Journal: Pediatric nephrology (Berlin, Germany)

Article Title: Glomerular endothelial cells and podocytes can express CD80 in patients with minimal change disease during relapse

doi: 10.1007/s00467-020-04541-3

Figure Lengend Snippet: (A) Immunostaining with a mouse monoclonal anti human CD80 (red) was performed on paraffin embedded sections from patients with MCD and FSGS. Positive and negative controls are shown (upper panel). Upregulation of glomerular CD80 was noted in most of MCD but few FSGS patients (lower panel). (B) CD80 (green, upper panel) colocalized with caveolin 1 in an endothelial specific pattern (arrows). To less extent, CD80 (red, lower panel) colocalized with nephrin (arrowheads). (C) Specificity of immunostaining was confirmed by silver staining. No signal detected in kidney tissue sample from same MCD patient in relapse when primary antibody was omitted. (D) Electron microscopy (EM) from kidney tissue from patient with MCD is shown. CD80 colocalized with glomerular endothelial cells and rarely podocytes. Original EM images captured at 6000x (far right) and 30000x. Podocyte (P), capillary lumen (CL), endothelial cell (EC), urinary space (U), glomerular basement membrane (GBM). Scale bars: 100 μm.

Article Snippet: Reagents and antibodies The following primary antibodies were used CD80 (AF740, R&D) at 1:100 dilution; CD80 (MAB140, clone 37711, R&D) at 1:20; caveolin 1 (D46G3, #3267, Cell Signaling) at 1:800, nephrin (provided by Verma R), ICAM-1 (AF796, R&D) at 1:1000, synaptopodin (10R-2373, Fitzgerald) at 1:20.

Techniques: Immunostaining, Silver Staining, Electron Microscopy

Journal: bioRxiv

Article Title: Epigenetic therapy remodels the immune synaptic cytoskeleton to potentiate cancer susceptibility to γδ T cells

doi: 10.1101/2020.04.30.069955

Figure Lengend Snippet: ( A ) Immunofluorescence imaging of immune synapses between H1299 lung cancer cells and γδ T cells by phosphotyrosine (pTyr) staining. H1299 lung cancer cells are pretreated with phosphate- buffered saline (PBS) or DAC prior to coculture with γδ T cells. Quantifications of immune synapses per cancer cell on eight randomly taken high power fields for each treatment are shown in the dot plots (mean ± SD). Scale bar: 100 μm. p value is calculated by the Mann-Whitney test. ( B ) A scatter plot of DAC-induced surface proteomes in H1299 (y-axis) and A549 (x-axis) human lung cancer cells following daily treatment of 100 nM DAC for 72 hours and culture in drug-free medium for 3 days (D3R3). ICAM-1 is among the top upregulated surface proteins by DAC in both cells. ( C ) Western blot analyses of ICAM-1 protein expression in mock-treated vs. DAC-treated human lung cancer cells. D3: daily treatment of 100 nM decitabine for 72 hours. D3R3: daily treatment for 72 hours, followed by a 3-day rest period in drug-free medium. β-actin: loading control. ( D ) Immunofluorescence staining of ICAM-1 and immune synapse molecules (e.g., LFA-1, LAT) at immune synapses formed between γδ T cells and DAC-treated H1299 lung cancer cells. Scale bar: 10 μm. ( E ) Representative flow cytometric dot plot showing H1299 lung cancer cells with CRISPR-knockout of ICAM1 (KO-ICAM1) subject to γδ T cell killing for 2 hours. The effector to target (E: T) ratio is 3:1. Lung cancer cells are pre-treated with mock, DAC alone, γδ T cells alone or a combination of DAC and γδ T cells. The X-axis denotes surface ICAM1 levels. Y-axis represents signal intensities of propidium iodide. ( F ) Bar graphs showing percent cell death of human lung cancer cell lines (i.e., H1299, CL1-0, and A549) with CRISPR-knockout of ICAM-1 subject to γδ T cell killing for 2 hours. Cell death is measured by Annexin V and propidium iodide apoptosis assays (mean ± SEM, n = 3). Statistical significance is determined by one-way ANOVA test. ( G ) Representative flow cytometric dot plot showing H1299 lung cancer cells with a Tet-on expression system of ICAM1 (OV-ICAM1) subject to γδ T cell killing for 2 hours. Doxycycline (1 μg/mL) is added 24 hours prior to coculture to induce ICAM-1 protein expression. Cell death is measured by Annexin V (x-axis) and propidium iodide (y-axis) apoptosis assays. ( H ) Bar graphs showing cell death of human lung cancer cell lines (i.e., H1299, CL1-0, and A549) with ICAM-1 over-expression subject to γδ T cell killing for 2 hours. E:T ratio is 3:1. Cell death is measured by Annexin V and propidium iodide apoptosis assays. Statistical significance is determined by one-way ANOVA test (* p < 0.05, ** p < 0.01, ***, p < 0.001). ( I ) Immunofluorescence imaging of immune synapses between H1299 KO-ICAM1 lung cancer cells and γδ T cells by phosphotyrosine (pTyr) staining. Scale bar: 100 μm. Quantifications of immune synapses per cancer cell on six randomly taken high power fields for each treatment are shown in the dot plots (mean ± SD). p value is calculated by the Mann-Whitney test.

