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Addgene inc
vamp4 sequence ![Figure 2. VAMP2 is detected preferentially in fusion events (puffs) delivering MOR to the surface. (A) Schematic of a VAMP2+ puff in SpH-cargo and VAMP2-pHuji co-expressing cells. When a vesicle carrying both SpH-cargo and VAMP2-pHuji fuses to the plasma membrane, the fluorescence intensity increases in both the SpH channel and the pHuji channel. (B) Montage of a SpH-MOR puff colocalizing with VAMP2-pHuji (SpH-MOR in green and VAMP2-pHuji in magenta) from SpH-MOR and VAMP2-pHuji co-expressing cells 5 min after DAMGO treatment at 37°C. Scale bar = 2 µm. (C) Representative time-course traces of mean SpH-MOR (cyan) and the corresponding mean VAMP2-pHuji fluorescence (magenta) from a VAMP2+ puff of the SpH-MOR expressing cells. (D) Representative time-course traces of mean SpH-B2AR (red) and the corresponding mean VAMP2-pHuji fluorescence (magenta) from a VAMP2-negative puff of the SpH-B2AR expressing cells. (E) Quantification of VAMP enrichment in the population of puffs for each SpH-cargo. VAMP2 or <t>VAMP4</t> enrichment of individual puff event was calculated as the fold change of VAMP-pHuji fluorescence at the peak of the event over baseline SD, as described in the text (median ± 95% confidence interval [CI]; TfR-SpH: 2 cells, puff = 85; SpH-B2AR: 3 cells, puff = 85; SpH-MOR-VAMP2: 3 cells, puff = 59; SpH-MOR-VAMP4: 4 cells, puff = 44; all conditions from two independent experiments). SpH-MOR puffs showed significantly more enrichment of VAMP2 compared with other cargos, but showed no VAMP4 enrichment (one-way ANOVA, post-hoc Kruskal–Wallis test: TfR vs. B2AR: P > 0.9999; TfR vs. MOR: P < 0.0001; B2AR vs. MOR: P < 0.0001; MOR- VAMP2 vs. MOR-VAMP4: P < 0.0001). (F) The fraction of VAMP2+ puffs (% population) as defined by different folds of VAMP2 enrichment over baseline SD (cutoff) shows a consistent enrichment of VAMP2 preferentially in MOR puffs across all cutoffs. (G) Kernel density estimation of the pooled population of all puffs to estimate subclasses. The best fit predicted three subclasses based on VAMP2 enrichment. Three Gaussian mixture models of the actual distribution (solid line) and predicted subclasses (dashed lines) are shown. (H) Fraction of puffs in each predicted subclass shows distinct population composition of different SpH-cargos and a preferential enrichment of VAMP2+ subclasses in SpH-MOR puffs.](https://pub-med-unpaywalled-images-cdn.bioz.com/pub_med_ids_ending_with_2307/pm37022307/pm37022307__page4_image1.jpg) Vamp4 Sequence, supplied by Addgene inc, used in various techniques. Bioz Stars score: 93/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more https://www.bioz.com/result/vamp4 sequence/product/Addgene inc Average 93 stars, based on 1 article reviews
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2017 n a vamp4 kd1 mscarlet  2017 N A Vamp4 Kd1 Mscarlet, supplied by Addgene inc, used in various techniques. Bioz Stars score: 93/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more https://www.bioz.com/result/2017 n a vamp4 kd1 mscarlet/product/Addgene inc Average 93 stars, based on 1 article reviews
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TaKaRa
egfp n1 mammalian expression vector Egfp N1 Mammalian Expression Vector, supplied by TaKaRa, 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/egfp n1 mammalian expression vector/product/TaKaRa Average 86 stars, based on 1 article reviews
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vamp4 phuji plasmid Vamp4 Phuji Plasmid, supplied by Addgene inc, used in various techniques. Bioz Stars score: 92/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more https://www.bioz.com/result/vamp4 phuji plasmid/product/Addgene inc Average 92 stars, based on 1 article reviews
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Boster Bio Anti-VAMP4 Antibody (Catalog# A05647). Tested in IF, ICC, ELISA applications. This antibody reacts with Human, Mouse.
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The VAMP4 Antibody from Novus is a VAMP4 antibody to VAMP4. This antibody reacts with Human. The VAMP4 antibody has been validated for the following applications: Western Blot.
