For proteins of < 20 kDa, this new radical site dissociation method cleaves different and many more backbone bonds than the conventional MS/MS methods (e.g., collisionally activated dissociation, CAD) that add energy directly to the even-electron ions. A minimum kinetic energy difference between the electron and ion maximizes capture; a 1 eV difference reduces capture by 10(3). Thus, in an FTMS ion cell with added electron trapping electrodes, capture appears to be achieved best at the boundary between the potential wells that trap the electrons and ions, now providing 80 +/- 15% precursor ion conversion efficiency. Capture cross section is dependent on the ionic charge squared (z2), minimizing the secondary dissociation of lower charge fragment ions. Electron capture is postulated to occur initially at a protonated site to release an energetic (approximately 6 eV) H. atom that is captured at a high-affinity site such as -S-S- or backbone amide to cause nonergodic (before energy randomization) dissociation. Cleavages between every pair of amino acids in mellitin (2.8 kDa) and ubiquitin (8.6 kDa) are represented in their ECD and CAD spectra, providing complete data for their de novo sequencing. Because posttranslational modifications such as carboxylation, glycosylation, and sulfation are less easily lost in ECD than in CAD, ECD assignments of their sequence positions are far more specific.
Disulfide bonds in gaseous multiply-protonated proteins are preferentially cleaved in the mass spectrometer by low-energy electrons, in sharp contrast to excitation of the ions by photons or low-energy collisions. For S−S cyclized proteins, capture of one electron can break both an S−S bond and a backbone bond in the same ring, or even both disulfide bonds holding two peptide chains together (e.g., insulin), enhancing the sequence information obtainable by tandem mass spectrometry on proteins in trace amounts. Electron capture at uncharged S−S is unlikely; cleavage appears to be due to the high S−S affinity for H• atoms, consistent with a similar favorability found for tryptophan residues. RRKM calculations indicate that H• capture dissociation of backbone bonds in multiply-charged proteins represents nonergodic behavior, as proposed for the original direct mechanism of electron capture dissociation.
Characterization of larger proteins by mass spectrometry (MS) is especially promising because the information complements that of classical techniques and can be obtained on as little as 10-17 mol of protein. Using MS to localize errors in the DNA-derived sequence or modifications (posttranslational, derivatized active sites, etc.) usually involves extensive proteolysis to yield peptides of <3 kDa, with separation and MS/MS to compare their sequences to those expected (the “bottom up” approach). In contrast, an alternative “top down” approach limits the dissociation (proteolysis or MS/MS) to yield larger products from which a small set of complementary peptides can be found whose masses sum to those of the molecule. Thus a disagreement with the predicted molecular mass can be localized to a fragment(s) without examining all others, with further dissociation of the fragments in the same way providing further localization. Using carbonic anhydrase (29 kDa) as an example, Fourier transform mass spectrometry is unusually effective for the bottom up approach, in that a single spectrum of an extensive chymotryptic digest identifies 64 expected peptides, but these only cover 95% of the sequence; 20 fragment masses are unassigned so that any set whose masses sum to that of the molecule would be misleading. Extensive Lys-C dissociation yields 17 peptides, 23 unassigned masses, and 96% coverage. In the contrasting “top down” approach, less extensive initial dissociation by Lys-C, MS/MS, or CNBr in each case provides 100% coverage, so that modified protein fragment(s) could easily be recognized among the complementary sets. MS/MS of such a fragment or more extensive proteolysis provide further localization of the modification. The combined methods cleaved 137 of the 258 amide bonds between residues.
Mass spectrometry (MS) has been revolutionized by electrospray ionization (ESI), which is sufficiently ''gentle'' to introduce nonvolatile biomolecules such as proteins and nucleic acids (RNA or DNA) into the gas phase without breaking covalent bonds. Although in some cases noncovalent bonding can be maintained sufficiently for ESI/MS characterization of the solution structure of large protein complexes and native enzyme/substrate binding, the new gaseous environment can ultimately cause dramatic structural alterations. The temporal (picoseconds to minutes) evolution of native protein structure during and after transfer into the gas phase, as proposed here based on a variety of studies, can involve side-chain collapse, unfolding, and refolding into new, non-native structures. Control of individual experimental factors allows optimization for specific research objectives.electrospray ionization ͉ gaseous proteins ͉ mass spectrometry ͉ protein conformations ͉ proteomics
The unfolding enthalpy of the native state of ubiquitin in solution is 5 to 8 times that of its gaseous ions, as determined by electron capture dissociation (ECD) mass spectrometry. Although two-state folding occurs in solution, the three-state gaseous process proposed for this by Clemmer and co-workers based on ion mobility data is supported in general by ECD mass spectra, including relative product yields, distinct Delta H(unfolding) values between states, site-specific melting temperatures, and folding kinetics indicating a cooperative process. ECD also confirms that the 13+ ions represent separate conformers, possibly with side-chain solvated alpha-helical structures. However, the ECD data on the noncovalent bonding in the 5+ to 13+ ions, determined overall in 69 of the 75 interresidue sites, shows that thermal unfolding proceeds via a diversity of intermediates whose conformational characteristics also depend on charge site locations. As occurs with increased acidity in solution, adding 6 protons to the 5+ ions completely destroys their tertiary noncovalent bonding. However, solvation of the newly protonated sites to the backbone instead increases the stability of the secondary structure (possibly an alpha-helix) of these gaseous ions, while in solution these new sites aid denaturation by solvation in the aqueous medium. Extensive ion equilibration can lead to even more compact and diverse conformers. The three-state unfolding of gaseous ubiquitin appears to involve ensembles of individual chain conformations in a "folding funnel" of parallel reaction paths. This also provides a further caution for characterizing solution conformers from their gas-phase behavior.
In previous studies, electron capture dissociation (ECD) has been successful only with ionized smaller proteins, cleaving between 33 of the 153 amino acid pairs of a 17 kDa protein. This has been increased to 99 cleavages by colliding the ions with a background gas while subjecting them to electron capture. Presumably this ion activation breaks intramolecular noncovalent bonds of the ion's secondary and tertiary structure that otherwise prevent separation of the products from the nonergodic ECD cleavage of a backbone covalent bond. In comparison to collisionally activated dissociation, this "activated ion" (AI) ECD provides more extensive, and complementary, sequence information. AI ECD effected cleavage of 116, 60, and 47, respectively, backbone bonds in 29, 30, and 42 kDa proteins to provide extensive contiguous sequence information on both termini; AI conditions are being sought to denature the center portion of these large ions. This accurate "sequence tag" information could potentially identify individual proteins in mixtures at far lower sample levels than methods requiring prior proteolysis.
Here a fully automated computer algorithm is applied to complex mass spectra of peptides and proteins. This method uses a subtractive peak finding routine to locate possible isotopic clusters in the spectrum, subjecting these to a combination of the previous Fourier transform/Patterson method for primary charge determination and the method for least-squares fitting to a theoretically derived isotopic abundance distribution for m/z determination of the most abundant isotopic peak, and the statistical reliability of this determination. If a predicted protein sequence is available, each such m/z value is checked for assignment as a sequence fragment. A new signal-to-noise calculation procedure has been devised for accurate determination of baseline and noise width for spectra with high peak density. In 2 h, the program identified 824 isotopic clusters representing 581 mass values in the spectrum of a GluC digest of a 191 kDa protein; this is >50% more than the number of mass values found by the extremely tedious operator-applied methodology used previously. The program should be generally applicable to classes of large molecules, including DNA and polymers. Thorough high resolution analysis of spectra by Horn (THRASH) is proposed as the program's verb.
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