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Using a high-throughput chemical screen,we identified two small molecules that enhance the survival of human embryonic stem cells (hESCs). By characterizing their mechanisms of action,we discovered an essential role of E-cadherin signaling for ESC survival. Specifically,we showed that the primary cause of hESC death following enzymatic dissociation comes from an irreparable disruption of E-cadherin signaling,which then leads to a fatal perturbation of integrin signaling. Furthermore,we found that stability of E-cadherin and the resulting survival of ESCs were controlled by specific growth factor signaling. Finally,we generated mESC-like hESCs by culturing them in mESC conditions. And these converted hESCs rely more on E-cadherin signaling and significantly less on integrin signaling. Our data suggest that differential usage of cell adhesion systems by ESCs to maintain self-renewal may explain their profound differences in terms of morphology,growth factor requirement,and sensitivity to enzymatic cell dissociation. View Publication

The molecular basis for the unique proliferative and self-renewal properties that hierarchically distinguish human stem cells from progenitors and terminally differentiated cells remains largely unknown. We report a role for the Bcl-2 family member myeloid cell leukemia-1 (Mcl-1) as an indispensable regulator of self-renewal in human stem cells and show that a functional dependence on Mcl-1 defines the human stem cell hierarchy. In vivo pharmacologic targeting of the Bcl-2 family members in human hematopoietic stem cells (HSCs) and human leukemic stem cells reduced stem cell regenerative and self-renewal function. Subsequent protein expression studies showed that,among the Bcl-2 family members,only Mcl-1 was up-regulated exclusively in the human HSC fraction on in vivo regeneration of hematopoiesis. Short hairpin RNA-knockdown of Mcl-1 in human cord blood cells did not affect survival in the HSC or hematopoietic progenitor cell fractions in vitro but specifically reduced the in vivo self-renewal function of human HSCs. Moreover,knockdown of Mcl-1 in ontogenetically primitive human pluripotent stem cells resulted in almost complete ablation of stem cell self-renewal function. Our findings show that Mcl-1 is an essential regulator of stem cell self-renewal in humans and therefore represents an axis for therapeutic interventions. View Publication

The sympathetic (SNS) and parasympathetic (PNS) branches of the autonomic nervous system have been implicated in the modulation of the renewal of many tissues,including the intestinal epithelium. However,it is not known whether these mechanisms are direct,requiring an interaction between autonomic neurotransmitters and receptors on proliferating epithelial cells. To evaluate the existence of a molecular framework for a direct effect of the SNS or PNS on intestinal epithelial renewal,we measured gene expression for the main autonomic neurotransmitter receptors in this tissue. We separately evaluated intestinal epithelial regions comprised of the stem,progenitor,and mature cells,which allowed us to investigate the distinct contributions of each cell population to this proposed autonomic effect. Notably,we found that the stem cells expressed the receptors for the SNS-associated alpha2A adrenoreceptor and the PNS-associated muscarinic acetylcholine receptors (M1 and M3). In a separate experiment,we found that the application of norepinephrine or acetylcholine decreases the expression of cyclin D1,a gene necessary for cell cycle progression,in intestinal epithelial organoids compared with controls (P {\textless} 0.05). Together,these results provide evidence of a direct mechanism for the autonomic nervous system influence on intestinal epithelial stem cell proliferation. View Publication

When transmitted through the oral route,Toxoplasma gondii first interacts with its host at the small intestinal epithelium. This interaction is crucial to controlling initial invasion and replication,as well as shaping the quality of the systemic immune response. It is therefore an attractive target for the design of novel vaccines and adjuvants. However,due to a lack of tractable infection models,we understand surprisingly little about the molecular pathways that govern this interaction. The in vitro culture of small intestinal epithelium as 3D enteroids shows great promise for modeling the epithelial response to infection. However,the enclosed luminal space makes the application of infectious agents to the apical epithelial surface challenging. Here,we have developed three novel enteroid-based techniques for modeling T. gondii infection. In particular,we have adapted enteroid culture protocols to generate collagen-supported epithelial sheets with an exposed apical surface. These cultures retain epithelial polarization,and the presence of fully differentiated epithelial cell populations. They are susceptible to infection with,and support replication of,T. gondii. Using quantitative label-free mass spectrometry,we show that T. gondii infection of the enteroid epithelium is associated with up-regulation of proteins associated with cholesterol metabolism,extracellular exosomes,intermicrovillar adhesion,and cell junctions. Inhibition of host cholesterol and isoprenoid biosynthesis with Atorvastatin resulted in a reduction in parasite load only at higher doses,indicating that de novo synthesis may support,but is not required for,parasite replication. These novel models therefore offer tractable tools for investigating how interactions between T. gondii and the host intestinal epithelium influence the course of infection. View Publication

