| Description | Inquire | Cell proliferation detection is a basic experimental method to evaluate the health of cells, genotoxicity and the effect of antitumor drugs. The most accurate method to detect cell proliferation is the BrdU method. Edu detection kit is a revolutionary breakthrough of BrdU method. Edu (5-ethynyl-2 '-Cell proliferation detection is a basic experimental method to evaluate the health of cells, genotoxicity and the effect of antitumor drugs. The most accurate method to detect cell proliferation is the BrdU method. Edu detection kit is a revolutionary breakthrough of BrdU method. Edu (5-ethynyl-2 '- deoxyuridine) is a pyrimidine analog that integrates into the DNA duplex during DNA synthesis. Edu detection is based on the "click" reaction. A copper catalyzed azide reacts covalently with alkynes to form covalent bonds. In this kit, edu contains alkynes, Aladdin ® 488 / 555/594/647a azide dyes contain azide compounds. The edu labeling proliferation of click method is rapid and effective, and easy to use. BrdU method requires DNA denaturation (such as acid denaturation, thermal denaturation or digestion with DNase) to expose BrdU, so as to facilitate BrdU antibody binding; The edu method only needs paraformaldehyde fixation and Triton X-100 penetration to make the detection reagent enter the cells, and only a small amount of azide dye is needed to label the integrated edu very effectively. This kit contains all components required for edu method detection, and can be used for proliferation detection of cultured cells in vitro. Component:Product parameters: 590/617 nm Instruction:Experimental materials (self provided). 10 mM PBS, pH 7.2-7.6. 4% paraformaldehyde fixing solution (in PBS)Propensive reagent (0.5% Triton X -100 in PBS). 2 mg/mL glycine solution (in ddH2O). 3% BSA in PBS, pH 7.2-7.6. 1% BSA in PBS, pH 7.2-7.6. ddH2O. 96/24/12/6 well culture plate or dishFluorescence microscopy detection method1. Cell cultureTake logarithmic growth stage cells and inoculate them into a 96 well plate with 4 × 103-1 × 105 cells per well (the number and density of cells can be adjusted according to cell size, growth rate, and specific requirements of experimental treatment), and culture until normal growth stage.2. Drug treatmentPerform various drug treatments according to experimental needs.3. EdU marking(1) Dilute EdU solution (component A) in a certain proportion with complete cell culture medium to an appropriate concentration, then add it to the cells and mix well; Set up a negative control group without EdU treatment.Note: The labeling concentration of EdU needs to be adjusted according to cell type, and it is recommended to explore with an initial concentration of 10 µ M. In the pre experiment, it is recommended to set an EdU concentration gradient, which can be referred to in Tables 2 and 3.(2) Incubate in a cell culture incubator for 2 hours.Note: The optimal incubation time is related to the cell cycle. Most tumor cell lines can use a 2-hour incubation time, as shown in Appendix 2. The concentration of EdU is related to incubation time,Short term incubation (<2 hours) should use high concentrations, such as 10-50 µ M; Long term incubation (>24 hours) should use low concentrations, such as 1-10 µ M; You can also refer to Appendix 3.4. Cell fixation and permeation promotionNote: For experiments that require cell surface antigen labeling, it can be considered to wash the cells twice with a 3% BSA washing solution after completing EdU incubation, before cell fixation and permeation promotion.(1) After incubation, remove the culture medium. Wash cells twice with 1X PBS for 5 minutes each time to remove EdU residues that have not been incorporated into DNA. Cells with weak adhesion can reduce cleaning intensity. Join 50 µ After incubating at room temperature for 20 minutes with 4% paraformaldehyde fixative, remove the fixative.(2) Add 50 to each hole µ L 2 mg/mL glycine solution, incubate at room temperature for 5 minutes, and neutralize the remaining fixed solution.(3) At a rate of 100 per hole µ Wash cells twice with 3% BSA.(4) Remove the washing solution and add 100 µ L 0.5% Triton X -100, incubate at room temperature for 10 minutes.5. EdU detectionNote: Each sample in this reference step uses 100 µ The working fluid of L can be adjusted by users according to their own sample situation.