技术资料

Melanoma brain metastasis is linked to dismal prognosis and low overall survival and is detected in up to 80% of patients at autopsy. Circulating tumor cells (CTC) are the smallest functional units of cancer and precursors of fatal metastasis. We previously used an unbiased multilevel approach to discover a unique ribosomal protein large/small subunit (RPL/RPS) CTC gene signature associated with melanoma brain metastasis. In this study,we hypothesized that CTC-driven melanoma brain metastasis secondary metastasis (“metastasis of metastasis” per clinical scenarios) has targeted organ specificity for the liver. We injected parallel cohorts of immunodeficient and newly developed humanized NBSGW (huNBSGW) mice with cells from CTC-derived melanoma brain metastasis to identify secondary metastatic patterns. We found the presence of a melanoma brain–liver metastasis axis in huNBSGW mice. Furthermore,RNA sequencing analysis of tissues showed a significant upregulation of the RPL/RPS CTC gene signature linked to metastatic spread to the liver. Additional RNA sequencing of CTCs from huNBSGW blood revealed extensive CTC clustering with human B cells in these mice. CTC:B-cell clusters were also upregulated in the blood of patients with primary melanoma and maintained either in CTC-driven melanoma brain metastasis or melanoma brain metastasis CTC–derived cells promoting liver metastasis. CTC-generated tumor tissues were interrogated at single-cell gene and protein expression levels (10x Genomics Xenium and HALO spatial biology platforms,respectively). Collectively,our findings suggest that heterotypic CTC:B-cell interactions can be critical at multiple stages of metastasis. This study provides important insights into the relevance of prometastatic CTC:B-cell clusters in melanoma progression,extends the importance of the CTC RPL/RPS gene signature beyond primary metastasis/melanoma brain metastasis driving targeted organ specificity for liver metastasis (“metastasis of metastasis”),and identifies new targets for clinical melanoma metastasis therapies. View Publication

Borrelia (or Borreliella ) burgdorferi,the causative agent of Lyme disease,is a motile and invasive zoonotic pathogen adept at navigating between its arthropod vector and mammalian host. While motility and chemotaxis are well known to be essential for its enzootic cycle,the role of each methyl-accepting chemotaxis proteins (MCPs) in the infectious cycle of B . burgdorferi remains unclear. In this study,we show that mcp5,a gene encoding one of the most abundant MCPs in B . burgdorferi,is differentially expressed in response to environmental signals and at distinct stages of the pathogen’s enzootic cycle. Notably,mcp5 expression is regulated by the Hk1-Rrp1 and Rrp2-RpoN-RpoS pathways,two key regulatory pathways that are critical for the spirochete’s colonization of the tick vector and mammalian host,respectively. Infection experiments with an mcp5 mutant revealed that spirochetes lacking MCP5 were unable to establish infections in either C3H/HeN mice or Severe Combined Immunodeficiency (SCID) mice,which are deficient in adaptive immunity,underscoring MCP5’s critical role in mammalian infection. However,the mcp5 mutant was able to establish infection and disseminate in NOD SCID Gamma (NSG) mice,which are deficient in both adaptive and most innate immune responses,suggesting that MCP5 plays an important role in evading host innate immunity. Moreover,NK cell depletion in C3H and SCID mice restored the infectivity of the mcp5 mutant,further highlighting MCP5’s role in evading NK cell-associated immunity. Co-culture assays with NK cells and macrophages revealed that the mcp5 mutant enhanced interferon-gamma production by NK cells. In the tick vector,the mcp5 mutants survived feeding but failed to transmit to mice. These findings reveal that MCP5,regulated by both the Rrp1 and Rrp2 pathways,is critical for establishing infection in mammalian hosts by evading NK cell-mediated host innate immunity and is important for the transmission of spirochetes from ticks to mammalian hosts. This work provides a foundation for further elucidation of chemotactic signals sensed by MCP5 that facilitate B . burgdorferi in evading host defenses. View Publication

