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mouse anti par  (Trevigen)

 
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    Trevigen mouse anti par
    Mouse Anti Par, supplied by Trevigen, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/mouse anti par/product/Trevigen
    Average 86 stars, based on 1 article reviews
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    86/100 stars

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    The cytometric analysis (SSC and FCS) of isolated human resting platelets (A, D) , gated and <t>labeled</t> <t>PAR-1</t> without activation (B, E) , and gated and labeled PAR-1 with activation by 10 µM TRAP (C, F) ; labeled with anti-CD61-FITC and PAR-1-APC antibodies (G–I) . The level of PAR-1 expression was read from gates P1. Markers M1 and M2 indicate the gates for microparticles and normal platelets, with the PAR-1 analysis applied to the summed population. An example image from a patient with DM is shown.
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    mouse anti human par2 antibody  (Santa Cruz Biotechnology)
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    Examination of the mechanism of influence of TF on Tau protein expression and phosphorylation in differentiated SH-SY5Y cells. SH-SY5Y (2 × 10 5 ) were treated with recombinant relipidated Innovin TF (0.65 ng/ml) together with or without human fVIIa (5 nM) or fVIIa alone. In some experiments, the TF aliquots were pre-incubated for 1 h, with 10H10 antibody (20 µg/ml) capable of blocking TF signalling, HTF-1 antibody (20 µg/ml) to block TF-fVIIa protease/procoagulant activity, or a mouse control isotype IgG antibody (20 µg/ml; not shown). In other experiments, fVIIa was pre-incubated for 1 h with the chemical inhibitor PCI27483 (10 µg/ml). Alternatively, the neuronal cells were treated with AIIB2 antibody (20 µg/ml) to block β1-integrin signalling, SAM11 antibody (20 µg/ml) capable of blocking <t>PAR2</t> signalling, or PAR2-activating peptide (PAR2-AP; 20 µM) to induce PAR2 signalling. Cells were harvested at 24 h, and cellular lysates (10 µg protein) were examined for Tau and phospho-Thr181 Tau by western blot analysis. All values were normalised against the respective GAPDH and for comparison, all ratios were calculated against the average from the non-treated cells ± the calculated standard deviation. The number of experiments is shown in each column, and all data groups were determined to have normal distributions and are shown in each column. A SH-SY5Y protein electrophoresis, B SH-SY5Y phospho-Thr181 Tau electrophoresis, C SH-SY5Y Tau protein ratio, and D SH-SY5Y phospho-Thr181 Tau ratio
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    Examination of the mechanism of influence of TF on Tau protein expression and phosphorylation in differentiated SH-SY5Y cells. SH-SY5Y (2 × 10 5 ) were treated with recombinant relipidated Innovin TF (0.65 ng/ml) together with or without human fVIIa (5 nM) or fVIIa alone. In some experiments, the TF aliquots were pre-incubated for 1 h, with 10H10 antibody (20 µg/ml) capable of blocking TF signalling, HTF-1 antibody (20 µg/ml) to block TF-fVIIa protease/procoagulant activity, or a mouse control isotype IgG antibody (20 µg/ml; not shown). In other experiments, fVIIa was pre-incubated for 1 h with the chemical inhibitor PCI27483 (10 µg/ml). Alternatively, the neuronal cells were treated with AIIB2 antibody (20 µg/ml) to block β1-integrin signalling, SAM11 antibody (20 µg/ml) capable of blocking <t>PAR2</t> signalling, or PAR2-activating peptide (PAR2-AP; 20 µM) to induce PAR2 signalling. Cells were harvested at 24 h, and cellular lysates (10 µg protein) were examined for Tau and phospho-Thr181 Tau by western blot analysis. All values were normalised against the respective GAPDH and for comparison, all ratios were calculated against the average from the non-treated cells ± the calculated standard deviation. The number of experiments is shown in each column, and all data groups were determined to have normal distributions and are shown in each column. A SH-SY5Y protein electrophoresis, B SH-SY5Y phospho-Thr181 Tau electrophoresis, C SH-SY5Y Tau protein ratio, and D SH-SY5Y phospho-Thr181 Tau ratio
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    mouse anti pan par  (Merck & Co)
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    Examination of the mechanism of influence of TF on Tau protein expression and phosphorylation in differentiated SH-SY5Y cells. SH-SY5Y (2 × 10 5 ) were treated with recombinant relipidated Innovin TF (0.65 ng/ml) together with or without human fVIIa (5 nM) or fVIIa alone. In some experiments, the TF aliquots were pre-incubated for 1 h, with 10H10 antibody (20 µg/ml) capable of blocking TF signalling, HTF-1 antibody (20 µg/ml) to block TF-fVIIa protease/procoagulant activity, or a mouse control isotype IgG antibody (20 µg/ml; not shown). In other experiments, fVIIa was pre-incubated for 1 h with the chemical inhibitor PCI27483 (10 µg/ml). Alternatively, the neuronal cells were treated with AIIB2 antibody (20 