(1) Prepare 1 x Click iT EdU reaction buffer (component C): Dilute component C 10 times with ddH2O.(2) Configure 5 x Click iT EdU buffer additives (component E): add 300 µ Mix L of ddH2O into a 30 mg E component tube (final concentration of 100 mg/mL) until completely dissolved. After use, the remaining storage solution is stored at -20 ℃ and can be stored for one year. Once the solution turns brown, it indicates that the active ingredients have degraded and cannot be reused.Note: Different specifications of component E are dissolved in ddH2O according to this ratio, and prepared into a 5 x storage solution for future use.(3) Prepare 1 x Click iT EdU buffer additive: Dilute 5 x Click iT EdU buffer additive with ddH2O to 1 x, and the solution should be prepared and used immediately.(4) Prepare Click it working solution according to Table 1.Table 1 Click it working fluid Reaction components Taking the sample size of 10 holes as an example 1 x Click it EdU reaction buffer 855 µL CuSO4 (component D) 40 µL YF® 488/555/594/647A Azide(Component B) 5 µL 1 x Click it EdU buffer additive 100 µL Total volume 1 mL (5) Remove penetration enhancer, 100 per well µ Wash twice with 3% BSA washing solution of L.(6) Add 100 to each hole µ L Click iT working solution, evenly covering cells.(7) Incubate at room temperature in dark for 30 minutes.(8) Remove Click-iT working fluid and add 100 µ After washing cells twice with 3% BSA, remove the washing solution and add 100 µ L PBS keeps cells moist. If there are no other special requirements, photography analysis can be carried out.6. DNA re staining (optional)(1) Using 100 µ Wash the cells once with PBS and remove the washing solution.(2) Dilute Hoechst 33342 (component F) 2000 times with PBS.(3) Add 100 to each hole µ Incubate L 1 x Hoechst 33342 solution at room temperature in dark for 15-30 minutes.(4) Remove Hoechst 33342 solution and use 100 µ Wash cells twice with PBS.7. Imaging and analysisIt is recommended to take fluorescence microscopy photos immediately after staining is completed for observation; If conditions permit, please store in a dark and moist environment at 4 ° C for 3 days before taking photos. Flow cytometry detection method1. Cell cultureInoculate 1 × 105~3 × 106 cells per well into a 6-well plate.2. Drug treatmentPerform various drug treatments according to experimental needs.3. EdU labeled cells(1) Dilute EdU solution (component A) in a certain proportion with complete cell culture medium to an appropriate concentration, then add it to the cells and mix well; Set up a negative control group without EdU treatment.Note: The labeling concentration of EdU needs to be adjusted according to cell type, and it is recommended to explore with an initial concentration of 10 µ M. In the pre experiment, it is recommended to set an EdU concentration gradient, which can be referred to in Tables 2 and 3.(2) Incubate in a cell culture incubator for 2 hours. The time of EdU incubation of cells can be directly used as an indicator for measuring cell DNA synthesis, and the choice of time point and incubation time depend on the cell growth rate. Pulse labeled cells incubated with brief EdU can be used to study cell cycle dynamics.Note: The optimal incubation time is related to the cell cycle. Most tumor cell lines can use a 2-hour incubation time, as shown in Appendix 2. The concentration of EdU is related to the incubation time, and high concentrations, such as 10-50, should be used for short-term incubation (<2 hours) µ M; Long term incubation (>24 hours) should use low concentrations, such as 1-10 µ M; You can also refer to Appendix 3.4. Cell fixation and permeation promotionNote: For experiments that require cell surface antigen labeling, it can be considered to wash cells twice with 1% BSA after completing EdU incubation, before cell fixation and permeation promotion.(1) After incubation, collect cells, add 1 mL of PBS to each tube to clean the cells, centrifuge at 1000 rpm for 5 minutes, and discard the supernatant to remove EdU residue that has not been added to DNA.(2) Add 1 mL of 4% paraformaldehyde fixative to each tube to resuspend cells.(3) Incubate at room temperature for 20 minutes, centrifuge at 1000 rpm for 5 minutes, and discard the supernatant.