Project description:Background and aims: Primary liver cancers (LCs), including HCC and intrahepatic cholangiocarcinoma (iCCA), are derived from a common developmental lineage, conferring a molecular spectrum between them. To elucidate the molecular spectrum, we performed an integrative analysis of transcriptome profiles associated with patients' radiopathologic features. Approach and results: We identified four LC subtypes (LC1-LC4) from RNA-sequencing profiles, revealing intermediate subtypes between HCC and iCCA. LC1 is a typical HCC characterized by active bile acid metabolism, telomerase reverse transcriptase promoter mutations, and high uptake of gadoxetic acid in MRI. LC2 is an iCCA-like HCC characterized by expression of the progenitor cell-like trait, tumor protein p53 mutations, and rim arterial-phase hyperenhancement in MRI. LC3 is an HCC-like iCCA, mainly small duct (SD) type, associated with HCC-related etiologic factors. LC4 is further subclassified into LC4-SD and LC4-large duct iCCAs according to the pathological features, which exhibited distinct genetic variations (e.g., KRAS , isocitrate dehydrogenase 1/2 mutation, and FGF receptor 2 fusion), stromal type, and prognostic outcomes. Conclusions: Our integrated view of the molecular spectrum of LCs can identify subtypes associated with transcriptomic, genomic, and radiopathologic features, providing mechanistic insights into heterogeneous LC progression.

Project description:Atopic dermatitis (AD) is a common, chronic inflammatory skin disease that seriously affects quality of life and is a major cause of skin diseases worldwide. Staphylococcus aureus (S. aureus) colonization on the skin plays an important role in the pathogenesis of AD; however, the mechanism of how it modulates skin immunity to exacerbate AD remains unclear. MicroRNAs are short non-coding RNAs that act as post-transcriptional regulators of genes. They are involved in the pathogenesis of various inflammatory skin diseases. In this study, we established miRNA expression profiles for keratinocytes stimulated with heat-killed S. aureus (HKSA). We found that miR-939 was highly upregulated in HKSA-stimulated keratinocytes and AD lesions. In vitro studies revealed that miR-939 increased the expression of matrix metalloproteinase genes, including MMP1, MMP3, and MMP9, as well as the cell adhesion molecule ICAM1 in human primary keratinocytes. In vivo studies indicated that miR-939 increased the expression of matrix metalloproteinases to promote the colonization of S. aureus and exacerbated S. aureus-induced AD-like skin inflammation. Taken together, these findings suggest that miR-939 is an important regulator of skin inflammation in AD.

Project description:Lung carcinoids (LCs) are rare and slow growing primary lung neoplasms that are understudied. Here, we performed targeted exome sequencing using a 354-cancer gene panel (n=29), mRNA sequencing (n=30) and DNA methylation assay (n=18) on macro-dissected lung carcinoids. The mutations we identified were enriched for genes involved in covalent histone modification/chromatin remodeling (34.5%) (MEN1, ARID1A, KMT2C and KMT2A were recurrently mutated) as well as DNA repair (17.2%) pathways. Unsupervised clustering and principle component analysis on gene expression and DNA methylation profiles showed 3 robust molecular subtypes (LC1, LC2, LC3) with distinct clinical features. MEN1 gene mutations were found to be enriched and exclusively in the LC2 subtype (p-value<0.001). The LC3 subtype is predominately found at endobronchial lung and earlier age of diagnosis. Immunohistochemical staining of two biomarkers, ASCL1 and S100, is sufficient to stratify the three subtypes. This molecular classification of lung carcinoids into three subtypes may help improve treatment decision and clinical management.

