Sequencing branched peptides with CID/PSD MALDI-TOF in the low-picomole range: application to the structural study of the posttranslational polyglycylation of tubulin

Sequencing conditions for postsource decay and collision-induced dissociation/postsource decay matrix-assisted laser desorption/ionization time-of-flight mass spectrometry have been optimized to elucidate the structure of polyglycylation of tubulin. This posttranslational modification involves the linkage of multiple glycine residues through the gamma-carboxyl of glutamic acid residues in the carboxyl termini of the protein. Individual alpha- and beta-tubulin polypeptides contain respectively three and four potential glycylation sites. The sample preparation we used was the thin-layer preparation of the target specimen in the presence of alpha-cyano-4-hydroxycinnamic acid and nitrocellulose. The study of different synthetic polyglycylated peptides fragmentation (modified peptides with the linear sequence DATAEEEGEFEEEGEQ) shows that the peptides fragment regularly to form major fragments of b- and y-type ions with negligible side-chain fragmentation. The rules were applied to the structural elucidation of a Paramecium beta-tubulin hexaglycylated peptide available in the subpicomole range. Polyglycylation was identified on the last four glutamic acid residues.     

Rapid identification of comigrating gel-isolated proteins by ion trap-mass spectrometry

In the search for novel nuclear binding proteins, two bands from a sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gel were analyzed and each was found to contain a number of proteins that subsequently were identified by tandem mass spectrometry (MS/MS) on a quadrupole ion trap instrument. The bands were digested with trypsin in situ on a polyvinylidene difluoride (PVDF) membrane following electroblot transfer. Analysis of a 2.5% aliquot of each peptide mixture by matrix assisted laser desorption/ionization-mass spectrometry (MALDI-MS) followed by an initial database search with the peptide masses failed to identify the proteins. The peptides were separated by reversed-phase capillary high performance liquid chromatography (HPLC) in anticipation of subsequent Edman degradation, but mass analysis of the chromatographic fractions by MALDI-MS revealed multiple, coeluting peptides that precluded this approach. Selected fractions were analyzed by capillary HPLC-electrospray ionization-ion trap mass spectrometry. Tandem mass spectrometry provided significant fragmentation from which full or partial sequence was deduced for a number of peptides. Two stages of fragmentation (MS3) were used in one case to determine additional sequence. Database searches, each using a single peptide mass plus partial sequence, identified four proteins from a single electrophoretic band at 45 kDa, and four proteins from a second band at 60 kDa. Many of these proteins were derived from human keratin. The protein identifications were corroborated by the presence of multiple matching peptide masses in the MALDI-MS spectra. In addition, a novel sequence, not found in protein or DNA databases, was determined by interpretation of the MS/MS data. These results demonstrate the power of the quadrupole ion trap for the identification of multiple proteins in a mixture, and for de novo determination of peptide sequence. Reanalysis of the fragmentation data with a modified database searching algorithm showed that the same sets of proteins were identified from a limited number of fragment ion masses, in the absence of mass spectral interpretation or amino acid sequence. The implications for protein identification solely from fragment ion masses are discussed, including advantages for low signal levels, for a reduction of the necessary interpretation expertise, and for increased speed.     

Aspects of oligonucleotide and peptide sequencing with MALDI and electrospray mass spectrometry

