Protein methods

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Protein methods are the techniques used to study proteins. There are experimental methods for studying proteins (e.g., for detecting proteins, for isolating and purifying proteins, and for characterizing the structure and function of proteins, often requiring that the protein first be purified). Computational methods typically use computer programs to analyze proteins. However, many experimental methods (e.g., mass spectrometry) require computational analysis of the raw data.

Genetic methods

Experimental analysis of proteins typically requires expression and purification of proteins. Expression is achieved by manipulating DNA that encodes the protein(s) of interest. Hence, protein analysis usually requires DNA methods, especially cloning. Some examples of genetic methods include conceptual translation, Site-directed mutagenesis, using a fusion protein, and matching allele with disease states. Some proteins have never been directly sequenced, however by translating codons from known mRNA sequences into amino acids by a method known as conceptual translation. (See genetic code.) Site-directed mutagenesis selectively introduces mutations that change the structure of a protein. The function of parts of proteins can be better understood by studying the change in phenotype as a result of this change. Fusion proteins are made by inserting protein tags, such as the His-tag, to produce a modified protein that is easier to track. An example of this would be GFP-Snf2H which consists of a protein bound to a green fluorescent protein to form a hybrid protein. By analyzing DNA alleles can be identified as being associated with disease states, such as in calculation of LOD scores.

Protein extraction from tissues

Protein extraction from tissues with tough extracellular matrices (e.g., biopsy samples, venous tissues, cartilage, skin) is often achieved in a laboratory setting by impact pulverization in liquid nitrogen. Samples are frozen in liquid nitrogen and subsequently subjected to impact or mechanical grinding. As water in the samples becomes very brittle at these temperature, the samples are often reduced to a collection of fine fragments, which can then be dissolved for protein extraction. Stainless steel devices known as tissue pulverizers are sometimes used for this purpose.

Advantages of these devices include high levels of protein extraction from small, valuable samples, disadvantages include low-level cross-over contamination.

Protein purification

Detecting proteins

The considerably small size of protein macromolecules makes identification and quantification of unknown protein samples particularly difficult. Several reliable methods for quantifying protein have been developed to simplify the process. These methods include Warburg–Christian method, Lowry assay, and Bradford assay (all of which rely on absorbance properties of macromolecules).

Bradford assay method uses a dye to bind to protein. Most commonly, Coomassie brilliant blue G-250 dye is used. When free of protein, the dye is red but once bound to protein it turns blue. The dye-protein complex absorbs light maximally at the wavelength 595 nanometers and is sensitive for samples containing anywhere from 1 ug to 60 ug. Unlike Lowry and Warburg-Christian Methods, Bradford assays do not rely on Tryptophan and Tyrosine content in proteins which allows the method to be more accurate hypothetically.

Lowry assay is similar to biuret assays, but it uses Folin reagent which is more accurate for quantification. Folin reagent is stable at only acidic conditions and the method is susceptible to skewing results depending on how much tryptophan and tyrosine is present in the examined protein. The Folin reagent binds to tryptophan and tyrosine which means the concentration of the two amino acids affects the sensitivity of the method. The method is sensitive at concentration ranges similar to the Bradford method, but requires a minuscule amount more of protein.

Warburg–Christian method screens proteins at their naturally occurring absorbance ranges. Most proteins absorb light very well at 280 nanometers due to the presence of tryptophan and tyrosine, but the method is susceptible to varying amounts of the amino acids it relies on.

More methods are listed below which link to more detailed accounts for their respective methods.

Non-specific methods that detect total protein only

Specific methods which can detect amount of a single protein

Protein structures

Interactions involving proteins

Protein–protein interactions

Protein–DNA interactions

Protein–RNA interactions

Computational methods

Other methods

See also

Bibliography

  • Daniel M. Bollag, Michael D. Rozycki and Stuart J. Edelstein. (1996.) Protein Methods, 2 ed., Wiley Publishers. ISBN 0-471-11837-0.

References