100 Ni-NTA Agarose


Agarose purification resin
The His tag is the most widely used affinity tag due to its small size, low immunogenicity, and versatility under native or denaturing conditions, as well as in presence of detergents and many other additives. Cube Biotech introduces the novel PureCube 100 Ni-NTA Agarose, based on high quality crosslinked agarose with 100 µm mean diameter, providing high flow rates in batch and FPLC applications. Due to the excellent flow properties of PureCube 100 Agarose, combined with the high capacity NTA ligand, high dynamic yield and protein purity can be achieved. Even at flow rates of 7 ml/min, more than 20 mg/ml his-tagged protein could be purified. In batch setups, protein yields were at least 80 mg/ml (Fig.1) PureCube 100 Ni-NTA Agarose shows high affinity to his-tagged proteins. Recovery rates of 85-nearly 100% were achieved, even with low concentrated protein samples (Fig.2). PureCube 100 Ni-NTA Agarose is provided as a 50% suspension. To detect His-tagged proteins in Western Blot experiments, Cube Biotech offers the highly specific PentaHis antibody.

Why PureCube 100 Ni-NTA Agarose?

  • 100 µm agarose beads for high flow rates in batch and FPLC
  • High binding capacity (up to 80 mg/mL) and high purity even at high flow rates
  • Excellent recovery even with low concentrated samples
  • Stable in 10 mM DTT and 1 mM EDTA. Need to use higher concentrations?

The properties of Ni-NTA 100 Resins in detail

His_purification_absorbance
His_purification_westernblot
Fig. 1: High dynamic binding capacity of PureCube 100 Ni-NTA Agarose. GFP was spiked into E.coli lysates and purified on a 1 mL PureCube Cartridge filled with PureCube 100 Ni-NTA Agarose at flow rates from 1 to 7 ml/min, and in a gravity flow batch procedure. Left: Flow diagram, Right: SDS-PAGE analysis of elution fractions 1-4 (E1-4).
His-tag_protein_recovery; PureCube-Protein_recovery
Fig.2: Excellent protein recovery with PureCube 100 Ni-NTA Agarose. GFP was spiked into E.coli lysates in defined quantities (10, 5, 2.5, 1.25, and 0.625 mg) and purified on a 1 mL PureCube Cartridge filled with PureCube 100 Ni-NTA Agarose. Recovered GFP was quantified by absorption at 488 nm.

Features

Usage Specific binding and purification of 6x his-tagged proteins
Specifity Affinity to His-tagged proteins
Binding capacity >80 mg/mL
Chelator stability Stable in buffer containing 10 mM DTT and 1 mM EDTA
Filling quantity Delivered as a 50 % suspension
Bead size 100 μm and therefore suitable for high flow rates in batch and FPLC
Bead Ligand Ni-NTA
Required equipment
 
  • Lysis Buffer
  • Wash Buffer
  • Elution Buffer
  • Ice bath
  • Refrigerated centrifuge for 50 mL tube (min 10,000 x g)
  • 50 mL centrifuge tube
  • Micropipettor and Micropipetting tips
  • Disposable gravity flow columns with capped bottom outlet, 2 ml
  •  pH meter
  • End-over-end shaker
  • SDS-PAGE buffers, reagents and equipment Optional: Western Blot reagents and equipment

Applications

All protocols and buffer compositions are also avaible as PDF-Files on the Protocols & Datasheets page.
   
A.Protocol for purification under native conditions:
 