Introduction: Pathogenic variants in the OFD1 gene are linked to a spectrum of syndromes that exhibit partial clinical overlap. Hemizygous loss-of-function variants are considered lethal in males,while heterozygous loss-of-function variants generally result in oro-facial-digital syndrome type 1. A reported phenotype,Simpson–Golabi–Behmel syndrome type 2,was published once but remains controversial,with many specialists questioning its validity and arguing about its continued listing in the OMIM database. Methods: To investigate the genetic and phenotypic characteristics of the patients,we performed clinical exome sequencing,family-based genetic analysis,X-inactivation studies,electron microscopy,and detailed clinical assessments. Results: Three patients from unrelated families carrying loss-of-function variants in the OFD1 gene were identified,emphasizing the diverse phenotypic spectrum of OFD1 -associated disorders. The first patient,a female with a heterozygous frameshift variant p.(Gln398LeufsTer2),was diagnosed with oro-facial-digital syndrome type 1. The second patient,a male with a heterozygous nonsense variant p.(Gln892Ter),presented with features resembling Simpson–Golabi–Behmel syndrome type 2,as previously reported under this diagnosis. The third patient,a male with another heterozygous nonsense variant p.(Glu879Ter),exhibited isolated primary ciliary dyskinesia without any syndromic features. Conclusions: This study contributes to the growing body of evidence on the expanding phenotypic spectrum of OFD1 -associated disorders. It underscores the need for further investigation into the molecular mechanisms underlying the diverse presentations and the necessity of re-evaluating diagnostic classifications for conditions such as SGBS2 in the context of variants in the OFD1 gene. View Publication

Cancer stem cells (CSCs) play a key role in non-small cell lung cancer (NSCLC) chemoresistance and metastasis. In this study,we used two NSCLC cell lines to investigate the regulating effect of hypoxia in the induction and maintenance of CSC traits. Our study demonstrated hypoxia-induced stemness and chemoresistance at levels comparable to those in typical CSC sphere culture. Activation of the NF-κB pathway (by transfection of NF-κB-p65) plays a key role in NSCLC CSCs and chemoresistance. Disulfiram (DS),an anti-alcoholism drug,showed a strong in vitro anti-CSC effect. It blocked cancer cell sphere reformation and clonogenicity,synergistically enhanced the cytotoxicity of four anti-NSCLC drugs (doxorubicin,gemcitabine,oxaliplatin and paclitaxel) and reversed hypoxia-induced resistance. The effect of DS on CSCs is copper-dependent. A very short half-life in the bloodstream is the major limitation for the translation of DS into a cancer treatment. Our team previously developed a poly lactic-co-glycolic acid (PLGA) nanoparticle encapsulated DS (DS-PLGA) with a long half-life in the bloodstream. Intra venous injection of DS-PLGA in combination with the oral application of copper gluconate has strong anticancer efficacy in a metastatic NSCLC mouse model. Further study may be able to translate DS-PLGA into cancer applications. View Publication

Previous studies have indicated that the presence of cancer stem cells may be a contributing factor to the development of metastasis in colorectal cancer patients. Cancer stem cells represent a small subpopulation within the tumor mass that exhibits heightened resistance to treatment and possesses the capacity for self-replication,epithelial–mesenchymal transition,and the generation of new tumors. The tumor microenvironment secretes and releases several molecules that facilitate the self-renewal of cancer stem cells and provide support for colorectal cancer progression. microRNAs are involved in direct cell-to-cell signaling and paracrine signaling between tumor cells and other tumor microenvironment components. They could act as tumor suppressors or oncomiRs,and their deregulation is involved in colorectal cancer progression and cancer stem cell formation. In our previous studies,we demonstrated the oncosuppressive function of miR-486-5p in colorectal cancer; these findings prompted us to conduct a more detailed investigation into its role in cancer stem cell phenotypes. Background: Colorectal cancer (CRC) is the third diagnosed cancer worldwide. Forty-four percent of metastatic colorectal cancer patients were diagnosed at an early stage. Despite curative resection,approximately 40% of patients will develop metastases within a few years. Previous studies indicate the presence of cancer stem cells (CSCs) and their contribution to CRC progression and metastasis. miRNAs deregulation plays a role in CSCs formation and in tumor development. In light of previous studies,we investigated the role of miR-486-5p to understand its role in CSC better. Methods: The expression of miR-486-5p was assessed in adherent cells and spheres generated from two CRC cell lines to observe the difference in expression in CSC-enriched spheroids. Afterward,we overexpressed and underexpressed this miRNA in adherent and sphere cultures through the transfection of a miR-486-5p mimic and a mimic inhibitor. Results: The results demonstrated that miR-486-5p exhibited a notable downregulation in CSC models,and its overexpression led to a significant decrease in colony size. Conclusions: In this study,we confirmed that miR-486-5p plays an oncosuppressive role in CRC,thereby advancing our understanding of the role of this microRNA in the CSC phenotype. View Publication

