Protocol

Thiol-Activated Resin for SH Group Coupling: A Step-by-Step Protocol

Products

1 μm BcMag™ Thiol-Activated Magnetic Beads
Cat. No.  FX101

Unit Size  150 mg
Order
1 μm BcMag™ Thiol-Activated Magnetic Beads
Cat. No.  FX102

Unit Size  300 mg
Order
5 μm BcMag™ Thiol-Activated Magnetic Beads
Cat. No.  FX103

Unit Size  150 mg
Order
5 μm BcMag™ Thiol-Activated Magnetic Beads
Cat. No.  FX104

Unit Size  300 mg
Order
1 μm BcMag™ Long Arm Thiol-Activated Magnetic Beads
Cat. No.  FX105

Unit Size  150 mg
Order
1 μm BcMag™ Long Arm Thiol-Activated Magnetic Beads
Cat. No.  FX106

Unit Size  300 mg
Order
5 μm BcMag™ Long Arm Thiol-Activated Magnetic Beads
Cat. No.  FX107

Unit Size  150 mg
Order
5 μm BcMag™ Long Arm Thiol-Activated Magnetic Beads
Cat. No.  FX108

Unit Size  300 mg
Order
Previous slide
Next slide

Cat. No.

Product Name

Unit Size

Order

FX101

1 μm BcMag™ Thiol-Activated Magnetic Beads

150 mg

FX102

1 μm BcMag™ Thiol-Activated Magnetic Beads

300 mg

FX103

5 μm BcMag™ Thiol-Activated Magnetic Beads

150 mg

FX104

5 μm BcMag™ Thiol-Activated Magnetic Beads

300 mg

FX105

1 μm BcMag™ Long Arm Thiol-Activated Magnetic Beads

150 mg

FX106

1 μm BcMag™ Long Arm Thiol-Activated Magnetic Beads

300 mg

FX107

5 μm BcMag™ Long Arm Thiol-Activated Magnetic Beads

150 mg

FX108

5 μm BcMag™ Long Arm Thiol-Activated Magnetic Beads

300 mg

Specification

Composition

Magnetic beads grafted with Thiol group on the surface

Number of Beads

~ 1.68 x 109 beads/mg (1μm beads)

~ 5 x 107 beads /mg (5μm beads)

Stability

Short Term (<1 hour): pH 3-11; Long-Term: pH 4-10

Temperature: 4°C -140°C; Most organic solvents

Magnetization

~40-45 EMU/g

Type of Magnetization

Superparamagnetic

Formulation

Lyophilized Powder

Functional Group Density

1μm Magnetic Beads

~240 μmole / g of Beads

5μm Magnetic Beads

~200 μmole / g of Beads

1μm Long-Arm Magnetic Beads

~195 μmole / g of Beads

5μm Long-Arm Magnetic Beads

~165 μmole / g of Beads

Storage

Ship at room temperature. Store at -20°C upon receipt.

These chemicals can be utilized to create disulfide bonds and introduce sulfhydryl groups in proteins. Pyridyl disulfides can form disulfide connections with sulfhydryl groups in a broad pH range, with the optimal range being pH 4 to 5. The reaction between the molecule’s -SH group and the reagent’s 2-pyridyldithiol group results in a disulfide exchange that can take place even at physiological pH, albeit at a slower rate.

Pyridyldithiol compounds have numerous applications in affinity purification procedures, as they generate reversible conjugates that can be easily cleaved using disulfide reducing agents, such as DTT or SDS-PAGE sample buffer. Pyridyldisulfide magnetic beads can serve as an excellent alternative to maleimide and haloacetyl reagents in experiments where it is crucial to reverse the sulfhydryl-conjugation step to recover the original sulfhydryl-containing molecule precisely.