 
  1. Thaw the E. coli cell pellets corresponding to 200 mL bacterial culture on ice for 15 min. Optional: Freezing the cell pellet at -20 °C for 30 min prior to incubation at room temperature improves lysis by lysozyme.
  2. Resuspend the cell pellet in 10 mL Native Lysis Buffer supplemented with 1 mg/mL lysozyme, and pour it into a 50 mL conical centrifuge tube.
  3. If the solution is very viscous, add 3 units Benzonase® per mL E.coli culture volume to the lysis buffer. Alternatively or additionally, sonicate the lysate to improve cell disruption.
  4. Incubate on an end-over-end shaker at room temperature for 30 min, or at 4 °C for 1 h, depending on the temperature stability of the protein.
  5. Centrifuge the lysate for 30 min at 10,000 x g and 2-8 °C. Carefully collect the supernatant without touching the pellet. Note: The supernatant contains the cleared lysate fraction. We recommend to take aliquots of all fractions for SDS-PAGE analysis.
  6. Resuspend the PureCube Ni-NTA Agarose by inverting the bottle until the suspension is homogeneous. Transfer 1 mL of the 50 % suspension (corresponding to 500 μL bed volume) to a 15 mL conical centrifuge tube. Allow the resin to settle by gravity and remove the supernatant. Tip: Alternatively, resin equilibration can be performed directly in the disposable gravity flow column.
  7. Add 2.5 mL Native Lysis Buffer and gently resuspend the slurry to equilibrate the resin. Allow the resin to settle by gravity and remove 2 mL supernatant.
  8. Add 10 mL cleared lysate to the equilibrated PureCube Ni-NTA Agarose resin and incubate at 4 °C for 1 h on an end-over-end shaker. Tip: Alternatively, batch binding can be performed directly in a gravity flow column with closed bottom and top outlets.
  9. Transfer the binding suspension to a disposable gravity flow column with a capped bottom outlet. Use Lysis Buffer to rinse the centrifuge tube and remove resin adhered to the wall.
  10. Remove the bottom cap of the column and collect the flow-through.
  11. Wash the column with 5 mL Native Wash Buffer. Repeat the washing step at least 3 times.
  12. Elute the His-tagged protein 5 times using 0.5 mL Native Elution Buffer. Collect each eluate in a separate tube and determine the protein concentration of each fraction. Optional: Incubate the resin for 15 min in Elution Buffer before collecting the eluate to increase protein yields.
  13. Analyze all fractions by SDS-PAGE. Note: Do not boil membrane proteins. Instead, incubate samples at 46 °C for 30 min in preparation for SDS-PAGE analysis.
  14. Optional: Perform Western Blot experiment using PentaHis Antibody.
 B.Protocol for purification under denaturing conditions:
 
 
  1. Thaw the E. coli cell pellet on ice.
  2. Resuspend the cell pellet in 10 mL Denaturing Lysis Buffer. Optional: Benzonase® can be added to the lysate to reduce viscosity caused by nucleic acids (3 U/mL bacterial culture). Nucleic acids can also be sheared by passing the lysate 10 times through a fine-gauge needle.
  3. Incubate at room temperature for 30 min on an end-over-end shaker.
  4. Centrifuge the lysate for 30 min at room temperature and 10,000 x g. Collect the supernatant. Note: The supernatant contains the cleared lysate fraction. We recommend to take aliquots of all fractions for SDS-PAGE analysis.
  5. Resuspend the PureCube Ni-NTA Agarose by inverting the bottle until the suspension is homogeneous. Transfer 1 mL of the 50% suspension (corresponding to 0.5 mL bed volume) into a 15 mL conical centrifuge tube. Allow the resin to settle by gravity and remove the supernatant.
  6. Add the cleared lysate to the resin and incubate the mixture for 1 h at room temperature on an end-over-end shaker. Tip: Alternatively, batch binding can be done directly in a gravity flow column with closed top and bottom outlet.
  7. Transfer the binding suspension to a disposable gravity flow column with a capped bottom outlet. Use Lysis Buffer to rinse the centrifuge tube and remove resin adhered to the wall.
  8. Remove the bottom cap of the column and collect the flow-through.
  9. Wash the column with 5 mL Denaturing Wash Buffer. Repeat the washing step at least 3 times.
  10. Elute the His-tagged protein 5 times using 0.5 mL Denaturing Elution Buffer. Collect each eluate in a separate tube and determine the protein concentration of each fraction. Tip: If the target protein is acid-labile, elution can be performed with 250-500 mM imidazole.
  11. Analyze all fractions by SDS-PAGE. Note: Do not boil membrane proteins. Instead, incubate samples at 46˚C for 30 min in preparation for SDS-PAGE analysis.
  12. Optional: Perform Western Blot experiment using PentaHis Antibody.
 C.Wash protocol - Recommended after each use
 
 
Note: "bv" refers to column bed volume, i.e., 10 bv calls for 10 mL of buffer for a 1 mL column bed volume.
  1. Remove the majority of the fluid in the column containing the Ni-NTA matrix. Add 10 bv dd water and allow the majority of the water volume to drip out of the column. Note: You can allow the fluid to drip through the column by gravity, or use a pressure bulb to gently force the fluid through the matrix. Ensure not to dry out the matrix.
  2. . Add 10 bv Wash Buffer to the column and allow the volume to completely flow through the matrix.
  3. Rinse the column again with 10 bv dd water.
  4. Add 10 bv 20% (v/v) ethanol and allow the majority of the volume to drip out of the column. The matrix is now ready to be re-used.
 D.Wash & Regeneration protocol without the use of DTT (recommended after each run, latest after 5 runs)
 