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The VAMP4 Antibody - BSA Free from Novus is a VAMP4 antibody to VAMP4. This antibody reacts with Human, Mouse, Rat. The VAMP4 antibody has been validated for the following applications: Western Blot.
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Image Search Results
Journal: The Journal of cell biology
Article Title: Vesicle-associated membrane protein 2 is a cargo-selective v-SNARE for a subset of GPCRs.
doi: 10.1083/jcb.202207070
Figure Lengend Snippet: Figure 2. VAMP2 is detected preferentially in fusion events (puffs) delivering MOR to the surface. (A) Schematic of a VAMP2+ puff in SpH-cargo and VAMP2-pHuji co-expressing cells. When a vesicle carrying both SpH-cargo and VAMP2-pHuji fuses to the plasma membrane, the fluorescence intensity increases in both the SpH channel and the pHuji channel. (B) Montage of a SpH-MOR puff colocalizing with VAMP2-pHuji (SpH-MOR in green and VAMP2-pHuji in magenta) from SpH-MOR and VAMP2-pHuji co-expressing cells 5 min after DAMGO treatment at 37°C. Scale bar = 2 µm. (C) Representative time-course traces of mean SpH-MOR (cyan) and the corresponding mean VAMP2-pHuji fluorescence (magenta) from a VAMP2+ puff of the SpH-MOR expressing cells. (D) Representative time-course traces of mean SpH-B2AR (red) and the corresponding mean VAMP2-pHuji fluorescence (magenta) from a VAMP2-negative puff of the SpH-B2AR expressing cells. (E) Quantification of VAMP enrichment in the population of puffs for each SpH-cargo. VAMP2 or VAMP4 enrichment of individual puff event was calculated as the fold change of VAMP-pHuji fluorescence at the peak of the event over baseline SD, as described in the text (median ± 95% confidence interval [CI]; TfR-SpH: 2 cells, puff = 85; SpH-B2AR: 3 cells, puff = 85; SpH-MOR-VAMP2: 3 cells, puff = 59; SpH-MOR-VAMP4: 4 cells, puff = 44; all conditions from two independent experiments). SpH-MOR puffs showed significantly more enrichment of VAMP2 compared with other cargos, but showed no VAMP4 enrichment (one-way ANOVA, post-hoc Kruskal–Wallis test: TfR vs. B2AR: P > 0.9999; TfR vs. MOR: P < 0.0001; B2AR vs. MOR: P < 0.0001; MOR- VAMP2 vs. MOR-VAMP4: P < 0.0001). (F) The fraction of VAMP2+ puffs (% population) as defined by different folds of VAMP2 enrichment over baseline SD (cutoff) shows a consistent enrichment of VAMP2 preferentially in MOR puffs across all cutoffs. (G) Kernel density estimation of the pooled population of all puffs to estimate subclasses. The best fit predicted three subclasses based on VAMP2 enrichment. Three Gaussian mixture models of the actual distribution (solid line) and predicted subclasses (dashed lines) are shown. (H) Fraction of puffs in each predicted subclass shows distinct population composition of different SpH-cargos and a preferential enrichment of VAMP2+ subclasses in SpH-MOR puffs.
Article Snippet: VAMP4-pHuji plasmid expressing human VAMP4 was cloned by first replacing VAMP2 sequence of VAMP2-pHuji with a
Techniques: Expressing, Clinical Proteomics, Membrane, Fluorescence
Journal: The Journal of cell biology
Article Title: Vesicle-associated membrane protein 2 is a cargo-selective v-SNARE for a subset of GPCRs.
