Fred W. McLafferty

Tandem mass spectrometry

Coupling mass spectrometers in series provides a new technique that has many advantages for the analysis of specific organic compounds in complex mixtures. Sensitivity to picograms of targeted compounds can be achieved with high specificity and nearly instantaneous response. The targeted compound is selectively ionized, and its characteristic ions are separated from most others of the mixture in the first mass spectrometer. The selected primary ions are then decomposed by collision, and from the resulting products the final mass analyzer selects secondary ions characteristic of the targeted compound. Tandem mass spectrometry can achieve specificities and sensitivities equivalent of those of methods such as radioimmunoassay and gas chromatography/mass spectrometry, while performing analyses in much shorter times.

Automated reduction and interpretation of high resolution electrospray mass spectra of large molecules

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 \s>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.

Attomole protein characterization by capillary electrophoresis-mass spectrometry

Electrospray ionization with an ultralow flow rate (≤4 nanoliters per minute) was used to directly couple capillary electrophoresis with tandem mass spectrometry for the analysis and identification of biomolecules in mixtures. A Fourier transform mass spectrometer provided full spectra (>30 kilodaltons) at a resolving power of ≈60,000 for injections of 0.7 × 10−18 to 3 × 10−18 mole of 8- to 29-kilodalton proteins with errors of <1 dalton in molecular mass. Using a crude isolate from human blood, a value of 28,780.6 daltons (calculated, 28,780.4 daltons) was measured for carbonic anhydrase, representing 1 percent by weight of the protein in a single red blood cell. Dissociation of molecular ions from 9 × 10−18 mole of carbonic anhydrase gave nine sequence-specific fragment ions, more data than required for unique retrieval of this enzyme from the protein database.

Stepwise evolution of protein native structure with electrospray into the gas phase, 10(-12) to 10(2) s.

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.

Top-down mass spectrometry of a 29-kDa protein for characterization of any posttranslational modification to within one residue

A mass difference between the measured molecular weight of a protein and that of its DNA-predicted sequence indicates sequence errors and/or posttranslational modifications. In the top-down mass spectrometry approach, the measured molecular ion is dissociated, and these fragment masses are matched against those predicted from the protein sequence to restrict the locations of the errors/modifications. The proportion of the ions interresidue bonds that are cleaved determines the specificity of such locations; previously, ubiquitin (76 residues) was the largest for which all such bonds were dissociated. Now, cleavages are achieved for carbonic anhydrase at 250 of the 258 interresidue locations. Cleavages of three spectra would define posttranslational modifications at 235 residues to within one residue. For 24 of the 34 possible phosphorylation sites, the cleavages of one spectrum would delineate exactly all −PO3H substitutions. This result has been achieved with electron-capture dissociation by minimizing the further cleavage of primary product ions and by denaturing the tertiary noncovalent bonding of the molecular ions under a variety of conditions.

Thiamin biosynthesis in prokaryotes

Abstract Twelve genes involved in thiamin biosynthesis in prokaryotes have been identified and overexpressed. Of these, six are required for the thiazole biosynthesis (thiFSGH, thiI, and dxs), one is involved in the pyrimidine biosynthesis (thiC), one is required for the linking of the thiazole and the pyrimidine (thiE), and four are kinase genes (thiD, thiM, thiL, and pdxK). The specific reactions catalyzed by ThiEF, Dxs, ThiDM, ThiL, and PdxK have been reconstituted in vitro and ThiS thiocarboxylate has been identified as the sulfur source. The X-ray structures of thiamin phosphate synthase and 5-hydroxyethyl-4-methylthiazole kinase have been completed. The genes coding for the thiamin transport system (thiBPQ) have also been identified. Remaining problems include the cloning and characterization of thiK (thiamin kinase) and the gene(s) involved in the regulation of thiamin biosynthesis. The specific reactions catalyzed by ThiC (pyrimidine formation), and ThiGH and ThiI (thiazole formation) have not yet been identified.