Article Snippet: The overexpression and loss of ICAM-1 protein were validated by flow cytometry with an anti-ICAM1 antibody (BBA20, R&D Systems).

Techniques: Immunofluorescence, Imaging, Staining, Saline, MANN-WHITNEY, Western Blot, Expressing, Control, CRISPR, Knock-Out, Over Expression

Journal: bioRxiv

Article Title: Epigenetic therapy remodels the immune synaptic cytoskeleton to potentiate cancer susceptibility to γδ T cells

doi: 10.1101/2020.04.30.069955

Figure Lengend Snippet: Sequencing results of the KO-ICAM1 lung cancer cells are aligned against the reference sequence of the ICAM1 genome locus. Alignment gaps are denoted as hyphens (-) to mark the lost (knockout) regions of the edited ICAM1 genome locus.

Article Snippet: The overexpression and loss of ICAM-1 protein were validated by flow cytometry with an anti-ICAM1 antibody (BBA20, R&D Systems).

Techniques: Sequencing, Knock-Out

Journal: bioRxiv

Article Title: Epigenetic therapy remodels the immune synaptic cytoskeleton to potentiate cancer susceptibility to γδ T cells

doi: 10.1101/2020.04.30.069955

Figure Lengend Snippet: ( A ) Immunofluorescence staining of F-actin (red), ICAM-1 (green), pTyr (phosphotyrosine, white) at immune synapses between γδ T cells and DAC-pretreated H1299 lung cancer cells at D3R3. Accumulation of F-actin beneath the cell membrane is noted in DAC-pretreated lung cancer cells. DAPI: 4′,6-diamidino-2-phenylindole, as a nuclear counterstain. Scale bar: 10 μm. ( B ) Representative immunofluorescence images of the interfaces between γδ T cells and H1299 lung cancer cells (parental vs. ICAM-1 knockout (KO-ICAM1)). Signals of F-actin (red) in the periphery of H1299 cancer cells are shown in two- and-a-half-dimensional (2.5D) images in the lower panels. Scale bar: 10 μm. ( C ) Dot plots of signal intensities of F-actin (left panel) and ICAM-1 (right panel) from five pTry-positive immune synapses between γδ T cells and H1299 lung cancer cells (parental or KO-ICAM1). p value is calculated by two-way ANOVA test. ( D ) Immunofluorescence images of immune synapses between γδ T cells (marked with T) and H1299 lung cancer cells (marked with C) stained for ICAM-1 (green), F-actin (Red) and phosphotyrosine (pTyr, white). Lung cancer cells (parental or KO-ICAM1) are pretreated with PBS (Mock) or 100 nM DAC and cocultured with γδ T cells at D3R3. ( E ) Dot plots of F-actin signal intensities at immune synapses between γδ T cells and H1299 cells. H1299 cells are pretreated with PBS (Mock), DAC alone or combination of DAC pretreatment (D3R3) and 1 μg/mL Cyto B (cytochalasin B, an inhibitor of actin filament polymerization) for 1.5 hours prior to coculture with γδ T cells (mean ± SD). p value is calculated by one-way ANOVA with Tukey’s multiple comparisons test (***, p < 0.001; ****, p < 0.0001). ( F ) Representative immunofluorescence images of immune synapses (pTyr staining) between γδ T and H1299 cells pretreated with PBS (Mock), DAC alone, and combination of DAC and Cyto B. Blow-up images of the square areas for each treatment are shown in the lower panels. Arrows denote immune synapses between γδ T and H1299 cells. Scale bar: 100 μm (upper) and 20 μm (lower panels). ( G ) Dot plots showing numbers of immune synapses per cancer cell on eight randomly taken high power fields for H1299 cells pretreated with PBS (Mock), DAC, and combination of DAC and Cyto B (mean ± SD). p value is calculated by one-way ANOVA with Tukey’s multiple comparisons test (*, statistical significance).

Article Snippet: The overexpression and loss of ICAM-1 protein were validated by flow cytometry with an anti-ICAM1 antibody (BBA20, R&D Systems).

Techniques: Immunofluorescence, Staining, Membrane, Knock-Out

Journal: bioRxiv

Article Title: Epigenetic therapy remodels the immune synaptic cytoskeleton to potentiate cancer susceptibility to γδ T cells

doi: 10.1101/2020.04.30.069955

Figure Lengend Snippet: Parental or ICAM-1 knockout (KO-ICAM1) H1299 cells are pretreated daily with PBS (Mock) or 100 nM DAC for 72 hours followed by 3-day drug-free culture before coculture with γδ T cells. Signal intensities of each protein (F-actin, red; ICAM-1, green; phosphotyrosine, pTyr, white) along the immune synapse area are graphed on the right. DAPI: 4’,6-diamidino-2-phenylindole, as nuclear counterstain. Scale bar: 10 μm.