Project description:Background: Atopic dermatitis (AD) is a common inflammatory skin disease with a TH2 immune polarity and is often colonized with Staphylococcus aureus. Despite recent advances in understanding Staphylococcus species infection and the impact of polar TH cytokines on the skin, the interactions between these factors in AD pathology are poorly understood. Methods: AD-related key immune biomarkers were measured by quantitative real-time PCR in human keratinocytes exposed heat-killed S. epidermidis or S. aureus with/without polar T-cell derived cytokines such as IFN-γ (TH1), IL-4/IL-13 (TH2), and IL-22 (TH22). Further analysis was performed by RNA-sequencing to define broader responses in both Staphylococcus species and polar cytokines. The similarity of gene expression patterns in AD skin lesions and stimulated keratinocytes was evaluated by gene-set variation analysis (GSVA). Results: Gene expression analysis exhibited distinct immune responses in keratinocytes depending on individual bacterial or polar cytokine exposure. Besides, numerous genes were synergistically upregulated by the combination exposure of bacteria and polar TH cytokines. Moreover, GSVA revealed that combined exposure of S. aureus and IL-4 + IL-13 exhibited significantly higher correlations with a genomic signature of AD skin lesions than their single exposure or combinations of other polar TH cytokines. Conclusions: Our findings provide novel insights into AD-related transcriptional activation and illustrate a potentially novel pathogenic function of S. aureus and IL-4/IL-13 interactions in AD.

Project description:Langerhans cells (LCs) populate the mucosal epithelium, a major entry portal for pathogens, yet their ontogeny remains unclear. In contrast to skin LCs originating from self-renewing radioresistant embryonic precursors, we found that oral mucosal LCs derive from circulating radiosensitive precursors. Mucosal LCs can be segregated into CD103+CD11blow (CD103+LCs) and CD11b+CD103- (CD11b+LCs) subsets. We further demonstrated that similar to non-lymphoid dendritic cells (DCs), CD103+LCs originate from pre-DCs, whereas CD11b+LCs differentiate from both pre-DCs and monocytic precursors. Despite this ontogenetic discrepancy between skin and mucosal LCs, transcriptomic signature and immunological function of oral LCs highly resemble those of skin LCs but not DCs. These findings, along with their epithelial position, morphology and expression of LC-associated phenotype strongly suggest that oral mucosal LCs are genuine LCs. Collectively, in a tissue-dependent manner, murine LCs differentiate from at least three distinct precursors (embryonic, pre-DCs and monocytic) in steady state The following cells were isolated from mice (2-4 replicates): Lung DCs, mucosal CD103+ LC, mucosal CD11b+ LC, Skin LC. Transcriptome analysis was performed.

Project description:DNA CpG methylation profiling of LC patients samples were performed to understand genotype to phenotype corrlelations , novel molecular subtypes and cell of origins Lung carcinoids (LCs) are rare and slow growing primary lung neoplasms that are understudied. Here, we performed targeted exome sequencing using a 354-cancer gene panel (n=29), mRNA sequencing (n=30) and DNA methylation assay (n=18) on macro-dissected lung carcinoids. The mutations we identified were enriched for genes involved in covalent histone modification/chromatin remodeling (34.5%) (MEN1, ARID1A, KMT2C and KMT2A were recurrently mutated) as well as DNA repair (17.2%) pathways. Unsupervised clustering and principle component analysis on gene expression and DNA methylation profiles showed 3 robust molecular subtypes (LC1, LC2, LC3) with distinct clinical features. MEN1 gene mutations were found to be enriched and exclusively in the LC2 subtype (p-value<0.001). The LC3 subtype is predominately found at endobronchial lung and earlier age of diagnosis. Immunohistochemical staining of two biomarkers, ASCL1 and S100, is sufficient to stratify the three subtypes. This molecular classification of lung carcinoids into three subtypes may help improve treatment decision and clinical management.

