Protein analysis by electrospray ionization mass spectrometry

The applicability of electrospray ionization (ESI) mass spectrometry to protein analyses has been studied. The molecular weight of hen egg lysozyme (HEL) was determined with an accuracy of +/- 2 u. The choice of solvents and additives in sample preparations was important to achieve high sensitivity as well as high precision of molecular weight measurements.     

Folding and assembly of large macromolecular complexes monitored by hydrogen-deuterium exchange and mass spectrometry

Recent advances in protein mass spectrometry (MS) have enabled determinations of hydrogen deuterium exchange (HDX) in large macromolecular complexes. HDX-MS became a valuable tool to follow protein folding, assembly and aggregation. The methodology has a wide range of applications in biotechnology ranging from quality control for over-expressed proteins and their complexes to screening of potential ligands and inhibitors. This review provides an introduction to protein folding and assembly followed by the principles of HDX and MS detection, and concludes with selected examples of applications that might be of interest to the biotechnology community.     

Unraveling lactococcal phage baseplate assembly by mass spectrometry

Bacteriophages belonging to the Caudovirales order possess a tail acting as a molecular machine used during infection to recognize the host and ensure high-efficiency genome delivery to the cell cytoplasm. They bear a large and sophisticated multiprotein organelle at their distal tail end, either a baseplate or a tail-tip, which is the control center for infectivity. We report here insights into the baseplate assembly pathways of two lactoccocal phages (p2 and TP901-1) using electrospray ionization-mass spectrometry. Based on our "block cloning" strategy we have expressed large complexes of their baseplates as well as several significant structural subcomplexes. Previous biophysical characterization using size-exclusion chromatography coupled with on-line light scattering and refractometry demonstrated that the overproduced recombinant proteins interact with each other to form large (up to 1.9 MDa) and stable assemblies. The structures of several of these complexes have been determined by x-ray diffraction or by electron microscopy. In this contribution, we demonstrate that electrospray ionization-mass spectrometry yields accurate mass measurements for the different baseplate complexes studied from which their stoichiometries can be discerned, and that the subspecies observed in the spectra provide valuable information on the assembly mechanisms of these large organelles.     

Protein surface mapping by chemical oxidation: structural analysis by mass spectrometry

The solvent-accessible surface area of proteins is important in biological function for many reasons, including protein-protein interactions, protein folding, and catalytic sites. Here we present a chemical technique to oxidize amino acid side chains in a model protein, apomyoglobin, and subsequent elucidation of the effect of solvent accessibility on the sites of oxidation. Under conditions of low protein oxidation (zero to three oxygen atoms added per apomyoglobin molecule), we have positively identified five oxidation sites by liquid chromatography-tandem mass spectrometry and high-resolution Fourier transform mass spectrometry. Our results indicate that all oxidized amino acids, with the exception of methionine, have highly solvent-accessible side chains, but the rate of oxidation may not be dictated solely by solvent accessibility and amino acid identity.     

Direct analysis of protein complexes using mass spectrometry.

We describe a rapid, sensitive process for comprehensively identifying proteins in macromolecular complexes that uses multidimensional liquid chromatography (LC) and tandem mass spectrometry (MS/MS) to separate and fragment peptides. The SEQUEST algorithm, relying upon translated genomic sequences, infers amino acid sequences from the fragment ions. The method was applied to the Saccharomyces cerevisiae ribosome leading to the identification of a novel protein component of the yeast and human 40S subunit. By offering the ability to identify >100 proteins in a single run, this process enables components in even the largest macromolecular complexes to be analyzed comprehensively.     

Protein structure dynamics by crosslinking mass spectrometry

Crosslinking mass spectrometry captures protein structures in solution. The crosslinks reveal spatial proximities as distance restraints, but do not easily reveal which of these restraints derive from the same protein conformation. This superposition can be reduced by photo-crosslinking, and adding information from protein structure models, or quantitative crosslinking reveals conformation-specific crosslinks. As a consequence, crosslinking MS has proven useful already in the context of multiple dynamic protein systems. We foresee a breakthrough in the resolution and scale of studying protein dynamics when crosslinks are used to guide deep-learning-based protein modelling. Advances in crosslinking MS, such as photoactivatable crosslinking and in-situ crosslinking, will then reveal protein conformation dynamics in the cellular context, at a pseudo-atomic resolution, and plausibly in a time-resolved manner.     