µg/ml) to block β1-integrin signalling, SAM11 antibody (20 µg/ml) capable of blocking <t>PAR2</t> signalling, or PAR2-activating peptide (PAR2-AP; 20 µM) to induce PAR2 signalling. Cells were harvested at 24 h, and cellular lysates (10 µg protein) were examined for Tau and phospho-Thr181 Tau by western blot analysis. All values were normalised against the respective GAPDH and for comparison, all ratios were calculated against the average from the non-treated cells ± the calculated standard deviation. The number of experiments is shown in each column, and all data groups were determined to have normal distributions and are shown in each column. A SH-SY5Y protein electrophoresis, B SH-SY5Y phospho-Thr181 Tau electrophoresis, C SH-SY5Y Tau protein ratio, and D SH-SY5Y phospho-Thr181 Tau ratio
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    mouse anti par  (Trevigen)
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    Examination of the mechanism of influence of TF on Tau protein expression and phosphorylation in differentiated SH-SY5Y cells. SH-SY5Y (2 × 10 5 ) were treated with recombinant relipidated Innovin TF (0.65 ng/ml) together with or without human fVIIa (5 nM) or fVIIa alone. In some experiments, the TF aliquots were pre-incubated for 1 h, with 10H10 antibody (20 µg/ml) capable of blocking TF signalling, HTF-1 antibody (20 µg/ml) to block TF-fVIIa protease/procoagulant activity, or a mouse control isotype IgG antibody (20 µg/ml; not shown). In other experiments, fVIIa was pre-incubated for 1 h with the chemical inhibitor PCI27483 (10 µg/ml). Alternatively, the neuronal cells were treated with AIIB2 antibody (20 µg/ml) to block β1-integrin signalling, SAM11 antibody (20 µg/ml) capable of blocking <t>PAR2</t> signalling, or PAR2-activating peptide (PAR2-AP; 20 µM) to induce PAR2 signalling. Cells were harvested at 24 h, and cellular lysates (10 µg protein) were examined for Tau and phospho-Thr181 Tau by western blot analysis. All values were normalised against the respective GAPDH and for comparison, all ratios were calculated against the average from the non-treated cells ± the calculated standard deviation. The number of experiments is shown in each column, and all data groups were determined to have normal distributions and are shown in each column. A SH-SY5Y protein electrophoresis, B SH-SY5Y phospho-Thr181 Tau electrophoresis, C SH-SY5Y Tau protein ratio, and D SH-SY5Y phospho-Thr181 Tau ratio
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    Rotenone triggers time-dependent HMGB1 nuclear exit coupled with increased PARylation. A , representative confocal images of time-dependent HMGB1 ( green ) localization in SH-SY5Y cells treated with rotenone (5μM) or DMSO control. DAPI ( blue ) indicates nuclear staining (scale bar = 10 μm). B , quantification of SH-SY5Y cells with cytoplasmic enrichment of HMGB1 shown in ( A ). Nucleus was defined by area of DAPI. Cytosolic HMGB1 was calculated by subtracting nuclear region of interest (ROI) from the area of green channel. n = 100 cells for each quantification. C , immunoblot analysis of HMGB1 protein levels in the nuclear and cytosolic fraction of SH-SY5Y cells treated with rotenone for 2, 4, 6 and 24 h and compared with DMSO treated controls. GAPDH was used as cytosolic loading control and lamin A/C was used as a nuclear loading control ( left panel ). The nuclear to cytoplasmic ratio was quantified using the lower band obtained in the cytoplasmic fraction of the gels ( right panel ). D , co-immunoprecipitation analysis was performed to assess the PARylation status of HMGB1 in whole-cell extracts following 24 h of rotenone treatment. Cells were immunoprecipitated with an anti-HMGB1 antibody, and <t>PAR</t> ( upper panel ) and HMGB1 ( middle panel ; low and high exposures) levels were analyzed. Additionally, cells were immunoprecipitated with an <t>anti-PAR</t> antibody, and HMGB1 levels ( lower panel ) were examined. E , immunoblot analysis of HMGB1 protein levels in the nuclear and cytosolic fraction of cells treated with rotenone for 24 h in the presence or absence of the PARP inhibitor PJ34 (50μM). GAPDH was used as cytosolic loading control and lamin A/C was used as a nuclear loading control ( left panel ). The nuclear to cytoplasmic ratio was quantified using the lower band obtained in the cytoplasmic fraction of the gels ( right panel ). F , representative confocal images of HMGB1 ( green ) and DAPI (blue) in SH-SY5Y cells treated with rotenone or DMSO control in the presence of PJ34. DAPI ( blue ) indicates nuclear staining (scale bar = 10 μm). G , quantification of cells with cytoplasmic enrichment of HMGB1. n = 100 cells for each quantification. Data are presented as mean ± SD. Statistical significance was determined by one-way ANOVA with Tukey’s multiple comparison test (∗∗∗ p < 0.001; n = 3 biological replicates).
    Anti Par Antibody, supplied by Bio-Rad, used in various techniques. Bioz Stars score: 93/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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    Image Search Results