(4) Add 1 mL of 2 mg/mL glycine to each tube and incubate for 5 minutes. Neutralize the remaining fixed solution, centrifuge at 1000 rpm for 5 minutes, and discard the supernatant. Add 1 mL of PBS to each tube for cleaning once, centrifuge at 1000 rpm for 5 minutes, and discard the supernatant.(5) Add 1mL of 0.5% Triton X-100 osmotic enhancer to each tube and resuspend cells. Incubate at room temperature for 10 minutes.5. EdU detectionNote: For 6-well plate samples, reference can be made to 1 mL of working solution per well. Users can adjust the dosage according to their own sample situation.(1) Prepare 1 x Click iT EdU reaction buffer: Dilute component C 10 times with ddH2O.(2) Prepare 5 x Click iT EdU buffer additives (component E): Add 300 µ L ddH2O to 30 mg of component E in a test tube (final concentration 100 mg/mL), mix well until completely dissolved. After use, the remaining storage solution is stored at -20 ℃ and can be stored for one year. Once the solution turns brown, it indicates that the active ingredients have degraded and cannot be reused.Note: Different specifications of component E are dissolved in ddH2O according to this ratio to form 5 x storage solution for future use.(3) Prepare 1 x Click iT EdU buffer additive: Dilute 5 x Click iT EdU buffer additive storage solution with ddH2O to 1 x, and the solution should be prepared and used immediately.(4) Prepare Click it working solution according to Table 2.Table 2 Click it working fluid Reaction components Volume of liquid required for a single reaction 1×Click-iT EdU reaction buffer 875 µL CuSO4 (component D) 20 µL YF® 488/555/594/647A Azide(Component B) 5 µL 1×Click-iT EdU buffer additive 100 µL Total volume 1 mL (5) Soak at 1000 rpm for 5 minutes, discard the supernatant, remove the enhancer, add 1mL of 1% BSA washing solution to each tube and wash twice. Soak at 1000 rpm for 5 minutes, discard the supernatant.(6) Add 1 mL of Click iT working solution to each tube and mix well.(7) Incubate at room temperature in dark for 30 minutes.(8) Soak at 1000 rpm for 5 minutes, discard the staining reaction solution, add 1% BSA to each tube to wash the cells twice, centrifuge at 1000 rpm for 5 minutes, discard the supernatant, and resuspend the cells again with 1 mL of 1% BSA (the volume of resuspend cells can be adjusted according to the number of cells), and detect with a flow cytometer.Note: If other biomarker tests are required, please refer to step 4.6. Intracellular antigen labeling (optional steps)(1) Add antibody working solution and mix well.(2) Under dark conditions, incubate antibodies at appropriate temperature and time.7. Flow detection and analysis:(1) It is recommended to conduct flow cytometry testing immediately after dyeing is completed; If conditions are limited, please store in a dark place at 4 ℃ for testing, but it should not exceed 3 days.(2) It is recommended to test the number of cells up to one million levels as much as possible. If the number of cells is small, the number of cells tested can be adjusted to 100000 levels starting from the experiment. For cases where the cell yield is too low (just to the level of ten thousand), it may not be conducive to making a flow chart. Therefore, the cleaning frequency in step 5 (8) can be appropriately reduced.Matters needing attention:1. please centrifuge the product to the bottom of the tube immediately before use, and then conduct subsequent experiments. 2. fluorescent dyes have quenching problems. Please try to avoid light during experimental operation to slow down fluorescence quenching. 3. click it edu buffer additive solution should be prepared and used immediately to ensure the best results. 4. for your safety and health, please wear experimental clothes and disposable gloves.Scope of application:Cell proliferation detection (cell imaging flow universal)... Read More | The aladdin 488 Caspase-3 live cell assay kit contains the aladdin 488 Caspase-3 substrate and the Ac-DEVD-CHO Caspase-3 inhibitor. aladdin 488 Caspase-3 Substrate provides an effective tool for detecting apoptosis based on Caspase-3 activity, suitable for fluorescence microscopy and flow cytometry.The aladdin 488 Caspase-3 live cell assay kit contains the aladdin 488 Caspase-3 substrate and the Ac-DEVD-CHO Caspase-3 inhibitor. aladdin 488 Caspase-3 Substrate provides an