Structural analysis of multiprotein complexes by cross-linking, mass spectrometry, and database searching

Most protein complexes are inaccessible to high resolution structural analysis. We report the results of a combined approach of cross-linking, mass spectrometry, and bioinformatics to two human complexes containing large coiled-coil segments, the NDEL1 homodimer and the NDC80 heterotetramer. An important limitation of the cross-linking approach, so far, was the identification of cross-linked peptides from fragmentation spectra. Our novel approach overcomes the data analysis bottleneck of cross-linking and mass spectrometry. We constructed a purpose-built database to match spectra with cross-linked peptides, define a score that expresses the quality of our identification, and estimate false positive rates. We show that our analysis sheds light on critical structural parameters such as the directionality of the homodimeric coiled coil of NDEL1, the register of the heterodimeric coiled coils of the NDC80 complex, and the organization of a tetramerization region in the NDC80 complex. Our approach is especially useful to address complexes that are difficult in addressing by standard structural methods.     

Protein complexes in the archaeon Methanothermobacter thermautotrophicus analyzed by blue native/SDS-PAGE and mass spectrometry

Methanothermobacter thermautotrophicus is a thermophilic archaeon that produces methane as the end product of its primary metabolism. The biochemistry of methane formation has been extensively studied and is catalyzed by individual enzymes and proteins that are organized in protein complexes. Although much is known of the protein complexes involved in methanogenesis, only limited information is available on the associations of proteins involved in other cell processes of M. thermautotrophicus. To visualize and identify interacting and individual proteins of M. thermautotrophicus on a proteome-wide scale, protein preparations were separated using blue native electrophoresis followed by SDS-PAGE. A total of 361 proteins, corresponding to almost 20% of the predicted proteome, was identified using peptide mass fingerprinting after MALDI-TOF MS. All previously characterized complexes involved in energy generation could be visualized. Furthermore the expression and association of the heterodisulfide reductase and methylviologen-reducing hydrogenase complexes depended on culture conditions. Also homomeric supercomplexes of the ATP synthase stalk subcomplex and the N5-methyl-5,6,7,8-tetrahydromethanopterin:coenzyme M methyltransferase complex were separated. Chemical cross-linking experiments confirmed that the multimerization of both complexes was not experimentally induced. A considerable number of previously uncharacterized protein complexes were reproducibly visualized. These included an exosome-like complex consisting of four exosome core subunits, which associated with a tRNA-intron endonuclease, thereby expanding the constituency of archaeal exosomes. The results presented show the presence of novel complexes and demonstrate the added value of including blue native gel electrophoresis followed by SDS-PAGE in discovering protein complexes that are involved in catabolic, anabolic, and general cell processes.     

Mapping multiprotein complexes by affinity purification and mass spectrometry

The combination of affinity purification and tandem mass spectrometry (MS) has emerged as a powerful approach to delineate biological processes. In particular, the use of epitope tags has allowed this approach to become scaleable and has bypassed difficulties associated with generation of antibodies. Single epitope tags and tandem affinity purification (TAP) tags have been used to systematically map protein complexes generating protein interaction data at a near proteome-wide scale. Recent developments in the design of tags, optimisation of purification conditions, experimental design and data analysis have greatly improved the sensitivity and specificity of this approach. Concomitant developments in MS, including high accuracy and high-throughput instrumentation together with quantitative MS methods, have facilitated large-scale and comprehensive analysis of multiprotein complexes.     