Project description:<p>The NIH Intramural Skin Microbiome Consortium (NISMC) is a collaboration of investigators with primary expertise in genomics, bioinformatics, large-scale DNA sequencing, dermatology, immunology, allergy, infectious disease, and clinical microbiology. Atopic dermatitis (AD, "eczema") is a chronic relapsing skin disorder that affects ~15% of U.S. children and is associated with $1 billion of medical costs annually. AD is characterized by dry, itchy skin, infiltrated with immune cells. Colonization by Staphylococcus aureus (S. aureus) is ten-fold more common in AD patients and is associated with disease flares. We hypothesize that, in addition to S. aureus, AD may also be associated with additional novel microbes and/or selective shifts of commensal microbes that are relevant to disease progression. The NISMC seeks to define the microbiota that resides in and on the skin and nares of three patient groups, all of whom have eczematous lesions and are currently seen at the NIH Clinical Center: (1) AD patients; (2) Wiskott-Aldrich syndrome (WAS) patients; and (3) Hyper IgE syndrome (HIES) syndrome patients. Examination of the microbiome of patients with WAS or HIES syndromes, both rare immunodeficiencies, will advance our understanding of how an individual&#39;s immune system shapes their cutaneous microbial community. We are performing a prospective longitudinal study that follows these groups of patient thorough the cycles of eczema flares, ascertaining clinical data and samples at each stage.</p>

Project description:Characterization of functionally distinct Dendritic Cell (DC) subsets in mice has fueled interest in whether analogous counterparts exist in humans. Transcriptional modules of coordinately expressed genes were utilized for defining shared functions between the species. Comparing modules derived for four human skin DC subsets, and modules derived from the Immunological Genome Project database for all mouse DC subsets, revealed that human Langerhans Cells (LCs) and the mouse XCR1+CD8α+CD103+ DCs shared the Class I-mediated antigen processing and cross-presentation transcriptional modules that, however, were not seen in mouse LCs. Furthermore, human LCs were enriched in a transcriptional signature specific to the blood cross-presenting CD141/BDCA-3+ DCs, the proposed equivalent to mouse CD8α+ DCs. Consistent with our analysis, LCs were highly adept at inducing primary CTL responses. Thus, our study suggests that the function of LCs may not be conserved between mouse and human and supports human LCs as an especially relevant therapeutic target. RNA from sorted populations was purified using TRIzol. RNA was processed, amplified, labeled and hybridized at Washington University Core Facility (GTAC) with Illumina HumanHT-12 v4 Expression BeadChip. Data were background subtracted and quantile normalized.

Project description:Langerhans cells (LCs) populate the mucosal epithelium, a major entry portal for pathogens, yet their ontogeny remains unclear. In contrast to skin LCs originating from self-renewing radioresistant embryonic precursors, we found that oral mucosal LCs derive from circulating radiosensitive precursors. Mucosal LCs can be segregated into CD103+CD11blow (CD103+LCs) and CD11b+CD103- (CD11b+LCs) subsets. We further demonstrated that similar to non-lymphoid dendritic cells (DCs), CD103+LCs originate from pre-DCs, whereas CD11b+LCs differentiate from both pre-DCs and monocytic precursors. Despite this ontogenetic discrepancy between skin and mucosal LCs, transcriptomic signature and immunological function of oral LCs highly resemble those of skin LCs but not DCs. These findings, along with their epithelial position, morphology and expression of LC-associated phenotype strongly suggest that oral mucosal LCs are genuine LCs. Collectively, in a tissue-dependent manner, murine LCs differentiate from at least three distinct precursors (embryonic, pre-DCs and monocytic) in steady state

Project description:Characterization of functionally distinct Dendritic Cell (DC) subsets in mice has fueled interest in whether analogous counterparts exist in humans. Transcriptional modules of coordinately expressed genes were utilized for defining shared functions between the species. Comparing modules derived for four human skin DC subsets, and modules derived from the Immunological Genome Project database for all mouse DC subsets, revealed that human Langerhans Cells (LCs) and the mouse XCR1+CD8α+CD103+ DCs shared the Class I-mediated antigen processing and cross-presentation transcriptional modules that, however, were not seen in mouse LCs. Furthermore, human LCs were enriched in a transcriptional signature specific to the blood cross-presenting CD141/BDCA-3+ DCs, the proposed equivalent to mouse CD8α+ DCs. Consistent with our analysis, LCs were highly adept at inducing primary CTL responses. Thus, our study suggests that the function of LCs may not be conserved between mouse and human and supports human LCs as an especially relevant therapeutic target.