Journal: bioRxiv

Article Title: Invasion of glioma cells through confined space requires membrane tension regulation and mechano-electrical coupling via Plexin-B2

doi: 10.1101/2024.01.02.573660

Figure Lengend Snippet: (A) Schematic of CRISPR/Cas9-mediated PLXNB2 knockout (KO) with small guide (sg) RNA targeting second coding exon. (B) Western blots show Plexin-B2 expression in different SD2 GSCs, with β-actin as loading control. Note Plexin-B2 precursor at 240 kDa and mature form at 170 kDa. (C) IF images show Plexin-B2 expression in different SD2 GSCs, with Hoechst nuclear counterstain. (D) Left, schematic of atomic force microscopy (AFM) indentation method to probe cell stiffness by cantilever deflection. Middle, AFM indentation curves of different SD2 GSCs; right, box plots of cell stiffness, showing 25– 75% quartiles, median (line), and mean (plus sign). n= 6 cells per group. Kruskal–Wallis test followed by Dunn’s multiple comparisons test. (E) Left, depiction of membrane tension measurement with optical tweezers. Middle, force measurements during tether extrusion (shaded box). Right, quantifications of tether extrusion forces. n=5 cells per group. Kruskal–Wallis test followed by Dunn’s multiple comparisons test. (F) Left, schematic of FLIM of cell membranes labeled with Flipper-TR membrane dye, with low and high membrane tension associated with shorter and longer lifetimes, respectively. Middle top, representative FLIM images, with lifetime heatmap shown on right. Middle bottom, images show similar fluorescence intensities of Flipper-TR dye in WT and PB2 KO cells. Right top, violin plots show fluorescence lifetime from 3 images per group. Two-sided unpaired t-test. Right bottom, phasor plots of FLIM image data, with arrow indicating a shift to shorter lifetime values for PB2 KO cells. (G) Model of Plexin-B2 regulation of cortical contractility and membrane tension. Phalloidin staining show differences of F-actin network in WT and PB2 KO SD2 GSCs. DAPI for nuclear staining. Arrows point to stress fibers and spread-out contours of the WT GSCs.

Article Snippet: The lentiviral vector for Dox-inducible Plexin-B2 overexpression was generated by inserting human PLXNB2 cDNA into a Dox controlled expression vector (pLenti-CMVtight-PLXNB2 iOE; deposited as Addgene #176849) .

Techniques: CRISPR, Knock-Out, Western Blot, Expressing, Control, Microscopy, Membrane, Labeling, Fluorescence, Staining

Journal: bioRxiv

Article Title: Invasion of glioma cells through confined space requires membrane tension regulation and mechano-electrical coupling via Plexin-B2

doi: 10.1101/2024.01.02.573660

Figure Lengend Snippet: (A) Top, timeline for dextran uptake assay. Bottom, live-cell imaging of WT and PB2 KO SD2 GSCs labeled with SPY-Actin and exposed to dextran-Alexa488. Enlarged images of boxed areas are shown below. Quantification of the areas of dextran + clusters per cell are shown in box plots, with 25–75% quartiles, median (line), and mean (plus sign). n=85 cells for WT, n=44 cells for PB2 KO. Mann–Whitney–Wilcoxon test. (B) Top, live cell confocal plane images of WT and PB2 KO GSCs with side views of z-stacks showing intracellular localization of diffuse dextran-Alexa 488 signals in PB2 KO cells in addition to dextran endosome signals. In contrast, WT cells contained only dextran + endosomes. Bottom, histograms show fluorescence profiles showing bimodal distribution of dextran-Alexa 488 fluorescence intensities in PB2 KO GSCs (blue and brown arrows). n=177 cells for WT, n=161 cells for PB2 KO. Mann–Whitney–Wilcoxon test. (C, D) Left, schematic of myr-palm-GFP or -CFP attached to inner membrane leaflet. Right, live cell fluorescence imaging at 72 hr after transfection shows internalization of myr-palm-GFP or -CPF on endomembranes (arrow) in WT GSCs, in contrast to membrane retention of the probes (arrowhead) in PB2 KO GSCs. (E) Left, schematic of TauSTED super-resolution microscopy of GSCs labeled with MemGlow. Middle, TauSTED live-cell images show reduced endosomes (arrowheads) in PB2 KO cells compared to WT. Right, box plots show areas of MemGlow clusters in each cell. n=26 cells for WT, n=13 cells for PB2 KO. Two-sided unpaired t-test. (F) Working model of regulation of cortical and membrane tension by Plexin-B2, affecting endocytosis and membrane permeability in GSCs.

