Before the antibody is added it is necessary to block the membrane to prevent any nonspecific binding of the detection antibody. Blocking the membrane improves the sensitivity and signal-to-noise ratio of your assay. Milk and BSA are the most commonly used blocking agents.

The blocking agent used will depend on the antibody as some antibodies have been shown to non-specifically to bind to milk. When probing with phosphorylation sensitive antibodies it is recommended to use BSA.

It is important to note that if your primary antibody was made against a horse, cow, goat or donkey that you cow proteins BSA or milk can’t be used to block the membrane due to the potential for cross reaction or IgG contamination.

Wash steps in a western blot are necessary to remove any unbound reagents and reduce background. Failure to wash properly can result in a high background noise, too much washing can elute the antigen from the blot.

The amount of detergent used in your wash buffer can vary depending of your assay with concentrations ranging from 0.05 to 0.5% for detergents like Tween 20. It is recommended to make fresh stocks of detergents e.g. Tween 20 as microbial growth can result in high background noise. Furthermore, as detergents contain peroxides it is essential to use high-purity detergents.

Once the membrane has been blocked to prevent non-specific binding it can now be probed with the primary antibody. A good primary antibody will recognise a specific protein or epitope on a group of proteins. The antibody used will depend on the protein under investigation.

When choosing a primary antibody a number of considerations must be taken into account, is the antibody species specific as epitope can vary between species, the antibody/protein interaction may be sensitive to denaturing conditions and post-translational modifications and finally not all primary antibodies are suitable for western blotting and may need verification.

Following incubation with primary antibody the membrane should be washed x5 times for 5 minutes with wash buffer

In general, as the primary antibody is not detectable a labelled secondary antibody must be used which binds the primary antibody and enables detection of the target antigen. The choice of secondary antibody used can depend on the species the primary antibody was raised in or the tag linked to the primary antibody e.g biotin, histidine. For instance, if the primary antibody is an unmodified rabbit monoclonal antibody the secondary antibody used must be an anti-mouse secondary antibody from a non-mouse host.

As mentioned above secondary antibodies are conjugated to different developing molecules, for film detection and chemiluminescence HRP or AP is commonly used whilst for laser capture a fluorophore is necessary.

The dilution at which the antibody should be used at is commonly recommended by manufacturers. However, the optimal dilution of antibody can vary depending on the specifications of the assay. More strongly expressed proteins and assays of high sensitivity will require less antibody in comparison to more weakly expressed proteins and less sensitive assays. Using less antibody decrease background noise and increase specificity. Antibody dilutions are normally made in wash buffer.

The type of label on the secondary antibody will determine the development system used. For enzymatically labelled antibodies e.g. HRP and AP a chemiluminescence method is needed. If a conjugated fluorophore was used a fluorescent scanning device can be used instantaneously.

HRP conjugated antibodies are the most widely used and considered superior to AP conjugates because of the specific activities of both enzyme and antibody due to the smaller size of the HRP enzyme and its compatibility with conjugation reactions. Furthermore, HRP substrates are widely available in addition to offering a high activity rate and stability.

AP although possessing a linear reaction rate the increased reaction time required can often result in a high background signal and low signal-to-noise ratio.

The signal generated from HRP/AP conjugates is transient and only persists as long as the enzyme-substrate reaction is occurring. A well optimised assay of antibody dilution and sufficient substrate can produce light for 1 to 24hrs, allowing for documentation either with X-ray film or digital imaging equipment. X-ray film can be used to obtain semi-quantitative data but digital imaging allows for a detection of broad dynamic range and enables the retrieval of quantitative data for western blots. In chemiluminescent blotting the signal obtained is variable and generally regarded as semi-quantitative.

Fluorophore conjugated antibodies require fewer steps as no substrate is used making the protocol much shorter. Specialised equipment is however required to detect the signal requiring an excitation light source. The development of infrared, near-infrared and quantum dots has increased the sensitivity of fluorescent probed for western blot analysis.

An advantage of using fluorescent detection over chemiluminescent detection is the ability to multiplex using more than one fluorophore. Florescent blotting also enables quantitative and consistent results across repeat experiments. Disadvantages of fluorescent detection can include a low signal to noise ratio as a result of auto- fluorescence and a failure to amplify lowly expressed proteins when using a charged-couple device camera.

The removal of primary and secondary antibodies from a western blot membrane is known as stripping. Stripping enables the investigator to look at more than 1 protein on the blot e.g the protein of interest and a loading control. Probing can also be used for multiple targets and is advantageous as it saves time and sample.

Stripping works best on a PVDF membrane as it has greater capabilities to keep the protein attached and not elute. Chemiluminescent reagents such as ECL are recommended for stripping as they don’t stain the membrane which can interfere with the detection of targets of similar molecular weights. How many times a membrane can be stripped and stained depends on how optimised the stripping protocol is.

Following stripping it is important to thoroughly was the membrane with buffer and block it before primary antibody incubation.

There 2 different strengths of stripping buffer which can be used mild or harsh.

A mild stripping buffer uses a low pH glycine solution to dissociate bound antibodies. The low pH acts to remove bound antibodies via structural alteration and deactivation of the active site.

A harsh stripping is primarily used on blots with a high signal strength. Harsh stripping buffers also rely on a low pH to alter antibody structure and release the target protein. In harsh buffers this activity is achieved through the use of a neutral Tris-HCl solution containing reducing agents such as beta-mercaptoethanol and SDS. This solution is heated with the blot at 50–80°C for up to 45 minutes with agitation. It should be noted that the activities of SDS and beta-mercaptoethanol can’t be reversed and the stripped antibody recovered. Furthermore, thorough washing is required following the use of a harsh buffer to prevent denaturation of the re-probing antibody.

The separation of protein by gel electrophoresis can be visualised in 2 ways: Coomassie staining or copper staining. The choice of staining used depends largely on the downstream applications of the protein.

Coomassie staining is used to determine whether the protein has migrated uniformly and evenly. A coomassie stain should only be used on gel if the aim is not to transfer but to observe the results of SDS-Page separation as coomassie staining not reversible.

Copper staining should be used if you wish to transfer the protein following visualization. The copper staining is said to be faster and more sensitive than coomassie staining.

The efficiency and success of the transfer can be assessed by staining the PVDF or nitrocellulose membrane with Ponceau Red. Staining with ponceau red is easily reversed with washing and therefore enable subsequent antibody probing.