    The cytometric analysis (SSC and FCS) of isolated human resting platelets (A, D) , gated and labeled PAR-1 without activation (B, E) , and gated and labeled PAR-1 with activation by 10 µM TRAP (C, F) ; labeled with anti-CD61-FITC and PAR-1-APC antibodies (G–I) . The level of PAR-1 expression was read from gates P1. Markers M1 and M2 indicate the gates for microparticles and normal platelets, with the PAR-1 analysis applied to the summed population. An example image from a patient with DM is shown.

    Journal: Frontiers in Molecular Biosciences

    Article Title: The predictive role of protease-activated receptor (PAR-1) polymorphisms and activated microplatelets on the severity of atherosclerosis – preliminary studies

    doi: 10.3389/fmolb.2025.1662954

    Figure Lengend Snippet: The cytometric analysis (SSC and FCS) of isolated human resting platelets (A, D) , gated and labeled PAR-1 without activation (B, E) , and gated and labeled PAR-1 with activation by 10 µM TRAP (C, F) ; labeled with anti-CD61-FITC and PAR-1-APC antibodies (G–I) . The level of PAR-1 expression was read from gates P1. Markers M1 and M2 indicate the gates for microparticles and normal platelets, with the PAR-1 analysis applied to the summed population. An example image from a patient with DM is shown.

    Article Snippet: Next: For the PAR-1 test without PLT activation, 5 μL of PAR-1-APC antibodies at a concentration of 5 μg/5 × 10 5 cells (Allophycocyanin (APC)-conjugated mouse monoclonal anti-human PAR-1; clone# 731115; mouse isotype: IgG1, R&D Systems, Minneapolis, Canada) and 5 μL of CD61-FITC antibodies (Monoclonal Mouse Anti-Human CD61, Platelet Glycoprotein IIIa/FITC, Clone Y2/51, code: F0803, DakoCytomation, Glostrup, Denmark) were added.

    Techniques: Isolation, Labeling, Activation Assay, Expressing

    The percentage of PAR-1 receptor expression before and after the addition of the thrombin receptor activating peptide (TRAP) in blood samples from patients with diabetic macroangiopathy (DM), the control group (CONTROL), and atherosclerosis obliterans (AO).

    Journal: Frontiers in Molecular Biosciences

    Article Title: The predictive role of protease-activated receptor (PAR-1) polymorphisms and activated microplatelets on the severity of atherosclerosis – preliminary studies

    doi: 10.3389/fmolb.2025.1662954

    Figure Lengend Snippet: The percentage of PAR-1 receptor expression before and after the addition of the thrombin receptor activating peptide (TRAP) in blood samples from patients with diabetic macroangiopathy (DM), the control group (CONTROL), and atherosclerosis obliterans (AO).

