The Principles and Methodology of 2D Electrophoresis and its Application in Proteomics and Disease Diagnosis.

 

Principles of IEF and SDS PAGE.

The first step of 2DE is the step involving IEF and the investigation to discover and identify the pI of the samples tested. Depending on the pH of there surroundings proteins carry a positive, negative or a zero net charge and it leads to them being known as amphoteric molecules. The total amount of positive and negative charge of a proteins amino acid side chains and carboxyl terminal is known as the net charge of that protein. When the net charge of the protein is zero in a specific pH this is known as its pI. When the pH is higher than the pI the proteins will carry a negative charge and at a lower pH they will carry a positive charge. When carrying out separation of a protein in a pH gradient and you introduce an electric field, the proteins will move along to the position in the gradient where its net charge is zero. Negatively charged proteins will migrate in the direction of the anode until it reaches the point of that individual proteins pI and the positively charged will move towards the cathode until they reach their pI. The proteins charge can be regained if it diffuses away from the pI and they will migrate back across the gradient. It is this that is the focusing effect of IEF which allows proteins to be separated on the basis of very small charge differences5. The second step technique is a common method for the separation of proteins using discontinuous polyacrylamide gels as a medium with SDS to denature the proteins. It is known as sodium dodecyl sulfate polyacrylamide gel electrophoresis or SDS PAGE. As SDS is an anionic detergent the molecules hold a net negative charge throughout a wide range of pH. The SDS becomes bound to a polypeptide chain in accordance with its Mr, it is the SDS’s negative charge that destroys most of the proteins structure and is attracted to the positively charged electrode known as an anode in the electric field. The gel has varying sizes of pores throughout its structure that slow the larger molecules migrating and allows the smaller molecules to pass through faster during separation. SDS-PAGE is used to estimate relative molecular mass6. These two procedures are brought together to perform 2DE. The IEF is run at a current of 2mA for 30 minutes to allow the pH gradient to gain equilibrium. The current runs through for a further 30 minutes to achieve full separation of the proteins. The IPG strip or gel rods are then removed when the migration is complete. The gel rod is then transferred to the SDS PAGE after being treated in the buffer to achieve equilibration. This part of the method is run at 100-200 V until the front of the dye is 1cm from the edge of the slab. Using either a silver stain or coomassie blue the gel is processed for analysis5.  

Advances in technology and disease diagnosis.

As well as advances in procedure from the method by Smithies and Poulik1 to the method pioneered by O’Farrell and Klose4 and the alternative to carrier ampholytes by Görg et al2, methods in sample preparation have also seen advances and improvements. For a high performance 2DE it is critical that good solubilisation of the protein samples prior to the IEF step is achieved. Traditional methods of sample preparation are very time consuming and laborious. The method for the solubilisation of the sample usually requires a solubilisation/denaturation (SD) buffer7. This not only separates the proteins but also denatures the protein to ensure reliable running in the IEF phase “Quantitative proteomic analyses have traditionally used two-dimensional gel electrophoresis (2DE) for separation and characterisation of complex protein mixtures. Among the difficulties associated with this approach is the solubilisation of protein mixtures for isoelectric focusing (IEF)”8. A new approach to the method of solubilisation has been developed by using the Taguchi approach, “Taguchi methods are  methods developed by  to improve the quality of manufactured goods”9. This method has been used for several decades in industry to maximise the process of there products, and is now being applied in the field of science. To find the optimum conditions for 2DE Khoudoli et al8 applied the principles of the Taguchi method in the formation of the rehydration buffer and optimised the sample reduction and alkylation procedure. The result of applying this method improved the solubility and resolution of protein mixtures derived from a variety of sources on 2DE, “With the updated protocol we routinely detected approximately 4-fold more polypeptides on samples containing complex protein mixtures resolved on small format 2D gels. In addition the pI and size ranges over which proteins could be resolved was substantially improved” 8. The application of 2DE has been used extensively in the field of neuro-proteomics investigating conditions such as Alzheimer’s and Parkinson’s disease. Sheta et al10 reported that using this technique it enabled the identification of diseased specific serum biomarkers relating to these diseases. The report also outlines the massive potential the technique has for pathway measurement in blood tests for diagnosis, and therapeutic monitoring. The use of 2DE has been utilised in the investigation of human hepatocellular carcinoma-related (HHC) biomarkers11. In an attempt to improve therapy and reduce the mortality of HHC it is important to identify changes in tumour specific biomarkers associated in the progression of this disease. 2DE was used combined with nano flow liquid chromatography tandem mass spectrometry to investigate differentially expressed proteins in HCC successfully and showed that in HHC sixteen proteins seemed to be up regulated and 14 proteins were down regulated. There was a significant up regulation in the 14-3-3 gamma protein in HHC. Isoforms of this protein have been linked to carcinogenesis. “In conclusion, 2D-DIGE is an efficient strategy that enables us to identify differentially expressed proteins in HCC. Identification of potential biomarkers, such as the pinpointing of 14-3-3gamma in our findings, may provide further useful insights into the pathogenesis of HCC” 11.

Conclusion.

In proteomics the use of 2DE has proved to be an invaluable tool in the investigation into disease diagnosis. Through out its introduction it has continued to be the preferred method for protein separation due to its unparalleled ability to separate simultaneously thousands of proteins. I have discussed the changes in the methods and principles of two-dimensional electrophoresis from starch gels to the development of SDS PAGE and the developed protocol of the Taguchi approach in respect to sample preparation. This technique has shown to very effective in investigation of neuro proteomics and HCC which has enabled us to identify chemical biomarkers associated with disease and enables us to monitor therapy more effectively. The use of 2DE in disease diagnosis is enabling us to have better understanding of disease and its process and with the aid of this technique will help us come closer to cures and treatments for a range of diseases.

Barry Hollinshead.

Word count 2073.

   

References.

1. Olof Vesterberg. 1989. History of Electrophoretic Methods. Journal of Chromatography, 480, 3-19.
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4. Pier Giorgio Righetti. 2005. Electrophoresis: The March of Pennies, the March of Dimes. Journal of Chromatography A, 1079, 24-40.
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9. Unknown. Taguchi methods. Wikipedia, the free encyclopedia. .
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