SNAP25 Antibody [P1D7]

Catalog No.: F7835

    Application: Reactivity:
    • Lane 1: Mouse brain, Lane 2: Rat brain
    1/

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    代表番号: 045-509-1970|電子メール:sales@selleck.co.jp

    キーポイント

    WB
    転写条件(ウェット): 200 mA, 60 min

    使用情報

    Dilution
    1:1000
    1:1250
    1:200
    Application
    WB, IF, FCM
    Source
    Rabbit Monoclonal Antibody
    Reactivity
    Mouse, Human, Rat
    Storage Buffer
    PBS, pH 7.2+50% Glycerol+0.05% BSA+0.01% NaN3
    Storage (from the date of receipt)
    -20°C (avoid freeze-thaw cycles), 2 years
    Predicted MW Observed MW
    23 kDa 27 kDa, 25 kDa
    *なぜ予測分子量と実際の分子量が異なるのか?
    下記の原因により、実際の分子量が予測と異なる:タンパク質の翻訳後修飾(リン酸化/糖鎖付加),スプライシングバリアント,イソフォーム,相対的な電荷,ポリマー。
    ポジティブコントロール Human brain tissue; Mouse brain tissue; Mouse hippocampus tissue; Rat brain tissue lysate; Rat hippocampus tissue; SH-SY5Y cells; Neuro-2a cells; K562 cells
    ネガティブコントロール

    プロトコール

    WB
    Experimental Protocol:
     
    Sample preparation
    1. Tissue: Lyse the tissue sample by adding an appropriate volume of ice-cold RIPA/NP-40 Lysis Buffer (containing Protease Inhibitor Cocktail),and homogenize the tissue at a low temperature or lyse it by sonication on ice, then incubate on ice for 30 minutes.
    2. Adherent cell: Aspirate the culture medium and wash the cells with ice-cold PBS twice. Lyse the cells by adding an appropriate volume of RIPA/NP-40 Lysis Buffer (containing Protease Inhibitor Cocktail) , sonicate to lyse the cells, and incubate on ice for 30 minutes.
    3. Suspension cell: Transfer the culture medium to a pre-cooled centrifuge tube. Centrifuge and aspirate the supernatant. Wash the cells with ice-cold PBS twice. Lyse the cells by adding an appropriate volume of RIPA/NP-40 Lysis Buffer (containing Protease Inhibitor Cocktail) , sonicate to lyse the cells, and incubate on ice for 30 minutes.
    4. Place the lysate into a pre-cooled microcentrifuge tube. Centrifuge at 4°C for 15 min. Collect the supernatant;
    5. Remove a small volume of lysate to determine the protein concentration;
    6. Combine the lysate with protein loading buffer. Boil 20 µL sample under 95-100°C for 5 min. Centrifuge for 5 min after cool down on ice.
     
    Electrophoretic separation
    1. According to the concentration of extracted protein, load appropriate amount of protein sample and marker onto SDS-PAGE gels for electrophoresis. Recommended separating gel (lower gel) concentration: 10%. Reference Table for Selecting SDS-PAGE Separation Gel Concentrations
    2. Power up 80V for 30 minutes. Then the power supply is adjusted (110 V~150 V), the Marker is observed, and the electrophoresis can be stopped when the indicator band of the predyed protein Marker where the protein is located is properly separated. (Note that the current should not be too large when electrophoresis, too large current (more than 150 mA) will cause the temperature to rise, affecting the result of running glue. If high currents cannot be avoided, an ice bath can be used to cool the bath.)
     
    Transfer membrane
    1. Take out the converter, soak the clip and consumables in the pre-cooled converter;
    2. Activate PVDF membrane with methanol for 1 min and rinse with transfer buffer;
    3. Install it in the order of "black edge of clip - sponge - filter paper - filter paper - glue -PVDF membrane - filter paper - filter paper - sponge - white edge of clip";
    4. The protein was electrotransferred to PVDF membrane. ( 0.45 µm PVDF membrane is recommended ) Reference Table for Selecting PVDF Membrane Pore Size Specifications
    Recommended conditions for wet transfer: 200 mA, 60 min.
    ( Note that the transfer conditions can be adjusted according to the protein size. For high-molecular-weight proteins, a higher current and longer transfer time are recommended. However, ensure that the transfer tank remains at a low temperature to prevent gel melting.)
     
    Block
    1. After electrotransfer, wash the film with TBST at room temperature for 5 minutes;
    2. Incubate the film in the blocking solution for 1 hour at room temperature;
    3. Wash the film with TBST for 3 times, 5 minutes each time.
     
    Antibody incubation
    1. Use 5% skim milk powder to prepare the primary antibody working liquid (recommended dilution ratio for primary antibody 1:1000), gently shake and incubate with the film at 4°C overnight;
    2. Wash the film with TBST 3 times, 5 minutes each time;
    3. Add the secondary antibody to the blocking solution and incubate with the film gently at room temperature for 1 hour;
    4. After incubation, wash the film with TBST 3 times for 5 minutes each time.
     