    Article Snippet: Next: For the PAR-1 test without PLT activation, 5 μL of PAR-1-APC antibodies at a concentration of 5 μg/5 × 10 5 cells (Allophycocyanin (APC)-conjugated mouse monoclonal anti-human PAR-1; clone# 731115; mouse isotype: IgG1, R&D Systems, Minneapolis, Canada) and 5 μL of CD61-FITC antibodies (Monoclonal Mouse Anti-Human CD61, Platelet Glycoprotein IIIa/FITC, Clone Y2/51, code: F0803, DakoCytomation, Glostrup, Denmark) were added.

    Techniques: Expressing, Control

    (A) Separation of DNA molecules in a 3% agarose gel of PAR-1 gene amplification products with the −506 I/D polymorphism. Lanes: 1 – homozygous I/I, 2 – heterozygous I/D, 3 – homozygous D/D, M–GeneRuler™ 50bp DNA Ladder (Fermentas). (B) The percentage distribution of the −506 I/D polymorphism variants in the PAR-1 gene: homozygous D/D (blue), heterozygous I/D (red), and homozygous I/I (green).

    Journal: Frontiers in Molecular Biosciences

    Article Title: The predictive role of protease-activated receptor (PAR-1) polymorphisms and activated microplatelets on the severity of atherosclerosis – preliminary studies

    doi: 10.3389/fmolb.2025.1662954

    Figure Lengend Snippet: (A) Separation of DNA molecules in a 3% agarose gel of PAR-1 gene amplification products with the −506 I/D polymorphism. Lanes: 1 – homozygous I/I, 2 – heterozygous I/D, 3 – homozygous D/D, M–GeneRuler™ 50bp DNA Ladder (Fermentas). (B) The percentage distribution of the −506 I/D polymorphism variants in the PAR-1 gene: homozygous D/D (blue), heterozygous I/D (red), and homozygous I/I (green).

    Article Snippet: Next: For the PAR-1 test without PLT activation, 5 μL of PAR-1-APC antibodies at a concentration of 5 μg/5 × 10 5 cells (Allophycocyanin (APC)-conjugated mouse monoclonal anti-human PAR-1; clone# 731115; mouse isotype: IgG1, R&D Systems, Minneapolis, Canada) and 5 μL of CD61-FITC antibodies (Monoclonal Mouse Anti-Human CD61, Platelet Glycoprotein IIIa/FITC, Clone Y2/51, code: F0803, DakoCytomation, Glostrup, Denmark) were added.

    Techniques: Agarose Gel Electrophoresis, Amplification

    (A) The result of the restriction digestion of PCR products with the MvaI enzyme to check for the presence of the −1426 C/T polymorphism in the PAR-1 gene. Lanes: 1 – 6 homozygotes C/C, M–GeneRuler™ 100bp DNA Ladder (Fermentas). (B) The percentage distribution of the variants of the −1426 C/T polymorphism in the PAR-1 gene: homozygote C/C (blue color), heterozygote C/T (red color), homozygote T/T (green color).

    Journal: Frontiers in Molecular Biosciences

    Article Title: The predictive role of protease-activated receptor (PAR-1) polymorphisms and activated microplatelets on the severity of atherosclerosis – preliminary studies

    doi: 10.3389/fmolb.2025.1662954

    Figure Lengend Snippet: (A) The result of the restriction digestion of PCR products with the MvaI enzyme to check for the presence of the −1426 C/T polymorphism in the PAR-1 gene. Lanes: 1 – 6 homozygotes C/C, M–GeneRuler™ 100bp DNA Ladder (Fermentas). (B) The percentage distribution of the variants of the −1426 C/T polymorphism in the PAR-1 gene: homozygote C/C (blue color), heterozygote C/T (red color), homozygote T/T (green color).

    Article Snippet: Next: For the PAR-1 test without PLT activation, 5 μL of PAR-1-APC antibodies at a concentration of 5 μg/5 × 10 5 cells (Allophycocyanin (APC)-conjugated mouse monoclonal anti-human PAR-1; clone# 731115; mouse isotype: IgG1, R&D Systems, Minneapolis, Canada) and 5 μL of CD61-FITC antibodies (Monoclonal Mouse Anti-Human CD61, Platelet Glycoprotein IIIa/FITC, Clone Y2/51, code: F0803, DakoCytomation, Glostrup, Denmark) were added.