Biopolymer sequencing with mass spectrometry has become increasingly important and accessible with the development of matrix-assisted laser desorption/ionization (MALDI) and electrospray ionization (ESI). Here we examine the use of sequential digestion for the rapid identification of proteolytic fragments, in turn highlighting the general utility of enzymatic MALDI ladder sequencing and ESI tandem mass spectrometry. Analyses were performed on oligonucleotides ranging in size from 2 to 50 residues, on peptides ranging in size from 7 to 44 residues and on viral coat proteins. MALDI ladder sequencing using exonuclease digestion generated a uniform distribution of ions and provided complete sequence information on the oligonucleotides 2-30 nucleic acid residues long. Only partial sequence information was obtained on the longer oligonucleotides. C-terminal peptide ladder sequencing typically provided information from 4 to 7 amino acids into the peptide. Sequential digestion, or endoprotease followed by exoprotease exposure, was also successfully applied to a trypsin digest of viral proteins. Analysis of ladder sequenced peptides by LCMS generated less information than in the MALDI-MS analysis and ESI-MS2 normally provided partial sequence information on both the small oligonucleotides and peptides. In general, MALDI ladder sequencing offered information on a broader mass range of biopolymers than ESI-MS2 and was relatively straightforward to interpret, especially for oligonucleotides.     

Direct sequencing of neuropeptides in biological tissue by MALDI-PSD mass spectrometry

Dissected tissue pieces of the pituitary pars intermedia from the amphibian Xenopus laevis was directly subjected to matrix-assisted laser desorption/ionization (MALDI) mass analysis. The obtained MALDI peptide profile revealed both previously known and unexpected processing products of the proopiomelanocortin gene. Mass spectrometric peptide sequencing of a few of these neuropeptides was performed by employing MALDI combined with postsource decay (PSD) fragment ion mass analysis. The potential of MALDI-PSD for sequence analysis of peptides directly from unfractionated tissue samples was examined for the first time for the known desacetyl-alpha-MSH-NH2 and the presumed vasotocin neuropeptide. In addition, the sequence of an unknown peptide which was present in the pars intermedia tissue sample at mass 1392.7 u was determined. The MALDI-PSD mass spectrum of precursor ion 1392.7 u contained sufficient structural information to uniquely identify the sequence by searching protein sequence databases. The determined amino acid sequence corresponds to the vasotocin peptide with a C-terminal extension of Gly-Lys-Arg ("vasotocinyl-GKR"), indicating incomplete processing of the vasotocin precursor protein in the pituitary pars intermediate of X. laevis. Both vasotocin and vasotocinyl-GKR are nonlinear peptides containing a disulfide (S-S) bridge between two cysteine residues. Interpretation of the spectra of these two peptides reveals three different forms of characteristic fragment ions of the cysteine side chain: peptide-CH2-SH (regular mass of Cys-containing fragment ions), peptide-CH2-S-SH (regular mass + 32 u) and peptide = CH2 (regular mass -34 u) due to cleavage on either side of the sulfur atoms.     

Accurate peptide sequencing by post-source decay matrix-assisted laser desorption/ionization time-of-flight mass spectrometry

Partial 18O-labeling of peptides has been applied to post-source decay experiments in a matrix-assisted laser desorption/ionization time-of-flight mass spectrometer. The ions which originate from the carboxyl terminus of a peptide partially retain 18O atoms which have readily been incorporated into the C-terminal carboxyl groups during enzymatic hydrolysis in a buffer containing 40 atom percent H218O. The isotopic resolution of singly charged precursor ions and their product ions obtained for peptides up to ca. 2800 Da has been achieved using the delayed extraction method, which permits the rapid identification and assignment of the 18O-labeled and non-labeled ion species in the PSD spectra. The results obtained from several 18O-labeled peptides, derived from an enzymatic digest, demonstrate the accuracy and reproducibility of the present method, which will be in widespread use for protein identification via database searching or for investigations of totally unknown proteins.     

Investigations of the metastable decay of DNA under ultraviolet matrix-assisted laser desorption/ionization conditions with post-source-decay analysis and hydrogen/deuterium exchange

The fragmentation of positive ions of DNA under the conditions of matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) was investigated by post-source decay (PSD) analysis and hydrogen/deuterium (H/D) exchange. Spectra of five different synthetic 4mer oligonucleotides were recorded. As a main result the hypothesis was confirmed that for these ions all fragment ions result from processes, initiated by protonation/deuteration of a suitable base followed by a loss of this base as a neutral or ion and further backbone cleavages. The three bases adenine, guanine, and cytosine all exhibit comparable lability for fragmentation. The spectra show evidence for an interaction of the adenine base with the phosphate backbone. Signals of fragments containing TT- and CT-cycloadducts were observed in the spectra.     

