Project description:After feeding CD-HFD diet for 15 month, tumors from WT and FABP5 hepatocyte KO mice were collected and digested with collagenase to generate single cell suspension before proceeding with 10X Single Cell RNA-Sequencing.
Project description:We perform scRNA-seq in the livers of C57BL/6 mice fed a CD-HFD for 15 months. Starting from the 13M, mice were treated with FABP5 inhibitor to ameliorate HCC.
Project description:Single cell RNA-seq of single cell suspension from the HCC region of mice fed CD-HFD for 15 mice and treated with FABP5 inhibitor or control
Project description:Purpose: Mouse BMDM is the universal cell type of studying innate immunity. This study was designed to analyze LPS induced innate immune response and the gene expression in FABP5 KO BMDMs with overexpression of FABP5 WT or FABP5 C127S. Methods: FABP5 KO BMDMs were nucleofected with 5 μg pXJ40-3xFlag-FABP5 WT or C127S plasmid using the Amaxa Mouse Macrophage Nucleofector Kit (Lonza, VPA-1009) following the manufacturer’s instructions. Replace medium 6 hours post Nucleofection and add 500 ng/mL LPS to the fresh medium. 24 hours after treatment, harvest cells by using GenElute Single Cell RNA Purification Kit (Sigma, RNB300) and perform RNA-seq. Then mRNA profiles of these samples were generated by high-throughput sequencing analysis, using Illumina NovaSeq6000. And the differential mRNA profiles were analyzed. Results: mRNA profiles were analyzed, and differential expression profiles were compared. Conclusions: Our study demonstrated the transcriptional profiles of FABP5 KO BMDMs with overexpression of FABP5 WT or FABP5 C127S upon LPS treatment, with biologic replicates, generated by RNA-seq technology.
Project description:High-throughput scRNA-seq transcriptionally profiled an estimated 15093 cells from CD islets and 18906 from HFD islets. The mean number of reads per sequenced cell was 43,301 for CD islets and 33,867 for HFD islets, while the median number of genes per sequenced cell was 2105 and 1775, respectively.
Project description:Differential susceptibility to recurrent infection and exacerbation in COPD is not well understood. Here we investigated the potential impact of genetic variation in Fatty Acid Binding Protein 5 (FABP5), a metabolic regulator we previously demonstrated to be downregulated in COPD and further downregulated in patients reporting one or more exacerbation. Through negative binomial analysis of the COPDGene SNP dataset, we identified 5 novel linked single nucleotide polymorphisms (SNPs) across the FABP5 locus that were significantly associated with severe exacerbations in a Non-Hispanic White cohort (rs4338057, rs12549270, rs202275, rs202277, and rs202279). We integrated multiple sources of previously published data to prioritize SNPs most likely to exert regulatory function. Ultimately, rs202275 emerged as the lead candidate due to unique alignment with the loading site of a bidirectional RNA Pol II signature of active enhancer utilization in our recently published patient-derived airway epithelial PRO-seq dataset, suggesting a critical regulatory role for the region harboring this variant. Using Micro-C genome-wide chromosome conformation capture, we found that the region harboring rs202275 makes three-dimensional physical contacts with the FABP5 transcription start site (TSS), suggesting the SNP region could regulate FABP5 transcription through a looping mechanism. To examine SNP function, we analyzed previously deposited gene-array data (GEO Accession #GSE42057) from peripheral blood mononuclear cell (PBMC) samples and found that COPD patients carrying the rs202275 risk allele (T) express significantly lower levels of FABP5 compared to non-carrier patients. Seahorse real-time mitochondrial respiration assays in freshly isolated PBMCs further revealed disrupted oxidative phosphorylation in cells from patients carrying the rs202275 risk allele. As macrophage polarization from pro-inflammatory toward pro-resolving phenotype is dependent on oxidative metabolism, the functional impact of the rs202275 risk allele and associated reduction in FABP5 transcription may contribute to increased or prolonged systemic inflammation, thereby increasing susceptibility to exacerbation in COPD.
Project description:Background: Gastric cancer (GC) is the second most lethal cancer globally and is associated with poor prognosis. Fatty acid-binding proteins (FABPs) can regulate the biological properties of carcinoma cells. FABP5 is overexpressed in many types of cancers; however, the role and mechanism of FABP5 in GC are still unclear. Aim: In this study, we aimed to evaluate the clinical and biological function of FABP5 in GC. Methods: We assessed FABP5 expression using immunohistochemical analysis of 79 GC patients and evaluated its biological functions following in vitro and in vivo ectopic expression. FABP5 targets relevant to GC progression were determined using RNA sequencing (RNA-seq) analyses. Results: Elevated FABP5 expression was closely related to poor outcomes, and ectopic expression of FABP5 promoted GC cell proliferation, invasion, migration, and carcinogenicity, suggesting its potential tumor-promoting role in GC. Additionally, RNA-seq analysis indicated that FABP5 activates immune-related pathways, including cytokine–cytokine receptor-interaction pathways, interleukin-17 signaling, and tumor necrosis factor signaling, suggesting an important rationale for the possible development of therapies combining FABP5-targeted drugs with immunotherapeutics. Conclusion: These findings highlight the biological mechanisms and clinical implications of FABP5 in GC and suggest its potential as an adverse prognostic factor and/or therapeutic target.
Project description:Macrophages are considered as a homogeneous population in the heart. We used single cell RNA sequencing (scRNA-seq) to analyze thediversity of macrophages in control diet (CD) mouse, high fat diet (HFD) mouse and Western diet (WD) mouse heart.
Project description:We used RNA-seq to study the function of FABP5 in gastric cancer cells (AGS and MGC803). Down-regulation of FABP5 suppressed cell proliferation, cell migration and invasion, and induced cell apoptosis. Bioinformatics analysis revealed that Hippo signaling pathway was related to FABP5 in GC cells.Our data suggested that FABP5 might act as a potential target associated with Hippo signaling pathway for GC treatment.