    Techniques:

    (A) Example separations of amplification products of the DNA fragment encompassing the IVSn-14 A/T polymorphism site of the PAR-1 gene using the SNaPshot method. Alleles were determined based on the size of primers and the colors of fluorescently labeled ddNTPs (terminators) incorporated during the primer extension reaction. (A) red peak, wild-type homozygote (AA); (B) green and red peaks, heterozygote (AT); (C) green peak, mutated homozygote (TT). (B) The percentage distribution of the variants of the IVS-14 A/T polymorphism of the PAR-1 gene is as follows: homozygote A/A (blue color), heterozygote A/T (red color), and homozygote T/T (green color).

    Journal: Frontiers in Molecular Biosciences

    Article Title: The predictive role of protease-activated receptor (PAR-1) polymorphisms and activated microplatelets on the severity of atherosclerosis – preliminary studies

    doi: 10.3389/fmolb.2025.1662954

    Figure Lengend Snippet: (A) Example separations of amplification products of the DNA fragment encompassing the IVSn-14 A/T polymorphism site of the PAR-1 gene using the SNaPshot method. Alleles were determined based on the size of primers and the colors of fluorescently labeled ddNTPs (terminators) incorporated during the primer extension reaction. (A) red peak, wild-type homozygote (AA); (B) green and red peaks, heterozygote (AT); (C) green peak, mutated homozygote (TT). (B) The percentage distribution of the variants of the IVS-14 A/T polymorphism of the PAR-1 gene is as follows: homozygote A/A (blue color), heterozygote A/T (red color), and homozygote T/T (green color).

    Article Snippet: Next: For the PAR-1 test without PLT activation, 5 μL of PAR-1-APC antibodies at a concentration of 5 μg/5 × 10 5 cells (Allophycocyanin (APC)-conjugated mouse monoclonal anti-human PAR-1; clone# 731115; mouse isotype: IgG1, R&D Systems, Minneapolis, Canada) and 5 μL of CD61-FITC antibodies (Monoclonal Mouse Anti-Human CD61, Platelet Glycoprotein IIIa/FITC, Clone Y2/51, code: F0803, DakoCytomation, Glostrup, Denmark) were added.

    Techniques: Amplification, Labeling

    Multivariate analysis: (A–D) Number of microparticles with PAR-1+TRAP; (E–F) Number of microparticles with BMI (Figure 4.12E-F) and age with smoking.

    Journal: Frontiers in Molecular Biosciences

    Article Title: The predictive role of protease-activated receptor (PAR-1) polymorphisms and activated microplatelets on the severity of atherosclerosis – preliminary studies

    doi: 10.3389/fmolb.2025.1662954

    Figure Lengend Snippet: Multivariate analysis: (A–D) Number of microparticles with PAR-1+TRAP; (E–F) Number of microparticles with BMI (Figure 4.12E-F) and age with smoking.

    Article Snippet: Next: For the PAR-1 test without PLT activation, 5 μL of PAR-1-APC antibodies at a concentration of 5 μg/5 × 10 5 cells (Allophycocyanin (APC)-conjugated mouse monoclonal anti-human PAR-1; clone# 731115; mouse isotype: IgG1, R&D Systems, Minneapolis, Canada) and 5 μL of CD61-FITC antibodies (Monoclonal Mouse Anti-Human CD61, Platelet Glycoprotein IIIa/FITC, Clone Y2/51, code: F0803, DakoCytomation, Glostrup, Denmark) were added.

    Techniques:

    Examination of the mechanism of influence of TF on Tau protein expression and phosphorylation in differentiated SH-SY5Y cells. SH-SY5Y (2 × 10 5 ) were treated with recombinant relipidated Innovin TF (0.65 ng/ml) together with or without human fVIIa (5 nM) or fVIIa alone. In some experiments, the TF aliquots were pre-incubated for 1 h, with 10H10 antibody (20 µg/ml) capable of blocking TF signalling, HTF-1 antibody (20 µg/ml) to block TF-fVIIa protease/procoagulant activity, or a mouse control isotype IgG antibody (20 µg/ml; not shown). In other experiments, fVIIa was pre-incubated for 1 h with the chemical inhibitor PCI27483 (10 µg/ml). Alternatively, the neuronal cells were treated with AIIB2 antibody (20 µg/ml) to block β1-integrin signalling, SAM11 antibody (20 µg/ml) capable of blocking PAR2 signalling, or PAR2-activating peptide (PAR2-AP; 20 µM) to induce PAR2 signalling. Cells were harvested at 24 h, and cellular lysates (10 µg protein) were examined for Tau and phospho-Thr181 Tau by western blot analysis. All values were normalised against the respective GAPDH and for comparison, all ratios were calculated against the average from the non-treated cells ± the calculated standard deviation. The number of experiments is shown in each column, and all data groups were determined to have normal distributions and are shown in each column. A SH-SY5Y protein electrophoresis, B SH-SY5Y phospho-Thr181 Tau electrophoresis, C SH-SY5Y Tau protein ratio, and D SH-SY5Y phospho-Thr181 Tau ratio

    Journal: Cellular and Molecular Neurobiology

    Article Title: Procoagulant Extracellular Vesicles Increase Neuronal Tau expression, Metabolism and Processing Through Tissue Factor and Protease Activated Receptor 2

    doi: 10.1007/s10571-025-01658-7

    Figure Lengend Snippet: Examination of the mechanism of influence of TF on Tau protein expression and phosphorylation in differentiated SH-SY5Y cells. SH-SY5Y (2 × 10 5 ) were treated with recombinant relipidated Innovin TF (0.65 ng/ml) together with or without human fVIIa (5 nM) or fVIIa alone. In some experiments, the TF aliquots were pre-incubated for 1 h, with 10H10 antibody (20 µg/ml) capable of blocking TF signalling, HTF-1 antibody (20 µg/ml) to block TF-fVIIa protease/procoagulant activity, or a mouse control isotype IgG antibody (20 µg/ml; not shown). In other experiments, fVIIa was pre-incubated for 1 h with the chemical inhibitor PCI27483 (10 µg/ml). Alternatively, the neuronal cells were treated with AIIB2 antibody (20 µg/ml) to block β1-integrin signalling, SAM11 antibody (20 µg/ml) capable of blocking PAR2 signalling, or PAR2-activating peptide (PAR2-AP; 20 µM) to induce PAR2 signalling. Cells were harvested at 24 h, and cellular lysates (10 µg protein) were examined for Tau and phospho-Thr181 Tau by western blot analysis. All values were normalised against the respective GAPDH and for comparison, all ratios were calculated against the average from the non-treated cells ± the calculated standard deviation. The number of experiments is shown in each column, and all data groups were determined to have normal distributions and are shown in each column. A SH-SY5Y protein electrophoresis, B SH-SY5Y phospho-Thr181 Tau electrophoresis, C SH-SY5Y Tau protein ratio, and D SH-SY5Y phospho-Thr181 Tau ratio

    Article Snippet: Alternatively, the neuronal cells were treated with a rat anti-human antibody (20 μg/ml; AIIB2; Merck KGaA) to block β1-integrin signalling, a mouse anti-human PAR2 antibody, SAM11 (20 μg/ml; Santa Cruz Biotechnology, Heidelberg, Germany), capable of blocking PAR2 signalling, or PAR2-activating peptide (PAR2-AP; 20 μM) to induce PAR2 signalling.

    Techniques: Expressing, Phospho-proteomics, Recombinant, Incubation, Blocking Assay, Activity Assay, Control, Western Blot, Comparison, Standard Deviation, Protein Electrophoresis, Electrophoresis

    Time-course analysis of the Tau protein fragments in differentiated SH-SY5Y cells, following treatment with TF . SH-SY5Y (2 × 10 5 ) were treated with as single dose of recombinant relipidated Innovin TF (0.65 ng/ml) together with human fVIIa (5 nM). In some experiments, the TF aliquots were pre-incubated for 1 h, with 10H10 antibody (20 µg/ml) capable of blocking TF signalling, HTF-1 antibody (20 µg/ml) to block TF-fVIIa protease/procoagulant activity, or a mouse control isotype IgG antibody (20 µg/ml; not shown). Alternatively, the neuronal cells were treated with AIIB2 antibody (20 µg/ml) to block β1-integrin signalling, or SAM11 antibody (20 µg/ml) capable of blocking PAR2 signalling. Sets of cells were harvested at A 48 h and D at 72 h and cellular lysates (10 µg protein) were examined for Tau by western blot analysis. All values were normalised against the respective GAPDH (see Supplementary Fig. 6 A and B) and for comparison, all ratios were calculated against the average from the non-treated cells ± the calculated standard deviation. The data were obtained from 6 biological experiments, and all data groups were determined to have normal distributions. A Electrophoresis at 48 h, B calculated ratios of 50 kDa bands at 48 h, C calculated ratios of 30–35 kDa bands at 48 h, D electrophoresis at 72 h, E calculated ratios of 50 kDa bands at 72 h, F calculated ratios of 40 kDa bands at 72 h, G calculated ratios of 30–35 kDa bands at 72 h