doi: 10.1083/jcb.202207070
Figure Lengend Snippet: Figure 3. VAMP2 depletion inhibits the recycling of SpH-MOR but not that of SpH-B2AR and TfR-SpH. (A) Representative confocal image of PC12 cells expressing shScramble-tagBFP (blue) immunostained for endogenous VAMP2 (magenta) after 48 h of Dox treatment. (B) Representative confocal image of PC12 cells expressing shVAMP2-tagBFP (blue) immunostained for endogenous VAMP2 (magenta) after 48 h of Dox treatment, showing depletion of VAMP2. Scale bar = 20 µm. (C) Scatter plots of normalized IDoT of VAMP2 immunostaining in shScramble-tagBFP (shScramble) or shVAMP2-tagBFP (shVAMP2) expressing cells (median ± 95% CI, n = 45 or 46 cells, respectively, from two independent experiments), showing depletion of VAMP2 in the latter (P < 0.0001, unpaired two-tailed t test). (D) The number of TfR-SpH puffs per cell per minute (/cell • min) in cells expressing either TfR-SpH alone (Dox alone) or in cells co- expressing shScramble or shVAMP2, treated with 48 h of Dox, show no significant difference (Dox alone: n = 11; shScramble: n = 10; shVAMP2: n = 10, from two independent experiments; one-way ANOVA, post-hoc Tukey test). (E) A similar comparison shows no difference in the numbers of SpH-B2AR puffs across the three conditions (Dox alone: n = 27; shScramble + Dox: n = 24; shVamp2 + Dox: n = 36, from three independent experiments, one-way ANOVA, post-hoc Tukey test). (F) A similar comparison shows significant reduction in the number of SpH-MOR puffs in cells co-expressing shVAMP2 compared with the other two conditions (Dox alone: n = 27; shScramble: n = 23; shVAMP2: n = 28, from three independent experiments, one-way ANOVA, post-hoc Tukey test). (G) A similar comparison in cells co-expressing SpH-MOR and shScramble or VAMP4 shRNA (shVAMP4), shows no difference in the numbers of SpH-MOR puffs (shScramble, n = 15; shVAMP2, n = 13, from one experiment, unpaired two-tailed t test, checked by power analysis). Cells from E–G were treated with agonists for 5 min at 37°C before imaging. Filled dots in red from E–G represented outliers identified by the Tukey plot that were included in the statistical analysis. “+” in the Tukey plots from D–G represented mean. (H) Schematic of the treatment and labeling conditions for the flow cytometry assay. Cells were labeled with M1-Alexa-647 (M1-647) antibody at the endpoint of treatment conditions to measure surface MOR levels: at baseline (NT), after DAMGO for 20 min at 37°C (T), or after washing out DAMGO and incubating in Naltrexone for 20 min at 37°C (WO). (I) Representative histograms of PC12 cells co-expressing FLAG-MOR and shVAMP2, either without (shVAMP2 −Dox) or with (shVAMP2 +Dox) pretreatment of Dox for 48 h. (J) Quantification of mean (left panel) and geometric mean (geomean, right panel) of surface MOR levels normalized to unlabeled baseline (±SEM, three samples each condition from one experiment).
Article Snippet: VAMP4-pHuji plasmid expressing human VAMP4 was cloned by first replacing VAMP2 sequence of VAMP2-pHuji with a
Techniques: Expressing, Immunostaining, Two Tailed Test, Comparison, shRNA, Imaging, Labeling, Flow Cytometry
Journal: Cell reports
Article Title: The vSNAREs VAMP2 and VAMP4 control recycling and intracellular sorting of post-synaptic receptors in neuronal dendrites.