effective tool for detecting apoptosis based on Caspase-3 activity, suitable for fluorescence microscopy and flow cytometry. Compared with other fluorescent substrates or fluorescent inhibitors of Caspase based on ( FLICA ) analysis, aladdin 488 Caspase-3 Substrate does not inhibit the apoptosis process of intact cells while detecting Caspase-3 activity. Substrate is composed of fluorescent DNA dyes coupled with Caspase-3 DEVD recognition sequence. Substrate initially had no fluorescence and entered the cytoplasm through the cell membrane. In apoptotic cells, Caspase-3 cleaves the Substrate and releases high-affinity DNA staining, which migrates to the nucleus to label DNA and emits bright green fluorescence.Therefore, aladdin 488 Caspase-3 Substrate is bifunctional, which can not only detect Caspase-3 activity, but also visualize the morphological changes of the nucleus during apoptosis. Aladdin 488 staining can be fixed in formaldehyde and compatible with subsequent immunostaining experiments.Parameters:aladdin 488:Ex/Em = 500/530 nm (with DNA)Component:Points for attention:1.Please instantaneously centrifuge the product to the bottom of the tube before use, and then carry out subsequent experiments. 2.Cells can be co-stained with a final concentration of 1µM Hoechst 33342 dye to produce blue fluorescence staining of the nucleus ( Ex / Em = 346 / 460 nm ). 3.Aladdin 488 staining can be fixed by formaldehyde, but it is not compatible with methanol fixation. 4.Formaldehyde-fixed aladdin 488-stained cells can be treated with 0.1 % TritonX-100 for subsequent staining, but the brightness of the treated staining may be weakened. 5.Fluorescent dyes all have quenching problems, please try to avoid light to slow down the fluorescence quenching. 6.For your safety and health, please wear experimental clothes and wear disposable gloves.Scope of application:Caspase 3 kit and apoptosis detectionUsage:1. Experimental optimization: The experimental steps provided below are based on the endpoint detection system. Aladdin 488 Substrate can also be used for long-term cell incubation course research. Cell density, substrate concentration, and inhibitor concentration may need to be optimized. The optimal substrate concentration may be between 1-10 µ Between M. Cells can be incubated with substrates in culture medium, PBS, or other buffer of your choice. For adherent cells, we recommend replacing them with fresh culture media containing substrates to prevent background heterogeneity. The operation of changing the medium or washing the cells after substrate incubation is freely selectable.2. We suggest that you set the following controls:A. Negative control: cells that do not induce apoptosis;B. Positive control: cells that induce apoptosis;C. Inhibitor control: Induce cell apoptosis while incubating Caspase-3/7 inhibitors (or 10-30 minutes in advance), and finally add Aladdin 488 Caspase-3 substrate.3. The Caspase-3/7 inhibitor Ac-DEVD-CHO in the Ac-DEVD-CHO Caspase-3 inhibitor control kit can be used to confirm that Caspase-3/7 depends on the fluorescence signal of aladdin 488. For inhibitor control, the final concentration of the inhibitor should be at least twice the substrate concentration (e.g. when using 5 µ At substrate M aladdin 488, the concentration of Ac-DEVD-CHO is 10 µ M). Before adding the substrate, incubate Ac-DEVD-CHO at room temperature for 15-30 minutes. After adding the substrate, continue to retain the inhibitor in the incubation solution. Ac-DEVD-CHO is a reversible competitive inhibitor. In certain cell types, effective Caspase-3/7 inhibitors require the use of irreversible inhibitors, such as Z-DEVD-FMK, or the addition of inhibitors before or during apoptosis induction.4. Flow cytometry(1) Choose appropriate methods to induce cell apoptosis, with untreated cell samples as controls.(2) Adhering cells should be digested with trypsin or other methods before performing the aladdin 488 Caspase-3 experiment.(3) Resuspend cells with culture medium or buffer to achieve a cell density of 106 cells/mL(4) Suck 0.2 mL of cell suspension into a flow cytometry test tube.(5) Inhibitor control samples were treated with Ac-DEVD-CHO on cells (see 3 above) Ac-DEVD-CHO Caspase-3 inhibitor control.