    Journal: Cellular and Molecular Neurobiology

    Article Title: Procoagulant Extracellular Vesicles Increase Neuronal Tau expression, Metabolism and Processing Through Tissue Factor and Protease Activated Receptor 2

    doi: 10.1007/s10571-025-01658-7

    Figure Lengend Snippet: Time-course analysis of the Tau protein fragments in differentiated SH-SY5Y cells, following treatment with TF . SH-SY5Y (2 × 10 5 ) were treated with as single dose of recombinant relipidated Innovin TF (0.65 ng/ml) together with human fVIIa (5 nM). In some experiments, the TF aliquots were pre-incubated for 1 h, with 10H10 antibody (20 µg/ml) capable of blocking TF signalling, HTF-1 antibody (20 µg/ml) to block TF-fVIIa protease/procoagulant activity, or a mouse control isotype IgG antibody (20 µg/ml; not shown). Alternatively, the neuronal cells were treated with AIIB2 antibody (20 µg/ml) to block β1-integrin signalling, or SAM11 antibody (20 µg/ml) capable of blocking PAR2 signalling. Sets of cells were harvested at A 48 h and D at 72 h and cellular lysates (10 µg protein) were examined for Tau by western blot analysis. All values were normalised against the respective GAPDH (see Supplementary Fig. 6 A and B) and for comparison, all ratios were calculated against the average from the non-treated cells ± the calculated standard deviation. The data were obtained from 6 biological experiments, and all data groups were determined to have normal distributions. A Electrophoresis at 48 h, B calculated ratios of 50 kDa bands at 48 h, C calculated ratios of 30–35 kDa bands at 48 h, D electrophoresis at 72 h, E calculated ratios of 50 kDa bands at 72 h, F calculated ratios of 40 kDa bands at 72 h, G calculated ratios of 30–35 kDa bands at 72 h

    Article Snippet: Alternatively, the neuronal cells were treated with a rat anti-human antibody (20 μg/ml; AIIB2; Merck KGaA) to block β1-integrin signalling, a mouse anti-human PAR2 antibody, SAM11 (20 μg/ml; Santa Cruz Biotechnology, Heidelberg, Germany), capable of blocking PAR2 signalling, or PAR2-activating peptide (PAR2-AP; 20 μM) to induce PAR2 signalling.

    Techniques: Recombinant, Incubation, Blocking Assay, Activity Assay, Control, Western Blot, Comparison, Standard Deviation, Electrophoresis

