof-of-concept that this BM-MPS is applicable for in vitro hematopoietic safety profiling of immunotherapeutics. Subject terms: Biologics,Haematopoiesis,Lab-on-a-chip,Drug safety View Publication

Nonsense-mediated RNA decay (NMD) is a highly conserved RNA turnover pathway that influences several biological processes. Specific features in messenger RNAs (mRNAs) have been found to trigger decay by NMD,leading to the assumption that NMD sensitivity is an intrinsic quality of a given transcript. Here,we provide evidence that,instead,an overriding factor dictating NMD sensitivity is the cell environment. Using several genome-wide techniques to detect NMD-target mRNAs,we find that hundreds of mRNAs are sensitized to NMD as human embryonic stem cells progress to form neural progenitor cells. Another class of mRNAs escape from NMD during this developmental progression. We show that the differential sensitivity to NMD extends to in vivo scenarios,and that the RNA-binding protein,HNRNPL,has a role in cell type-specific NMD. We also addressed another issue in the field—whether NMD factors are core or branch-specific in their action. Surprisingly,we found that UPF3B,an NMD factor critical for the nervous system,shares only 30% of NMD-target transcripts with the core NMD factor UPF2. Together,our findings have implications for how NMD is defined and measured,how NMD acts in different biological contexts,and how different NMD branches influence human diseases. View Publication

Mucopolysaccharidosis (MPS) IVA is a bone-affecting lysosomal storage disease (LSD) caused by impaired degradation of the glycosaminoglycans (GAGs) keratan sulfate (KS) and chondroitin 6-sulfate (C6S) due to deficient N-acetylgalactosamine-6-sulfatase (GALNS) enzyme activity. Previously,we successfully developed and validated a CRISPR/nCas9-based gene therapy (GT) to insert an expression cassette at the AAVS1 and ROSA26 loci in human MPS IVA fibroblasts and MPS IVA mice,respectively. In this study,we have extended our approach to evaluate the effectiveness of our CRISPR/nCas9-based GT in editing human CD34+ cells to mediate cross-correction of MPS IVA fibroblasts. CD34+ cells were electroporated with the CRISPR/nCas9 system,targeting the AAVS1 locus. The nCas9-mediated on-target donor template insertion,and the stemness of the CRISPR/nCas-edited CD34+ cells was evaluated. Additionally,MPS IVA fibroblasts were co-cultured with CRISPR/nCas-edited CD34+ cells to assess cross-correction. CRISPR/nCas9-based gene editing did not affect the stemness of CD34+ cells but did lead to supraphysiological levels of the GALNS enzyme. Upon co-culture,MPS IVA fibroblasts displayed a significant increase in the GALNS enzyme activity along with lysosomal mass reduction,pro-oxidant profile amelioration,mitochondrial mass recovery,and pro-apoptotic and pro-inflammatory profile improvement. These results show the potential of our CRISPR/nCas9-based GT to edit CD34+ cells to mediate cross-correction. View Publication

The tumor microenvironment and healing wounds both contain extremely high concentrations of adenosine triphosphate (ATP) compared to normal tissue. The P2Y2 receptor,an ATP-activated purinergic receptor,is typically associated with pulmonary,endothelial,and neurological cell signaling. Here,we examine ATP-dependent signaling in breast epithelial cells and how it is altered in metastatic breast cancer. Using rapid imaging techniques,we show how ATP-activated P2Y2 signaling causes an increase in intracellular Ca 2+ in non-tumorigenic breast epithelial cells,approximately 3-fold higher than their tumorigenic and metastatic counterparts. The non-tumorigenic cells respond to increased Ca 2+ with actin polymerization and localization to the cell edges after phalloidin staining,while the metastatic cells remain unaffected. The increase in intracellular Ca 2+ after ATP stimulation was blunted to control levels using a P2Y2 antagonist,which also prevented actin mobilization and significantly increased cell dissemination from spheroids in non-tumorigenic cells. Furthermore,the lack of Ca 2+ changes and actin mobilization in metastatic breast cancer cells could be due to the reduced P2Y2 expression,which correlates with poorer overall survival in breast cancer patients. This study elucidates the rapid changes that occur after elevated intracellular Ca 2+ in breast epithelial cells and how metastatic cancer cells have adapted to evade this cellular response. View Publication

Acute myeloid leukemia (AML) is associated with unfavorable patient outcomes primarily related to disease relapse. Since specific types of leukemic hematopoietic stem and progenitor cells (HSPCs) are suggested to contribute to AML propagation,this study aimed to identify and explore relapse-initiating HSPC subpopulations present at diagnosis,using single-cell analysis (SCA). We developed unique high-resolution techniques capable of tracking single-HSPC-derived subclones during AML evolution. Each subclone was evaluated for chemo-resistance,in vivo leukemogenic potential,mutational profile,and the cell of origin. In BM samples of 15 AML patients,GMP-like and MLP-like HSPC subpopulations were identified as prevalent at relapse,exhibiting chemo-resistance to commonly used chemotherapy agents cytosine arabinoside (Ara-C) and daunorubicin. Reconstruction of phylogenetic lineage trees combined with genetic analysis of single HSPCs and single-HSPC-derived subclones demonstrated two distinct clusters,originating from MLP-like or GMP-like subpopulations,observed both at diagnosis and relapse. These subpopulations induced leukemia development ex vivo and in vivo. Genetic SCA showed that these relapse-related subpopulations harbored mutated EZH2 and TP53,detected already at diagnosis. This study,using combined molecular,functional,and genomic analyses at the level of single cells,identified patient-specific chemo-resistant HSPC subpopulations at the time of diagnosis,promoting AML relapse. View Publication

This study investigates the use of silver nanoparticles as a potential new treatment for colorectal cancer. Colorectal cancer is one of the most common cancers worldwide,and finding more effective treatments is essential. The researchers tested silver nanoparticles AgNPs with two different surface coatings to see how they affect cancer cells compared to healthy cells. One type of nanoparticles showed significant effects,reducing cancer cell growth and inducing cell death,while the other had minimal impact. These findings suggest that modifying the surface of nanoparticles could help target cancer cells more specifically,leading to treatments that are both more effective and have fewer side effects. This research could pave the way for new therapies for colorectal cancer and other types of cancer,ultimately improving patient outcomes and advancing cancer treatment strategies. View Publication