Journal: Cell Communication and Signaling : CCS

Article Title: Endomucin selectively regulates vascular endothelial growth factor receptor-2 endocytosis through its interaction with AP2

doi: 10.1186/s12964-024-01606-w

Figure Lengend Snippet: Essential role of EMCN in facilitating VEGFR2 and AP2 interaction and clathrin recruitment. A Colocalization of clathrin HC (heavy chain) (green) and VEGFR2 (red) were visualized in control HRECs with or without VEGF165 (10 ng/ml). Examples of colocalization of VEGFR2 and clathrin HC (white arrowhead), and clathrin (white arrow) were shown in magnified view. Bar = 10 µm B Fraction of VEGFR2 that colocalized with clathrin was quantified by Image J CoJAP plugin. Student t-test was used for the comparison. * P < 0.05, n = 3. C Colocalization of clathrin HC (heavy chain) (green) and VEGFR2 (red) were visualized in siNT or siEMCN HRECs with VEGF165 (10 ng/ml) stimulation. Examples of colocalization of VEGFR2 and clathrin HC (white arrowheads), and VEGFR2 (white arrow) were shown in magnified view. Bar = 10 µm D Fraction of VEGFR2 that colocalized with clathrin in siNT and siEMCN HRECs was quantified. Student t-test was used for the comparison. ** P < 0.01, n = 3. E Colocalization of clathrin HC (heavy chain) (green) and AP2 (red) were visualized in control in siNT and siEMCN HRECs with VEGF(10 ng/ml) stimulation. Examples of colocalization of clathrin HC and AP2 (white arrowhead) were shown in magnified view. Bar = 10 µm ( F ) Fraction of clathrin that colocalized with AP2 in siNT and siEMCN HRECs with VEGF stimulation were quantified. Student t-test was used for the comparison. P > 0.05, n = 3. G EMCN is required for interaction between VEGFR2 and AP2A2. HRECs were lysed and VEGFR2 that co-immunoprecipitated with AP2A2 in the presence and absence of EMCN was observed. n = 3

Article Snippet: Recombinant human VEGF165 (#293-VE), PlGF-2 (#6837-PL), and FGF2 (#233-FB) were purchased from R&D Systems.

Techniques: Control, Comparison, Immunoprecipitation

Journal: Cell Communication and Signaling : CCS

Article Title: Endomucin selectively regulates vascular endothelial growth factor receptor-2 endocytosis through its interaction with AP2

doi: 10.1186/s12964-024-01606-w

Figure Lengend Snippet: EMCN does not modulate VEGF165 or PIGF-induced endothelial migration or VEGFR1 internalization. A EMCN knockdown did not affect PlGF-2-induced HREC migration. HRECs were transfected with either siNT or siEMCN, mechanically scratched, stimulated with PlGF-2 (10 ng/ml) or VEGF165 (10 ng/ml), and the resulting cell migration was quantified by image analysis (left). ** P < 0.01, n = 6 or 9. Representative images of each group at time zero (white dashed line) and 15 h time (yellow dashed line) points (right). The scale bar represents 500 µm. B Illustration of the cell surface receptor internalization assay. Growth factors bind to its cell surface receptors and induce receptor internalization. Cell surface proteins are biotinylated, the cell surface fraction is separated using avidin resin, and western blot analysis were used to analyze the fraction of receptors remaining at the cell surface. C HRECs incubated in serum-free media were stimulated with VEGF165 (10 ng/ml) for 30 min with and without EMCN knockdown, and cell surface membrane-bound VEGFR1 (mVEGFR1) levels were analyzed by western blot analysis. * P < 0.05, ** P < 0.01, *** P < 0.001, n = 6. One-way ANOVA was used for statistical analysis

Article Snippet: Recombinant human VEGF165 (#293-VE), PlGF-2 (#6837-PL), and FGF2 (#233-FB) were purchased from R&D Systems.

Techniques: Migration, Knockdown, Transfection, Cell Surface Receptor Assay, Avidin-Biotin Assay, Western Blot, Incubation, Membrane

Journal: Cell Communication and Signaling : CCS

Article Title: Endomucin selectively regulates vascular endothelial growth factor receptor-2 endocytosis through its interaction with AP2

doi: 10.1186/s12964-024-01606-w

Figure Lengend Snippet: EMCN is not required for FGF2-induced HREC cell migration or FGFR1 internalization. A EMCN knockdown did not affect FGF2-induced HREC migration. HRECs were transfected with either siNT or siEMCN, incubated in serum-free media for 8 h, mechanically scratched, and stimulated with FGF2 (10 ng/ml) or VEGF165 (10 ng/ml). Quantification of cell migration for all the treatment groups based on image analysis (left). Student t-test was used for comparisons within groups. * P < 0.05, n = 8. Representative images of each group at time zero (white dashed line) and 15 h time (yellow dashed line) points (right). The scale bar represents 500 µm. B EMCN knockdown did not affect FGF2-induced FGFR1 internalization in HREC. Serum-starved HRECs were stimulated with FGF2 for 45 min, and then the cell surface proteins were isolated and visualized by western blot. Quantification of FGFR1 at the cell surface from all treatment groups by western blot analysis (left). Student-t test was used for statistical analysis. * P < 0.05, n = 7. A representative western blot for all treatment groups (right). C EMCN does not interact with VEGFR1 or FGFR1 in HRECs. HRECs overexpressing myc-tagged EMCN were lysed, and cell surface receptors that co-immunoprecipitated with EMCN were observed. n = 3. Note that the IgG and Myc groups were overexposed together for the better detection of the different receptors because of the low protein levels, while the input groups were kept at a lower exposure

Article Snippet: Recombinant human VEGF165 (#293-VE), PlGF-2 (#6837-PL), and FGF2 (#233-FB) were purchased from R&D Systems.