Article Snippet: The lentiviral vector for Dox-inducible Plexin-B2 overexpression was generated by inserting human PLXNB2 cDNA into a Dox controlled expression vector (pLenti-CMVtight-PLXNB2 iOE; deposited as Addgene #176849) .

Techniques: Live Cell Imaging, Labeling, MANN-WHITNEY, Fluorescence, Membrane, Imaging, Transfection, Super-Resolution Microscopy, Permeability

Journal: bioRxiv

Article Title: Invasion of glioma cells through confined space requires membrane tension regulation and mechano-electrical coupling via Plexin-B2

doi: 10.1101/2024.01.02.573660

Figure Lengend Snippet: (A) Left, schematic of PH(PLCδ1)-GFP PIP2 probe. Right, live-cell imaging at 72 hr post transfection reveals that the PH(PLCδ1)-GFP probes were largely internalized in WT GSCs (arrow), but retained on membrane of PB2 KO GSCs (arrowhead). (B) Left, still images of videography show accumulation of the PH(PLCδ1)-GFP probes (arrow) in front of the nucleus (NucSpot) of migrating WT SD2 GSCs in tunnels, more so in 3 than 8 µm tunnel, but not in PB2 KO cells. Dashed lines delineate cell boundary. Long arrow denotes direction of migration. Right, quantifications of the ratio of PH(PLCδ1)-GFP fluorescence intensity at front vs. rear of GSCs during passage. n=13-16 cells per condition. One-way ANOVA followed by Tukey’s multiple comparison test. Data represent mean ± SEM. (C) Left, schematic of R(+8)-pre-GFP probe for negative surface charge of inner plasma membrane. Right, live-cell imaging at 72 hr post-transfection shows internalization of the probes (arrow) in WT GSCs, in contrast to the predominant membrane localization in PB2 KO GSCs (arrowhead). (D) Left, still images of videography show accumulation of the R(+8)-pre-GFP probes (arrow) at front zone of WT GSCs when traversing the 3 µm tunnel, but not in PB2 KO cells. Right, bar graphs show the ratio of R-pre-GFP fluorescence intensity at rear vs. front of GSCs when passing through tunnels. n=22 cells for WT, n=27 cells for PB2 KO. Mann–Whitney–Wilcoxon test. Data represent mean ± SEM. (E) Diagram illustrating voltage sensitive FluoVolt membrane dye, with fluorescent intensity quenched by voltage-sensitive electron transfer from electron-rich donor mediated by “molecular wire” in plasma membrane. (F) Left, FluoVolt live-cell imaging shows reduced FluoVolt fluorescent intensity in cell membrane of Plexin-B2 KO cells, consistent with higher negative charges of inner membrane. Right, box plots of membrane FluoVolt intensity. n=25 cells for WT, n=27 cells for PB2 KO. Two-sided unpaired t-test. Data represent mean ± SEM. (G) Left, still images from videography show higher FluoVolt fluorescent signals at rear zone (arrowhead) of WT GSCs when traversing tunnels, more so in 3 than 8 µm tunnel, but not in PB2 KO cells. Migration direction is denoted by long arrow. Right, bar graphs show the ratio of FluoVolt intensity at rear vs. front during confined migration. n=15 cells per group. One-way ANOVA followed by Tukey’s multiple comparison test. Data represent mean ± SEM. (H) Live-cell images and quantifications show the effects of constitutive active (CA) RAP1B-V12 or dominant-negative (DN) RAP1B-N17 on FluoVolt intensity in WT or PB2 KO GSCs. n=25 cells per group. Kruskal–Wallis test followed by Dunn’s multiple comparisons test. (I) Left, still images capture calcium localization (Fluo4-AM fluorescence, arrowhead) at the rear of WT GSCs when traversing tunnels, more so in 3 than 8 µm tunnel, but not in PB2 KO cells. Migration direction is denoted by long arrow. Right, bar graphs showing Fluo4-AM intensity ratio at rear vs. front in GSC during passage through tunnels. n=15-16 cells. One-way ANOVA followed by Tukey’s multiple comparison test. Data represent mean ± SEM. (J) Left, still images from videography show that calcium chelator BAPTA-AM disrupted the pattern of high FluoVolt signals at the rear of WT GSCs (arrowhead) during confined migration. Right, bar graphs show FluoVolt intensity ratio at rear vs. front of GSCs when traversing tunnels. n=21 cells for WT, n=16 cells for PB2 KO. Two-sided unpaired t-test. Data represent mean ± SEM. (K) Model of Plexin-B2 signaling affecting membrane surface charge and electric field during polarized confined migration, with PIP2 enrichment at cell front and Ca 2+ at rear zone, leading to asymmetry of FluoVolt and R(+8)-pre-GFP.