Improving mass spectrometric sequencing of arginine-containing peptides by derivatization with acetylacetone

Modification of arginine residues in bradykinin, [1-5]-bradykinin, splenopentin and two synthetic pentapeptides with acetylacetone (pentane-2,4-dione) significantly increases the relative abundance of sequence-specific fragment ions produced by matrix-assisted laser desorption/ionization (MALDI). The fragmentation efficiency as measured by post-source decay in a reflectron time-of-flight mass spectrometer increases by a factor of 2-3.5. Peptide bonds adjacent to modified residues are more susceptible to cleavage than in the non-derivatized peptide ions. The increased lability of these bonds gives rise to more complete sequence information. In addition, the relative abundances of sequence-specific fragment ions are enhanced. This strategy makes it possible to obtain valuable structural information from arginine-containing peptides that otherwise do not fragment well.     

Separation and identification of peptides in single neurons by microcolumn liquid chromatography-matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and postsource decay analysis

Microcolumn liquid chromatography (LC) was interfaced with matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) for separation and identification of peptides present in single neurons from the brain of the snail Lymnaea stagnalis. The nanoliter microcolumn LC effluent, mixed off-line with nanoliter matrix solution, was deposited onto the sample target every 60 s, producing fractions of approximately 145 nL in volume, which, upon drying, produced spots of approximately 1 mm in size. At the end of the chromatographic separation, fractions from the sample target were scanned by MALDI-TOF-MS. Identification of peptide peaks was achieved on the basis of LC elution order and mass information. Further identification based on sequence information was carried out for a native peptide fractionated by microcolumn LC from a single neuron with the postsource decay technique.     

Differentiation of lysine/glutamine in peptide sequence analysis by electrospray ionization sequential mass spectrometry coupled with a quadrupole ion trap

Electrospray ionization coupled to a quadrupole ion trap mass spectrometer is used to differentiate between the isobaric amino acids lysine and glutamine in sequence analysis of peptides. Collision-induced dissociation is used for fragmentation. Several isobaric peptides with one or more lysines or glutamines at different positions were investigated. The ambiguous amino acid either in the peptide chain or at the C- or N-terminus can be clearly identified based on specific side chain fragment ions resulting from MS3 or MS4 of B- and Y"-fragment ions.     

Negative ion postsource decay time-of-flight mass spectrometry of peptides containing acidic amino acid residues

Acidic peptides have been studied by negative ion postsource decay (PSD) matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry. The peptides contained from 5 to 16 residues and were chosen on the basis of their patterns of the acidic residues. Using typical MALDI sample preparation techniques employing an acidic matrix, gastrin I (1-14), and epidermal mitosis inhibiting pentapeptide yielded much larger deprotonated ion signals, [M - H]-, than protonated ions, [M + H]+. This may be due to their absence of basic residues, coupled with their arrays of acidic residues. The PSD fragmentation of the peptide negative ions showed that an array of acidic residues, as in gastrin I (1-14), yielded simple spectra containing mainly backbone cleavage ions from the C-terminus. Hirudin (54-65), which contains two sets of two consecutive Glu residues, and fibrinopeptide A and fibrinopeptide B, with isolated acidic residues, also showed backbone cleavages as common fragment ions. In addition, the two sets of isolated consecutive amino acid residues in Cys(Bzl)84-CD4 (81-92) and hirudin (54-56) yielded internal ions from the cleavages at the (O=C)-NH bond between the acidic residues. Also observed were ions with unique side chain losses, such as the loss of C6H4O from a tyrosine residue and SCH2C6H5 and CH2C6H5 from a benzylated cysteine residue. Compared to the positive mode, the negative-ion PSD yielded fewer fragments which usually involved only one type of backbone cleavage (e.g., [Yn - H2O]-). These simple spectra aided interpretation. Overall, the acidic peptides studied yielded negative ion PSD spectra that were useful for peptide sequencing.     

