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grb2 knockout  (OriGene)


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    Structured Review

    OriGene grb2 knockout
    Figure 1. <t>GRB2</t> complexes with AGO2 under non-stimulated conditions. Schematic diagram of, (a) AGO2 and, (b) GRB2 domain structures. Domains are named and colour coded and attributed amino acid sequence number. Red arrows indicate positions of PXXP motifs investigated in this work. (c) Western blot of AGO2 co-immunoprecipitated with GRB2 in serum starved HEK293T, A498 and PC3 cells. A longer exposure was used to capture AGO2 bands than for GRB2 and GAPDH. All images are taken from the same western blot. (d) Fluorescence and fluorescence resonance energy transfer signals of RFP-tagged GRB2 and GFP-tagged AGO2. HEK293T cells overexpressing fluorescent proteins were serum-starved before imaging. N = 3. Scale bars are 10 μm.
    Grb2 Knockout, supplied by OriGene, used in various techniques. Bioz Stars score: 91/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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    Images

    1) Product Images from "Regulation of microRNA expression by the adaptor protein GRB2."

    Article Title: Regulation of microRNA expression by the adaptor protein GRB2.

    Journal: Scientific reports

    doi: 10.1038/s41598-023-36996-3

    Figure 1. GRB2 complexes with AGO2 under non-stimulated conditions. Schematic diagram of, (a) AGO2 and, (b) GRB2 domain structures. Domains are named and colour coded and attributed amino acid sequence number. Red arrows indicate positions of PXXP motifs investigated in this work. (c) Western blot of AGO2 co-immunoprecipitated with GRB2 in serum starved HEK293T, A498 and PC3 cells. A longer exposure was used to capture AGO2 bands than for GRB2 and GAPDH. All images are taken from the same western blot. (d) Fluorescence and fluorescence resonance energy transfer signals of RFP-tagged GRB2 and GFP-tagged AGO2. HEK293T cells overexpressing fluorescent proteins were serum-starved before imaging. N = 3. Scale bars are 10 μm.
    Figure Legend Snippet: Figure 1. GRB2 complexes with AGO2 under non-stimulated conditions. Schematic diagram of, (a) AGO2 and, (b) GRB2 domain structures. Domains are named and colour coded and attributed amino acid sequence number. Red arrows indicate positions of PXXP motifs investigated in this work. (c) Western blot of AGO2 co-immunoprecipitated with GRB2 in serum starved HEK293T, A498 and PC3 cells. A longer exposure was used to capture AGO2 bands than for GRB2 and GAPDH. All images are taken from the same western blot. (d) Fluorescence and fluorescence resonance energy transfer signals of RFP-tagged GRB2 and GFP-tagged AGO2. HEK293T cells overexpressing fluorescent proteins were serum-starved before imaging. N = 3. Scale bars are 10 μm.

    Techniques Used: Sequencing, Western Blot, Immunoprecipitation, Fluorescence, Förster Resonance Energy Transfer, Imaging

    Figure 2. Binding of GRB2 to AGO2 is mediated by GRB2 NSH3 and a PXXP motif in AGO2 PAZ domain. (a) Isothermal titration calorimetry (ITC) of a peptide spanning the proline-rich motif 323PHLP326 in AGO2 PAZ domain. (KD = 4.27 ± 1.17 µM). (b, c) ITC of MBP-tagged AGO2 PAZ domain titrated into GRB2. (b) PAZ WT (KD = 585 ± 61 nM). (c) No binding observed for mutation of PXXP (MBP-PAZ 4A). N = 2. (d) Fluorescence resonance energy transfer (FRET) between wild type (WT) and 323AAAA326 (4A) mutant GFP-tagged AGO2 and RFP-tagged GRB2 in HEK293T cells under conditions of serum starvation. White arrows indicate intracellular puncta which show increased FRET when WT AGO2 is expressed. N = 2. Scale bars are 10 μm. (e) Fluorescence lifetime imaging microscopy of RFP-tagged GRB2 proteins and GFP-AGO2 overexpressed in serum-starved HEK293T cells. The formation of a protein complex results in a reduction in fluorescent lifetime represented by a shift to the left of the population of fluorophores (measured in number of pixels). Lifetime population distribution shown by red line on graphs. x = Lifetime (ns), y = number of pixels. Solid black line corresponds to average fluorescent lifetime for GFP, 2.1 ns. Scale bars 25 μm. (f) Expanded region of interest (ROI) further exemplifying left-shift for AGO2/NSH3-SH2 interaction.
    Figure Legend Snippet: Figure 2. Binding of GRB2 to AGO2 is mediated by GRB2 NSH3 and a PXXP motif in AGO2 PAZ domain. (a) Isothermal titration calorimetry (ITC) of a peptide spanning the proline-rich motif 323PHLP326 in AGO2 PAZ domain. (KD = 4.27 ± 1.17 µM). (b, c) ITC of MBP-tagged AGO2 PAZ domain titrated into GRB2. (b) PAZ WT (KD = 585 ± 61 nM). (c) No binding observed for mutation of PXXP (MBP-PAZ 4A). N = 2. (d) Fluorescence resonance energy transfer (FRET) between wild type (WT) and 323AAAA326 (4A) mutant GFP-tagged AGO2 and RFP-tagged GRB2 in HEK293T cells under conditions of serum starvation. White arrows indicate intracellular puncta which show increased FRET when WT AGO2 is expressed. N = 2. Scale bars are 10 μm. (e) Fluorescence lifetime imaging microscopy of RFP-tagged GRB2 proteins and GFP-AGO2 overexpressed in serum-starved HEK293T cells. The formation of a protein complex results in a reduction in fluorescent lifetime represented by a shift to the left of the population of fluorophores (measured in number of pixels). Lifetime population distribution shown by red line on graphs. x = Lifetime (ns), y = number of pixels. Solid black line corresponds to average fluorescent lifetime for GFP, 2.1 ns. Scale bars 25 μm. (f) Expanded region of interest (ROI) further exemplifying left-shift for AGO2/NSH3-SH2 interaction.

