| Description | 3-Phosphoglycerate kinase (PGK) is a key enzyme in glycolysis, widely present in animals, plants, and microorganisms. It catalyzes the reaction of 3-phosphoglycerate and ATP to produce 1,3-bisphosphoglycerate. The latter, under the action of glyceraldehyde-3-phosphate dehydrogenase and NADH, 3-Phosphoglycerate kinase (PGK) is a key enzyme in glycolysis, widely present in animals, plants, and microorganisms. It catalyzes the reaction of 3-phosphoglycerate and ATP to produce 1,3-bisphosphoglycerate. The latter, under the action of glyceraldehyde-3-phosphate dehydrogenase and NADH, produces glyceraldehyde-3-phosphate and NAD+. The activity of 3-phosphoglycerate kinase (PGK) is determined by measuring the decrease in NADH.Component100TStorageExtraction Buffer100 mL2-8℃. Store in the dark.Reagent 11EA-20℃. Store in the dark.Reagent 23EA2-8℃Reagent 31EA-20℃Reagent 415 mL2-8℃Reagent 51EA-20℃Reagent Preparation:Reagent 1 (Powder, 1 vial):Before use, centrifuge at 8000 g, 4°C for 2 min to collect the powder at the bottom (tap manually if needed).Add 1.1 mL of distilled water to dissolve.The dissolved reagent can be aliquoted and stored at -20°C.Reagent 2 (Powder, 3 vials):Before use, centrifuge at 8000 g, 4°C for 2 min to collect the powder at the bottom (tap manually if needed).Add 0.4 mL of distilled water to dissolve.The dissolved reagent can be aliquoted and stored at -20°C (use within one month after dissolution).Reagent 3 (Liquid, 1 vial):Before use, centrifuge at 8000 g, 4°C for 2 min to collect the liquid at the bottom (tap manually if needed).Add 1.1 mL of distilled water to dissolve. The dissolved reagent can be aliquoted and stored at -20°C.Reagent 5 (Powder, 1 vial):Before use, centrifuge at 8000 g, 4°C for 2 min to collect the powder at the bottom (tap manually if needed).Add 1.1 mL of distilled water to dissolve.The storage period is the same as the kit's expiry date.User-Prepared Instruments & MaterialsMortar (homogenizer), ice bucket (ice maker), benchtop centrifuge, adjustable pipettes, water bath (oven, incubator, metal bath), 96-well plate, centrifuge tubes, microplate reader, distilled water (deionized water or ultrapure water is acceptable).Sample Extraction1. Tissue Samples: Weigh approximately 0.1 g of tissue, add 1 mL of Extraction Buffer, homogenize on ice, and then centrifuge at 12000 rpm, 4°C for 5 minutes. Collect the supernatant for assay.Note: If increasing the sample amount, use a ratio of 1:5 to 1:10 (tissue weight (g) : Extraction Buffer volume (mL)) for extraction.2. Bacterial/Cell Samples: Collect bacteria or cells into a centrifuge tube by centrifugation and discard the supernatant. Take approximately 5 million bacteria or cells, add 1 mL of Extraction Buffer, and disrupt using ultrasound on ice (power 200 W, ultrasonicate for 3 s, interval 10 s, repeat 30 times). Centrifuge at 12000 rpm, 4°C for 10 minutes. Collect the supernatant and keep it on ice for assay.Note: If increasing the sample amount, use a ratio of 500-1000 (x10⁴ cells) : 1 (mL Extraction Buffer) for extraction.Assay Procedure1. Preheat the microplate reader for 30 minutes. Set the wavelength to 340 nm and the temperature to 25°C.2. Thaw all reagents to room temperature (25°C).3. In a well of the 96-well plate, add sequentially:Reagent (µL)Test TubeSample20Reagent 110Reagent 210Reagent 310Reagent 4140Mix well and incubate at room temperature (25°C) for 10 minutes.4. Add Reagent (µL)Test TubeReagent 5105. Mix gently. At room temperature (25°C), read the absorbance at 340 nm at 30 seconds (A1) and then again after 10 minutes (A2). Calculate ΔA = A1 - A2.Notes:1. If ΔA is close to zero, the reaction time can be appropriately extended to 20 minutes before reading A2. The modified reaction time (T) must be substituted into the calculation formula. Alternatively, increase the sample volume appropriately (e.g., to 40 µL, with a corresponding decrease in Reagent 4 volume). The modified sample volume (V1) must be substituted into the calculation formula.2. If the decreasing trend is unstable, read the absorbance every 20 seconds and select a linear decreasing period for calculation. The corresponding ΔA value should be substituted into the calculation formula.3. If the initial absorbance A1 is too high (e.g., >2, as in deeply pigmented plant leaves), appropriately reduce the sample volume. The modified sample volume (V1) must be substituted into the calculation formula. Alternatively, add a small amount of activated carbon to the sample, mix, let stand for 5 min, then centrifuge at 12000 rpm, 4°C for 10 min, and use the supernatant for detection.4. If ΔA is greater than 0.5, reduce the reaction time (e.g., to 5 min) or reduce the sample volume (e.g., to 10 µL). The modified reaction time (T) and sample volume (V1) must be substituted into the calculation formula.PGK Activity Calculation1. Based on Sample Mass:Unit Definition: One unit of enzyme activity is defined as the consumption of 1 nmol NADH per minute per gram of tissue.Formula:PGK (nmol/min/g fresh weight) = [ΔA ÷ (ε × d) × V2 × 