doi: 10.1016/j.celrep.2021.109678
Figure Lengend Snippet: Figure 1. VAMP2 and VAMP4 are markers of recycling endosome exocytosis in the soma and dendrites of hippocampal neurons (A–C) Images (top) and kymographs (bottom) of neurons (14 DIV) transfected with TfR-SEP (A), VAMP2-SEP (B), or VAMP4-SEP (C). Exocytosis events (sudden appearance of a bright cluster) are marked with green arrowheads. In (A), dim stable spots represent clathrin coated endocytic zones. Scale bar, 2 mm. (legend continued on next page)
Article Snippet: REAGENT or RESOURCE SOURCE IDENTIFIER Antibodies Rabbit anti VAMP4 Synaptic Systems Cat# 136002, RRID AB_887816 Mouse anti Rab11 BD Biosciences Cat# 610657, RRID AB_397984 Rabbit anti GluA1 Sigma Aldrich Cat# AB1504, RRID AB_2113602 Mouse anti VAMP2 Synaptic Systems Cat# 104211, RRID AB_2619758 Rabbit anti FIP2 Antibodies Online Cat# ABIN6275434, RRID AB_11206004 Chicken anti mScarlet Synaptic Systems Cat# 409006, RRID AB_2725776 Mouse anti actin Sigma Aldrich Cat# A5316, RRID AB_476743 Chemicals, peptides, and recombinant proteins D-APV Abcam Cat# ab120003 Picrotoxin Sigma Cat# P1675 Strychnine hydrochloride Sigma Cat# S8753 Experimental models: Organisms/strains Rat, Sprague Dawley Janvier Labs N/A Oligonucleotides VAMP4 shRNA1 target sequence CTATCTTTATTTAACAACA N/A VAMP4 shRNA2 target sequence GGACCATCTGGACCAAGAT N/A scramble shRNA AATTCTCCGAACGTGTCAC N/A Recombinant DNA SEP-GluA1 Jullié et al., 2014; Rosendale et al., 2017 N/A TfR-SEP Jullié et al., 2014; Rosendale et al., 2017 N/A VAMP4-SEP This paper Addgene 174406 VAMP2-SEP Martineau et al., 2017 N/A TeNT-LC Proux-Gillardeaux et al., 2005 N/A TeNT-LC E234Q Proux-Gillardeaux et al., 2005 N/A VAMP4-HA This paper N/A Homer1c-tdTomato Rosendale et al., 2017 N/A VAMP2-SNAPtag Martineau et al.,
Techniques: Transfection
Journal: Cell reports
Article Title: The vSNAREs VAMP2 and VAMP4 control recycling and intracellular sorting of post-synaptic receptors in neuronal dendrites.
doi: 10.1016/j.celrep.2021.109678
Figure Lengend Snippet: Figure 2. Downregulation of VAMP4, but not VAMP2, impairs RE exocytosis and recycling to the plasma membrane (A) Frequency of exocytosis events in neurons transfected with TfR-SEP and TeNT-LC E234Q (n = 6) or TeNT-LC (n = 10). (B) Images of neurons co-transfected with VAMP2-SEP and TeNT-LC E234Q or TeNT-LC. VAMP2-SEP is enriched in the axon (cyan arrows) in the first case but not the second case. Scale bar, 10 mm. (C) Immunofluorescence images of endogenous VAMP4 in cells expressing GFP and a combination of shRNA targeted against VAMP4 for four days. In cells expressing GFP and the shRNA (cyan arrows), the labeling is strongly decreased compared to untransfected cells or cells expressing scramble (scr) shRNA. In cells co-expressing TfR, VAMP4-HA, and KD1, the VAMP4 staining is strong. Scale bar, 10 mm. Bottom, quantification of VAMP4 staining in the area delimited by the GFP mask (soma and dendrites). The staining is decreased by 50% in all KD conditions. The number of cells is indicated above the bars for all conditions. Comparison with scr with one-way ANOVA; *p < 0.05 and ***p < 0.001. (D) Frequency of exocytosis events recorded in cells expressing TfR-SEP and shRNAs targeted to VAMP4: scr (33 cells; 3 cells have frequencies of 0.132, 0.157, and 0.119 events.mm2.min1 and are represented above the axis limit), KD1 (23 cells), KD2 (10 cells), KD1+2 (18 cells), cells expressing VAMP4-HA (8 cells), and KD1+VAMP4-HA (12 cells). *p < 0.05 one-way ANOVA. (E) Images of neurons expressing scr or KD1 shRNAs in GFP vectors, labeled with A568-Tf (50 mg/ml) for 5 min and chased with unlabeled transferrin (2 mg/ml) at 37C for the indicated times. Scale bar, 10 mm. (F) Quantification of the Alexa568 fluorescence in the GFP mask from the pulse-chase experiments described in (E). 70 to 88 cells per condition from 4 inde- pendent experiments. Error bars represent SEM; **p < 0.01. (G) Estimation of TfR-SEP surface fraction. Top, cartoons showing the fraction of fluorescent TfR-SEP. At pH 7.4, surface receptors are fluorescent, but not at pH 5.5. Receptors in acidic intracellular organelles are not fluorescent, but become fluorescent with NH4Cl. Bottom left, images of a dendrite bathed successively in solutions at pH 7.4 (images 1, 3, and 5), pH 5.5 (image 2), and pH 7.4 containing NH4Cl (image 4). For image 4, the contrast is 23 lower than in the other images. Bottom right, quantification of the TfR-SEP surface fraction for neurons transfected with scr (n = 27) and KD1 (n = 26). See STAR Methods for calculation. ***p < 0.001.