Previous studies have shown that aggregated alpha-synuclein (α-s) protein,a key pathological marker of Parkinson’s disease (PD),can propagate between cells,thus participating in disease progression. This prion-like propagation has been widely studied using in vivo and in vitro models,including rodent and human cell cultures. In this study,our focus was on temporal assessment of functional changes during α-s aggregation and propagation in human induced pluripotent stem cell (hiPSC)-derived neuronal cultures and in engineered networks. Here,we report an engineered circular tripartite human neuronal network model in a microfluidic chip integrated with microelectrode arrays (MEAs) as a platform to study functional markers during α-s aggregation and propagation. We observed progressive aggregation of α-s in conventional neuronal cultures and in the exposed (proximal) compartments of circular tripartite networks following exposure to preformed α-s fibrils (PFF). Furthermore,aggregated forms propagated to distal compartments of the circular tripartite networks through axonal transport. We observed impacts of α-s aggregation on both the structure and function of neuronal cells,such as in presynaptic proteins,mitochondrial motility,calcium oscillations and neuronal activity. The model enabled an assessment of the early,middle,and late phases of α-s aggregation and its propagation during a 13-day follow-up period. While our temporal analysis suggested a complex interplay of structural and functional changes during the in vitro propagation of α-s aggregates,further investigation is required to elucidate the underlying mechanisms. Taken together,this study demonstrates the technical potential of our introduced model for conducting in-depth analyses for revealing such mechanisms. Subject terms: Parkinson's disease,Neurological models View Publication

The COVID-19 pandemic has created a global health crisis,with challenges arising from the ongoing evolution of the SARS-CoV-2 virus,the emergence of new strains,and the long-term effects of COVID-19. Aiming to overcome the development of viral resistance,our study here focused on developing broad-spectrum pan-coronavirus antiviral therapies by targeting host protein quality control mechanisms essential for viral replication. Screening an in-house compound library led to the discovery of three candidate compounds targeting cellular proteostasis. The three compounds are (1) the nucleotide analog cordycepin,(2) a benzothiozole analog,and (3) an acyldepsipeptide analog initially developed as part of a campaign to target the mitochondrial ClpP protease. These compounds demonstrated dose-dependent efficacy against multiple coronaviruses,including SARS-CoV-2,effectively inhibiting viral replication in vitro as well as in lung organoids. Notably,the compounds also showed efficacy against SARS-CoV-2 delta and omicron strains. As part of this work,we developed a BSL2-level cell-integrated SARS-CoV-2 replicon,which could serve as a valuable tool for high-throughput screening and studying intracellular viral replication. Our study should aid in the advancement of antiviral drug development efforts. Subject terms: High-throughput screening,Small molecules View Publication

Chronic lymphocytic leukemia is a malignant lymphoproliferative disorder for which primary or acquired drug resistance represents a major challenge. To investigate the underlying molecular mechanisms,we generate a mouse model of ibrutinib resistance,in which,after initial treatment response,relapse under therapy occurrs with an aggressive outgrowth of malignant cells,resembling observations in patients. A comparative analysis of exome,transcriptome and proteome of sorted leukemic murine cells during treatment and after relapse suggests alterations in the proteasome activity as a driver of ibrutinib resistance. Preclinical treatment with the irreversible proteasome inhibitor carfilzomib administered upon ibrutinib resistance prolongs survival of mice. Longitudinal proteomic analysis of ibrutinib-resistant patients identifies deregulation in protein post-translational modifications. Additionally,cells from ibrutinib-resistant patients effectively respond to several proteasome inhibitors in co-culture assays. Altogether,our results from orthogonal omics approaches identify proteasome inhibition as potentially attractive treatment for chronic lymphocytic leukemia patients resistant or refractory to ibrutinib. The molecular mechanisms underlying resistance to therapy in Chronic lymphocytic leukemia (CLL) remain to be explored. Here,the authors perform multi-omics analysis in a mouse model of ibrutinib resistance and suggest proteasome inhibition for overcoming it. View Publication

Seven female individuals with multiple congenital anomalies,developmental delay and/or intellectual disability have been found to have a genetic variant of uncertain significance in the mediator complex subunit 12 gene ( MED12 c.3412C>T,p.Arg1138Trp). The functional consequence of this genetic variant in disease is undetermined,and insight into disease mechanism is required. We identified a de novo MED12 p.Arg1138Trp variant in a female patient and compared disease phenotypes with six female individuals identified in the literature. To investigate affected biological pathways,we derived two induced pluripotent stem cell (iPSC) lines from the patient: one expressing wildtype MED12 and the other expressing the MED12 p.Arg1138Trp variant. We performed neural disease modelling,transcriptomics and protein analysis,comparing healthy and variant cells. When comparing the two cell lines,we identified altered gene expression in neural cells expressing the variant,including genes regulating RNA polymerase II activity,transcription,pre-mRNA processing,and neural development. We also noted a decrease in MED12L expression. Pathway analysis indicated temporal delays in axon development,forebrain differentiation,and neural cell specification with significant upregulation of pre-ribosome complex gene pathways. In a human neural model,expression of MED12 p.Arg1138Trp altered neural cell development and dysregulated the pre-ribosome complex providing functional evidence of disease aetiology and mechanism in MED12-related disorders. The online version contains supplementary material available at 10.1186/s10020-025-01365-5. View Publication

