Years of experience in manufacturing and developing agarose beads have accumulated to the high protein yield of 80 mg protein per ml resin, which is leading in the market compared to other Ni-NTA suppliers.

1. Protein Binding Capacity

The protein binding capacity is up to 80 mg/mL, as determined by purification of 6xHis-tagged GFP protein from E.coli cleared lysates, and quantified via spectrophotometry. Proteins are eluted with high purity.

2.  Compatibility

PureCube 100 Ni-NTA Agarose is very stable and can resist the following conditions in most situations: pH 3-13, 100% methanol, 100% ethanol, 8 M urea, 6 M guanidinium hydrochloride, 30% (v/v) acetonitrile, 10 mM DTT, 1 mM EDTA, 1 M NaOH.

3. High yield and purity

Our unique production process yields a Ni-NTA Agarose that exhibits a protein binding capacity >20% higher than that of two leading competitor products. Figure 1 shows the SDS-PAGE of GFP expressed in E. coli and purified in gravity colums with PureCube Ni-NTA Agarose and the Ni-NTA resin from Competitor G and Competitor Q. The protein yield in 4 elutions (E1-E4, Cube) was 80 mg/mL, compared to 65 and 48 mg/mL obtained with the alternative resins (E1-E4, Competitor G, Competitor Q). Similar results (10-18% higher binding capacity; data not shown here) were obtained comparing the purification of JNK1 (Kinase, 48 kDa) on PureCube Ni-NTA and the Ni-NTA of leading providers.

Fig. 1: Over 20% more yield obtained with PureCube Ni-NTA Agarose. SDS-PAGE of GFP expressed in E. coli and purified in gravity columns with PureCube Ni-NTA Agarose and Ni-NTA resin from Competitor Q. 80 mg/mL protein yield was obtained with PureCube Ni-NTA Agarose (E1–E4, Cube) compared to 65 and 48 mg/mL, respectively, with the widely used alternative resins G and Q (E1–E4, Competitor G / Competitor Q).

4.Superior DTT and EDTA stability

PureCube Ni-NTA Agarose is very robust in the presence of DTT and EDTA. In a stability test, PureCube Ni-NTA Agarose was exposed to increasing concentrations of DTT or EDTA for 1 h. Thereafter, the resins were used to purify E. coli-expressed GFP-His in gravity columns. The binding capacity of the resin decreased in the presence of both DTT and EDTA but the decay rate was shallow. In presence of DTT, PureCube Ni-NTA Agarose lost on average 8% binding capacity with each increase in DTT concentration, resulting in an overall decay of 22% at 10 mM. Even at 1.5 mM EDTA, the resin still exihibits 54% of its maximum binding capacity (Fig. 2).

Fig. 2: NTA is robust in the presence of reducing and chelating agents. GFP-His was purified on gravity columns containing PureCube Ni-NTA Agarose after exposing the resin for 1 h to 3 concentrations of DTT or EDTA. NTA exhibits a shallow decay rate in binding capacity.

5.Robust against oxidation and regenerable

PureCube Ni-NTA Agarose retains its color and function after exposure to as much as 10 mM DTT. Figure 3 shows a photo series of the resin after a 1 h exposure to 5 mM DTT. Unlike other resins, PureCube Ni-NTA Agarose did not turn brown (A). The resin was still able to bind GFP (B), with a measured binding capacity of 65 mg/mL (see Fig. 2). The resin could then be regenerated by stripping the NTA, turning the resin white (C), and reloading it with nickel ions (D). The protocol for regenerating PureCube Ni-NTA Agarose can be downloaded.

 Fig. 3: PureCube Ni-NTA Agarose is robust against oxidation and regenerable. PureCube Ni-NTA Agarose was exposed to 5mM DTT for 1 h (A). After demonstrating that it could still bind GFP (B), the resin was washed, stripped (C), and reloaded with Ni2+ (D) following standard Cube protocol (see Cube Protocols & Datasheets).