Article Snippet: The overexpression and loss of ICAM-1 protein were validated by flow cytometry with an anti-ICAM1 antibody (BBA20, R&D Systems).

Techniques: Knock-Out

Journal: bioRxiv

Article Title: Epigenetic therapy remodels the immune synaptic cytoskeleton to potentiate cancer susceptibility to γδ T cells

doi: 10.1101/2020.04.30.069955

Figure Lengend Snippet: ( A ) Visualization of multi-omics data (i.e., mRNA-seq, Omni-ATAC-seq, and MethylationEPIC arrays) for DAPK3 , EVPLL, and TUBE1 in H1299 lung cancer cells. ( B ) Promoter methylation status and mRNA expression levels of the ICAM1 gene measured by Infinium MethylationEPIC arrays (left panels) and mRNA-seq (right panels) in human lung cancer cells treated without and with DAC 100 nM DAC for 3 days followed by a 3-day drug-free culture. ( C ) Open chromatin regions in the promoter areas of the ICAM1 gene in human lung cancer cells upon 100 nM DAC treatment analyzed by Omni-ATAC-seq. The green bar represents a CpG island. ( D ) Validation of Omni-ATAC-seq by quantitative real-time PCR on transposase-accessible chromatin at the ICAM1 promoter of human lung cancer cells subject to daily treatment of 100 nM DAC treatment for 3 days, followed by a 3-day drug-free culture. Experiments are performed in triplicates, and data are presented as mean ± SD. p value was calculated by unpaired t test (*, p < 0.05). ( E ) IPA Network analysis of mRNA expression changes in human lung cancer cells treated by DAC reveals coordinated changes of the immune-related surface molecules and the cytoskeleton-associated genes. ( F ) IPA upstream regulator analysis of mRNA expression changes in human lung cancer cells treated by DAC. T cell effector cytokines such as TNF-α and IFN-γ may enhance DAC-induced expression changes of immune-related molecules and ICAM-1 in lung cancer cells. TP53 is a potential master regulator for cancer cytoskeleton reorganization essential for DAC-potentiated γδ T cell killing.

Article Snippet: The overexpression and loss of ICAM-1 protein were validated by flow cytometry with an anti-ICAM1 antibody (BBA20, R&D Systems).

Techniques: Biomarker Discovery, Methylation, Expressing, Real-time Polymerase Chain Reaction

Journal: bioRxiv

Article Title: Epigenetic therapy remodels the immune synaptic cytoskeleton to potentiate cancer susceptibility to γδ T cells

doi: 10.1101/2020.04.30.069955

Figure Lengend Snippet: ( A ) Diagram of transcription factor binding sites at the ICAM1 promoter derived from the ENCODE ChIP-seq data ( https://www.encodeproject.org ). Visualizations of ATAC-seq peaks at the ICAM1 promoter in PC9 and CL1-5 lung cancer cell lines subject to DAC treatment are shown above. ( B ) Promoter methylation status and mRNA expression levels of putative transcription factors (i.e., RELB, NFKB2, STATS, and RUNX3) at the ICAM1 promoter in A549, H1299, PC9, and CL1-5 lung cancer cells. Dot and line plots represent methylation levels (β values) of promoter probes measured by Infinium MethylationEPIC arrays. The promoter probes with β values greater or equal to 0.5 at baseline (Mock) are shown. Bar graphs represent relative mRNA expression levels based on normalized FPKM measured by mRNA-seq.

Article Snippet: The overexpression and loss of ICAM-1 protein were validated by flow cytometry with an anti-ICAM1 antibody (BBA20, R&D Systems).

Techniques: Binding Assay, Derivative Assay, ChIP-sequencing, Methylation, Expressing

Journal: Frontiers in Veterinary Science

Article Title: Unrevealing the therapeutic potential of artesunate against emerging zoonotic Babesia microti infection in the murine model

doi: 10.3389/fvets.2024.1383291

Figure Lengend Snippet: Regulating effect of artesunate (AS) after 4 weeks of treatment. (A) Shows protein levels of inflammation markers including SICAM-1, ICAM-1, and C-reactive protein and proapoptotic factor Bax and anti-apoptotic factor Bcl-2. (B) Shows a bar graph of the percentage of band intensity relative protein expression compared within the control group (CG), the B. microti (BM) group, and the experimental groups B. microti + artesunate 2 mg/kg low-dose group (LG), B . microti + artesunate 4 mg/kg medium-dose group, and 8 mg/kg high-dose group. (a) SICAM-1, (b) ICAM-1, (c) CRP, (d) BAX, (e) Bcl-2 bar graph, with asterisks representing a higher level of significance, “*” ( p < 0.05) “**”( p < 0.01) ***”( p < 0.001)”****”( p < 0.0001).

Article Snippet: 3 , ICAM-1 , ICAM-1; 1:2000; Catalogue# HY-P80502; Med Chem Express, China.

Techniques: Expressing, Control