    Techniques Used: Binding Assay, Isothermal Titration Calorimetry, Mutagenesis, Fluorescence, Förster Resonance Energy Transfer, Imaging, Microscopy

    Figure 3. Impact of GRB2-AGO2 complex on interaction with DICER1 and miRNA. (a) Western blot of AGO2 and DICER1 pulldown by GST-GRB2 in HEK293T cells. HEK293T cells were serum-starved before lysis. Bands captured with both a long and short exposure are shown for DICER1, whereas only the image captured with a short exposure is shown for AGO2. GST proteins were detected by ponceau stain. All images are taken from the same western blot. N = 3. (b–d) MST of AGO2 binding to DICER1 C-terminal region, upon pre-incubation of AGO2 with increasing concentrations of GRB2. The difference in binding affinity was negligible. (e) MST of GRB2 with DICER1 C-terminal region. No binding is observed within a physiologically relevant range hence the two do not interact directly. (f) Expanded ribbon model of molecular docking of GRB2 (green; PDB: 1GRI77) to AGO2 PAZ domain (cyan; red and blue indicate positive and negative charges respectively; PDB: 6RA478). The 323PHLP326 sequence is shown (yellow). GRB2 W36 (magenta) interacts with AGO2 P249 (red). Other residues in GRB2 which may contribute towards the interaction are shown in orange. Also shown is space-filling representation of AGO2 PAZ domain with PRM shown (below); and ribbon model of PAZ domain rotated by 90° to highlight juxtaposition of GRB2 binding site PRM and docking site for miRNA (right). Figures generated using PyMOL.
    Figure Legend Snippet: Figure 3. Impact of GRB2-AGO2 complex on interaction with DICER1 and miRNA. (a) Western blot of AGO2 and DICER1 pulldown by GST-GRB2 in HEK293T cells. HEK293T cells were serum-starved before lysis. Bands captured with both a long and short exposure are shown for DICER1, whereas only the image captured with a short exposure is shown for AGO2. GST proteins were detected by ponceau stain. All images are taken from the same western blot. N = 3. (b–d) MST of AGO2 binding to DICER1 C-terminal region, upon pre-incubation of AGO2 with increasing concentrations of GRB2. The difference in binding affinity was negligible. (e) MST of GRB2 with DICER1 C-terminal region. No binding is observed within a physiologically relevant range hence the two do not interact directly. (f) Expanded ribbon model of molecular docking of GRB2 (green; PDB: 1GRI77) to AGO2 PAZ domain (cyan; red and blue indicate positive and negative charges respectively; PDB: 6RA478). The 323PHLP326 sequence is shown (yellow). GRB2 W36 (magenta) interacts with AGO2 P249 (red). Other residues in GRB2 which may contribute towards the interaction are shown in orange. Also shown is space-filling representation of AGO2 PAZ domain with PRM shown (below); and ribbon model of PAZ domain rotated by 90° to highlight juxtaposition of GRB2 binding site PRM and docking site for miRNA (right). Figures generated using PyMOL.

    Techniques Used: Western Blot, Lysis, Staining, Binding Assay, Incubation, Sequencing, Generated