Article Snippet: REAGENT or RESOURCE SOURCE IDENTIFIER Antibodies Rabbit anti VAMP4 Synaptic Systems Cat# 136002, RRID AB_887816 Mouse anti Rab11 BD Biosciences Cat# 610657, RRID AB_397984 Rabbit anti GluA1 Sigma Aldrich Cat# AB1504, RRID AB_2113602 Mouse anti VAMP2 Synaptic Systems Cat# 104211, RRID AB_2619758 Rabbit anti FIP2 Antibodies Online Cat# ABIN6275434, RRID AB_11206004 Chicken anti mScarlet Synaptic Systems Cat# 409006, RRID AB_2725776 Mouse anti actin Sigma Aldrich Cat# A5316, RRID AB_476743 Chemicals, peptides, and recombinant proteins D-APV Abcam Cat# ab120003 Picrotoxin Sigma Cat# P1675 Strychnine hydrochloride Sigma Cat# S8753 Experimental models: Organisms/strains Rat, Sprague Dawley Janvier Labs N/A Oligonucleotides VAMP4 shRNA1 target sequence CTATCTTTATTTAACAACA N/A VAMP4 shRNA2 target sequence GGACCATCTGGACCAAGAT N/A scramble shRNA AATTCTCCGAACGTGTCAC N/A Recombinant DNA SEP-GluA1 Jullié et al., 2014; Rosendale et al., 2017 N/A TfR-SEP Jullié et al., 2014; Rosendale et al., 2017 N/A VAMP4-SEP This paper Addgene 174406 VAMP2-SEP Martineau et al., 2017 N/A TeNT-LC Proux-Gillardeaux et al., 2005 N/A TeNT-LC E234Q Proux-Gillardeaux et al., 2005 N/A VAMP4-HA This paper N/A Homer1c-tdTomato Rosendale et al., 2017 N/A VAMP2-SNAPtag Martineau et al.,
Techniques: Clinical Proteomics, Membrane, Transfection, Expressing, shRNA, Labeling, Staining, Comparison, Pulse Chase
![Figure 3. TfR-SEP and VAMP4-SEP exocytosis increase after chemical LTP (A) Images of a neuron transfected with TfR-SEP before and 15 min after induction of cLTP. Cyan crosses show the location of detected exocytosis events. Scale bar, 5 mm. (B) Normalized exocytosis frequency of neurons transfected with TfR-SEP at times relative to cLTP induction (n = 16, control [ctrl]). The light blue area denotes the time of incubation with cLTP inducing medium. The increase in frequency is significant 15 min after induction (Dunnett’s multiple comparison test, p = 0.003). In the presence of APV (100 mM), the frequency does not increase (n = 12). (C) Exocytosis frequencies before and 15 min after LTP induction. Paired t test p = 0.0008 (ctrl) and p = 0.14 (APV). (D) Normalized change in fluorescence intensity of TfR-SEP before and after cLTP induction. The increase is significant after 10 min or more (Dunnett’s multiple comparison). (E) Changes in TfR-SEP fluorescence 20 min after cLTP induction, in ctrl (carmin dots) or with APV (gray dots). Paired t test p = 0.0002 (ctrl) and p = 0.89 (APV). (F–J) Same as (A)–(E) for neurons transfected with VAMP2-SEP (n = 9) and with APV (n = 7). The increase in frequency is significant 10 min or more after induction (p = 0.002). (K–O) Same as (A)–(E) for neurons transfected with VAMP4-SEP (n = 15) and with APV (n = 15). The increase in frequency is significant 15 min or more after induction (p = 0.0082).](https://pub-med-unpaywalled-images-cdn.bioz.com/pub_med_ids_ending_with_6238/pm34496238/pm34496238__page8_image1.jpg)
Journal: Cell reports
Article Title: The vSNAREs VAMP2 and VAMP4 control recycling and intracellular sorting of post-synaptic receptors in neuronal dendrites.