Endogenous long double-stranded RNAs (dsRNAs),which are not edited by the RNA editing enzyme ADAR1,may activate the antiviral dsRNA receptor MDA5 to trigger interferon-mediated immune responses. Among the large number of endogenous long dsRNAs,the key substrates that activate MDA5—termed as immunogenic dsRNAs—remain largely unidentified. Here we reveal that human immunogenic dsRNAs constitute a surprisingly small fraction of all cellular dsRNAs. We found that these immunogenic dsRNAs were highly enriched in mRNAs and depleted of introns,consistent with their role as cytosolic MDA5 substrates. We validated the MDA5-dependent immunogenicity of these dsRNAs,which was dampened following ADAR1-mediated RNA editing. Notably,immunogenic dsRNAs were enriched at genetic susceptibility loci associated with common inflammatory diseases,implying their functional importance. We anticipate that a focused analysis of immunogenic dsRNAs will enhance our understanding and treatment of cancer and inflammatory diseases,where the roles of dsRNA editing and sensing are increasingly recognized. The authors show that only a small subset of cytosolic double-stranded RNAs (dsRNAs) requires ADAR1-mediated RNA editing to evade an MDA5-dependent immune response. These immunogenic dsRNAs are enriched in mRNAs and overlap with GWAS signals for common inflammatory diseases. View Publication

In the CNS,oligodendrocytes act as the myelinating cells. Oligodendrocytes have been identified to be key players in several neurodegenerative disorders. This protocol describes a robust,fast and reproducible differentiation protocol to generate human oligodendrocytes from pluripotent stem cells (PSCs) using a chemically defined,growth factor-rich medium. Within 8 d,PSCs differentiate into paired box 6-positive (PAX6(+)) neural stem cells,which give rise to OLIG2(+) progenitors by day 12. Oligodendrocyte lineage transcription factor 2-positive (OLIG2(+)) cells begin to express the transcription factor NKX2.2 around day 18,followed by SRY-box 10 (SOX10) around day 40. Oligodendrocyte progenitor cells (OPCs) that are positive for the cell surface antigen recognized by the O4 antibody (O4(+)) appear around day 50 and reach,on average,43% of the cell population after 75 d of differentiation. O4(+) OPCs can be isolated by cell sorting for myelination studies,or they can be terminally differentiated to myelin basic protein-positive (MBP(+)) oligodendrocytes. This protocol also describes an alternative strategy for markedly reducing the length and the costs of the differentiation and generating ∼30% O4(+) cells after only 55 d of culture. View Publication

Transplantation of ex vivo expanded corneal limbal stem cells (LSCs) has been the main treatment for limbal stem cell deficiency,although the shortage of donor corneal tissues remains a major concern for its wide application. Due to the development of tissue engineering,embryonic stem cells (ESCs)-derived corneal epithelial-like cells (ESC-CECs) become a new direction for this issue. However,the immunogenicity of ESC-CECs is a critical matter to be solved. In the present study,we explored the immunological properties of ESC-CECs,which were differentiated from ESCs. The results showed that ESC-CECs had a similar character and function with LSCs both in vitro and in vivo. In ESC-CECs,a large number of genes related with immune response were down-regulated. The expressions of MHC-I,MHC-II,and co-stimulatory molecules were low,but the expression of HLA-G was high. The ESC-CECs were less responsible for T cell proliferation and NK cell lysis in vitro,and there was less immune cell infiltration after transplantation in vivo compared with LSCs. Moreover,the immunological properties were not affected by interferon-$$. All these results indicated a low immunogenicity of ESC-CECs,and they can be promising in clinical use. View Publication

Differentiation of pluripotent stem cells into cells of the definitive endoderm requires an in vitro gastrulation event. Differentiated somatic cells derived from this germ layer may then be used for cell replacement therapies of degenerative diseases of the liver,lung,and pancreas. Here we describe an endoderm differentiation protocol,which initiates the differentiation from a defined cell number of dispersed single cells and reliably yields in textgreater70-80 % endoderm-committed cells in a short 5-day treatment regimen. View Publication