Article Snippet: The lentiviral vector for Dox-inducible Plexin-B2 overexpression was generated by inserting human PLXNB2 cDNA into a Dox controlled expression vector (pLenti-CMVtight-PLXNB2 iOE; deposited as Addgene #176849) .

Techniques: Live Cell Imaging, Transfection, Membrane, Migration, Fluorescence, Comparison, Clinical Proteomics, MANN-WHITNEY, Dominant Negative Mutation

Journal: bioRxiv

Article Title: Invasion of glioma cells through confined space requires membrane tension regulation and mechano-electrical coupling via Plexin-B2

doi: 10.1101/2024.01.02.573660

Figure Lengend Snippet: (A) Structure model of the extracellular domain of human Plexin-B2 show the locations of lock1 and lock2 mutations predicted to form disulfide bridges that lock the ring structure. (B) Western blots show absence of mature Plexin-B2 (170 kDa) in PB2 KO GSC, and expression of lock mutants in PB2 KO SD2 and SD3 GSCs. β-actin serves as a loading control. (C) Still images from videography show passage of GSCs (nuclei visualized by NucSpot) through microchannels with PB2 wildtype rescue construct but not lock mutants, nor PB2 with deletion of extracellular domain (dECTO). Chevrons point to 3 µm constrictions. (D) Box plots show velocity through constrictions, stalling time at constrictions, and sum of forward and backward movements, with 25–75% quartiles, minimal and maximal values (whiskers), median (line), and mean (cross). For velocity and sum of movements: n=17-20 cells per condition. For stalling time at constriction: n=14-28 cells per condition. One-way ANOVA followed by Dunnett’s multiple comparisons test. (E) Still images from videography show F-actin assembly (SPY-actin, arrowhead) at cell rear and MemGlow + endosomes (arrow) at cell front of SD3 GSCs with Plexin-B2 WT rescue but not mutant rescues when traversing 3 µm constrictions (chevrons). (F) Bar graphs showing fluorescence intensity ratio of SPY-actin and MemGlow at rear vs. front of GSCs during confined migration. n=10-18 cells per condition. Kruskal–Wallis test followed by Dunn’s multiple comparisons test. Data represent mean ± SEM. (G) Model of Plexin-B2 signaling and mechano-electrical regulation of membrane tension and membrane surface charge during polarized confined migration. Regionalized enrichment of endocytosis/PIP2 at cell front and F-actin/Ca 2+ at rear zone lead to asymmetry of FluoVolt and R(+8)-pre-GFP membrane probes.

Article Snippet: The lentiviral vector for Dox-inducible Plexin-B2 overexpression was generated by inserting human PLXNB2 cDNA into a Dox controlled expression vector (pLenti-CMVtight-PLXNB2 iOE; deposited as Addgene #176849) .

Techniques: Western Blot, Expressing, Control, Construct, Mutagenesis, Fluorescence, Migration, Membrane