Profiling of methyltransferases and other S-adenosyl-L-homocysteine-binding Proteins by Capture Compound Mass Spectrometry (CCMS)

J Vis Exp. 2010 Dec 20:(46):2264. doi: 10.3791/2264.

Abstract

There is a variety of approaches to reduce the complexity of the proteome on the basis of functional small molecule-protein interactions such as affinity chromatography (1) or Activity Based Protein Profiling (2). Trifunctional Capture Compounds (CCs, Figure 1A) (3) are the basis for a generic approach, in which the initial equilibrium-driven interaction between a small molecule probe (the selectivity function, here S-adenosyl-(L)-homocysteine, SAH, Figure 1A) and target proteins is irreversibly fixed upon photo-crosslinking between an independent photo-activable reactivity function (here a phenylazide) of the CC and the surface of the target proteins. The sorting function (here biotin) serves to isolate the CC - protein conjugates from complex biological mixtures with the help of a solid phase (here streptavidin magnetic beads). Two configurations of the experiments are possible: "off-bead" (4) or the presently described "on-bead" configuration (Figure 1B). The selectivity function may be virtually any small molecule of interest (substrates, inhibitors, drug molecules). S-Adenosyl-(L)-methionine (SAM, Figure 1A) is probably, second to ATP, the most widely used cofactor in nature (5, 6). It is used as the major methyl group donor in all living organisms with the chemical reaction being catalyzed by SAM-dependent methyltransferases (MTases), which methylate DNA (7), RNA (8), proteins (9), or small molecules (10). Given the crucial role of methylation reactions in diverse physiological scenarios (gene regulation, epigenetics, metabolism), the profiling of MTases can be expected to become of similar importance in functional proteomics as the profiling of kinases. Analytical tools for their profiling, however, have not been available. We recently introduced a CC with SAH as selectivity group to fill this technological gap (Figure 1A). SAH, the product of SAM after methyl transfer, is a known general MTase product inhibitor (11). For this reason and because the natural cofactor SAM is used by further enzymes transferring other parts of the cofactor or initiating radical reactions as well as because of its chemical instability (12), SAH is an ideal selectivity function for a CC to target MTases. Here, we report the utility of the SAH-CC and CCMS by profiling MTases and other SAH-binding proteins from the strain DH5α of Escherichia coli (E. coli), one of the best-characterized prokaryotes, which has served as the preferred model organism in countless biochemical, biological, and biotechnological studies. Photo-activated crosslinking enhances yield and sensitivity of the experiment, and the specificity can be readily tested for in competition experiments using an excess of free SAH.

Publication types

  • Research Support, Non-U.S. Gov't
  • Video-Audio Media

MeSH terms

  • Escherichia coli / chemistry
  • Escherichia coli / enzymology
  • Escherichia coli / metabolism
  • Escherichia coli Proteins / analysis
  • Escherichia coli Proteins / metabolism
  • Mass Spectrometry / methods*
  • Methyltransferases / analysis*
  • Methyltransferases / metabolism
  • Photochemical Processes
  • Proteomics / methods
  • S-Adenosylhomocysteine / analysis*
  • S-Adenosylhomocysteine / metabolism

Substances

  • Escherichia coli Proteins
  • S-Adenosylhomocysteine
  • Methyltransferases