 
Note: "bv" refers to column bed volume, i.e., 10 bv calls for 10 mL of buffer for a 1 mL column bed volume.
  1. Remove the majority of the fluid in the column containing the Ni-NTA matrix. Add 10 bv dd water and allow the majority of the volume to drip out of the column.
  2. Note: For removal of contaminations with very hydrophobic proteins or lipids, or precipitated proteins, incubate the matrix with one of the following chemicals for 1-2 h: 100% methanol, 100% ethanol, 8 M urea, 6 M guanidinium hydrochloride, 30% acetonitrile, or 1 M NaOH. Thoroughly wash with distilled water.
  3. Add 10 bv 100 mM EDTA to the column and allow the entire volume to flow through the matrix.
  4. Rinse the column again with 10 bv dd water
  5. Add 10 bv Wash Buffer to the column and allow the entire volume to flow through the matrix.
  6. Rinse the column with 10 bv dd water
  7. Add 10 bv 10m M NiSO4 to recharge the matrix. Allow the volume to drip through the column by gravity
  8. Rinse the column with 5 bv dd water.
  9. Wash twice with 5 bv dd water each.
  10. Wash with 5 bv 20 mM Tris pH 8.0.
  11. Wash twice with 5 bv dd water each.
  12. Add 10 bv of 20% (v/v) ethanol and allow the majority of the volume to drip out of the column. The matrix is now ready to be re-used.
 E.Wash & Regeneration protocol after the use of DTT (Neccessary after each run!)
 
 
Note: "bv" refers to column bed volume, i.e., 10 bv calls for 10 mL of buffer for a 1 mL column bed volume.
  1. Remove the majority of the fluid in the column containing the Ni-NTA resin. Add 10 bv dd water and allow the majority of the volume to drip out of the column.
  2. Briefly wash the resin with 10 bv 1–3% (v/v) HCl. Minimize the exposure time of the resin to HCl. Note: The concentration of HCl depends on the extent to which the resin is reduced. For example, 1% HCl was sufficient to strip Ni-NTA resin exposed to 1 mM DTT, 2% HCl for 5 mM DTT, and 3% for 10 mM DTT.
  3. Rinse the column with 10 bv dd water
  4. If the resin is not completely white, repeat steps 2 and 3. Otherwise, continue to step 4.
  5. Add 10 bv Wash Buffer and allow the majority of the volume to drip out of the column.
  6. Rinse the column with 10 bv dd water.
  7. Add 10 bv 10 mM NiSO4 to recharge the resin. Allow the volume to drip through the column by gravity.
  8. Rinse the column with 5 bv dd water
  9. Add 5 bv of Regeneration Buffer and incubate the matrix for 15 min at room temperature.
  10. Wash twice with 5 bv dd water each.
  11. Wash with 5 bv 20 mM Tris pH 8.0. Note: The extensive wash steps remove free nickel ions from the column, enhancing performance of the material in subsequent purifications, especially in presence of DTT.
  12. Wash twice with 5 bv dd water each
  13. . Add 10 bv 20% (v/v) ethanol and allow the majority of the volume to drip out of the column. The matrix is now ready to be re-used.

Frequently asked questions

What are reasons for non specific binding?
Some histidine rich proteins can also bind to nickel. But washing with NaOH after elution of your protein of interest removes unspecific bound proteins from your resin.
 
I want to use high concentration of EDTA and DTT. Is it possible to use Ni-NTA from Cube Biotech?
No it is not recommended because nickel is reduced with DTT or dissolved with EDTA. If you want to use high concentrations of EDTA and DTT you should use our Indigo resin.
 
How is the capacity at high flow rates?
Due to the high ligand density of PURE Cube Ni-NTA agarose the material shows good performance even at high flow rates.
 
After using DTT my resin turned orange. How to regenerate it?
Read our detailed protocol for more information.
 