BcMag™ Thiol-activated Magnetic Beads are uniform magnetic beads that contain high-density thiol functional groups (2-pyridyl disulfide) on their surface. These beads can immobilize thiol-containing ligands reversibly under mild conditions. After affinity purification, reducing agents, such as DTT or β-mercaptoethanol, can cleave and separate the target molecule-ligand complex from the beads. BcMag™ thiol-activated magnetic beads are best suited for conjugating large proteins, while BcMag™ long-arm thiol-activated Magnetic Beads are recommended for small peptides, as the long-arm hydrophilic linker can help reduce steric hindrance.

Immobilization of Thiol activated magnetic beads

Workflow

The magnetic matrix works perfectly as affinity resin for a wide variety of affinity purification to refine thiol group-containing proteins or other molecules from the sample. After washing away unbound material, the thiol-containing substance is eluted by the addition of a reducing agent such as DTT or 2-mercaptoethanol.

Workflow of magnetic beads for affinity purification

Features and Advantages

Pre-activated and ready-to-use

A cleavable built-in disulfide bond allows the ligand-target molecule complex separated from the beads

Specific isolation of cysteine proteins/peptides

Stable covalent bond with minimal ligand leakage

Produces reusable affinity matrix

Low nonspecific binding

Applications: Affinity purification, immunoprecipitation, purification of antibodies, proteins/peptides, DNA/RNA

Protocol

Note:

The following protocol is an example for coupling protein and peptides to BcMag™ Thiol-Activated magnetic beads. We strongly recommended titrating the quantity of beads used for each application. This protocol can be scaled up and down accordingly.

A.

Materials Required

1.

Coupling Buffer : 0.1 M sodium phosphate, pH 7.0, 5mM EDTA

2.

L-Cysteine•HCl

3.

TCEP (tris(2-carboxyethyl) phosphine)

4.

Washing Buffer: 1 M NaCl, 0.05% NaN3

5.

Magnetic Rack (for manual operation)

Based on sample volume, the user can choose one of the following Magnetic Racks:

1. BcMag™ Magnetic Rack-2 for holding two individual 1.5 ml centrifuge tubes (Cat. No. MS-01);

2. BcMag™ Magnetic Rack-6 for holding six individual 1.5 ml centrifuge tubes (Cat. No. MS-02);

3. BcMag™ Magnetic Rack-24 for holding twenty-four individual 1.5-2.0 ml centrifuge tubes (Cat. No. MS-03);

4. BcMag™ Magnetic Rack-50 for holding one 50 ml centrifuge tube, one 15 ml centrifuge tube, and four individual 1.5 ml centrifuge tubes (Cat. No. MS-04);

5. BcMag™ Magnetic Rack-96 for holding a 96 ELISA plate or PCR plate (Cat. No. MS-05).

B.

Ligand Preparation

Note:

Make sure that the protein/peptide to be conjugated has free (reduced) sulfhydryl. To ensure free sulfhydryl groups are available, treat the protein/peptide with a reducing agent such as DTT (dithiothreitol), TCEP (tris(2-carboxyethyl) phosphine), or 2-MEA (2-Mercaptoethylamine•HCl) followed by desalting or dialysis to remove the reducing agent.

Newly Synthesized peptides may be directly used for coupling if used immediately after reconstitution.

For protein, treat protein with 5-10 mM TCEP solution for 30 minutes at room temperature, followed by dialysis or a desalting column. For IgG antibodies, 2-MEA is recommended due to its selective reduction of hinge-region disulfide bonds.

If the sample contains reducing agents with free sulfhydryl (e.g., 2-mercaptoethanol, DTT, or TCEP), these agents must be entirely removed by dialysis or desalting.

1.

Prepare 100 μl of protein solution (0.5-1mg/ml) or peptide solution (200 μmoles/ml) with coupling buffer.

2.

If samples have already been suspended in another buffer, dilute samples with an equal volume of coupling buffer.

C.

Magnetic Beads preparation

1.

Prepare 3% magnetic beads with Ethanol (30 mg/ml) and mix well.

Note: Store the unused beads in acetone solution at 4°C. It has been stabling for over a year.

