research use only
Cat.No.: F9725
| Dilution |
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| Application |
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| WB, IP, IHC, IF |
| Reactivity |
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| Human |
| Source |
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| Rabbit Monoclonal Antibody |
| Storage Buffer |
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| PBS, pH 7.2+50% Glycerol+0.05% BSA+0.01% NaN3 |
| Storage (from the date of receipt) |
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| -20°C (avoid freeze-thaw cycles), 2 years |
| Predicted MW Observed MW |
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| 45 kDa 48 kDa |
| *Why do the predicted and actual molecular weights differ? The following reasons may explain differences between the predicted and actual protein molecular weight. Post-translational modifications(e.g., phosphorylation, glycosylation); Splice variants and isoforms; Relative charge; Multimerization. |
| Positive Control | Human tonsil tissue; Human pancreas tissue; HeLa cells; A431 cells; Jurkat cells; 293T cells |
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| Negative Control |
| WB |
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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, 120 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 1:10000), 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 |
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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.
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| IHC |
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Experimental Protocol:
Deparaffinization/Rehydration
1. Deparaffinize/hydrate sections:
2. Incubate sections in three washes of xylene for 5 min each.
3. Incubate sections in two washes of 100% ethanol for 10 min each.
4. Incubate sections in two washes of 95% ethanol for 10 min each.
5. Wash sections two times in dH2O for 5 min each.
6.Antigen retrieval: For Citrate: Heat slides in a microwave submersed in 1X citrate unmasking solution until boiling is initiated; continue with 10 min at a sub-boiling temperature (95°-98°C). Cool slides on bench top for 30 min.
Staining
1. Wash sections in dH2O three times for 5 min each.
2. Incubate sections in 3% hydrogen peroxide for 10 min.
3. Wash sections in dH2O two times for 5 min each.
4. Wash sections in wash buffer for 5 min.
5. Block each section with 100–400 µl of blocking solution for 1 hr at room temperature.
6. Remove blocking solution and add 100–400 µl primary antibody diluent in to each section. Incubate overnight at 4°C.
7. Remove antibody solution and wash sections with wash buffer three times for 5 min each.
8. Cover section with 1–3 drops HRPas needed. Incubate in a humidified chamber for 30 min at room temperature.
9. Wash sections three times with wash buffer for 5 min each.
10. Add DAB Chromogen Concentrate to DAB Diluent and mix well before use.
11. Apply 100–400 µl DAB to each section and monitor closely. 1–10 min generally provides an acceptable staining intensity.
12. Immerse slides in dH2O.
13. If desired, counterstain sections with hematoxylin.
14. Wash sections in dH2O two times for 5 min each.
15. Dehydrate sections: Incubate sections in 95% ethanol two times for 10 sec each; Repeat in 100% ethanol, incubating sections two times for 10 sec each; Repeat in xylene, incubating sections two times for 10 sec each.
16. Mount sections with coverslips and mounting medium.
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| Specificity |
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| RCC1 Antibody (Rabbit mAb) [J20J20] detects endogenous levels of total RCC1 protein. |
| Subcellular Location |
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| Chromosome, Cytoplasm, Nucleus |
| Uniprot ID |
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| P18754 |
| Clone |
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| J20J20 |
| Synonym(s) |
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| CHC1, RCC1, Regulator of chromosome condensation, Cell cycle regulatory protein, Chromosome condensation protein 1 |
| Background |
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| RCC1 (regulator of chromosome condensation 1) is the canonical guanine nucleotide exchange factor for the Ran GTPase and a chromatin-bound scaffold that establishes the RanGTP gradient across the nuclear envelope and on mitotic chromosomes, thereby coordinating nucleocytoplasmic transport, nuclear envelope dynamics, and spindle assembly with cell‑cycle progression. The protein adopts a seven‑bladed β‑propeller fold that binds directly to nucleosomes and double‑stranded DNA, and this chromatin association concentrates RCC1–Ran complexes on chromosomes so that GDP–GTP exchange on Ran generates high local RanGTP, while RanGAP and RanBP1 in the cytoplasm promote RanGDP, together forming a spatially polarized Ran system that governs cargo release from importins in the nucleus and promotes assembly of spindle and nuclear envelope components in the vicinity of chromatin. During interphase, RCC1‑driven nuclear RanGTP maintains directionality of classical importin‑β–dependent protein import and exportin‑mediated RNA and protein export, and perturbation of RCC1 levels or activity disrupts this transport, leading to mislocalization of key regulators and defects in G1/S transition and mitotic entry. During mitosis, high chromosome-associated RanGTP generated by RCC1 activates spindle assembly factors such as TPX2 and NuMA by liberating them from importin complexes, promotes proper kinetochore–microtubule attachments, and supports timely metaphase–anaphase transition; RCC1 also contributes to inner centromere composition and kinetochore regulation in ways that include Ran‑independent displacement of Shugoshin‑1 and the chromosomal passenger complex at the metaphase–anaphase transition. RCC1 is frequently overexpressed and behaves as a tumor facilitator: integrative pan‑cancer analyses show that high RCC1 levels correlate with cell‑cycle gene signatures, increased proliferation indices, immunosuppressive tumor microenvironment features, and poor prognosis, and functional studies in clear cell renal cell carcinoma demonstrate that RCC1 supports G1/S progression, suppresses apoptosis, and stabilizes EZH2 protein, so that RCC1 knockdown reduces proliferation, increases apoptotic markers, and promotes EZH2 degradation. Targeted RCC1 silencing in breast and lung cancer models similarly reduces viability, colony formation, and migration, increases apoptosis, and downregulates pathways involved in DNA replication and repair, highlighting a broader role for RCC1 in sustaining oncogenic survival and cell‑cycle programs. RCC1 also acts as an oncogenic driver that maintains cytoplasmic Skp2 and low p27Kip1 levels; loss of RCC1 disrupts Skp2 nucleo‑cytoplasmic trafficking and stability, leading to p27 accumulation and G1 arrest, which further links RCC1’s Ran‑dependent transport function to control of ubiquitin ligase activity and CDK regulation in tumor cells. In the nervous system, newly described biallelic RCC1 missense variants cause an autosomal-recessive acute-onset axonal neuropathy in children, where mutant RCC1 proteins show reduced GDP–GTP exchange activity and decreased thermal stability, and patient fibroblasts exhibit stress‑induced defects in Ran nuclear localization and nucleocytoplasmic transport, indicating that intact RCC1–Ran signaling is required for axonal integrity and that RCC1 dysfunction can underlie severe, infection‑triggered neurodegeneration that clinically mimics Guillain–Barré syndrome. |
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