    Antibody staining
    1. Add the prepared ECL luminescent substrate (or select other color developing substrate according to the second antibody) and mix evenly;
    2. Incubate with the film for 1 minute, remove excess substrate (keep the film moist), wrap with plastic film, and expose in the imaging system.
    IF
    Experimental Protocol:
     
    Sample Preparation
    1. Adherent Cells: Place a clean, sterile coverslip in a culture dish. Once the cells grow to near confluence as a monolayer, remove the coverslip for further use.
    2. Suspension Cells: Seed the cells onto a clean, sterile slide coated with poly-L-lysine.
    3. Frozen Sections: Allow the slide to thaw at room temperature. Wash it with pure water or PBS for 2 times, 3 minutes each time.
    4. Paraffin Sections: Deparaffinization and rehydration. Wash the slide with pure water or PBS for 3 times, 3 minutes each time. Then perform antigen retrieval.
     
    Fixation
    1. Fix the cell coverslips/spots or tissue sections at room temperature using a fixative such as 4% paraformaldehyde (4% PFA) for 10-15 minutes.
    2. Wash the sample with PBS for 3 times, 3 minutes each time.
     
    Permeabilization
    1.Add a detergent such as 0.1–0.3% Triton X-100 to the sample and incubate at room temperature for 10–20 minutes.
    (Note: This step is only required for intracellular antigens. For antigens expressed on the cell membrane, this step is unnecessary.)
    Wash the sample with PBS for 3 times, 3 minutes each time.
     
    Blocking
    Add blocking solution and incubate at room temperature for at least 1 hour. (Common blocking solutions include: serum from the same source as the secondary antibody, BSA, or goat serum.)
    Note: Ensure the sample remains moist during and after the blocking step to prevent drying, which can lead to high background.
     
    Immunofluorescence Staining (Day 1)
    1. Remove the blocking solution and add the diluted primary antibody.
    2. Incubate the sample in a humidified chamber at 4°C overnight.
     
    Immunofluorescence Staining (Day 2)
    1. Remove the primary antibody and wash with PBST for 3 times, 5 minutes each time.
    2. Add the diluted fluorescent secondary antibody and incubate in the dark at 4°C for 1–2 hours.
    3. Remove the secondary antibody and wash with PBST for 3 times, 5 minutes each time.
    4. Add diluted DAPI and incubate at room temperature in the dark for 5–10 minutes.
    5. Wash with PBST for 3 times, 5 minutes each time.
     
    Mounting
    1. Mount the sample with an anti-fade mounting medium.
    2. Allow the slide to dry at room temperature overnight in the dark.
    3. Store the slide in a slide storage box at 4°C, protected from light.
     

    Datasheet & SDS

    生物学的記述

    Specificity
    SNAP25 Antibody [P1D7] detects endogenous levels of total SNAP25 protein.
    タンパク質の局在
    細胞膜、細胞質、細胞内膜系、シナプス、シナプトソーム
    Uniprot ID
    P60880
    Clone
    P1D7
    Synonym(s)
    SNAP, SNAP25, Synaptosomal-associated protein 25, SNAP-25, Super protein, Synaptosomal-associated 25 kDa protein, SUP
    Background
    SNAP25 (synaptosomal‑associated protein 25) is a neuron‑enriched t‑SNARE of the synaptobrevin–syntaxin–SNAP25 family that anchors on the presynaptic plasma membrane and provides two of the four α‑helices in the core SNARE bundle that drives fast Ca²⁺‑regulated exocytosis of synaptic vesicles and other secretory organelles. The protein contains two SNARE motifs separated by a flexible linker and lacks a transmembrane domain; palmitoylation of clustered cysteines in the central region targets SNAP25 to cholesterol‑rich domains of the presynaptic membrane where it assembles with syntaxin‑1 and vesicular synaptobrevin/VAMP2 into a parallel four‑helix bundle that bridges vesicle and plasma membranes and supplies the energy for membrane merger. Within this fusion machinery, SNAP25 functions as a central organizing platform that not only contributes half of the helical core but also binds regulatory factors such as synaptotagmin, complexins, Munc18 and Munc13, and scaffolding proteins that define release probability, vesicle priming, and coupling of SNARE zippering to Ca²⁺ sensing. The C‑terminal SNARE motif of SNAP25 contains defined interfaces for synaptotagmin‑1 and synaptotagmin‑7, and targeted alterations within these interfaces shift the balance between vesicle docking, priming, and fusion, indicating that SNAP25–synaptotagmin contacts position Ca²⁺ sensors at sites where partially zippered SNARE complexes await Ca²⁺ influx to trigger final fusion. SNAP25 participates in multiple exocytotic pathways, including fast synchronous synaptic vesicle release, asynchronous and spontaneous neurotransmitter release, and dense‑core vesicle fusion for neuropeptide secretion, where its presence or partial functional replacement by homologs such as SNAP23 and SNAP29 defines the efficiency and developmental timing of these secretory events. Expression is highest in neurons of the central nervous system, with SNAP25a and SNAP25b splice isoforms showing developmentally regulated patterns that correlate with maturation of synaptic transmission and plasticity; switching from the a to the b isoform refines short‑term plasticity and release kinetics without changing the basic SNARE architecture. At the pathway level, SNAP25 integrates into the neurotransmitter release cycle, with phosphorylation by kinases such as PKA and PKC, palmitoylation turnover, and interactions with Ca²⁺ channels and K⁺ channels shaping vesicle pool dynamics, presynaptic excitability, and coupling between action potentials and exocytosis. Disease‑linked missense variants in SNAP25 cluster in regions that contact synaptotagmin and other SNAREs, change the energy landscape of SNARE complex assembly, reduce vesicle priming, and alter spontaneous versus evoked release, and these mechanistic defects associate with epileptic encephalopathy, intellectual disability, and movement or neurodevelopmental disorders.
    References

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