    Rotenone triggers time-dependent HMGB1 nuclear exit coupled with increased PARylation. A , representative confocal images of time-dependent HMGB1 ( green ) localization in SH-SY5Y cells treated with rotenone (5μM) or DMSO control. DAPI ( blue ) indicates nuclear staining (scale bar = 10 μm). B , quantification of SH-SY5Y cells with cytoplasmic enrichment of HMGB1 shown in ( A ). Nucleus was defined by area of DAPI. Cytosolic HMGB1 was calculated by subtracting nuclear region of interest (ROI) from the area of green channel. n = 100 cells for each quantification. C , immunoblot analysis of HMGB1 protein levels in the nuclear and cytosolic fraction of SH-SY5Y cells treated with rotenone for 2, 4, 6 and 24 h and compared with DMSO treated controls. GAPDH was used as cytosolic loading control and lamin A/C was used as a nuclear loading control ( left panel ). The nuclear to cytoplasmic ratio was quantified using the lower band obtained in the cytoplasmic fraction of the gels ( right panel ). D , co-immunoprecipitation analysis was performed to assess the PARylation status of HMGB1 in whole-cell extracts following 24 h of rotenone treatment. Cells were immunoprecipitated with an anti-HMGB1 antibody, and PAR ( upper panel ) and HMGB1 ( middle panel ; low and high exposures) levels were analyzed. Additionally, cells were immunoprecipitated with an anti-PAR antibody, and HMGB1 levels ( lower panel ) were examined. E , immunoblot analysis of HMGB1 protein levels in the nuclear and cytosolic fraction of cells treated with rotenone for 24 h in the presence or absence of the PARP inhibitor PJ34 (50μM). GAPDH was used as cytosolic loading control and lamin A/C was used as a nuclear loading control ( left panel ). The nuclear to cytoplasmic ratio was quantified using the lower band obtained in the cytoplasmic fraction of the gels ( right panel ). F , representative confocal images of HMGB1 ( green ) and DAPI (blue) in SH-SY5Y cells treated with rotenone or DMSO control in the presence of PJ34. DAPI ( blue ) indicates nuclear staining (scale bar = 10 μm). G , quantification of cells with cytoplasmic enrichment of HMGB1. n = 100 cells for each quantification. Data are presented as mean ± SD. Statistical significance was determined by one-way ANOVA with Tukey’s multiple comparison test (∗∗∗ p < 0.001; n = 3 biological replicates).

    Journal: The Journal of Biological Chemistry

    Article Title: Tubulin hyperacetylation drives HMGB1 nuclear exit via the ROS-PARP1 axis, leading to rotenone-induced G2/M arrest

    doi: 10.1016/j.jbc.2025.110695

    Figure Lengend Snippet: Rotenone triggers time-dependent HMGB1 nuclear exit coupled with increased PARylation. A , representative confocal images of time-dependent HMGB1 ( green ) localization in SH-SY5Y cells treated with rotenone (5μM) or DMSO control. DAPI ( blue ) indicates nuclear staining (scale bar = 10 μm). B , quantification of SH-SY5Y cells with cytoplasmic enrichment of HMGB1 shown in ( A ). Nucleus was defined by area of DAPI. Cytosolic HMGB1 was calculated by subtracting nuclear region of interest (ROI) from the area of green channel. n = 100 cells for each quantification. C , immunoblot analysis of HMGB1 protein levels in the nuclear and cytosolic fraction of SH-SY5Y cells treated with rotenone for 2, 4, 6 and 24 h and compared with DMSO treated controls. GAPDH was used as cytosolic loading control and lamin A/C was used as a nuclear loading control ( left panel ). The nuclear to cytoplasmic ratio was quantified using the lower band obtained in the cytoplasmic fraction of the gels ( right panel ). D , co-immunoprecipitation analysis was performed to assess the PARylation status of HMGB1 in whole-cell extracts following 24 h of rotenone treatment. Cells were immunoprecipitated with an anti-HMGB1 antibody, and PAR ( upper panel ) and HMGB1 ( middle panel ; low and high exposures) levels were analyzed. Additionally, cells were immunoprecipitated with an anti-PAR antibody, and HMGB1 levels ( lower panel ) were examined. E , immunoblot analysis of HMGB1 protein levels in the nuclear and cytosolic fraction of cells treated with rotenone for 24 h in the presence or absence of the PARP inhibitor PJ34 (50μM). GAPDH was used as cytosolic loading control and lamin A/C was used as a nuclear loading control ( left panel ). The nuclear to cytoplasmic ratio was quantified using the lower band obtained in the cytoplasmic fraction of the gels ( right panel ). F , representative confocal images of HMGB1 ( green ) and DAPI (blue) in SH-SY5Y cells treated with rotenone or DMSO control in the presence of PJ34. DAPI ( blue ) indicates nuclear staining (scale bar = 10 μm). G , quantification of cells with cytoplasmic enrichment of HMGB1. n = 100 cells for each quantification. Data are presented as mean ± SD. Statistical significance was determined by one-way ANOVA with Tukey’s multiple comparison test (∗∗∗ p < 0.001; n = 3 biological replicates).

    Article Snippet: For determining the level of PARylation, anti-PAR antibody (#MCA-1480) and mouse monoclonal antibody for β-actin (#MCA5775GA) was obtained from Bio-Rad.

    Techniques: Control, Staining, Western Blot, Immunoprecipitation, Comparison