Blocking Buffers for Western Blotting

Explore: Western blot blocking buffers  Western Blot Protocols

The membrane supports, such as nitrocellulose and polyvinylidene difluoride (PVDF), used in western blotting have a high affinity for proteins. To prevent non-specific binding of detection antibodies during the steps following transfer, unoccupied sites on the membrane surface must be blocked. Blocking buffer formulations vary widely and may contain milk, normal serum, or highly purified proteins to block free membrane sites. The blocking step is imperative and improves the signal-to-noise ratio of the assay by reducing background interference. Inadequate amounts of blocker result in excessive background noise and a reduced signal-to-noise ratio; in contrast, excessive concentrations of blocker may mask antibody-antigen interactions or inhibit the marker enzyme, which causes a reduction of the target signal.

Several types of blocking buffers have been successfully used in western blotting. A majority of western blot blocking buffers are inert solutions of either mixed proteins or a single purified protein that ideally have little to no interaction with the detection antibodies or antigens on the blot. Typically, blocking agents are diluted in either Tris-buffered saline (TBS) or phosphate-buffered saline (PBS), with or without detergent. Detergents, such as Tween-20, can be added to the blocking buffer to further reduce non-specific binding. The amount of Tween-20 (0.05%-0.2%) will vary depending on the strength of the antibodies used. Weak-binding antibodies may be washed away by too much detergent in subsequent washes.

Selection of blocking buffer for western blotting applications is often system-dependent. Determining the proper blocking buffer can help to increase the system’s signal-to-noise ratio. Occasionally, when switching from one substrate to another, the blocking buffer may need to be changed in order to avoid problems with diminished signal or increased background. For example, with applications using an alkaline phosphatase (AP) conjugate, a blocking buffer in Tris-buffered saline (TBS) should be selected because phosphate-buffered saline (PBS) interferes with AP activity. Empirically testing various blocking buffers for use with a given system can help achieve the best possible results. No single blocking agent is ideal for every application because each antibody-antigen pair has unique characteristics.

The accompanying figures illustrate the value of testing different blocking buffers as part of western blotting optimization. In these example experiments, in which all other conditions were equal, different blocking buffers quenched or enhanced the sensitivity and specificity of the western blot for individual proteins. In other cases, weak blocking buffers might cause non-specific bands.

In the detection of pAKT in 293T cell lysates, 2% BSA and StartingBlock Blocking Buffer provided the highest sensitivity. However, 2% BSA weakly blocked non-specific binding from the detection antibodies, which is seen with the non-specific banding patterns at higher total lysate load. 5% NF-Milk provided the lowest background, but at a cost to the limit of detection.

In the detection of highly abundant, Hsp90 in 293T cell lysates, all blocking buffers tested provided reasonable signal-to-noise ratios. 5% BSA exhibited a higher level of non-specific binding from the detection antibodies, but provided good sensitivity.

Particles and contaminants in blocking and wash buffers can settle on membranes and create fluorescent artifacts, so it’s important to use high-quality, filtered buffers in fluorescent western blotting. In addition, limit the use of detergents during blocking steps, as common detergents can auto-fluoresce, possibly increasing non-specific background.

1. DenHollander, N, Defus D. (1989) Loss of Antigen from Immunoblotting membranes. J Immunol Methods 122(1):129–35.

• Handbook: Western Blotting Handbook
• Handbook: Protein Research
• Handbook: Antibody-Based Tools for Biomedical Research