技术资料

Dishevelled-associated activator of morphogenesis1 (DAAM1) is a member of the evolutionarily conserved Formin family and plays a significant role in the malignant progression of various human cancers. This study aims to explore the clinical and biological significance of DAAM1 in pancreatic cancer. Multiple public datasets and an in-house cohort were utilized to assess the clinical relevance of DAAM1 in pancreatic cancer. The LinkedOmics platform was employed to perform enrichment analysis of DAAM1-associated molecular pathways in pancreatic cancer. Subsequently,a series of in vitro and in vivo experiments were conducted to evaluate the biological roles of DAAM1 in pancreatic cancer cells and its effects on intratumoral T cells. DAAM1 was found to be upregulated in pancreatic cancer tissues,with higher expression levels observed in tumor cells. Additionally,high expression of DAAM1 was associated with poor prognosis. DAAM1 acted as an oncogene in pancreatic cancer,and its inhibition suppressed tumor cell proliferation,migration,and invasion,while promoted apoptosis. Furthermore,DAAM1 was involved in the JAK1/STAT1 signaling pathway and regulated PD-L1 expression in pancreatic cancer cells. The inhibition of DAAM1 also significantly reduced the exhaustion levels of CD8+ T cells. In conclusion,DAAM1 functions as an oncogene and is immunologically implicated in pancreatic cancer,these findings suggest that DAAM1 may serve as a promising therapeutic target for the clinical management of pancreatic cancer. The online version contains supplementary material available at 10.1186/s12935-024-03631-8. View Publication

Chimeric antigen receptor (CAR)-engineered T cell therapy holds promise for treating myeloid malignancies,but challenges remain in bone marrow (BM) infiltration and targeting BM-resident malignant cells. Current autologous CAR-T therapies also face manufacturing and patient selection issues,underscoring the need for off-the-shelf products. In this study,we characterize primary patient samples and identify a unique therapeutic opportunity for CAR-engineered invariant natural killer T (CAR-NKT) cells. Using stem cell gene engineering and a clinically guided culture method,we generate allogeneic CD33-directed CAR-NKT cells with high yield,purity,and robustness. In preclinical mouse models,CAR-NKT cells exhibit strong BM homing and effectively target BM-resident malignant blast cells,including CD33-low/negative leukemia stem and progenitor cells. Furthermore,CAR-NKT cells synergize with hypomethylating agents,enhancing tumor-killing efficacy. These cells also show minimal off-tumor toxicity,reduced graft-versus-host disease and cytokine release syndrome risks,and resistance to allorejection,highlighting their substantial therapeutic potential for treating myeloid malignancies. Subject terms: Cancer therapy,Immunotherapy,Leukaemia View Publication

To fully utilize the potential of human induced pluripotent stem cells (hiPSCs) for allogeneic stem cell–based therapies,efficient and scalable expansion procedures must be developed. For other adherent human cell types,the combination of microcarriers (MCs) and stirred tank bioreactors has been shown to meet these demands. In this study,a hiPSC quasi-perfusion expansion procedure based on MCs was developed at 100-mL scale in spinner flasks. Process development began by assessing various medium exchange strategies and MC coatings,indicating that the hiPSCs tolerated the gradual exchange of medium well when cultivated on Synthemax II–coated MCs. This procedure was therefore scaled-up to the 1.3-L Eppendorf BioBLU 1c stirred tank bioreactor by applying the lower limit of Zwietering’s suspension criterion ( N s 1 u ),thereby demonstrating proof-of-concept when used in combination with hiPSCs for the first time. To better understand the bioreactor and its bioengineering characteristics,computational fluid dynamics and bioengineering investigations were performed prior to hiPSC cultivation. In this manner,improved process understanding allowed an expansion factor of ≈ 26 to be achieved,yielding more than 3 × 10 9 cells within 5 days. Further quality analyses confirmed that the hiPSCs maintained their viability,identity,and differentiation potential throughout cultivation. • N s 1 u can be used as a scale-up criterion for hiPSC cultivations in MC-operated stirred bioreactors • Uniform distribution and attachment of cells to the MCs are crucial for efficient expansion • Perfusion is advantageous and supports the cultivation of hiPSCs The online version contains supplementary material available at 10.1007/s00253-024-13372-3. View Publication

