Peptide mass fingerprinting

thumb|300px|A typical workflow of a peptide mass fingerprinting experiment.

Peptide mass fingerprinting (PMF), also known as protein fingerprinting, is an analytical technique for protein identification in which the unknown protein of interest is first cleaved into smaller peptides, whose absolute masses can be accurately measured with a mass spectrometer such as MALDI-TOF or ESI-TOF. The method was developed in 1993 by several groups independently. The peptide masses are compared to either a database containing known protein sequences or even the genome. This is achieved by using computer programs that translate the known genome of the organism into proteins, then theoretically cut the proteins into peptides, and calculate the absolute masses of the peptides from each protein. They then compare the masses of the peptides of the unknown protein to the theoretical peptide masses of each protein encoded in the genome. The results are statistically analyzed to find the best match.

The advantage of this method is that only the masses of the peptides have to be known. A disadvantage is that the protein sequence has to be present in the database of interest. Additionally most PMF algorithms assume that the peptides come from a single protein. The presence of a mixture can significantly complicate the analysis and potentially compromise the results. Typical for the PMF-based protein identification is the requirement for an isolated protein. Mixtures exceeding a number of 2–3 proteins typically require the additional use of MS/MS-based protein identification to achieve sufficient specificity of identification. Therefore, typical PMF samples are isolated proteins from two-dimensional gel electrophoresis (2D gels) or isolated SDS-PAGE bands. Additional analyses by MS/MS can either be direct, e.g., MALDI-TOF/TOF analysis or downstream nanoLC-ESI-MS/MS analysis of gel spot eluates.

Origins

Due to the long, tedious process of analyzing proteins, peptide mass fingerprinting was developed. Edman degradation was used in protein analysis, and it required almost an hour to analyze one amino acid residue. SDS-PAGE was also used to separate proteins in very complex mixtures, which also employed methods of electroblotting and staining. Then, bands would be extracted from the gel and sequenced, automatically. A recurring problem in the process was that interfering proteins would also purify with the protein of interest. The sequences of these interfering proteins were compiled into what came to known as the Dayhoff database. Ultimately, having the sequences of these known protein contaminants in databases decreased instrument time and expenses involved in protein analysis.

Sample preparation

Protein samples can be derived from SDS-PAGE

A small fraction of the peptide (usually 1 microliter or less) is pipetted onto a MALDI target and a chemical called a matrix is added to the peptide mix. Common matrices are sinapinic acid, Alpha-Cyano-4-hydroxycinnamic acid, and 2,3-Dihydroxybenzoic acid. The matrix molecules are required for the desorption of the peptide molecules. Matrix and peptide molecules co-crystallize on the MALDI target and are ready to be analyzed. There is one predominantly MALDI-MS sample preparation technique, namely dried droplet technique. The target is inserted into the vacuum chamber of the mass spectrometer and the desorption and ionisation of the polypeptide fragments is initiated by a pulsed laser beam which transfers high amounts of energy into the matrix molecules. The energy transfer is sufficient to promote the ionisation and transition of matrix molecules and peptides from the solid phase into the gas phase. The ions are accelerated in the electric field of the mass spectrometer and fly towards an ion detector where their arrival is detected as an electric signal. Their mass-to-charge ratio is proportional to their time of flight (TOF) in the drift tube and can be calculated accordingly.

Coupling ESI with capillary LC can separate peptides from protein digests, while obtaining their molecular masses at the same time. Capillary electrophoresis coupled with ESI-MS is another technique; however, it works best when analyzing small amounts of proteins.