    Figure 4. GRB2 regulates miRNA expression in HEK293T cells. (a) Western blot of GRB2 expression in wild type (293 T) and depleted (G1) HEK293T clones 1 (G1.1) and 2 (G1.2). While G1.1 is a complete knockout, G1.2 contains a deletion and large insertion in the N-terminal SH3 domain. GRB2 was blotted with an antibody which recognised the C-terminal SH3 domain. Both long and short exposures were used to capture the GRB2 bands, whereas the GAPDH image was captured using a short exposure only. All images are taken from the same western blot. N = 3. (b) Heat plot highlighting miRNAs which show significant log2(fold changes) in expression (p < 0.05) between wild type HEK293T and G1 cells, measured by small RNA sequencing. Cells were deprived of growth factor. miRNAs demonstrated positive (red) and negative (blue) expression changes. N = 2. (c, d) RT-qPCR analysis of fold-change in mean expression of precursor miRNA transcripts (precursor and primary, pre-mir-, hashed bars) and mature miRNA (miR-, plain bars) derived from serum-starved G1 or wild type HEK293T cells. Two groups of miRNAs were observed: (c) miRNAs which diminished at both the level of the precursor and mature transcripts and, (d) miRNAs which were enhanced as mature transcripts but not as precursors. Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 4. ns = not significant.
    Figure Legend Snippet: Figure 4. GRB2 regulates miRNA expression in HEK293T cells. (a) Western blot of GRB2 expression in wild type (293 T) and depleted (G1) HEK293T clones 1 (G1.1) and 2 (G1.2). While G1.1 is a complete knockout, G1.2 contains a deletion and large insertion in the N-terminal SH3 domain. GRB2 was blotted with an antibody which recognised the C-terminal SH3 domain. Both long and short exposures were used to capture the GRB2 bands, whereas the GAPDH image was captured using a short exposure only. All images are taken from the same western blot. N = 3. (b) Heat plot highlighting miRNAs which show significant log2(fold changes) in expression (p < 0.05) between wild type HEK293T and G1 cells, measured by small RNA sequencing. Cells were deprived of growth factor. miRNAs demonstrated positive (red) and negative (blue) expression changes. N = 2. (c, d) RT-qPCR analysis of fold-change in mean expression of precursor miRNA transcripts (precursor and primary, pre-mir-, hashed bars) and mature miRNA (miR-, plain bars) derived from serum-starved G1 or wild type HEK293T cells. Two groups of miRNAs were observed: (c) miRNAs which diminished at both the level of the precursor and mature transcripts and, (d) miRNAs which were enhanced as mature transcripts but not as precursors. Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 4. ns = not significant.

    Techniques Used: Expressing, Western Blot, Clone Assay, Knock-Out, RNA Sequencing, Quantitative RT-PCR, Derivative Assay, Two Tailed Test

    Figure 5. The GRB2-let-7 axis regulates oncogene expression. (a) RT-qPCR measurement of fold change in mean expression of let-7 g-5p miRNA and five target mRNAs in serum-starved GRB2 knockout cells (G1) compared to wild type HEK293T (293 T). Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 3. (b) Western blot and (c) quantification of mean protein expression of let-7 targets in growth-factor-deprived G1 and HEK293T cells. The higher molecular band detected by the GRB2 antibody in G1 corresponds to an NSH3-mutated GRB2 polypeptide. For blot 1, a longer exposure was used to capture the DICER1 and GRB2 bands than was used for LIN28B and α-Tubulin. For blot 2, HMGA2 bands were captured using a longer exposure than that required for GRB2 and GAPDH. (d) Quantification of the area covered by migration of HEK293T cells expressing GFP-tagged wild type AGO2 (WT) or an AGO2 mutant which is incapable of binding GRB2 (4A), under conditions of reduced growth factor. Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 3.
    Figure Legend Snippet: Figure 5. The GRB2-let-7 axis regulates oncogene expression. (a) RT-qPCR measurement of fold change in mean expression of let-7 g-5p miRNA and five target mRNAs in serum-starved GRB2 knockout cells (G1) compared to wild type HEK293T (293 T). Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 3. (b) Western blot and (c) quantification of mean protein expression of let-7 targets in growth-factor-deprived G1 and HEK293T cells. The higher molecular band detected by the GRB2 antibody in G1 corresponds to an NSH3-mutated GRB2 polypeptide. For blot 1, a longer exposure was used to capture the DICER1 and GRB2 bands than was used for LIN28B and α-Tubulin. For blot 2, HMGA2 bands were captured using a longer exposure than that required for GRB2 and GAPDH. (d) Quantification of the area covered by migration of HEK293T cells expressing GFP-tagged wild type AGO2 (WT) or an AGO2 mutant which is incapable of binding GRB2 (4A), under conditions of reduced growth factor. Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 3.

    Techniques Used: Expressing, Quantitative RT-PCR, Knock-Out, Two Tailed Test, Western Blot, Migration, Mutagenesis, Binding Assay



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    Figure 1. <t>GRB2</t> complexes with AGO2 under non-stimulated conditions. Schematic diagram of, (a) AGO2 and, (b) GRB2 domain structures. Domains are named and colour coded and attributed amino acid sequence number. Red arrows indicate positions of PXXP motifs investigated in this work. (c) Western blot of AGO2 co-immunoprecipitated with GRB2 in serum starved HEK293T, A498 and PC3 cells. A longer exposure was used to capture AGO2 bands than for GRB2 and GAPDH. All images are taken from the same western blot. (d) Fluorescence and fluorescence resonance energy transfer signals of RFP-tagged GRB2 and GFP-tagged AGO2. HEK293T cells overexpressing fluorescent proteins were serum-starved before imaging. N = 3. Scale bars are 10 μm.
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    Figure 1. <t>GRB2</t> complexes with AGO2 under non-stimulated conditions. Schematic diagram of, (a) AGO2 and, (b) GRB2 domain structures. Domains are named and colour coded and attributed amino acid sequence number. Red arrows indicate positions of PXXP motifs investigated in this work. (c) Western blot of AGO2 co-immunoprecipitated with GRB2 in serum starved HEK293T, A498 and PC3 cells. A longer exposure was used to capture AGO2 bands than for GRB2 and GAPDH. All images are taken from the same western blot. (d) Fluorescence and fluorescence resonance energy transfer signals of RFP-tagged GRB2 and GFP-tagged AGO2. HEK293T cells overexpressing fluorescent proteins were serum-starved before imaging. N = 3. Scale bars are 10 μm.
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    Image Search Results