Acute myeloid leukemia (AML) is characterized by the accumulation of immature myeloid cells and a differentiation block,highlighting the urgent need for novel differentiation-inducing therapies. This study evaluated Adina rubella Hance (ARH) stem as a potent differentiation inducer by systematically screening 200 plant extracts. ARH stem promoted phenotypic differentiation in AML cells. In addition to its differentiation-inducing effects,ARH stem exhibited strong antileukemic activities,such as inhibiting cell proliferation,inducing cell death,and enhancing mitochondrial reactive oxygen species (mtROS) levels,the latter of which is critical for its differentiation-promoting activity. Comparative analysis with the extracts from other parts of the plant confirmed the superior efficacy of the stem extract because of its unique chemical composition. Ultra-high-performance liquid chromatography combined with quadrupole time-of-flight mass spectrometry analysis identified Picroside III as a major active compound within the stem extract,capable of recapitulating ARH stem-induced differentiation and demonstrating significant antileukemic properties. These findings underscore the therapeutic potential of ARH stem and its active component,Picroside III,as promising agents for differentiation-based treatment strategies in AML. View Publication

Understanding the interaction between genetic and epigenetic variation remains a challenge due to confounding environmental factors. We propose that human induced Pluripotent Stem Cells (iPSCs) are an excellent model to study the relationship between genetic and epigenetic variation while controlling for environmental factors. In this study,we have created a comprehensive resource of high-quality genomic,epigenomic,and transcriptomic data from iPSC lines and three iPSC-derived cell types (neural stem cell (NSC),motor neuron,monocyte) from three healthy donors. We find that epigenetic variation is most strongly associated with genetic variation at the iPSC stage,and that relationship weakens as epigenetic variation increases in differentiated cells. Additionally,cell type is a stronger source of epigenetic variation than genetic variation. Further,we elucidate a utility of studying epigenetic variation in iPSCs and their derivatives for identifying important loci for GWAS studies and the cell types in which they may be acting. Subject terms: Epigenomics,Genomics,Transcriptomics View Publication

Persistence of drug-resistant breast cancer stem cells (brCSCs) after a chemotherapeutic regime correlates with disease recurrence and elevated mortality. Therefore,deciphering mechanisms that dictate their drug-resistant phenotype is imperative for designing targeted and more effective therapeutic strategies. The transcription factor SOX2 has been recognized as a protagonist in brCSC maintenance,and previous studies have confirmed that inhibition of SOX2 purportedly eliminated these brCSCs. However,pharmacological targeting of transcription factors like SOX2 is challenging due to their structural incongruities and intrinsic disorders in their binding interfaces. Therefore,transcriptional co-activators may serve as a feasible alternative for effectively targeting the brCSCs. Incidentally,transcriptional co-activators YAP/TAZ were found to be upregulated in CD44 + /CD24 - /ALDH + cells isolated from patient breast tumors and CSC-enriched mammospheres. Interestingly,it was observed that YAP/TAZ exhibited direct physical interaction with SOX2 and silencing YAP/TAZ attenuated SOX2 expression in mammospheres,leading to significantly reduced sphere forming efficiency and cell viability. YAP/TAZ additionally manipulated redox homeostasis and regulated mitochondrial dynamics by restraining the expression of the mitochondrial fission marker,DRP1. Furthermore,YAP/TAZ inhibition induced DRP1 expression and impaired OXPHOS,consequently inducing apoptosis in mammospheres. In order to enhance clinical relevance of the study,an FDA-approved drug verteporfin (VP),was used for pharmacological inhibition of YAP/TAZ. Surprisingly,VP administration was found to reduce tumor-initiating capacity of the mammospheres,concomitant with disrupted mitochondrial homeostasis and significantly reduced brCSC population. Therefore,VP holds immense potential for repurposing and decisively eliminating the chemoresistant brCSCs,offering a potent strategy for managing tumor recurrence effectively. Subject terms: Cancer stem cells,Cancer stem cells View Publication