(6) 200 µ Add 5 to L cell suspension µ Substrate of 0.2 mM and immediately mix to achieve a substrate concentration of 5 µ M. The optimal substrate concentration for different cells may vary and requires analysis and optimization.(7) Incubate cells at room temperature in dark for 15-30 minutes.(8) Join 300 µ L-medium or PBS, analyzed by flow cytometry. Detect the channel for green fluorescence (Ex/Em=485/515 nm).5. Fluorescence microscope(1) Choose appropriate methods to induce cell apoptosis, with untreated cell samples as controls.(2) Inhibitor control samples were treated with Ac-DEVD-CHO on cells (see 3 above) Ac-DEVD-CHO Caspase-3 inhibitor control.(3) Using a solution containing 5 µ M Substrate's fresh culture medium or PBS is used to replace the cell culture medium (see 1 above) Experimental optimization). For the inhibitor control group, the inhibitor was incubated together with the substrate.(4) Incubate cells at room temperature for 30 minutes or longer.(5) Cells can be directly observed in culture media containing Substrate. For the endpoint analysis method, PBS was used to clean the cells, fluorescence microscopy was used to observe the cells, and a filter (Ex/Em=485/515 nm) was used to observe green fluorescence.6. Fluorescence enzyme-linked immunosorbent assay (ELISA) reader(1) Adherent cells grow in black 96 well plates; Suspend cells, adjust the density to 106 cells/mL, and divide 0.2 mL of cell suspension into one well.(2) Choose appropriate methods to induce cell apoptosis, with untreated cell samples as controls. Note: Cells may be processed in tubes or bottles and then transferred to a 96 well detection plate.(3) Inhibitor control samples were treated with Ac-DEVD-CHO on cells (see 3 above) Ac-DEVD-CHO Caspase-3 inhibitor control.(4) For suspended cells, directly add Substrate and mix well. For adherent cells, use a solution containing 5 µ M Substrate's fresh culture medium or PBS is used to replace the cell culture medium (see 1 above) Experimental optimization). For the inhibitor control group, the inhibitor was incubated together with the substrate.(5) Cells can be directly observed in culture media containing Substrate.(6) For suspended cells, gently shake to resuspend the cells. The fluorescence enzyme-linked immunosorbent assay instrument is set with an excitation wavelength of 488 nm and an emission wavelength of 520 nm. Suggest using bottom collection method for adherent cells. Changes in the density of adherent cells may lead to inaccurate readings... Read More | The Endo F Multi-Kit will deglycosylate N-linked glycans in both native and denatured conditions. Each enzyme has a distinct specificity for N-linked glycan release. One can choose to use the three enzymes in combination to completely remove all N-linked glycans present on a glycoprotein or peptide,The Endo F Multi-Kit will deglycosylate N-linked glycans in both native and denatured conditions. Each enzyme has a distinct specificity for N-linked glycan release. One can choose to use the three enzymes in combination to completely remove all N-linked glycans present on a glycoprotein or peptide, or to use each enzyme independently and thereby determine the type of N-glycans present.Product DescriptionThe Endo F Multi-kit is recommended to deglycosylate native proteins that are resistant to PNGase F cleavage under non-denatured conditions due to the glycan location within the protein’s three-dimensional structure, as these enzymes are known to be less sensitive to protein conformation.Each of the enzymes has a different N-linked glycan specificity:Endoglycosidase F1 cleaves high mannose and some hybrid type N-glycansEndoglycosidase F2 releases biantennary and high mannose glycans (at a 40X reduced rate)Endoglycosidase F3 will release triantennarry and fucosylated biantennary N-glycansContents1 vial: Endo F1- 20 µl (0.3 U)20 mM Tris-HCl pH 7.51 vial: Endo F2- 20 µl (0.1 U)10 mM sodium acetate, 25 mM NaCl, pH 4.51 vial: Endo F3- 20 µl (0.1 U)20 mM Tris-HCl pH 7.51 vial: 5x Reaction Buffer - 400 µl250 mM sodium acetate, pH4.51 vial: 5x Reaction Buffer - 400 µl250 mM sodium phosphate, pH5.5Specific ActivityDefined as the amount of enzyme required to catalyze the release of N-linked oligosaccharides from 1 micro-mole of denatured Ribonuclease B (Endo F1) or porcine fibrinogen peptides (Endo F2/F3) in 1 minute at 37°C, pH 5.5 (PH 4.5 for Endo F3). Cleavage