    misPLA analyses of phosphorylation states and protein-protein interactions in SK-BR cells with or without EGF stimulation. A) Phosphorylation targets: SK-BR cells were analyzed for phosphorylation of STAT5a (pSTAT5a), STAT3 (pSTAT3), AKT (pAKT), ERK (pERK), and EGFR (pEGFR), under unstimulated and EGF-stimulated conditions. All targets were visualized three at a time in sequential detection cycles and are shown simultaneously (upper panels, “All targets”) and subsequently as individual channels. PLA signals (red, cyan, green, purple) reflect activated protein states detected via dual-recognition proximity ligation. DAPI (blue) labels nuclei. Scale bars = 50 µm. B) Protein-protein interactions: Visualization of the following protein-protein interactions investigated by misPLA in unstimulated and EGF-stimulated SK-BR cells: MEK1–ERK2, GRB2–MEK1, EGFR–GRB2, STAT3–STAT5a, JAK1–JAK3, JAK1–PI3K, JAK2–STAT5a, JAK1–STAT3, and JAK2–JAK3. Upper panels (“All targets”) represent simultaneous visualization of all targets, imaged three at a time in sequential detection cycles, followed by separated signals per interaction. Scale bars = 50 µm.

    Journal: bioRxiv

    Article Title: Spatial mapping of proteins and their activity states in cancer models by multiplex in situ PLA

    doi: 10.1101/2025.07.11.662357

    Figure Lengend Snippet: misPLA analyses of phosphorylation states and protein-protein interactions in SK-BR cells with or without EGF stimulation. A) Phosphorylation targets: SK-BR cells were analyzed for phosphorylation of STAT5a (pSTAT5a), STAT3 (pSTAT3), AKT (pAKT), ERK (pERK), and EGFR (pEGFR), under unstimulated and EGF-stimulated conditions. All targets were visualized three at a time in sequential detection cycles and are shown simultaneously (upper panels, “All targets”) and subsequently as individual channels. PLA signals (red, cyan, green, purple) reflect activated protein states detected via dual-recognition proximity ligation. DAPI (blue) labels nuclei. Scale bars = 50 µm. B) Protein-protein interactions: Visualization of the following protein-protein interactions investigated by misPLA in unstimulated and EGF-stimulated SK-BR cells: MEK1–ERK2, GRB2–MEK1, EGFR–GRB2, STAT3–STAT5a, JAK1–JAK3, JAK1–PI3K, JAK2–STAT5a, JAK1–STAT3, and JAK2–JAK3. Upper panels (“All targets”) represent simultaneous visualization of all targets, imaged three at a time in sequential detection cycles, followed by separated signals per interaction. Scale bars = 50 µm.

    Article Snippet: The following primary antibodies were used for Western blotting: JAK1 (ProteinTech, 66466-1-Ig), STAT3 (ProteinTech, 60199-1-Ig; Abcam, ab171359), MEK1 (Abcam, ab239802), EGFR (Abcam, ab271834), AKT2 (Thermo Scientific, PA5-85518), ERK2 (Thermo Fisher, PA5-29636), phospho-PI3K p85/p55 (Cell Signaling Technology, 4228S), pSTAT3-Y705 (R&D Systems, AF4607), Grb2 (R&D Systems, mab38461), GAPDH (CST, 14C10), and Vinculin (CST, E1E9V), used at either 1:1000 or 1:2000 dilution.

    Techniques: Phospho-proteomics, Protein-Protein interactions, Ligation

    misPLA mapping of signaling interactions in a lymph-node Hodgkin lymphoma, mixed cellularity (right neck); Hodgkin lymphoma, lymphocyte-depleted (neck); Hodgkin lymphoma, lymphocyte-predominant (left neck); Hodgkin lymphoma, mixed cellularity (left neck); and thymoma type B3 (mediastinum). Top row (visualization cycle 1) displays MEK1–ERK2 (FITC), EGFR–GRB2 (Cy5) and GRB2–MEK1 (Cy3N) together with DAPI. Middle row (cycle 2) shows STAT3–STAT5a (FITC), JAK1–JAK3 (Cy5) and JAK1–PI3Kp85 (Cy3N). Bottom row (cycle 3) presents JAK2– STAT5a (FITC), JAK2–JAK3 (Cy5) and JAK1–STAT3 (Cy3N). All nine pairs of antibody-oligonucleotide conjugates were applied and then amplified in a single incubation. The RCA products were revealed using detection oligonucleotides conjugated with three fluorophores in three visualization cycles. A standard three-channel fluorescence microscope was used with identical settings for all three fluorophores. Scale bars, 50 µm.