Small nucleolar RNAs (snoRNAs) are non-coding RNAs that function in ribosome and spliceosome biogenesis,primarily by guiding modifying enzymes to specific sites on ribosomal RNA (rRNA) and spliceosomal RNA (snRNA). However,many orphan snoRNAs remain uncharacterized,with unidentified or unvalidated targets,and studies on additional snoRNA-associated proteins are limited. We adapted an enhanced chimeric eCLIP approach to comprehensively profile snoRNA-target RNA interactions using both core and accessory snoRNA-binding proteins as baits. Using core snoRNA-binding proteins,we confirmed most annotated snoRNA-rRNA and snoRNA-snRNA interactions in mouse and human cell lines and called novel,high-confidence interactions for orphan snoRNAs. While some of these interactions result in chemical modification,others may have modification-independent functions. We showed that snoRNA ribonucleoprotein complexes containing certain accessory proteins,like WDR43 and NOLC1,enriched for specific subsets of snoRNA-target RNA interactions with distinct roles in ribosome and spliceosome biogenesis. Notably,we discovered that SNORD89 guides 2′-O-methylation at two neighboring sites in U2 snRNA that fine-tune splice site recognition. Chimeric eCLIP of snoRNA-associating proteins enables a comprehensive framework for studying snoRNA-target interactions in an RNA-binding protein-dependent manner,revealing novel interactions and regulatory roles in RNA biogenesis. The online version contains supplementary material available at 10.1186/s13059-025-03508-7. View Publication

The targeting of cancer stem cells (CSCs) has proven to be an effective approach for limiting tumor progression,thus necessitating the identification of new drugs with anti-CSC activity. Through a high-throughput drug repositioning screen,we identify the antibiotic Nifuroxazide (NIF) as a potent anti-CSC compound. Utilizing a click chemistry strategy,we demonstrate that NIF is a prodrug that is specifically bioactivated in breast CSCs. Mechanistically,NIF-induced CSC death is a result of a synergistic action that combines the generation of DNA interstrand crosslinks with the inhibition of the Fanconi anemia (FA) pathway activity. NIF treatment mimics FA-deficiency through the inhibition of STAT3,which we identify as a non-canonical transcription factor of FA-related genes. NIF induces a chemical HRDness (Homologous Recombination Deficiency) in CSCs that (re)sensitizes breast cancers with innate or acquired resistance to PARP inhibitor (PARPi) in patient-derived xenograft models. Our results suggest that NIF may be useful in combination with PARPi for the treatment of breast tumors,regardless of their HRD status. Subject terms: Breast cancer,Mechanisms of disease,Target identification,Cancer stem cells View Publication

The clinical success of the immune checkpoint inhibitor (ICI) targeting programmed cell death protein 1 (PD-1) has revolutionized cancer treatment. However,the full potential of PD-1 blockade therapy remains unrealized,as response rates are still low across many cancer types. Interleukin-2 (IL-2)-based immunotherapies hold promise,as they can stimulate robust T cell expansion and enhance effector function - activities that could synergize potently with PD-1 blockade. Yet,IL-2 therapies also carry a significant drawback: they can trigger severe systemic toxicities and induce immune suppression by expanding regulatory T cells. To overcome the challenges of PD-1 blockade and IL-2 therapies while enhancing safety and efficacy,we have engineered a novel fusion protein,AWT020,combining a humanized anti-PD-1 nanobody and an engineered IL-2 mutein (IL-2c). The IL-2c component of AWT020 has been engineered to exhibit no binding to the IL-2 receptor alpha (IL-2Rα) subunit and attenuated affinity for the IL-2 receptor beta and gamma (IL-2Rβγ) complex,aiming to reduce systemic immune cell activation,thereby mitigating the severe toxicity often associated with IL-2 therapies. The anti-PD-1 antibody portion of AWT020 serves a dual purpose: it precisely delivers the IL-2c payload to tumor-infiltrating T cells while blocking the immune-inhibitory signals mediated by the PD-1 pathway. AWT020 showed significantly enhanced pSTAT5 signaling in PD-1 expressing cells and promoted the proliferation of activated T cells over natural killer (NK) cells. In preclinical studies using both anti-PD-1-sensitive and -resistant mouse tumor models,the mouse surrogate of AWT020 (mAWT020) demonstrated markedly enhanced anti-tumor efficacy compared to an anti-PD-1 antibody,IL-2,or the combination of an anti-PD-1 antibody and IL-2. In addition,the mAWT020 treatment was well-tolerated,with minimal signs of toxicity. Immune profiling revealed that mAWT020 preferentially expands CD8 + T cells within tumors,sparing peripheral T and NK cells. Notably,this selective tumoral T-cell stimulation enables potent tumor-specific T-cell responses,underscoring the molecule’s enhanced efficacy and safety. The AWT020 fusion protein offers a promising novel immunotherapeutic strategy by integrating PD-1 blockade and IL-2 signaling,conferring enhanced anti-tumor activity with reduced toxicity. View Publication