How much resin do I have to use?
That is depending on your expression level.
Agarose purification resin
The His tag is the most widely used affinity tag due to its small size, low immunogenicity, and versatility under native or denaturing conditions, as well as in presence of detergents and many other additives. Cube Biotech introduces the novel PureCube 100 Ni-NTA Agarose, based on high quality crosslinked agarose with 100 µm mean diameter, providing high flow rates in batch and FPLC applications. Due to the excellent flow properties of PureCube 100 Agarose, combined with the high capacity NTA ligand, high dynamic yield and protein purity can be achieved. Even at flow rates of 7 ml/min, more than 20 mg/ml his-tagged protein could be purified. In batch setups, protein yields were at least 80 mg/ml (Fig.1) PureCube 100 Ni-NTA Agarose shows high affinity to his-tagged proteins. Recovery rates of 85-nearly 100% were achieved, even with low concentrated protein samples (Fig.2). PureCube 100 Ni-NTA Agarose is provided as a 50% suspension. To detect His-tagged proteins in Western Blot experiments, Cube Biotech offers the highly specific PentaHis antibody.

Why PureCube 100 Ni-NTA Agarose?

  • 100 µm agarose beads for high flow rates in batch and FPLC
  • High binding capacity (up to 80 mg/mL) and high purity even at high flow rates
  • Excellent recovery even with low concentrated samples
  • Stable in 10 mM DTT and 1 mM EDTA. Need to use higher concentrations?

The properties of Ni-NTA 100 Resins in detail

His_purification_absorbance
His_purification_westernblot
Fig. 1: High dynamic binding capacity of PureCube 100 Ni-NTA Agarose. GFP was spiked into E.coli lysates and purified on a 1 mL PureCube Cartridge filled with PureCube 100 Ni-NTA Agarose at flow rates from 1 to 7 ml/min, and in a gravity flow batch procedure. Left: Flow diagram, Right: SDS-PAGE analysis of elution fractions 1-4 (E1-4).
His-tag_protein_recovery; PureCube-Protein_recovery
Fig.2: Excellent protein recovery with PureCube 100 Ni-NTA Agarose. GFP was spiked into E.coli lysates in defined quantities (10, 5, 2.5, 1.25, and 0.625 mg) and purified on a 1 mL PureCube Cartridge filled with PureCube 100 Ni-NTA Agarose. Recovered GFP was quantified by absorption at 488 nm.

Features

Usage Specific binding and purification of 6x his-tagged proteins
Specifity Affinity to His-tagged proteins
Binding capacity >80 mg/mL
Chelator stability Stable in buffer containing 10 mM DTT and 1 mM EDTA
Filling quantity Delivered as a 50 % suspension
Bead size 100 μm and therefore suitable for high flow rates in batch and FPLC
Bead Ligand Ni-NTA
Required equipment
 
  • Lysis Buffer
  • Wash Buffer
  • Elution Buffer
  • Ice bath
  • Refrigerated centrifuge for 50 mL tube (min 10,000 x g)
  • 50 mL centrifuge tube
  • Micropipettor and Micropipetting tips
  • Disposable gravity flow columns with capped bottom outlet, 2 ml
  •  pH meter
  • End-over-end shaker
  • SDS-PAGE buffers, reagents and equipment Optional: Western Blot reagents and equipment

Applications

All protocols and buffer compositions are also avaible as PDF-Files on the Protocols & Datasheets page.
   
A.Protocol for purification under native conditions:
 