    Journal: bioRxiv

    Article Title: Spatial mapping of proteins and their activity states in cancer models by multiplex in situ PLA

    doi: 10.1101/2025.07.11.662357

    Figure Lengend Snippet: misPLA mapping of signaling interactions in a lymph-node Hodgkin lymphoma, mixed cellularity (right neck); Hodgkin lymphoma, lymphocyte-depleted (neck); Hodgkin lymphoma, lymphocyte-predominant (left neck); Hodgkin lymphoma, mixed cellularity (left neck); and thymoma type B3 (mediastinum). Top row (visualization cycle 1) displays MEK1–ERK2 (FITC), EGFR–GRB2 (Cy5) and GRB2–MEK1 (Cy3N) together with DAPI. Middle row (cycle 2) shows STAT3–STAT5a (FITC), JAK1–JAK3 (Cy5) and JAK1–PI3Kp85 (Cy3N). Bottom row (cycle 3) presents JAK2– STAT5a (FITC), JAK2–JAK3 (Cy5) and JAK1–STAT3 (Cy3N). All nine pairs of antibody-oligonucleotide conjugates were applied and then amplified in a single incubation. The RCA products were revealed using detection oligonucleotides conjugated with three fluorophores in three visualization cycles. A standard three-channel fluorescence microscope was used with identical settings for all three fluorophores. Scale bars, 50 µm.

    Article Snippet: The following primary antibodies were used for Western blotting: JAK1 (ProteinTech, 66466-1-Ig), STAT3 (ProteinTech, 60199-1-Ig; Abcam, ab171359), MEK1 (Abcam, ab239802), EGFR (Abcam, ab271834), AKT2 (Thermo Scientific, PA5-85518), ERK2 (Thermo Fisher, PA5-29636), phospho-PI3K p85/p55 (Cell Signaling Technology, 4228S), pSTAT3-Y705 (R&D Systems, AF4607), Grb2 (R&D Systems, mab38461), GAPDH (CST, 14C10), and Vinculin (CST, E1E9V), used at either 1:1000 or 1:2000 dilution.

    Techniques: Amplification, Incubation, Fluorescence, Microscopy

    Analysis of primary blood cells from two patients diagnosed with CML, targeting molecular pathways known to be up-regulated in CML. The experiment used a slightly different oligonucleotide design compared to other experiments reported herein, but with similar performance ( .) A, E) Quantitative analysis of numbers of signals per cell revealed striking differences among individual blood cells. Top and bottom rows represent data for two different CML patients. Visualization cycle 1: phosphoPI3K-AKT1 in Cy3 (red), phosphoAKT1-AKT3 in Cy5 (green), AKT(pan)-AKT2 in FITC (yellow). Cycle 2: JAK2-JAK3 in Cy3 (blue), phosphorylated GRB2 in Cy5 (orange), MEK1-ERK in FITC (purple). Cycle 3: STAT3-phosphoSTAT3 in Cy5 (cyan), STAT3-phosphoSTAT3 in FITC (magenta) and STAT3-STAT5 in Cy3 (lime). The same color coding was used throughout all panels in the figure. B, F) Scatterplots of pairs of detection reactions, serving to visualize correlations across detection pairs (colors as in A, B)). C, G) Visualization of a zoomed-in view of detection reactions per cell. Outline of nuclei are shown in red. D, H) Cell to cell heterogeneity is visualized by overlaying individual detection reactions on the cells - here showing zoomed in region with D) phosphorylated GRB2 (in orange) and (h) STAT3-phosphoSTAT3 (in magenta). Cell nuclei are outlined in red. The raw image data from the full sample, together with detections are available for interactive viewing at https://ulflandegren2025.serve.scilifelab.se .

    Journal: bioRxiv

    Article Title: Spatial mapping of proteins and their activity states in cancer models by multiplex in situ PLA

    doi: 10.1101/2025.07.11.662357

    Figure Lengend Snippet: Analysis of primary blood cells from two patients diagnosed with CML, targeting molecular pathways known to be up-regulated in CML. The experiment used a slightly different oligonucleotide design compared to other experiments reported herein, but with similar performance ( .) A, E) Quantitative analysis of numbers of signals per cell revealed striking differences among individual blood cells. Top and bottom rows represent data for two different CML patients. Visualization cycle 1: phosphoPI3K-AKT1 in Cy3 (red), phosphoAKT1-AKT3 in Cy5 (green), AKT(pan)-AKT2 in FITC (yellow). Cycle 2: JAK2-JAK3 in Cy3 (blue), phosphorylated GRB2 in Cy5 (orange), MEK1-ERK in FITC (purple). Cycle 3: STAT3-phosphoSTAT3 in Cy5 (cyan), STAT3-phosphoSTAT3 in FITC (magenta) and STAT3-STAT5 in Cy3 (lime). The same color coding was used throughout all panels in the figure. B, F) Scatterplots of pairs of detection reactions, serving to visualize correlations across detection pairs (colors as in A, B)). C, G) Visualization of a zoomed-in view of detection reactions per cell. Outline of nuclei are shown in red. D, H) Cell to cell heterogeneity is visualized by overlaying individual detection reactions on the cells - here showing zoomed in region with D) phosphorylated GRB2 (in orange) and (h) STAT3-phosphoSTAT3 (in magenta). Cell nuclei are outlined in red. The raw image data from the full sample, together with detections are available for interactive viewing at https://ulflandegren2025.serve.scilifelab.se .