Applications of in-source fragmentation of protein ions for direct sequence analysis by delayed extraction MALDI-TOF mass spectrometry

In matrix-assisted laser desorption/ionization of proteins, there exists a certain amount of fast metastable decay immediately after laser irradiation. The fragment ions thus formed can be resolved and their m/z values measured accurately by employing delayed extraction linear time-of-flight mass spectrometry. At higher than threshold laser fluences, proteins exhibit a series of fragment ions providing useful sequence information. We also observe that when moderate amounts of salts are present in the sample with sinapinic acid being the matrix, the intensities of cn ions (N-terminal fragments) are enhanced compared to other types of fragment ions. This enhancement in cn ion signals allows direct sequencing of proteins. The cn ions are completely absent when Xxx-Pro bonds are encountered and are of lower intensity when Xxx-Gly bonds are involved. Further, the cn ion series is interrupted at Xxx-Cys, when the cysteine is involved in a disulfide bond. Upon reduction of the disulfide bonds, the series continues and information is available for longer stretches. Using 10-20 pmol of recombinant proteins, sometimes contiguous sequence information up to 70 residues is obtained in a matter of minutes. Applications of the technique to some recombinant proteins with intra- or interchain disulfide linkages are presented.     

Identifying the glycosylation sites and site-specific carbohydrate heterogeneity of glycoproteins by matrix-assisted laser desorption/ ionization mass spectrometry

A sensitive and facile method is described to identify the glycosylation sites and site-specific heterogeneity in the carbohydrate attached to glycoproteins. In this procedure, the peptide backbone of the glycoprotein is cleaved enzymatically. The resulting peptide/glycopeptide mixture is divided into three fractions. The first is analyzed directly by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS), while the other two aliquots are analyzed by MALDI-MS after enzymatic release of the N-linked chains and the N- and O-linked chains. Comparison of these MALDI mass spectra provides the molecular weight of each carbohydrate side chain and of the peptide to which it was attached. This information combined with the amino acid sequence of the protein identifies the glycosylation sites, and provides information concerning site-specific oligosaccharide heterogeneity. This approach does not require time-consuming liquid chromatographic separations and can be performed on as little as 10 pmol of glycoprotein. Thus, our approach is faster and simpler than procedures currently used for glycosylation site mapping, and may offer a slight sensitivity advantage.     

Structure analysis of acetylated and non-acetylated O-linked MUC1-glycopeptides by post-source decay matrix-assisted laser desorption/ionization mass spectrometry

We have investigated the potential of structural elucidation of O-linked glycopeptides by post-source decay matrix-assisted laser desorption ionization mass spectrometry (PSD-MALDI-MS). In order to establish detailed fragmentation patterns and to dissect fragment ions with and without carbohydrate content, the same O-linked MUC1-derived glycopeptides with acetylated and non-acetylated sugars were analysed and compared. Furthermore, we were interested to examine possible differences in the fragmentation between glycopeptides with acetylated and non-acetylated sugars. The obtained PSD-MALDI-MS spectra showed a rather complete set of fragmentation data which allows to localize the glycan on the peptide, in parallel with sequencing a short glycan and the backbone peptide. Fragmentations of the sugars were dominated by inter-ring cleavages at the glycosidic bond. Intra-ring cleavage did also occur from the non-reducing end, but to a much lower extent. The fragmentation of the peptide backbone was not changed either by acetylated or non-acetylated sugars. Glycosylated peptide fragments occurred as fully glycosylated fragment ions, partially deglycosylated ions and completely deglycosylated ions, and was not influenced by the acetylation of sugars. However, differences occurred in the quality and quantity of fragment ions from the non-reducing end of the glycan part when comparing acetylated with non-acetylated glycopeptides.     