2.

Transfer 100 μl (3mg) magnetic beads to a centrifuge tube.

3.

Place the tube on the magnetic rack for 1-3 minutes. Remove the supernatant while the tube remains on the rack. Remove the tube from the rack and resuspend the beads with 1 ml coupling buffer by vortex for 30 seconds.

4.

Repeat step 3 two times.

5.

Remove the supernatant, and the washed beads are ready for coupling.

Note: Once rehydrated using the coupling buffer, use the bead as soon as possible due to the stability of the functional group.

D.

Coupling

1.

Add the ligand to the washed magnetic beads and incubate at room temperature for 4-6 hours or overnight with continuous rotation.

Note: The user should optimize the incubation time.

2.

Wash the magnetic beads with 1ml coupling buffer four times.

3.

Block the excess active groups on the beads by suspending the beads in 1ml Coupling buffer containing 8mg L-Cysteine•HCl and incubate 30-60 minutes at room temperature with gentle rotation.

4.

Wash the beads with 1ml washing buffer four times.

5.

Resuspend the beads in PBS buffer containing 0.05% sodium azide and store them at 4C.

E.

General Affinity Purification Protocol

Note:

This protocol is a general affinity purification procedure. Designing a universal protocol for all protein purification is impossible because no two proteins are precisely alike. The user should determine the optimal working conditions for purifying the individual target protein to obtain the best results.

Avoid reducing agents in binding and washing buffers.

We strongly recommended titration to optimize the number of beads used for each application based on the amount of the target protein in the crude sample. Too many magnetic beads used will cause higher backgrounds, while too few beads used will cause lower yields. Each mg of magnetic beads typically binds to 10-20 μg of the target protein.

1.

Transfer the optimal amount of the beads to a centrifuge tube. Place the tube on the magnetic rack for 1-3 minutes. Remove the supernatant while the tube remains on the rack.

2.

Remove the tube and wash the beads with 5-bed volumes of PBS buffer by vortex for 30 seconds. Leave the tube at room temperature for 1-3 minutes. Place the tube on the magnetic rack for 1-3 minutes. Remove the supernatant while the tube remains on the rack.

3.

Repeat step 2 two times.

4.

Add washed beads to the crude sample containing the target protein and incubate at room or desired temperature for 1-2 hours (Lower temperatures require longer incubation time).

Note: Strongly recommended to perform a titration to optimize incubation time. More prolonged incubation may cause higher background.

5.

Extensively wash the beads with 5-beads volumes of PBS buffer or 1M NaCl until the absorbance of eluting at 280 nm approaches the background level (OD280 < 0.05).

Note: Adding a higher concentration of salts, nonionic detergent, and reducing agents may reduce the nonspecific background. For example, adding NaCl (up to 1-1.5 M), and 0.1-0.5% nonionic detergents such as Triton X100 or Tween20 to the washing buffer.

6.

Elute the target protein by appropriate methods such as low pH (2-4), high pH (10-12), high salt, high temperature, affinity elution, or boiling in SDS-PAGE sample buffer, or reducing agents.

7.

Cleave the Disulfide Bond

Note: Due to conformational variation from ligands to ligands, the user should determine the optimal working conditions such as reducing agent, pH, and temperature for cleaving the disulfide bond of individual ligands. The following is an example of cleaving conjugated GFP from the beads.

1)

Incubate the magnetic beads (30mg/ml) in either 140 mM β-mercaptoethanol or 5mM DTT (Dithiothreitol)

a. 100 mM Tris-HCl, pH 8.0, 50 mM EDTA, 140 mM β-mercaptoethanol for 2 hours to overnight at room temperature or 98°C for 5 minutes.

b. 100 mM Tris-HCl, pH 8.0, 50 mM EDTA, 5mM DTT for 2 hours to overnight at room temperature or 98°C for 5 minutes.

Welcome to BitClone

Magnetic Beads Make Things Simple