In-gel derivatization of proteins for cysteine-specific cleavages and their analysis by mass spectrometry

As a potential tool for proteomics and protein characterization, in-gel cysteine- and arginine-specific cleavage is demonstrated by means of trypsin or endoproteinase Lys-C for six model proteins (lysozyme, alpha-lactalbumin, beta-lactoglobulin, ribonuclease A, albumin, and transferrin), ranging in size from 14 kDa to 79 kDa. Chemical modifications of cysteine (aminoethylation with bromoethylamine or N-(iodoethyl)-trifluoroacetamide, and subsequent guanidination) and lysine (acetylation) prior to tryptic digestion releases peptides delineated by cysteine or arginine residues. Peptide products are analyzed by MALDI-TOF-MS, ESI-MS, and ESI- and MALDI-MS/MS (with a quadrupole time-of-flight instrument). Complications induced by acrylamide alkylations of cysteines were avoided by substituting lower pH bis-tris polyacrylamide gels for tris-glycine. Sequence coverages from 35 to 86% were obtained and amino acid compositions of generated peptides could be confirmed by comprehensive y- and b-ion series. Detailed information about, in particular, cysteine rich proteins after gel electrophoresis were obtained. The chemistries for modification and cleavage specificities at cysteine residues provide an alternative means to characterize and identify proteins separated by gel electrophoresis.     

Solid-supported enzymatic synthesis of pectic oligogalacturonides and their analysis by MALDI-TOF mass spectrometry

Solid-phase biosynthetic reactions, followed by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry analysis (MALDI-TOF), was used to gain insight into the biosynthesis of pectin oligomers. Sepharose supports bearing long pectic oligogalacturonides (OGAs) anchored through a disulfide-containing cleavable linker, were prepared. The OGAs (degrees of polymerization of 13 and 14) were efficiently immobilized through the reducing end via formation of an oxime linkage. These OGA-derivatized matrices were subsequently employed in novel solid-phase enzymatic reactions, with the pectin biosynthetic enzyme, alpha-1,4-galacturonosyltransferase, GalAT (solubilized from Arabidopsis thaliana) and the glycosyl donor, uridine diphosphate-galacturonic acid (UDP-GalA). Solid-supported biosynthesis was followed by cleavage of the immobilized OGAs and direct analysis of the products released into the liquid phases by MALDI-TOF mass spectrometry. In time course studies conducted with an immobilized (alpha-D-GalA)14 and limiting amounts of the glycosyl donor, the predominant product was an OGA extended by one GalA residue at the non-reducing end (i.e., (GalA)15). When UDP-GalA was added in approximately excess compared to immobilized (GalA)13, OGAs up to the 16-mer were synthesized, confirming the non-processivity of the GalAT in vitro.     

Protein N-terminal analysis using fast atom bombardment mass spectrometry

An immunoassay is described that discriminates between monomers and oligomers of human leukocyte interferon. The assay in principle can be used to distinguish between monomers and oligomers of any substance.     

Isolation and characterization of plant protein complexes by mass spectrometry

The components that enable cells and organisms to fulfill a plethora of chemical and physical reactions, including their ability to metabolize, replicate, repair and communicate with their environment are mostly based on the functioning of highly complex cellular machines which are to a large extent composed of proteins. With the development of MS techniques compatible with the analysis of minute amounts of biological material, it has become more and more feasible to dissect the composition and modification of these protein machineries. Indeed, new purification methods of protein complexes followed by MS analysis together with the genomic sequencing of various organisms - and in particular of crop species - now provide unforeseen insight to understand biological processes at a molecular level. We here review the current state of the art of in vivo protein complex isolation and their MS-based analytical characterization, emphasizing on the tandem affinity purification approach.     

Protein-nucleic acid complexes and the role of mass spectrometry in their structure determination

Mass spectrometry is now established as a powerful tool for the study of the stoichiometry, interactions, dynamics, and subunit architecture of large protein assemblies and their subcomplexes. Recent evidence has suggested that the 3D structure of protein complexes can be maintained intact in the gas phase, highlighting the potential of ion mobility to contribute to structural biology. A key challenge is to integrate the compositional and structural information from ion mobility mass spectrometry with molecular modelling approaches to produce 3D models of intact protein complexes. In this review, we focus on the mass spectrometry of protein-nucleic acid assemblies with particular attention to the application of ion mobility, an emerging technique in structural studies. We also discuss the challenges that lie ahead for the full integration of ion mobility mass spectrometry with structural biology.     