Polo-like kinase 1 (PLK1),a key regulator of the G2/M phase in mitosis,is frequently overexpressed in numerous tumors. Although PLK1 inhibitors have emerged as promising therapeutic agents for cancer,their use has been linked to significant anemia in a subset of patients,yet the underlying mechanisms remain poorly understood. In this study,we utilized an in vitro human umbilical cord blood-derived CD34 + cell-based erythroid differentiation system,alongside a murine model,to investigate the impact of PLK1 inhibitors on erythropoiesis. Our results indicate that PLK1 inhibitors,specifically GSK461364 and BI6727,significantly suppress the proliferation of erythroid cells,resulting in G2/M phase cell cycle arrest,increased apoptosis in erythroid cells,and the formation of abnormally nucleated late-stage erythroblasts. In vivo,administration of PLK1 inhibitors in mice induced severe anemia,as evidenced by a marked reduction in red blood cells and hemoglobin levels. More specifically,PLK1 inhibition impaired the differentiation and erythroid commitment of hematopoietic stem cells in the bone marrow,resulting in abnormal accumulation of BFU-E cells and reduced proliferation and differentiation of CFU-E,and a decrease in the number of terminal erythrocytes. Mechanistically,PLK1 inhibitors primarily induce apoptosis in erythroid cells by reducing Mitochondrial membrane potential and arresting the cell cycle at the G2/M phase. Overall,our findings underscore the critical role of PLK1 in erythropoiesis and shed light on the mechanisms underlying PLK1 inhibitor-induced anemia,providing essential guidance for developing strategies to prevent and manage anemia in clinical applications of PLK1-targeted therapies. View Publication

Human norovirus (HuNoV) is a major cause of enteric infectious gastroenteritis and is classified into several genotypes based on its capsid protein amino acid sequence and nucleotide sequence of the polymerase gene. Among these,GII.4 is the major genotype worldwide. Epidemiological studies have highlighted the prevalence of GII.2. Although recent advances using human tissue– and induced pluripotent stem cell (iPSC)–derived intestinal epithelial cells (IECs) have enabled in vitro replication of multiple HuNoV genotypes,GII.2 HuNoV could replicate only in tissue-derived IECs and not in iPSC-derived IECs. We investigated the factors influencing GII.2 HuNoV replication in IECs,focusing on histo-blood group antigens. We also assessed the immunogenicity of GII.2 virus-like particles (VLPs) and their ability to induce neutralizing antibodies. Antibody cross-reactivity was tested to determine whether GII.2 VLPs could neutralize other HuNoV genotypes,including GII.4,GII.3,GII.6,and GII.17. Our findings indicated that GII.2 HuNoV replication in vitro requires the presence of both H and B antigens. Moreover,GII.2 VLPs generated neutralizing antibodies effective against both GII.2 and GII.4 but not against GII.3,GII.6,or GII.17. Comparatively,GII.2 and GII.17 VLPs induced broader neutralizing responses than GII.4 VLPs. The findings of this study suggests that GII.2 and GII.17 VLPs may be advantageous as HuNoV vaccine candidates because they elicit neutralizing antibodies against the predominant GII.4 genotype,which could be particularly beneficial for infants without prior HuNoV exposure. These insights will contribute to the development of effective HuNoV vaccines. View Publication

Genome editing using CRISPR-Cas systems is a promising avenue for the treatment of genetic diseases. However,cellular and humoral immunogenicity of genome editing tools,which originate from bacteria,complicates their clinical use. Here we report reduced immunogenicity (Red)(i)-variants of two clinically relevant nucleases,SaCas9 and AsCas12a. Through MHC-associated peptide proteomics (MAPPs) analysis,we identify putative immunogenic epitopes on each nuclease. Using computational modeling,we rationally design these proteins to evade the immune response. SaCas9 and AsCas12a Redi variants are substantially less recognized by adaptive immune components,including reduced binding affinity to MHC molecules and attenuated generation of cytotoxic T cell responses,yet maintain wild-type levels of activity and specificity. In vivo editing of PCSK9 with SaCas9.Redi.1 is comparable in efficiency to wild-type SaCas9,but significantly reduces undesired immune responses. This demonstrates the utility of this approach in engineering proteins to evade immune detection. Subject terms: Protein design,Immunogenetics,CRISPR-Cas9 genome editing View Publication