is monitored by SDS-PAGE.FormulationThe enzymes are provided as a sterile-filtered solution.StabilitySeveral days exposure to ambient temperatures will not reduce activity. Stable at least 12 months when stored properly.SpecificityEndo F1 cleaves Asparagine-linked (N-linked) high mannose or hybrid oligosaccharides. Endo F2 cleaves N-linked biantennary oligosaccharides and high mannose (at a 40X reduced rate). Endo F3 cleaves free or N-linked fucosylated biantennary or triantennary oligosaccharides,as well as triamannosylchitobiose core structures. These enzymes cleave between the two N-acetylglucosamine residues in the diacetylchitobiose core of the oligosaccharide, generating a truncated sugar molecule with one N-acetylglucosamine residue remaining on the asparagine. The recombinant version is not glycosylated, which may result in properties differing from the native protein.Quality & PurityEndo F1, Endo F2, and Endo F3 are tested for contaminating protease as follows: 10 µg of denatured BSA is incubated at 37°C for 24 hours with 2 µl of enzyme. SDS-PAGE analysis of the treated BSA shows no evidence of degradation. The absence of exoglycosidase contaminants is confirmed by extended incubations with the corresponding pNP-glycosides. Directions for use 1. Add up to 200 µg of glycoprotein to an Eppendorf tube. Adjust to 34 µl final volume with de-ionized water. 2. Add 10 µl Endo F2 &F3 5x Reaction Buffer, 250 mM sodium acetate pH 4.5. Use Endo F1 buffer, 250 mM sodium phosphate pH 5.5 if you are using the Endo F1 enzyme alone. 4. Add 2.0 µl of each enzyme to the reaction. Incubate 3 hours at 37°C. Monitor cleavage by SDS-PAGE. Applications– Deglycosylation of native proteins resistant to PNGase F cleavage– Determination of glycan type (high mannose, biantennary, tri/tetrantennary)– Deglycosylating proteins which normally precipitate when deglycosylating– X-Ray CrystallographyThese three enzymes cleave asparagine-linked (N-linked) oligosaccharides between the two GlcNAc residues in the core of the oligosaccharide, generating a truncated sugar molecule with one N-acetylglucosamine residue remaining on the asparagine, enhancing the solubility of the protein. In contrast, PNGase F removes the oligosaccharide intact... Read More | This product is a cDNA first strand synthesis kit specially prepared for the first step experiment of two-step RT-PCR. The reverse transcriptase used in this kit is a novel and efficient reverse transcriptase that utilizes E. coli engineered bacteria for recombination and expression. It removes This product is a cDNA first strand synthesis kit specially prepared for the first step experiment of two-step RT-PCR. The reverse transcriptase used in this kit is a novel and efficient reverse transcriptase that utilizes E. coli engineered bacteria for recombination and expression. It removes RNase H activity and enhances its thermal stability. It can synthesize cDNA first strands using extremely low amounts of total RNA or mRNA, with an initial sample size as low as pg level. SuperRT reverse transcriptase has strong affinity for RNA and can read RNA templates with high GC content and complex secondary structures, obtaining high yields of cDNA. This product contains all the reagents required for reverse transcription from RNA templates to cDNA first strand, including Super RT efficient reverse transcriptase, reaction buffer, primers, dNTP, etc. It is simple and convenient to use. This system has high compatibility with subsequent PCR and quantitative PCR experiments, and is suitable for various DNA polymerase reactions. S665657 Component 100 T Storage S665657A SuperRT, 200 U/µL 100 µL -20℃. Avoid freeze/thaw cycle. S665657B 5×SuperRT Buffer 500 µL -20℃. Avoid freeze/thaw cycle. S665657C Primer Mix 240 µL -20℃. Avoid freeze/thaw cycle. S665657D dNTP Mix, 2.5 mM Each 500 µL -20℃. Avoid freeze/thaw cycle. S665657E RNase-Free Water 1 mL -20℃. Avoid freeze/thaw cycle.Product features:·Efficient reverse transcription: It has a high affinity for RNA templates, with a reverse transcription efficiency of up to 90%, and can recognize pg level templates.