Protein-nucleic acid complexes and the role of mass spectrometry in their structure determination

Mass spectrometry is now established as a powerful tool for the study of the stoichiometry, interactions, dynamics, and subunit architecture of large protein assemblies and their subcomplexes. Recent evidence has suggested that the 3D structure of protein complexes can be maintained intact in the gas phase, highlighting the potential of ion mobility to contribute to structural biology. A key challenge is to integrate the compositional and structural information from ion mobility mass spectrometry with molecular modelling approaches to produce 3D models of intact protein complexes. In this review, we focus on the mass spectrometry of protein-nucleic acid assemblies with particular attention to the application of ion mobility, an emerging technique in structural studies. We also discuss the challenges that lie ahead for the full integration of ion mobility mass spectrometry with structural biology.     

Protein folding and interactions revealed by mass spectrometry.

Mass spectrometry is capable of examining very large, dynamic proteins and this ability, coupled with its relatively high throughput and low sample requirements, is reflected by its increasing importance for the characterisation of protein structure. Recent developments in mass spectrometry, in particular the refinement of the electrospray process and its coupling with time-of-flight mass analysis, mean that it is poised to contribute not only as a complementary tool but also with a defined role in many areas of chemical biology.     

Protein and carbohydrate structural analysis of a recombinant soluble CD4 receptor by mass spectrometry

The primary structure of a soluble form of the CD4 receptor (sCD4) expressed in Chinese hamster ovary cells has been confirmed by mass spectrometric peptide mapping and and tandem mass spectrometry. These studies corroborated 95% of the 369-amino acid-long sequence and established the fidelity of translation of the NH2 and COOH terminal including the absence of "ragged ends." The arrangement of the three disulfide bonds in recombinant sCD4 was also established by mass spectrometry and comparative high performance liquid chromatography mapping and shown to be identical to that expected from previous studies of intrachain disulfide bonding in T4 antigens derived from sheep and mouse. No other arrangements of disulfides were detected. Carbohydrate mapping by mass spectrometry was used to establish that both potential Asn-linked glycosylation sites in sCD4 (Asn271 and Asn300) have oligosaccharides attached. Structural characterization by mass spectrometry and methylation analysis of the heterogeneous family of oligosaccharides at each of the specific attachment sites indicates that the major components of both families of oligosaccharides have the following biantennary structures: (Formula, see text) where m + n = 0-2, and x = 0,1. Minor carbohydrate components having three N-acetylneuraminic acid (NeuAc) groups and an additional hexose-hexosamine unit were detected by high performance anion-exchange chromatography.     

Negative and positive ion chemical ionization mass spectrometry of dioximes and their nickel complexes

The negative ion mass spectra of Ni(LH)₂ (where LH₂ is glyoxime, methylglyoxime, dimethylglyoxime and diphenylglyoxime), in the presence of ammonia or methane at 0.5 torr, are reported and compared with the spectra of the free ligands. In each case, the base peak of the complex is the molecular negative ion and the extent of fragmentation was found to decrease gradually going from the glyoximato to the diphenylglyoximato derivative. In the chemical ionization mass spectra of the free ligands, the [M]⁻ ion is absent in all cases. The base peak is [M  H]⁻ for methylglyoximine, dimethylglyoxime and diphenylglyoxime and [M  H  H₂]⁻ for glyoxime. The fragmentation occurs largely by loss of H, OH, H₂O and NO species. The positive ion chemical ionization mass spectra of the same complexes show very abundant [M + H]⁺ and [M]⁺ ions and weak fragments, whilst a rather high fragmentation is observed for the corresponding free ligands.