A matrix-assisted laser desorption ionization time-of-flight mass spectrometry approach to identify the origin of the glycan heterogeneity of diptericin, an O-glycosylated antibacterial peptide from insects

In a previous study, electrospray ionization mass spectrometry was used to analyze the structure of the O-glycopeptide diptericin, an antibacterial peptide from the fleshfly Phormia terranovae. Several glycoforms of diptericin differing in the length of their oligosaccharide chains were present at the final stage of purification. In order to determine the origin of this glycan heterogeneity, we analyzed by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) the relative abundance of the different diptericin glycoforms in fractions obtained after each purification step, and directly in the hemolymph and in the fat body which produces diptericin. MALDI-MS clearly shows that the purification procedure had no effect on the O-linked oligosaccharide chains of diptericin, suggesting that diptericin is synthesized as a family of heterogeneous glycopeptides. In addition, in these experiments, differential mapping by MALDI-MS of the hemolymph and fat body tissue from bacteria-challenged and naive larvae allowed us to detect induced or repressed molecules which may be involved in the immune response of P. terranovae.     

A peptide concentration and purification method for protein characterization in the subpicomole range using matrix assisted laser desorption/ionization-postsource decay (MALDI-PSD) sequencing

We here describe the use of added reversed-phase chromatographic beads to concentrate peptides from highly diluted solutions. In the procedure developed, peptide-bead suspensions are dried under vacuum to complete dryness; peptides are subsequently eluted in a small volume of matrix-assisted laser desorption/ionization (MALDI)-matrix containing organic/aqueous solvent and transferred to a MALDI-target for mass analysis. We show that by using this bead-peptide concentration procedure, low femtomole amounts of peptides are efficiently concentrated, up to 1000 times, to volumes smaller than 0.7 microL. We have used this concentration procedure in combination with MALDI-post-source decay analysis to identify subpicomole amounts of proteins present in polyacrylamide gels. Furthermore, we show that the bead-peptide concentration method can be elegantly used to clean up samples contaminated with high concentrations of substances normally deleterious to MALDI-mass spectrometry (MS) experiments. We have found additionally that the bead-peptide concentration procedure can be successfully used to store low femtomole amounts of peptide for prolonged periods of time without severe losses of peptide material. This bead-peptide concentration procedure therefore seems to be a simple and convenient step in the MALDI-MS sample preparation process.     

Suppression effects in enzymatic peptide ladder sequencing using ultraviolet - matrix assisted laser desorption/ionization - mass spectormetry

The techniques of enzymatic and chemical peptide ladder sequencing, coupled with ultraviolet - matrix assisted laser desorption/ionization - mass spectrometry (UV-MALDI-MS) have been improving continuously in the last five years and have now become important tools for primary structure identification. In this work, signal suppression effects, appearing in UV-MALDI-MS (excitation 337 nm) of ladder peptides, were investigated using the 17-amino acid peptide dynorphin A. We show, with examples of simple "two-peptide" systems and more complex "multi-peptide" systems, that suppression effects do in fact exist. The magnitude of the observed suppression is strongly dependent upon both the nature and the amount of the suppressing peptide. Suppression behavior of individual ladder peptides was investigated on equimolar mixtures of ten ladder peptides. Significant signal suppression was recorded for all ladder peptides, with some of them being approximately 170 times lower in signal intensity than the pure, i.e., unsuppressed peptide at the same concentration. For the investigated system--dynorphin A, 4-hydroxy-alpha-cyanocinnamic acid (4-HCCA) matrix, UV excitation--a correlation between the extent of suppression and an intractable combination of peptide hydrophobicity and the presence of several basic amino acids can be seen.     