Pancreatic cancer is one of the most malignant cancers,and limited therapeutic options are available. The induction of ferroptosis is considered to be a novel,promising strategy that has potential in cancer treatment,and ferroptosis inducers may be new options for eradicating malignant cancers that are resistant to traditional drugs. The exact mechanism underlying the function of sorcin in the initiation and progression of pancreatic cancer remains unclear. The expression of sorcin in cancer tissues was assessed by analyzing TCGA,GEO and immunohistochemical staining data,and the function of sorcin in the induction of ferroptosis in pancreatic cancer cells was investigated. The mechanism underlying the function of sorcin was revealed through proteomics,co-IP,Ch-IP,and luciferase assays. Natural product screening was subsequently performed to screen for products that interact with sorcin to identify new ferroptosis inducers. We first showed that sorcin expression was positively correlated with the survival and tumor stages of patients with pancreatic cancer,and we revealed that sorcin inhibited ferroptosis through its noncalcium binding function. Furthermore,we discovered that sorcin interacted with PAX5 in the cytoplasm and inhibited PAX5 nuclear translocation,which in turn decreased FBXL12 protein expression and then reduced ALDH1A1 ubiquitination,thus inhibiting ferroptosis. Moreover,an in-house natural product screen revealed that celastrol inhibited the interaction of sorcin and PAX5 by directly binding to the Cys194 residue of the sorcin protein; disruption of the sorcin-PAX5 interaction promoted the nuclear translocation of PAX5,induced the expression of FBXL12,increased the ubiquitylation of ALDH1A1,and eventually induced ferroptosis in pancreatic cancer cells. In this study,we revealed the mechanism of action of sorcin,which is a druggable target for inducing ferroptosis,we identified celastrol as a novel agent that induces ferroptosis,and we showed that disrupting the sorcin-PAX5 interaction is a promising therapeutic strategy for treating pancreatic cancer. The online version contains supplementary material available at 10.1186/s13045-025-01680-8. View Publication

Overall survival of acute myeloid leukemia (AML) remains limited. Inhibitors of the master mitotic kinase PLK1 have emerged as promising therapeutics,demonstrating efficacy in an undefined subset of patients with AML. However,the clinical success of PLK1 inhibitors remains hindered by a lack of predictive biomarkers. The Fanconi anemia (FA) pathway,a tumor-suppressive network comprised of at least 22 genes,is frequently mutated in sporadic AML. In this study,we demonstrate that FA pathway disruption sensitizes AML cells to PLK1 inhibition. Mechanistically,we identify novel interactions between PLK1 and both FANCA and FANCD2 at mitotic centromeres. We demonstrate that PLK1 inhibition impairs recruitment of FANCD2 to mitotic centromeres,induces damage to mitotic chromosomes,and triggers mitotic collapse in FANCA-deficient cells. Our findings indicate that PLK1 inhibition targets mitotic vulnerabilities specific to FA pathway–deficient cells and implicate FA pathway mutations as potential biomarkers for the identification of patients likely to benefit from PLK1 inhibitors. This work demonstrates that FA pathway mutations,which are frequently observed in sporadic AML,induce hypersensitivity to PLK1 inhibition,providing rationale for a novel synthetic lethal therapeutic strategy for this patient population. View Publication

Clinical translation of tissue-engineered advanced therapeutic medicinal products is hindered by a lack of patient-dependent and independent in-process biological quality controls that are reflective of in vivo outcomes. Recent insights into the mechanism of native bone repair highlight a robust path dependence. Organoid-based bottom-up developmental engineering mimics this path-dependence to design personalized living implants scaffold-free,with in-build outcome predictability. Yet,adequate (noninvasive) quality metrics of engineered tissues are lacking. Moreover,insufficient insight into the role of donor variability and biological sex as influencing factors for the mechanism toward bone repair hinders the implementation of such protocols for personalized bone implants. Here,male and female bone-forming organoids were compared to non-bone-forming organoids regarding their extracellular matrix composition,transcriptome,and secreted proteome signatures to directly link in vivo outcomes to quality metrics. As a result,donor variability in bone-forming callus organoids pointed towards two distinct pathways to bone,through either a hypertrophic cartilage or a fibrocartilaginous template. The followed pathway was determined early,as a biological sex-dependent activation of distinct progenitor populations. Independent of donor or biological sex,a cartilage-to-bone transition was driven by a common panel of secreted factors that played a role in extracellular matrix remodeling,mineralization,and attraction of vasculature. Hence,the secreted proteome is a source of noninvasive biomarkers that report on biological potency and could be the missing link toward data-driven decision-making in organoid-based bone tissue engineering. Subject terms: Bone,Bone quality and biomechanics View Publication