doi: 10.1016/j.celrep.2021.109678
Figure Lengend Snippet: Figure 3. TfR-SEP and VAMP4-SEP exocytosis increase after chemical LTP (A) Images of a neuron transfected with TfR-SEP before and 15 min after induction of cLTP. Cyan crosses show the location of detected exocytosis events. Scale bar, 5 mm. (B) Normalized exocytosis frequency of neurons transfected with TfR-SEP at times relative to cLTP induction (n = 16, control [ctrl]). The light blue area denotes the time of incubation with cLTP inducing medium. The increase in frequency is significant 15 min after induction (Dunnett’s multiple comparison test, p = 0.003). In the presence of APV (100 mM), the frequency does not increase (n = 12). (C) Exocytosis frequencies before and 15 min after LTP induction. Paired t test p = 0.0008 (ctrl) and p = 0.14 (APV). (D) Normalized change in fluorescence intensity of TfR-SEP before and after cLTP induction. The increase is significant after 10 min or more (Dunnett’s multiple comparison). (E) Changes in TfR-SEP fluorescence 20 min after cLTP induction, in ctrl (carmin dots) or with APV (gray dots). Paired t test p = 0.0002 (ctrl) and p = 0.89 (APV). (F–J) Same as (A)–(E) for neurons transfected with VAMP2-SEP (n = 9) and with APV (n = 7). The increase in frequency is significant 10 min or more after induction (p = 0.002). (K–O) Same as (A)–(E) for neurons transfected with VAMP4-SEP (n = 15) and with APV (n = 15). The increase in frequency is significant 15 min or more after induction (p = 0.0082).
Article Snippet: REAGENT or RESOURCE SOURCE IDENTIFIER Antibodies Rabbit anti VAMP4 Synaptic Systems Cat# 136002, RRID AB_887816 Mouse anti Rab11 BD Biosciences Cat# 610657, RRID AB_397984 Rabbit anti GluA1 Sigma Aldrich Cat# AB1504, RRID AB_2113602 Mouse anti VAMP2 Synaptic Systems Cat# 104211, RRID AB_2619758 Rabbit anti FIP2 Antibodies Online Cat# ABIN6275434, RRID AB_11206004 Chicken anti mScarlet Synaptic Systems Cat# 409006, RRID AB_2725776 Mouse anti actin Sigma Aldrich Cat# A5316, RRID AB_476743 Chemicals, peptides, and recombinant proteins D-APV Abcam Cat# ab120003 Picrotoxin Sigma Cat# P1675 Strychnine hydrochloride Sigma Cat# S8753 Experimental models: Organisms/strains Rat, Sprague Dawley Janvier Labs N/A Oligonucleotides VAMP4 shRNA1 target sequence CTATCTTTATTTAACAACA N/A VAMP4 shRNA2 target sequence GGACCATCTGGACCAAGAT N/A scramble shRNA AATTCTCCGAACGTGTCAC N/A Recombinant DNA SEP-GluA1 Jullié et al., 2014; Rosendale et al., 2017 N/A TfR-SEP Jullié et al., 2014; Rosendale et al., 2017 N/A VAMP4-SEP This paper Addgene 174406 VAMP2-SEP Martineau et al., 2017 N/A TeNT-LC Proux-Gillardeaux et al., 2005 N/A TeNT-LC E234Q Proux-Gillardeaux et al., 2005 N/A VAMP4-HA This paper N/A Homer1c-tdTomato Rosendale et al., 2017 N/A VAMP2-SNAPtag Martineau et al.,
Techniques: Transfection, Control, Incubation, Comparison
Journal: Cell reports
Article Title: The vSNAREs VAMP2 and VAMP4 control recycling and intracellular sorting of post-synaptic receptors in neuronal dendrites.
doi: 10.1016/j.celrep.2021.109678
Figure Lengend Snippet: Figure 4. Effect of TeNT-LC and VAMP4 KD on TfR-SEP exocytosis after cLTP (A) Exocytosis frequencies before and after LTP induction in neurons expressing TfR-SEP and either TeNT-LC E234Q (n = 13) or TeNT-LC (n = 13). In both conditions the increase in frequency is significant. (B) Images of dendrites before and after induction of cLTP. Scale bar, 5 mm. (C) TfR-SEP fluorescence in dendrites of neurons before and after cLTP induction. (D–F) Same as (A)–(C) for neurons expressing TfR-SEP and either scr (n = 10) or VAMP4 KD1 (n = 8) shRNA.