 
  1. Thaw the E. coli cell pellets corresponding to 200 mL bacterial culture on ice for 15 min. Optional: Freezing the cell pellet at -20 °C for 30 min prior to incubation at room temperature improves lysis by lysozyme.
  2. Resuspend the cell pellet in 10 mL Native Lysis Buffer supplemented with 1 mg/mL lysozyme, and pour it into a 50 mL conical centrifuge tube.
  3. If the solution is very viscous, add 3 units Benzonase® per mL E.coli culture volume to the lysis buffer. Alternatively or additionally, sonicate the lysate to improve cell disruption.
  4. Incubate on an end-over-end shaker at room temperature for 30 min, or at 4 °C for 1 h, depending on the temperature stability of the protein.
  5. Centrifuge the lysate for 30 min at 10,000 x g and 2-8 °C. Carefully collect the supernatant without touching the pellet. Note: The supernatant contains the cleared lysate fraction. We recommend to take aliquots of all fractions for SDS-PAGE analysis.
  6. Resuspend the PureCube Ni-NTA Agarose by inverting the bottle until the suspension is homogeneous. Transfer 1 mL of the 50 % suspension (corresponding to 500 μL bed volume) to a 15 mL conical centrifuge tube. Allow the resin to settle by gravity and remove the supernatant. Tip: Alternatively, resin equilibration can be performed directly in the disposable gravity flow column.
  7. Add 2.5 mL Native Lysis Buffer and gently resuspend the slurry to equilibrate the resin. Allow the resin to settle by gravity and remove 2 mL supernatant.
  8. Add 10 mL cleared lysate to the equilibrated PureCube Ni-NTA Agarose resin and incubate at 4 °C for 1 h on an end-over-end shaker. Tip: Alternatively, batch binding can be performed directly in a gravity flow column with closed bottom and top outlets.
  9. Transfer the binding suspension to a disposable gravity flow column with a capped bottom outlet. Use Lysis Buffer to rinse the centrifuge tube and remove resin adhered to the wall.
  10. Remove the bottom cap of the column and collect the flow-through.
  11. Wash the column with 5 mL Native Wash Buffer. Repeat the washing step at least 3 times.
  12. Elute the His-tagged protein 5 times using 0.5 mL Native Elution Buffer. Collect each eluate in a separate tube and determine the protein concentration of each fraction. Optional: Incubate the resin for 15 min in Elution Buffer before collecting the eluate to increase protein yields.
  13. Analyze all fractions by SDS-PAGE. Note: Do not boil membrane proteins. Instead, incubate samples at 46 °C for 30 min in preparation for SDS-PAGE analysis.
  14. Optional: Perform Western Blot experiment using PentaHis Antibody.
 B.Protocol for purification under denaturing conditions:
 
 
  1. Thaw the E. coli cell pellet on ice.
  2. Resuspend the cell pellet in 10 mL Denaturing Lysis Buffer. Optional: Benzonase® can be added to the lysate to reduce viscosity caused by nucleic acids (3 U/mL bacterial culture). Nucleic acids can also be sheared by passing the lysate 10 times through a fine-gauge needle.
  3. Incubate at room temperature for 30 min on an end-over-end shaker.
  4. Centrifuge the lysate for 30 min at room temperature and 10,000 x g. Collect the supernatant. Note: The supernatant contains the cleared lysate fraction. We recommend to take aliquots of all fractions for SDS-PAGE analysis.
  5. Resuspend the PureCube Ni-NTA Agarose by inverting the bottle until the suspension is homogeneous. Transfer 1 mL of the 50% suspension (corresponding to 0.5 mL bed volume) into a 15 mL conical centrifuge tube. Allow the resin to settle by gravity and remove the supernatant.
  6. Add the cleared lysate to the resin and incubate the mixture for 1 h at room temperature on an end-over-end shaker. Tip: Alternatively, batch binding can be done directly in a gravity flow column with closed top and bottom outlet.
  7. Transfer the binding suspension to a disposable gravity flow column with a capped bottom outlet. Use Lysis Buffer to rinse the centrifuge tube and remove resin adhered to the wall.
  8. Remove the bottom cap of the column and collect the flow-through.
  9. Wash the column with 5 mL Denaturing Wash Buffer. Repeat the washing step at least 3 times.
  10. Elute the His-tagged protein 5 times using 0.5 mL Denaturing Elution Buffer. Collect each eluate in a separate tube and determine the protein concentration of each fraction. Tip: If the target protein is acid-labile, elution can be performed with 250-500 mM imidazole.
  11. Analyze all fractions by SDS-PAGE. Note: Do not boil membrane proteins. Instead, incubate samples at 46˚C for 30 min in preparation for SDS-PAGE analysis.
  12. Optional: Perform Western Blot experiment using PentaHis Antibody.
 C.Wash protocol - Recommended after each use
 
 
Note: "bv" refers to column bed volume, i.e., 10 bv calls for 10 mL of buffer for a 1 mL column bed volume.
  1. Remove the majority of the fluid in the column containing the Ni-NTA matrix. Add 10 bv dd water and allow the majority of the water volume to drip out of the column. Note: You can allow the fluid to drip through the column by gravity, or use a pressure bulb to gently force the fluid through the matrix. Ensure not to dry out the matrix.
  2. . Add 10 bv Wash Buffer to the column and allow the volume to completely flow through the matrix.
  3. Rinse the column again with 10 bv dd water.
  4. Add 10 bv 20% (v/v) ethanol and allow the majority of the volume to drip out of the column. The matrix is now ready to be re-used.
 D.Wash & Regeneration protocol without the use of DTT (recommended after each run, latest after 5 runs)
 