    Article Snippet: The following primary antibodies were used for Western blotting: JAK1 (ProteinTech, 66466-1-Ig), STAT3 (ProteinTech, 60199-1-Ig; Abcam, ab171359), MEK1 (Abcam, ab239802), EGFR (Abcam, ab271834), AKT2 (Thermo Scientific, PA5-85518), ERK2 (Thermo Fisher, PA5-29636), phospho-PI3K p85/p55 (Cell Signaling Technology, 4228S), pSTAT3-Y705 (R&D Systems, AF4607), Grb2 (R&D Systems, mab38461), GAPDH (CST, 14C10), and Vinculin (CST, E1E9V), used at either 1:1000 or 1:2000 dilution.

    Techniques:

    Figure 1. GRB2 complexes with AGO2 under non-stimulated conditions. Schematic diagram of, (a) AGO2 and, (b) GRB2 domain structures. Domains are named and colour coded and attributed amino acid sequence number. Red arrows indicate positions of PXXP motifs investigated in this work. (c) Western blot of AGO2 co-immunoprecipitated with GRB2 in serum starved HEK293T, A498 and PC3 cells. A longer exposure was used to capture AGO2 bands than for GRB2 and GAPDH. All images are taken from the same western blot. (d) Fluorescence and fluorescence resonance energy transfer signals of RFP-tagged GRB2 and GFP-tagged AGO2. HEK293T cells overexpressing fluorescent proteins were serum-starved before imaging. N = 3. Scale bars are 10 μm.

    Journal: Scientific reports

    Article Title: Regulation of microRNA expression by the adaptor protein GRB2.

    doi: 10.1038/s41598-023-36996-3

    Figure Lengend Snippet: Figure 1. GRB2 complexes with AGO2 under non-stimulated conditions. Schematic diagram of, (a) AGO2 and, (b) GRB2 domain structures. Domains are named and colour coded and attributed amino acid sequence number. Red arrows indicate positions of PXXP motifs investigated in this work. (c) Western blot of AGO2 co-immunoprecipitated with GRB2 in serum starved HEK293T, A498 and PC3 cells. A longer exposure was used to capture AGO2 bands than for GRB2 and GAPDH. All images are taken from the same western blot. (d) Fluorescence and fluorescence resonance energy transfer signals of RFP-tagged GRB2 and GFP-tagged AGO2. HEK293T cells overexpressing fluorescent proteins were serum-starved before imaging. N = 3. Scale bars are 10 μm.

    Article Snippet: GRB2 knockout was achieved using the homology-directed repair (HDR)-mediated knockout kit (OriGene, KN200469), which utilises CRISPR/Cas9 technology to insert puromycin resistance and GFP genes into the start of GRB2.

    Techniques: Sequencing, Western Blot, Immunoprecipitation, Fluorescence, Förster Resonance Energy Transfer, Imaging

    Figure 2. Binding of GRB2 to AGO2 is mediated by GRB2 NSH3 and a PXXP motif in AGO2 PAZ domain. (a) Isothermal titration calorimetry (ITC) of a peptide spanning the proline-rich motif 323PHLP326 in AGO2 PAZ domain. (KD = 4.27 ± 1.17 µM). (b, c) ITC of MBP-tagged AGO2 PAZ domain titrated into GRB2. (b) PAZ WT (KD = 585 ± 61 nM). (c) No binding observed for mutation of PXXP (MBP-PAZ 4A). N = 2. (d) Fluorescence resonance energy transfer (FRET) between wild type (WT) and 323AAAA326 (4A) mutant GFP-tagged AGO2 and RFP-tagged GRB2 in HEK293T cells under conditions of serum starvation. White arrows indicate intracellular puncta which show increased FRET when WT AGO2 is expressed. N = 2. Scale bars are 10 μm. (e) Fluorescence lifetime imaging microscopy of RFP-tagged GRB2 proteins and GFP-AGO2 overexpressed in serum-starved HEK293T cells. The formation of a protein complex results in a reduction in fluorescent lifetime represented by a shift to the left of the population of fluorophores (measured in number of pixels). Lifetime population distribution shown by red line on graphs. x = Lifetime (ns), y = number of pixels. Solid black line corresponds to average fluorescent lifetime for GFP, 2.1 ns. Scale bars 25 μm. (f) Expanded region of interest (ROI) further exemplifying left-shift for AGO2/NSH3-SH2 interaction.

    Journal: Scientific reports

    Article Title: Regulation of microRNA expression by the adaptor protein GRB2.

    doi: 10.1038/s41598-023-36996-3

    Figure Lengend Snippet: Figure 2. Binding of GRB2 to AGO2 is mediated by GRB2 NSH3 and a PXXP motif in AGO2 PAZ domain. (a) Isothermal titration calorimetry (ITC) of a peptide spanning the proline-rich motif 323PHLP326 in AGO2 PAZ domain. (KD = 4.27 ± 1.17 µM). (b, c) ITC of MBP-tagged AGO2 PAZ domain titrated into GRB2. (b) PAZ WT (KD = 585 ± 61 nM). (c) No binding observed for mutation of PXXP (MBP-PAZ 4A). N = 2. (d) Fluorescence resonance energy transfer (FRET) between wild type (WT) and 323AAAA326 (4A) mutant GFP-tagged AGO2 and RFP-tagged GRB2 in HEK293T cells under conditions of serum starvation. White arrows indicate intracellular puncta which show increased FRET when WT AGO2 is expressed. N = 2. Scale bars are 10 μm. (e) Fluorescence lifetime imaging microscopy of RFP-tagged GRB2 proteins and GFP-AGO2 overexpressed in serum-starved HEK293T cells. The formation of a protein complex results in a reduction in fluorescent lifetime represented by a shift to the left of the population of fluorophores (measured in number of pixels). Lifetime population distribution shown by red line on graphs. x = Lifetime (ns), y = number of pixels. Solid black line corresponds to average fluorescent lifetime for GFP, 2.1 ns. Scale bars 25 μm. (f) Expanded region of interest (ROI) further exemplifying left-shift for AGO2/NSH3-SH2 interaction.