Techniques: Migration, Knockdown, Transfection, Incubation, Isolation, Western Blot, Immunoprecipitation

Journal: Cell Communication and Signaling : CCS

Article Title: Endomucin selectively regulates vascular endothelial growth factor receptor-2 endocytosis through its interaction with AP2

doi: 10.1186/s12964-024-01606-w

Figure Lengend Snippet: EMCN knockdown inhibits VEGF121 induced VEGFR2 internalization and HRECs migration similar to VEGF165. A Both VEGF165 (10 ng/ml)- and VEGF121 (7.29 ng/ml)-induced migration were inhibited with EMCN knockdown. Quantification of cell migration by image analysis is shown (left). Student-t test was used for comparisons between groups. * P < 0.05, ** P < 0.01, n = 10. Representative images of each group at time zero (white dashed line) and 15 h time (yellow dashed line) points. The scale bar represents 500 µm. B Schematic representation of VEGFA isoforms, VEGF165 and VEGF121. C HRECs were treated with siEMCN stimulated with VEGF121 (7.29 ng/ml) for a time course of up to 120 min. VEGF121 induced significant VEGFR2 endocytosis after 60 min of stimulation, except when EMCN was knockdown. One-way ANOVA was used for comparation within group. Student-t test was used for comparation between siNT and siEMCN at the same time point. # P < 0.05, * P < 0.05, *** P < 0.001, **** P < 0.0001, n = 3. D Representative image of the western blot for VEGFR2 internalization in both siNT and siEMCN groups. CD31 was blotted as cell surface fraction loading control

Article Snippet: Recombinant human VEGF165 (#293-VE), PlGF-2 (#6837-PL), and FGF2 (#233-FB) were purchased from R&D Systems.

Techniques: Knockdown, Migration, Western Blot, Control

Journal: Oncogene

Article Title: Neuropilin-2 regulates androgen-receptor transcriptional activity in advanced prostate cancer

doi: 10.1038/s41388-022-02382-y

Figure Lengend Snippet: Following ectopic expression of untagged NRP2B in C4–2B cells, nuclear and post-nuclear fractions were separated, and a pull-down assay was performed on the nuclear fraction with NRP2 antibody. Mass-Spectrometry was carried out with the pull-down samples. Using the genes detected in NRP2 Mass-Spectrometry. A. Sum of all the spectra associated with NRP2B pulldown sample is determined by the spectral graph. B. Venn-diagram represent the overlapping genes identified in two independent NRP2B mass-spectrometry assay. C. Group of nuclear pore proteins (Nups) identified through NRP2B Mass-Spectrometry. Schematic diagram indicating the relative positions of Nups around the nuclear pore. D. Validation of NRP2-Nup93 interactions in C4–2B. C4–2B cells were transfected with HA-tagged NRP2B. IP was carried out with HA-antibody and immunoblots were carried out with anti-Nup93. E. Endogenously, NRP2 and Nup93 interaction was validated in C4–2B and 22Rv1 cell lines. NRP2 was pull down with NRP2-specific antibody and IB with Nup93 antibody. F. NRP2B and AR interaction was carried out in C4–2B following ectopic interaction of HA-tagged NRP2B. Pulldown was carried out with HA-antibody and IP was carried out against NRP2 and AR. G. NRP2 and AR interaction was also monitored in PC3 and 22Rv1 following ectopic expression of HA-tagged NRP2B. IB was carried out against HA and AR. H. Co-IP for AR with NRP2 was carried out with pulldown of NRP2 by HA-antibody in C4–2B cells expressing wild type and mutant K892A NRP2B isoforms. NRP2B immunoblot was carried out with HA-antibody. I. IP with AR antibody was carried out to test the interaction among AR, Nup93 and NRP2 under the presence or absence of NRP2 and Nup 93 from the nuclear fraction of LNCaP C4–2B cells. An immunoblot was performed with anti-AR, anti-Nup93 and anti-NRP2 antibody. The Co-IP was carried out in the presence of 50ng/ml VEGF-C. J. PLA was carried out to validating the NRP2-AR interaction within the nucleus. Following ectopic expression of HA-tagged NRP2B, PLA was carried out with HA and endogenous AR antibodies under the presence or absence of NUP93. As a negative control, only HA-antibody was used for PLA reaction. Arrowhead indicates the immune-reactive PLA puncta. Nucleus was counter-stained with NUP98 to demarcate the nuclear periphery. DAPI used for nuclear staining. PLA quantification was shown in Bar diagram.

Article Snippet: NRP2B or NRP2A localization were chased with various experimental treatment condition for 1hrs under the following reagents VEGF-C (50ng/ml, R&D System, 752-VC-025), NRP2Fc (100ng/ml, R&D System, 2215-N2–025), SEMA3F (100ng/ml, R&D System, 9878-S3–025), Brefeldin A (0.5μM, Sigma, B6542).

Techniques: Expressing, Pull Down Assay, Mass Spectrometry, Biomarker Discovery, Transfection, Western Blot, Co-Immunoprecipitation Assay, Mutagenesis, Negative Control, Staining