技术资料

Neoscytalidium dimidiatum is a non-dermatophyte mold that commonly causes skin and nail infections in tropical regions and often resists conventional antifungal therapies. Because its clinical and laboratory features often resemble dermatophyte infections,diagnosis is frequently delayed and treatment is sometimes inappropriate. We therefore developed a dot-immunobinding assay (Dot-Iba) to detect N. dimidiatum antigens. We generated a highly specific monoclonal antibody,3E6F7 (MAb 3E6F7),for antigen capture,and used goat anti-mouse Ig conjugated with alkaline phosphatase (AP) as the signal generator. The test pad comprised a test hole,a nitrocellulose membrane (NC),and water-absorbent pads in a vertical flow-through format to allow a rapid antigen–antibody reaction. The assembled system detected N. dimidiatum antigens in vitro with high specificity and yielded visible results within 2 h; its detection limit was 0.9 µg without cross-reactivity to dermatophyte or non-dermatophyte fungi. This rapid,specific,and easy-to-use assay shows strong potential as a diagnostic tool,particularly in settings with limited access to fungal culture or advanced molecular diagnostics,where early,accurate identification is crucial. View Publication

Understanding how chemical stress perturbs human lung physiology requires models that capture dynamic molecular responses in real time. Here,we established a CRISPR/Cas9-engineered human induced pluripotent stem cell (hiPSC)-derived lung organoid expressing endogenous G3BP1–mCherry,enabling live,non-destructive visualization of stress granule (SG) formation under toxicant exposure. The organoids recapitulated airway and alveolar epithelial diversity and displayed lamellar body-like ultrastructures,indicating advanced maturation. Time-lapse imaging revealed rapid and reversible SG dynamics across chemically distinct stressors,while cytotoxicity assays showed that these organoids are significantly more sensitive than conventional 2D or cancer-derived lung models. Importantly,SG dynamics were linked to exposure duration–dependent changes in epithelial barrier integrity,indicating that SG formation precedes overt epithelial injury and serves as an early indicator of toxicant-induced cellular stress. Integration with high-content screening enabled quantitative,image-based analysis of cellular stress phenotypes,greatly enhancing throughput and mechanistic insight,thereby provided next-generation New Approach Methodologies for lung toxicity assessment. Together,this hiPSC-derived lung organoid SG reporter platform links early molecular stress adaptation to tissue-level responses,offering a predictive and mechanistically informative framework for human-relevant lung toxicity evaluation. View Publication

Background: Lenalidomide is an immunomodulatory drug approved in the treatment of autoimmune disease,inflammation,and cancer. Its impact continues to grow due to its diverse spectrum of effects hampered only by toxicities and reduced efficacy. Therefore,development of strategies that enhance function while reducing drawbacks remains a prime goal. Objective and Hypothesis: The mechanisms of action of lenalidomide on the activity of natural killer cells (NK cells) remains understudied yet could be critical for the development of strategies to enhance its efficacy. These cells are critical drivers of anti-tumor immune responses which are often functionally suppressed in malignancies. NK cell and T cell survival and function is driven by the IL-2 family of cytokines (IL-2 or IL-15) and work has shown that lenalidomide potentially works by increasing the secretion of IL-2 by other lymphocytes,such as CD4+ T helper cells. Thus,we hypothesized that improving NK activity with IL-2 family of cytokines could lead to enhanced lenalidomide-induced responses of these cells. Results: We show that lenalidomide does not affect NK cell viability but reduces their proliferation through cell cycle arrest which could be overcome by exogenous addition of IL-2 family of cytokines. Moreover,lenalidomide induced the secretion of IL-2 on isolated NK cells although it also modulated NK receptor expression,such as NKp46,trough downregulation of PI3K/AKT pathway reduction. This was overcome by exogeneous addition of IL-2 family of cytokines increasing natural cytotoxicity,through higher perforin and granzyme expression. Mechanistically,this increased gene and protein expression occurred through the activation of STAT5 by lenalidomide which was also enhanced through the exogenous addition of IL-2 family of cytokines and modulation of IL-2R subunit changes. Conclusions: These data provide a rationale for the combination of lenalidomide with IL-2 family of cytokines to enhance the effectiveness of NK cells. View Publication

A comprehensive genetics-based precision medicine strategy to selectively and permanently inactivate only mutant,not normal allele,could benefit many dominantly inherited disorders. Here,we demonstrate the power of our novel strategy of inactivating the mutant allele using haplotype-specific CRISPR/Cas9 target sites in Huntington's disease (HD),a late-onset neurodegenerative disorder due to a toxic dominant gain-of-function CAG expansion mutation. Focusing on improving allele specificity,we combined extensive knowledge of huntingtin (HTT) gene haplotype structure with a novel personalized allele-selective CRISPR/Cas9 strategy based on Protospacer Adjacent Motif (PAM)-altering SNPs to target patient-specific CRISPR/Cas9 sites,aiming at the mutant HTT allele-specific inactivation for a given diplotype. As proof-of-principle,simultaneously using two CRISPR/Cas9 guide RNAs (gRNAs) that depend on PAM sites generated by SNP alleles on the mutant chromosome,we selectively excised 44 kb DNA spanning promoter region,transcription start site,and the CAG expansion mutation of the mutant HTT gene,resulting in complete inactivation of the mutant allele without impacting the normal allele. This excision on the disease chromosome completely prevented the generation of mutant HTT mRNA and protein,unequivocally indicating permanent mutant allele-specific inactivation of the HD mutant allele. The perfect allele selectivity with broad applicability of our strategy in disorders with diverse disease haplotypes should also support precision medicine through inactivation of many other gain-of-function mutations. View Publication