Article Snippet: REAGENT or RESOURCE SOURCE IDENTIFIER Antibodies Rabbit anti VAMP4 Synaptic Systems Cat# 136002, RRID AB_887816 Mouse anti Rab11 BD Biosciences Cat# 610657, RRID AB_397984 Rabbit anti GluA1 Sigma Aldrich Cat# AB1504, RRID AB_2113602 Mouse anti VAMP2 Synaptic Systems Cat# 104211, RRID AB_2619758 Rabbit anti FIP2 Antibodies Online Cat# ABIN6275434, RRID AB_11206004 Chicken anti mScarlet Synaptic Systems Cat# 409006, RRID AB_2725776 Mouse anti actin Sigma Aldrich Cat# A5316, RRID AB_476743 Chemicals, peptides, and recombinant proteins D-APV Abcam Cat# ab120003 Picrotoxin Sigma Cat# P1675 Strychnine hydrochloride Sigma Cat# S8753 Experimental models: Organisms/strains Rat, Sprague Dawley Janvier Labs N/A Oligonucleotides VAMP4 shRNA1 target sequence CTATCTTTATTTAACAACA N/A VAMP4 shRNA2 target sequence GGACCATCTGGACCAAGAT N/A scramble shRNA AATTCTCCGAACGTGTCAC N/A Recombinant DNA SEP-GluA1 Jullié et al., 2014; Rosendale et al., 2017 N/A TfR-SEP Jullié et al., 2014; Rosendale et al., 2017 N/A VAMP4-SEP This paper Addgene 174406 VAMP2-SEP Martineau et al., 2017 N/A TeNT-LC Proux-Gillardeaux et al., 2005 N/A TeNT-LC E234Q Proux-Gillardeaux et al., 2005 N/A VAMP4-HA This paper N/A Homer1c-tdTomato Rosendale et al., 2017 N/A VAMP2-SNAPtag Martineau et al.,
Techniques: Expressing, shRNA
Journal: Cell reports
Article Title: The vSNAREs VAMP2 and VAMP4 control recycling and intracellular sorting of post-synaptic receptors in neuronal dendrites.
doi: 10.1016/j.celrep.2021.109678
Figure Lengend Snippet: Figure 6. Effect of post-synaptic VAMP4 KD and TeNT on glutamatergic synaptic transmission (A) Confocal image of an organotypic hippocampal slice culture infected with scr-mScarlet lentivirus at 1 DIV and fixed at 9 DIV. Many pyramidal neurons in CA1 are brightly fluorescent. (B) DIC image of two pyramidal neurons recorded simultaneously with patch pipettes (asterisks). Epifluorescent illumination shows that the neuron on the left is brightly fluorescent (infected) while the one on the right is not (uninfected control). (C) Averages of 30 EPSCs evoked by the same stimulation in pairs of neurons, uninfected and infected with scr-mScarlet (top), shRNA KD1-mScarlet (middle), or shRNA KD2-mScarlet (botttom). Both neurons were held at 70 mV then at +40 mV. Right, plots of peak EPSC amplitude at 70 mV for each pair of neurons. In the scr condition, dots are spread around the diagonal, while in the KD1 and KD2 conditions the amplitudes are systematically higher for infected neurons. (D) Same as (C) for neurons co-electroporated with TeNT-LC and GFP. In the neurons expressing TeNT-LC, the amplitude is sytematically smaller than in control neurons.