·Free response to complex templates: Even templates with high GC content and complex secondary structures can achieve good results without high-temperature denaturation.Notes:1. During the operation process, RNase contamination should be avoided to prevent RNA degradation or cross contamination during experiments. It is recommended to perform RNA operations in specialized areas, use specialized instruments and consumables, and have operators wear masks and disposable gloves, and frequently change gloves.2. Disposable plastic containers should be used as much as possible for experiments. If glass containers are used, they should be treated with a 0.1% DEPC (diethyl pyrocarbonate) aqueous solution at 37 ℃ for 12 hours, and sterilized under high pressure at 120 ℃ for 30 minutes before use. Alternatively, glass containers should be sterilized under dry heat at 180 ℃ for 60 minutes before use. The sterile water used in the experiment should be treated with 0.1% DEPC and then subjected to high-pressure sterilization.3. All reagents in this reagent kit should be gently mixed upside down before use, avoiding foaming as much as possible, and used after brief centrifugation. The enzymes involved should be returned to -20 ℃ as soon as possible after use to avoid repeated freeze-thaw cycles.If the initial amount of RNA is less than 50 ng, it is recommended to add RNA enzyme inhibitors (RNAsin). This kit is not provided.Usage:Note: 1 ng -5 µ g of total RNA can establish a 20 µ l reaction system. If the total RNA amount is greater than 5 µ g, please expand the reaction system proportionally.Steps for reverse transcription:1. Dissolve the RNA template, Primer Mix, dNTP Mix, SuperRT Buffer, SuperRT, and RNase Free Water and place them on ice for later use.2. Prepare a reaction system according to the following table, with a total volume of 20 µ L. Reagent 20 µlReaction system Final concentration dNTP Mix,2.5 mM Each 4 µl 500 µM Each Primer Mix 2 µl / RNA Template X µl 50 pg-5 µg SuperRT,200 U/µl 1 µl / RNase-Free Water up to 20 µl / Attention:1) If the initial amount of RNA is less than 50 ng, it is recommended to add RNA enzyme inhibitors (RNAsin). This kit is not provided.2) Primer Mix is formulated from Oligo (dT) and Random Primer. Oligo dT Primer or Gene Specific Primer can be used according to experimental needs, with a recommendation of 20 µ The reaction system Oligo dT Primer is 50 pmol, or Gene Specific Primer is 2 pmol.3. Vortex shake and mix well, briefly centrifuge to collect the solution on the pipe wall to the bottom of the pipe.Incubate at 4.42 ℃ for 30-50 minutes and 85 ℃ for 5 minutes. After the reaction is complete, centrifuge briefly and cool on ice.5. Reverse transcripts can be directly used for PCR reactions and fluorescence quantitative PCR reactions, or stored at -20 ℃ for a long time. Reagent 20 µ Final concentration of reaction system dNTP Mix, 2.5 mM Each 4 µ L 500 µ M Each Primer Mix 2 µ RNA Template X µ L 50 pg-5 µ g 5 x SuperRT Buffer 4 µ 1 x SuperRT, 200 U/ µ L 1 µ RNase Free Water up to 20 µ Lii If the reverse transcription efficiency is low, or the RNA template secondary structure is complex and the GC content is high, the following steps are recommended:1. Dissolve the RNA template, Primer Mix, dNTP Mix, SuperRT Buffer, SuperRT, and RNase Free Water and place them on ice for later use.2. Configure the reaction system according to the following table, with a total volume of 15 µ L. Reagent 20 µlReaction system Final concentration dNTP Mix,2.5 mM Each 4 µl 500 µM Each Primer Mix 2 µl / RNA Template X µl 50 pg-5 µg RNase-Free Water up to 15 µl / Note: Primer Mix is formulated from Oligo (dT) and Random Primer. Oligo dT Primer or Gene Specific Primer can be used according to experimental needs. 3. Incubate at 70 ℃ for 10 minutes and quickly ice bath for 2 minutes.4. Centrifuge briefly to collect the solution on the tube wall to the bottom of the tube.5. Continue to add the following reagents to the above reaction solution: Reagent 20 µlReaction system Final concentration 5×SuperRT Buffer 4 µl 1× SuperRT,200 U/µl 1 µl / Note: If the initial amount of RNA is less than 50 ng, it is recommended to add RNA enzyme inhibitors (RNasins). This kit is not provided. 6. Incubate at 42 ℃ for 30-50 minutes and 85 ℃ for 5 minutes.7. After the reaction is complete, centrifuge briefly and cool on ice.8. Reverse transcripts can be directly used for PCR reactions and fluorescence quantitative PCR reactions, or stored at -20 ℃ for a long time... Read More |