    Article Snippet: GRB2 knockout was achieved using the homology-directed repair (HDR)-mediated knockout kit (OriGene, KN200469), which utilises CRISPR/Cas9 technology to insert puromycin resistance and GFP genes into the start of GRB2.

    Techniques: Binding Assay, Isothermal Titration Calorimetry, Mutagenesis, Fluorescence, Förster Resonance Energy Transfer, Imaging, Microscopy

    Figure 3. Impact of GRB2-AGO2 complex on interaction with DICER1 and miRNA. (a) Western blot of AGO2 and DICER1 pulldown by GST-GRB2 in HEK293T cells. HEK293T cells were serum-starved before lysis. Bands captured with both a long and short exposure are shown for DICER1, whereas only the image captured with a short exposure is shown for AGO2. GST proteins were detected by ponceau stain. All images are taken from the same western blot. N = 3. (b–d) MST of AGO2 binding to DICER1 C-terminal region, upon pre-incubation of AGO2 with increasing concentrations of GRB2. The difference in binding affinity was negligible. (e) MST of GRB2 with DICER1 C-terminal region. No binding is observed within a physiologically relevant range hence the two do not interact directly. (f) Expanded ribbon model of molecular docking of GRB2 (green; PDB: 1GRI77) to AGO2 PAZ domain (cyan; red and blue indicate positive and negative charges respectively; PDB: 6RA478). The 323PHLP326 sequence is shown (yellow). GRB2 W36 (magenta) interacts with AGO2 P249 (red). Other residues in GRB2 which may contribute towards the interaction are shown in orange. Also shown is space-filling representation of AGO2 PAZ domain with PRM shown (below); and ribbon model of PAZ domain rotated by 90° to highlight juxtaposition of GRB2 binding site PRM and docking site for miRNA (right). Figures generated using PyMOL.

    Journal: Scientific reports

    Article Title: Regulation of microRNA expression by the adaptor protein GRB2.

    doi: 10.1038/s41598-023-36996-3

    Figure Lengend Snippet: Figure 3. Impact of GRB2-AGO2 complex on interaction with DICER1 and miRNA. (a) Western blot of AGO2 and DICER1 pulldown by GST-GRB2 in HEK293T cells. HEK293T cells were serum-starved before lysis. Bands captured with both a long and short exposure are shown for DICER1, whereas only the image captured with a short exposure is shown for AGO2. GST proteins were detected by ponceau stain. All images are taken from the same western blot. N = 3. (b–d) MST of AGO2 binding to DICER1 C-terminal region, upon pre-incubation of AGO2 with increasing concentrations of GRB2. The difference in binding affinity was negligible. (e) MST of GRB2 with DICER1 C-terminal region. No binding is observed within a physiologically relevant range hence the two do not interact directly. (f) Expanded ribbon model of molecular docking of GRB2 (green; PDB: 1GRI77) to AGO2 PAZ domain (cyan; red and blue indicate positive and negative charges respectively; PDB: 6RA478). The 323PHLP326 sequence is shown (yellow). GRB2 W36 (magenta) interacts with AGO2 P249 (red). Other residues in GRB2 which may contribute towards the interaction are shown in orange. Also shown is space-filling representation of AGO2 PAZ domain with PRM shown (below); and ribbon model of PAZ domain rotated by 90° to highlight juxtaposition of GRB2 binding site PRM and docking site for miRNA (right). Figures generated using PyMOL.

    Article Snippet: GRB2 knockout was achieved using the homology-directed repair (HDR)-mediated knockout kit (OriGene, KN200469), which utilises CRISPR/Cas9 technology to insert puromycin resistance and GFP genes into the start of GRB2.

    Techniques: Western Blot, Lysis, Staining, Binding Assay, Incubation, Sequencing, Generated

    Figure 4. GRB2 regulates miRNA expression in HEK293T cells. (a) Western blot of GRB2 expression in wild type (293 T) and depleted (G1) HEK293T clones 1 (G1.1) and 2 (G1.2). While G1.1 is a complete knockout, G1.2 contains a deletion and large insertion in the N-terminal SH3 domain. GRB2 was blotted with an antibody which recognised the C-terminal SH3 domain. Both long and short exposures were used to capture the GRB2 bands, whereas the GAPDH image was captured using a short exposure only. All images are taken from the same western blot. N = 3. (b) Heat plot highlighting miRNAs which show significant log2(fold changes) in expression (p < 0.05) between wild type HEK293T and G1 cells, measured by small RNA sequencing. Cells were deprived of growth factor. miRNAs demonstrated positive (red) and negative (blue) expression changes. N = 2. (c, d) RT-qPCR analysis of fold-change in mean expression of precursor miRNA transcripts (precursor and primary, pre-mir-, hashed bars) and mature miRNA (miR-, plain bars) derived from serum-starved G1 or wild type HEK293T cells. Two groups of miRNAs were observed: (c) miRNAs which diminished at both the level of the precursor and mature transcripts and, (d) miRNAs which were enhanced as mature transcripts but not as precursors. Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 4. ns = not significant.