 
Note: "bv" refers to column bed volume, i.e., 10 bv calls for 10 mL of buffer for a 1 mL column bed volume.
  1. Remove the majority of the fluid in the column containing the Ni-NTA matrix. Add 10 bv dd water and allow the majority of the volume to drip out of the column.
  2. Note: For removal of contaminations with very hydrophobic proteins or lipids, or precipitated proteins, incubate the matrix with one of the following chemicals for 1-2 h: 100% methanol, 100% ethanol, 8 M urea, 6 M guanidinium hydrochloride, 30% acetonitrile, or 1 M NaOH. Thoroughly wash with distilled water.
  3. Add 10 bv 100 mM EDTA to the column and allow the entire volume to flow through the matrix.
  4. Rinse the column again with 10 bv dd water
  5. Add 10 bv Wash Buffer to the column and allow the entire volume to flow through the matrix.
  6. Rinse the column with 10 bv dd water
  7. Add 10 bv 10m M NiSO4 to recharge the matrix. Allow the volume to drip through the column by gravity
  8. Rinse the column with 5 bv dd water.
  9. Wash twice with 5 bv dd water each.
  10. Wash with 5 bv 20 mM Tris pH 8.0.
  11. Wash twice with 5 bv dd water each.
  12. Add 10 bv of 20% (v/v) ethanol and allow the majority of the volume to drip out of the column. The matrix is now ready to be re-used.
 E.Wash & Regeneration protocol after the use of DTT (Neccessary after each run!)
 
 
Note: "bv" refers to column bed volume, i.e., 10 bv calls for 10 mL of buffer for a 1 mL column bed volume.
  1. Remove the majority of the fluid in the column containing the Ni-NTA resin. Add 10 bv dd water and allow the majority of the volume to drip out of the column.
  2. Briefly wash the resin with 10 bv 1–3% (v/v) HCl. Minimize the exposure time of the resin to HCl. Note: The concentration of HCl depends on the extent to which the resin is reduced. For example, 1% HCl was sufficient to strip Ni-NTA resin exposed to 1 mM DTT, 2% HCl for 5 mM DTT, and 3% for 10 mM DTT.
  3. Rinse the column with 10 bv dd water
  4. If the resin is not completely white, repeat steps 2 and 3. Otherwise, continue to step 4.
  5. Add 10 bv Wash Buffer and allow the majority of the volume to drip out of the column.
  6. Rinse the column with 10 bv dd water.
  7. Add 10 bv 10 mM NiSO4 to recharge the resin. Allow the volume to drip through the column by gravity.
  8. Rinse the column with 5 bv dd water
  9. Add 5 bv of Regeneration Buffer and incubate the matrix for 15 min at room temperature.
  10. Wash twice with 5 bv dd water each.
  11. Wash with 5 bv 20 mM Tris pH 8.0. Note: The extensive wash steps remove free nickel ions from the column, enhancing performance of the material in subsequent purifications, especially in presence of DTT.
  12. Wash twice with 5 bv dd water each
  13. . Add 10 bv 20% (v/v) ethanol and allow the majority of the volume to drip out of the column. The matrix is now ready to be re-used.

Frequently asked questions

What are reasons for non specific binding?
Some histidine rich proteins can also bind to nickel. But washing with NaOH after elution of your protein of interest removes unspecific bound proteins from your resin.
 
I want to use high concentration of EDTA and DTT. Is it possible to use Ni-NTA from Cube Biotech?
No it is not recommended because nickel is reduced with DTT or dissolved with EDTA. If you want to use high concentrations of EDTA and DTT you should use our Indigo resin.
 
How is the capacity at high flow rates?
Due to the high ligand density of PURE Cube Ni-NTA agarose the material shows good performance even at high flow rates.
 
After using DTT my resin turned orange. How to regenerate it?
Read our detailed protocol for more information.
 
How much resin do I have to use?
That is depending on your expression level.
Top seller
PureCube 100 Ni-NTA Agarose PureCube 100 Ni-NTA Agarose
Article number: 74103
100 Ni-NTA Agarose
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PureCube 100 Ni-NTA Agarose PureCube 100 Ni-NTA Agarose
2 ml 50% NTA Agarose, with 100 micron average bead size. Loaded with nickel (II) sulfate
Article number: 74103
Sales price: From €84.00 * €105.00 *
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