Article Snippet: REAGENT or RESOURCE SOURCE IDENTIFIER Antibodies Rabbit anti VAMP4 Synaptic Systems Cat# 136002, RRID AB_887816 Mouse anti Rab11 BD Biosciences Cat# 610657, RRID AB_397984 Rabbit anti GluA1 Sigma Aldrich Cat# AB1504, RRID AB_2113602 Mouse anti VAMP2 Synaptic Systems Cat# 104211, RRID AB_2619758 Rabbit anti FIP2 Antibodies Online Cat# ABIN6275434, RRID AB_11206004 Chicken anti mScarlet Synaptic Systems Cat# 409006, RRID AB_2725776 Mouse anti actin Sigma Aldrich Cat# A5316, RRID AB_476743 Chemicals, peptides, and recombinant proteins D-APV Abcam Cat# ab120003 Picrotoxin Sigma Cat# P1675 Strychnine hydrochloride Sigma Cat# S8753 Experimental models: Organisms/strains Rat, Sprague Dawley Janvier Labs N/A Oligonucleotides VAMP4 shRNA1 target sequence CTATCTTTATTTAACAACA N/A VAMP4 shRNA2 target sequence GGACCATCTGGACCAAGAT N/A scramble shRNA AATTCTCCGAACGTGTCAC N/A Recombinant DNA SEP-GluA1 Jullié et al., 2014; Rosendale et al., 2017 N/A TfR-SEP Jullié et al., 2014; Rosendale et al., 2017 N/A VAMP4-SEP This paper Addgene 174406 VAMP2-SEP Martineau et al., 2017 N/A TeNT-LC Proux-Gillardeaux et al., 2005 N/A TeNT-LC E234Q Proux-Gillardeaux et al., 2005 N/A VAMP4-HA This paper N/A Homer1c-tdTomato Rosendale et al., 2017 N/A VAMP2-SNAPtag Martineau et al.,
Techniques: Transmission Assay, Infection, Control, shRNA, Expressing
Journal: Cell reports
Article Title: The vSNAREs VAMP2 and VAMP4 control recycling and intracellular sorting of post-synaptic receptors in neuronal dendrites.
doi: 10.1016/j.celrep.2021.109678
Figure Lengend Snippet: Figure 7. Effect of post-synaptic VAMP4 KD and TeNT on LTP (A) Average EPSCs before (black traces) and 20 to 30 min after induction of LTP (color traces) in neurons electroporated with GFP and TeNT-LC (purple) or not (gray). The dotted line shows the peak EPSC before LTP induction. Scale bars, 40 pA and 20 ms. (B) Peak EPSC amplitude normalized to baseline for pairs of neurons transfected with TeNT-LC (purple) or not (gray) (C) Ratio of EPSC amplitude 20 to 30 min after LTP induction to baseline. (D) Same as (A) for neurons transduced with lentivirus expressing scr-mScarlet (blue), shRNA KD1-mScarlet (red), and shRNA KD2-mScarlet (green). Scale bars, 40 pA and 20 ms. (E) Peak EPSC amplitude normalized to baseline for of neurons expressing the corresponding shRNAs. (F) Same as (C) for transduced neurons. ****p < 0.0001. (G) Model of dendritic TfR and AMPAR receptor trafficking.
Article Snippet: REAGENT or RESOURCE SOURCE IDENTIFIER Antibodies Rabbit anti VAMP4 Synaptic Systems Cat# 136002, RRID AB_887816 Mouse anti Rab11 BD Biosciences Cat# 610657, RRID AB_397984 Rabbit anti GluA1 Sigma Aldrich Cat# AB1504, RRID AB_2113602 Mouse anti VAMP2 Synaptic Systems Cat# 104211, RRID AB_2619758 Rabbit anti FIP2 Antibodies Online Cat# ABIN6275434, RRID AB_11206004 Chicken anti mScarlet Synaptic Systems Cat# 409006, RRID AB_2725776 Mouse anti actin Sigma Aldrich Cat# A5316, RRID AB_476743 Chemicals, peptides, and recombinant proteins D-APV Abcam Cat# ab120003 Picrotoxin Sigma Cat# P1675 Strychnine hydrochloride Sigma Cat# S8753 Experimental models: Organisms/strains Rat, Sprague Dawley Janvier Labs N/A Oligonucleotides VAMP4 shRNA1 target sequence CTATCTTTATTTAACAACA N/A VAMP4 shRNA2 target sequence GGACCATCTGGACCAAGAT N/A scramble shRNA AATTCTCCGAACGTGTCAC N/A Recombinant DNA SEP-GluA1 Jullié et al., 2014; Rosendale et al., 2017 N/A TfR-SEP Jullié et al., 2014; Rosendale et al., 2017 N/A VAMP4-SEP This paper Addgene 174406 VAMP2-SEP Martineau et al., 2017 N/A TeNT-LC Proux-Gillardeaux et al., 2005 N/A TeNT-LC E234Q Proux-Gillardeaux et al., 2005 N/A VAMP4-HA This paper N/A Homer1c-tdTomato Rosendale et al., 2017 N/A VAMP2-SNAPtag Martineau et al.,
Techniques: Transfection, Transduction, Expressing, shRNA