    Journal: Scientific reports

    Article Title: Regulation of microRNA expression by the adaptor protein GRB2.

    doi: 10.1038/s41598-023-36996-3

    Figure Lengend Snippet: Figure 4. GRB2 regulates miRNA expression in HEK293T cells. (a) Western blot of GRB2 expression in wild type (293 T) and depleted (G1) HEK293T clones 1 (G1.1) and 2 (G1.2). While G1.1 is a complete knockout, G1.2 contains a deletion and large insertion in the N-terminal SH3 domain. GRB2 was blotted with an antibody which recognised the C-terminal SH3 domain. Both long and short exposures were used to capture the GRB2 bands, whereas the GAPDH image was captured using a short exposure only. All images are taken from the same western blot. N = 3. (b) Heat plot highlighting miRNAs which show significant log2(fold changes) in expression (p < 0.05) between wild type HEK293T and G1 cells, measured by small RNA sequencing. Cells were deprived of growth factor. miRNAs demonstrated positive (red) and negative (blue) expression changes. N = 2. (c, d) RT-qPCR analysis of fold-change in mean expression of precursor miRNA transcripts (precursor and primary, pre-mir-, hashed bars) and mature miRNA (miR-, plain bars) derived from serum-starved G1 or wild type HEK293T cells. Two groups of miRNAs were observed: (c) miRNAs which diminished at both the level of the precursor and mature transcripts and, (d) miRNAs which were enhanced as mature transcripts but not as precursors. Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 4. ns = not significant.

    Article Snippet: GRB2 knockout was achieved using the homology-directed repair (HDR)-mediated knockout kit (OriGene, KN200469), which utilises CRISPR/Cas9 technology to insert puromycin resistance and GFP genes into the start of GRB2.

    Techniques: Expressing, Western Blot, Clone Assay, Knock-Out, RNA Sequencing, Quantitative RT-PCR, Derivative Assay, Two Tailed Test

    Figure 5. The GRB2-let-7 axis regulates oncogene expression. (a) RT-qPCR measurement of fold change in mean expression of let-7 g-5p miRNA and five target mRNAs in serum-starved GRB2 knockout cells (G1) compared to wild type HEK293T (293 T). Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 3. (b) Western blot and (c) quantification of mean protein expression of let-7 targets in growth-factor-deprived G1 and HEK293T cells. The higher molecular band detected by the GRB2 antibody in G1 corresponds to an NSH3-mutated GRB2 polypeptide. For blot 1, a longer exposure was used to capture the DICER1 and GRB2 bands than was used for LIN28B and α-Tubulin. For blot 2, HMGA2 bands were captured using a longer exposure than that required for GRB2 and GAPDH. (d) Quantification of the area covered by migration of HEK293T cells expressing GFP-tagged wild type AGO2 (WT) or an AGO2 mutant which is incapable of binding GRB2 (4A), under conditions of reduced growth factor. Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 3.

    Journal: Scientific reports

    Article Title: Regulation of microRNA expression by the adaptor protein GRB2.

    doi: 10.1038/s41598-023-36996-3

    Figure Lengend Snippet: Figure 5. The GRB2-let-7 axis regulates oncogene expression. (a) RT-qPCR measurement of fold change in mean expression of let-7 g-5p miRNA and five target mRNAs in serum-starved GRB2 knockout cells (G1) compared to wild type HEK293T (293 T). Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 3. (b) Western blot and (c) quantification of mean protein expression of let-7 targets in growth-factor-deprived G1 and HEK293T cells. The higher molecular band detected by the GRB2 antibody in G1 corresponds to an NSH3-mutated GRB2 polypeptide. For blot 1, a longer exposure was used to capture the DICER1 and GRB2 bands than was used for LIN28B and α-Tubulin. For blot 2, HMGA2 bands were captured using a longer exposure than that required for GRB2 and GAPDH. (d) Quantification of the area covered by migration of HEK293T cells expressing GFP-tagged wild type AGO2 (WT) or an AGO2 mutant which is incapable of binding GRB2 (4A), under conditions of reduced growth factor. Comparisons were made using a two-tailed Student’s t-test and error bars show standard error of mean. N = 3.

    Article Snippet: GRB2 knockout was achieved using the homology-directed repair (HDR)-mediated knockout kit (OriGene, KN200469), which utilises CRISPR/Cas9 technology to insert puromycin resistance and GFP genes into the start of GRB2.

    Techniques: Expressing, Quantitative RT-PCR, Knock-Out, Two Tailed Test, Western Blot, Migration, Mutagenesis, Binding Assay