10⁹] ÷ (W × V1 ÷ V) ÷ T = 321.6 × ΔA ÷ W2. Based on Sample Protein Concentration:Unit Definition: One unit of enzyme activity is defined as the consumption of 1 nmol NADH per minute per mg of protein.Formula:PGK (nmol/min/mg prot) = [ΔA ÷ (ε × d) × V2 × 10⁹] ÷ (V1 × Cpr) ÷ T = 321.6 × ΔA ÷ Cpr3. Based on Bacterial/Cell Count:Unit Definition: One unit of enzyme activity is defined as the consumption of 1 nmol NADH per minute per 10⁴ cells.Formula:PGK (nmol/min/10⁴ cell) = [ΔA ÷ (ε × d) × V2 × 10⁹] ÷ (500 × V1 ÷ V) ÷ T = 0.64 × ΔAParameter Description:ε: NADH molar extinction coefficient, 6.22 × 10³ L/mol/cmd: Light path of the 96-well plate, 0.5 cmV: Volume of Extraction Buffer added, 1 mLV1: Volume of sample supernatant added, 0.02 mLV2: Total reaction volume, 0.2 mL = 2.0 × 10⁻⁴ LT: Reaction time, 10 minW: Sample mass, g500: Cell number, in units of 10⁴Cpr: Protein concentration of the supernatant, mg/mL; Aladdin BCA Protein Quantification Kit (B665595) or Ready-to-Use BCA Protein Quantification Kit (R1491648) are recommended.PrecautionsIt is recommended to first select 1-3 samples with significant differences (e.g., different types or groups) for preliminary experiments to familiarize yourself with the procedure. Determine or adjust the sample concentration based on the preliminary results to prevent unnecessary waste of samples or reagents... Read More | Product Descriptionalpha-L-fucoside fucohydrolase, alpha-L-fucosidase, alpha-(1-3,4) fucosidaseAlpha (1-3,4) Fucosidase The enzyme is very efficient and recognises α1-3,4 fucosylated glycans (e.g. Lewis X/A epitopes, including their sialylated counterparts) and hydrolyses terminal α1-3 andProduct Descriptionalpha-L-fucoside fucohydrolase, alpha-L-fucosidase, alpha-(1-3,4) fucosidaseAlpha (1-3,4) Fucosidase The enzyme is very efficient and recognises α1-3,4 fucosylated glycans (e.g. Lewis X/A epitopes, including their sialylated counterparts) and hydrolyses terminal α1-3 and α1-4 fucosyl linkages in these substrates without the need to remove sialic acid moieties.For removing core fucose linked α-(1-6) to the core GlcNAc of a GlcNAc-GlcNAc disaccharide structure we recommend our Alpha-(1-6) Fucosidase.• Non-sialidase dependant hydrolysis of antennary fucose moieties• Effective on both glycopeptides and free glycans• Highly specific (α1-3,4 fucosylated glycans)• Kit includes enzyme plus reaction buffer.• Sufficient for up to 50 samplesα(1-3,4) Fucosidase is useful for:nbsp;nbsp;Fucose linkage determinationnbsp;nbsp;Deglycosylating glycoproteins with Lewis structuresContentsAlpha-(1-3,4)-Fucosidase – 200 mM citrate buffer pH 6 containing 250 mM NaCl5x Reaction Buffer – 250 mM sodium phosphate pH 6... Read More | Product introduction:Used to isolate lymphocytes from human organsMatters needing attention:1. samples, reagents and experimental environment in the whole process shall be carried out at 20 ± 2 ℃. In order to obtain the best experimental results, it is best to carry out the Product introduction:Used to isolate lymphocytes from human organsMatters needing attention:1. samples, reagents and experimental environment in the whole process shall be carried out at 20 ± 2 ℃. In order to obtain the best experimental results, it is best to carry out the experiment within 2 h of sampling. The longer the sample is stored, the worse the cell separation effect is. The separation effect is even worse after the sample is placed for more than 6 h, or even cannot achieve the purpose of separation. 2. in this experiment, it is better not to use plastic products with high polymerization materials (such as polystyrene), but use non-static, low static ionization heart tubes and glass products without alkali treatment, because the electrostatic effect will lead to cell adhesion, and the surface of alkali treated glass will become rough, which will affect the effect of cell separation. 3. aspirating too many lymphocyte layers and separation liquid layers will cause the granulocytes at the junction of separation liquid to be aspirated, thus increasing the number of mixed granulocytes. 4. when the amount of separating solution is greater than that of tissue single cell suspension sample, the separation effect is better.Scope of application:Lymphocyte isolation... Read More | Inquire | DescriptionThe Baran Late-Stage Toolkit is a convenient collection of 12 highly innovative reagents that are highly effective in the diversification of complex molecules. The contents in the box are 11 Baran Diversinates™and one vial of Palau′Chlor®in amounts of 100 mg each. For DescriptionThe Baran Late-Stage Toolkit is a convenient collection of 12 highly innovative reagents that are highly effective in the diversification of complex molecules. The contents in the box are 11 Baran Diversinates™and one vial of Palau′Chlor®in amounts of 100 mg each. For obtaining larger amounts of any desired kit component, see the kit component table at the bottom of the page.Useful Topics:Late Stage FunctionalizationBaran Group – Professor Product PortalPalau′ChlorDiversinates... Read More |