Processing of neuropeptide Y and somatostatin in human cerebrospinal fluid as monitored by radioimmunoassay and mass spectrometry

The processing of four neuropeptides, neuropeptide Y (NPY) 1-36, NPY (18-36), somatostatin (SOM) 1-28, and SOM (15-28) was studied in human cerebrospinal fluid (CSF) by using a novel combination of methods that included radioimmunoassay (RIA) and mass spectrometry. Untreated CSF samples were chromatographed using reversed-phase high pressure liquid chromatography (RP-HPLC) followed by NPY-RIA or SOM-RIA. These results were compared with those obtained by incubating CSF with exogenous synthetic peptides and directly detecting peptide fragments by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-MS). Using this combination of methods, we were able to determine the probable identities of peptides/peptide fragments recognized in radioimmunoassays. The most important NPY-immunoreactive components in CSF were found to be NPY (1-36) and NPY (3-36). Metabolic products of SOM (15-28) were found to contribute to SOM-like immunoreactivity (SOM-LI) in CSF, but SOM (1-28) only to a lesser degree. Differences in the rate of neuropeptide processing were observed. These differences depended more on the length of the peptide than its sequence. NPY (18-36) and SOM (15-28) were rapidly and extensively processed, whereas NPV (1-36) and SOM (1-28) were processed much more slowly in CSF. The production of SOM (15-28) from SOM (1-28) by enzymes in CSF was not observed. Also, the presence of a disulfide bond in the somatostatins appeared to stabilize them against enzymatic digestion of the ring structure. The results detailed in this report confirm MALDI-MS important role in studies of neuropeptide processing in CSF.     

Capillary electrophoresis combined with matrix-assisted laser desorption/ionization mass spectrometry; continuous sample deposition on a matrix-precoated membrane target

Capillary electrophoresis (CE) and matrix-assisted laser desorption/ionization mass spectrometry (MALDI/MS) were combined in an off-line arrangement to provide separation and mass analysis of peptide and protein mixtures in the attomole range. A membrane target, precoated with MALDI matrix, was used for the continuous deposition of effluent exiting from a CE device. A sample track was produced by linear movement of the target during the electrophoretic separation and this track was subsequently analyzed by MALDI/MS. The technique is effective for peptides and proteins, having limits of detection (signal-to-noise >3) of about 50 amol for neurotensin (1673 Da) and 250 amol for cytochrome c (12361 Da) and apomyoglobin (16951 Da). The electrophoretic separation achieved from the membrane target, as measured by theoretical plate numbers from the mass spectrometric data, can be as high as 80-90% of that achieved by on-line UV detection under optimal conditions, although band broadening occurs and with some loss of separation efficiency. Non-volatile buffers such as 10-50 mM phosphate can also be used in the electrophoresis process and directly deposited on the membrane. The use of post-source decay techniques is shown for peptides in the CE sample track in order to obtain sequence verification. The effectiveness of this method of integration of CE and MALDI/MS is demonstrated with both peptide and protein mixtures and with the analysis of a tryptic digest of a protein.     

Protein identification by capillary zone electrophoresis/microelectrospray ionization-tandem mass spectrometry at the subfemtomole level

A method for the identification of proteins by their amino acid sequence at the low-femtomole to subfemtomole sensitivity level is described. It is based on an integrated system consisting of a capillary zone electrophoresis (CZE) instrument coupled to an electrospray ionization triple- quadrupole tandem mass spectrometer (ESI-MS/MS) via a microspray interface. The method consists of proteolytic fragmentation of a protein, peptide separation by CZE, analysis of separated peptides by ESI-MS/MS, and identification of the protein by correlation of the collision-induced dissociation (CID) patterns of selected peptides with the CID patterns predicted from all the isobaric peptides in a sequence database. Using standard peptides applied to a 20-microns-i.d. capillary, we demonstrate an ESI-MS limit of detection of less than 300 amol and CID spectra suitable for searching sequence databases obtained with 600 amol of sample applied to the capillary. Successful protein identification by the method was demonstrated by applying 50 and 38 fmol of a tryptic digest of the proteins beta-lactoglobulin and bovine serum albumin, respectively, to the system.