Optical aberrations hinder fluorescence microscopy of thick samples,reducing image signal,contrast,and resolution. Here we introduce a deep learning-based strategy for aberration compensation,improving image quality without slowing image acquisition,applying additional dose,or introducing more optics. Our method (i) introduces synthetic aberrations to images acquired on the shallow side of image stacks,making them resemble those acquired deeper into the volume and (ii) trains neural networks to reverse the effect of these aberrations. We use simulations and experiments to show that applying the trained ‘de-aberration’ networks outperforms alternative methods,providing restoration on par with adaptive optics techniques; and subsequently apply the networks to diverse datasets captured with confocal,light-sheet,multi-photon,and super-resolution microscopy. In all cases,the improved quality of the restored data facilitates qualitative image inspection and improves downstream image quantitation,including orientational analysis of blood vessels in mouse tissue and improved membrane and nuclear segmentation in C. elegans embryos. Subject terms: Microscopy,Fluorescence imaging View Publication

Th2 inflammation and epithelial-mesenchymal transition (EMT) play crucial roles in the pathophysiology of chronic rhinosinusitis with nasal polyps (CRSwNP). This study aimed to investigate the hypothesis that MMP-12,produced by M2 macrophages,induces EMT in nasal epithelial cells,thereby contributing to airway inflammation and remodeling in CRSwNP. The expression levels of MMP-12 were measured by RT-PCR in CRS nasal mucosa and THP-1 cells. mRNA and protein levels of E-cadherin,vimentin,α-SMA,and fibronectin were determined using RT-PCR,western blotting,and immunofluorescence staining in primary nasal epithelial cells and air-liquid interface culture. The expression of MMP-12 was significantly increased in CRSwNP and M2-like THP-1 cells. In co-culture with primary nasal epithelial cells and M2-like THP-1 cells,E-cadherin expression was inhibited,and fibronectin,vimentin,and α-SMA expression were increased. MMP-12 decreased E-cadherin but induced fibronectin,vimentin,and α-SMA mRNA and protein expression in primary nasal epithelial cells and air-liquid interface culture. MMP408,an MMP-12 inhibitor,inhibited EMT-related factors. These findings suggest that MMP-12 expression in M2 macrophages induces EMT in nasal epithelial cells and may contribute to the pathogenesis of CRSwNP. View Publication

Micropapillary adenocarcinoma (MPC) is an aggressive histological subtype of lung adenocarcinoma (LUAD). MPC is composed of small clusters of cancer cells exhibiting inverted polarity. However,the mechanism underlying its formation is poorly understood. Here we show that hypoxia is involved in MPC formation. Hypoxia induced the formation of MPC-like structures (MLSs) in a three-dimensional culture system using A549 human LUAD cells,and HIF-1α was indispensable for MLS formation. RNA sequencing analysis demonstrated that A549 cells forming MLSs exhibited a gene expression signature similar to that of lung MPC. Moreover,MLS formation enhanced the resistance of A549 cells to natural killer cell cytotoxicity. Our findings suggest that hypoxia drives lung MPC formation through HIF-1α and that immune escape from natural killer cells might underlie the aggressiveness of MPC. View Publication

Apigenin (API),a traditionally sourced flavonoid,is recognized for its anti-neoplastic properties. Despite well-documented effects on tumorigenesis,the detailed therapeutic impact on breast cancer stem cells (BCSCs) and the associated molecular mechanisms are yet to be clarified. The objective of this study is to elucidate the therapeutic effects of API on BCSCs and to uncover its molecular mechanisms through network pharmacology and experimental validation. Interactions of API with candidate targets were examined through target screening,enrichment analysis,construction of protein-protein interaction networks,and molecular docking. MCF-7-derived BCSCs were utilized as a model system to investigate and substantiate the anti-BCSC effects of API and the underlying mechanism. Molecular docking studies have shown that API and TP53 exhibit favorable binding affinity. Compared with the negative control group,API effectively suppressed the expression of BCSC-related proteins such as ALDH1A1,NANOG,EpCAM,and MYC,downregulated p-PI3K and p-AKT,and upregulated p53. This study demonstrates that API can play an anti-BCSC role by regulating the PI3K/AKT/p53 pathway in BCSCs of MCF-7 cells,highlighting its potential as a therapeutic agent for targeting BCSCs. View Publication