Electron capture dissociation of gaseous multiply charged ions by fourier-transform ion cyclotron resonance

Fourier-transform ion cyclotron resonance instrumentation is uniquely applicable to an unusual new ion chemistry, electron capture dissociation (ECD). This causes nonergodic dissociation of far larger molecules (42 kDa) than previously observed (<1 kDa), with the resulting unimolecular ion chemistry also unique because it involves radical site reactions for similarly larger ions. ECD is highly complementary to the well known energetic methods for multiply charged ion dissociation, providing much more extensive protein sequence information, including the direct identification of N- versus C-terminal fragment ions. Because ECD only excites the molecule near the cleavage site, accompanying rearrangements are minimized. Counterintuitively, cleavage of backbone covalent bonds of protein ions is favored over that of noncovalent bonds; larger (>10 kDa) ions give far more extensive ECD if they are first thermally activated. This high specificity for covalent bond cleavage also makes ECD promising for studying the secondary and tertiary structure of gaseous protein ions caused by noncovalent bonding.

Secondary and tertiary structures of gaseous protein ions characterized by electron capture dissociation mass spectrometry and photofragment spectroscopy

Over the last decade a variety of MS measurements, such as H/D exchange, collision cross sections, and electron capture dissociation (ECD), have been used to characterize protein folding in the gas phase, in the absence of solvent. To the extensive data already available on ubiquitin, here photofragmentation of its ECD-reduced (M + nH)(n−1)+• ions shows that only the 6+ to 9+, not the 10+ to 13+ ions, have tertiary noncovalent bonding; this is indicated as hydrogen bonding by the 3,050–3,775 cm−1 photofragment spectrum. ECD spectra and H/D exchange of the 13+ ions are consistent with an all α-helical secondary structure, with the 11+ and 10+ ions sufficiently destabilized to denature small bend regions near the helix termini. In the 8+ and 9+ ions these terminal helical regions are folded over to be antiparallel and noncovalently bonded to part of the central helix, whereas this overlap is extended in the 7+, 6+, and, presumably, 5+ ions to form a highly stable three-helix bundle. Thermal denaturing of the 7+ to 9+ conformers both peels and slides back the outer helices from the central one, but for the 6+ conformer, this instead extends the protein ends away to shrink the three-helix bundle. Thus removal of H2O from a native protein negates hydrophobic interactions, preferentially stabilizes the α-helical secondary structure with direct solvation of additional protons, and increases tertiary interhelix dipole-dipole and hydrogen bonding.

Fourier-transform electrospray instrumentation for tandem high-resolution mass spectrometry of large molecules

Department of Chemistry, Baker Laboratory, Cornell University, Ithaca, New York, USA Mass spectrometry instrumentation providing unit resolution and lo-ppm mass accuracy for molecules larger than 10 kDa was first reported in 1991. This instrumentation has now been improved with a 6.2-T magnet replacing that of 2.8 T, a more efficient vacuum system, ion injection with controlled ion kinetic energies, accumulated ion trapping with an open-cylindrical ion cell, acquisition of 2M data points, and updated electrospray apparatus. The resulting capabilities include resolving power of 5 × 105 for a 29-kDa protein, less than l-ppm mass measuring error, and dissociation of protein molecular ions to produce dozens of fragment ions whose exact masses can be identified from their mass-to-charge ratio values and isotopic peak spacing.

Top-down MS, a powerful complement to the high capabilities of proteolysis proteomics.

For the characterization of protein sequences and post‐translational modifications by MS, the ‘top‐down’ proteomics approach utilizes molecular and fragment ion mass data obtained by ionizing and dissociating a protein in the mass spectrometer. This requires more complex instrumentation and methodology than the far more widely used ‘bottom‐up’ approach, which instead uses such data of peptides from the proteins digestion, but the top‐down data are far more specific. The ESI MS spectrum of a 14 protein mixture provides full separation of its molecular ions for MS/MS dissociation of the individual components. False‐positive rates for the identification of proteins are far lower with the top‐down approach, and quantitation of multiply modified isomers is more efficient. Bottom‐up proteolysis destroys the information on the size of the protein and the connectivities of the peptide fragments, but it has no size limit for protein digestion. In contrast, the top‐down approach has a ∼ 500 residue, ∼ 50 kDa limitation for the extensive molecular ion dissociation required. Basic studies indicate that this molecular ion intractability arises from greatly strengthened electrostatic interactions, such as hydrogen bonding, in the gas‐phase molecular ions. This limit is now greatly extended by variable thermal and collisional activation just after electrospray (‘prefolding dissociation’). This process can cleave 287 inter‐residue bonds in the termini of a 1314 residue (144 kDa) protein, specify previously unidentified disulfide bonds between eight of 27 cysteines in a 1714 residue (200 kDa) protein, and correct sequence predictions in two proteins, one of 2153 residues (229 kDa).