Phosphorylation of Sic1p by G1 Cdk required for its degradation and entry into S phase.

G1 cyclin-dependent kinase (Cdk)-triggered degradation of the S-phase Cdk inhibitor Sic1p has been implicated in the transition from G1 to S phase in the cell cycle of budding yeast. A multidimensional electrospray mass spectrometry technique was used to map G1 Cdk phosphorylation sites in Sic1p both in vitro and in vivo. A Sic1p mutant lacking three Cdk phosphorylation sites did not serve as a substrate for Cdc34p-dependent ubiquitination in vitro, was stable in vivo, and blocked DNA replication. Moreover, purified phosphoSic1p was ubiquitinated in cyclin-depleted G1 extract, indicating that a primary function of G1 cyclins is to tag Sic1p for destruction. These data suggest a molecular model of how phosphorylation and proteolysis cooperate to bring about the G1/S transition in budding yeast.

Cell cycle regulation of myosin-V by calcium/calmodulin-dependent protein kinase II.

Organelle transport by myosin-V is down-regulated during mitosis, presumably by myosin-V phosphorylation. We used mass spectrometry phosphopeptide mapping to show that the tail of myosin-V was phosphorylated in mitotic Xenopus egg extract on a single serine residue localized in the carboxyl-terminal organelle-binding domain. Phosphorylation resulted in the release of the motor from the organelle. The phosphorylation site matched the consensus sequence of calcium/calmodulin-dependent protein kinase II (CaMKII), and inhibitors of CaMKII prevented myosin-V release. The modulation of cargo binding by phosphorylation is likely to represent a general mechanism regulating organelle transport by myosin-V.

Mammalian Chk2 is a downstream effector of the ATM-dependent DNA damage checkpoint pathway.

In response to DNA damage and replication blocks, cells activate pathways that arrest the cell cycle and induce the transcription of genes that facilitate repair. In mammals, ATM (ataxia telangiectasia mutated) kinase together with other checkpoint kinases are important components in this response. We have cloned the rat and human homologs of Saccharomyces cerevisiae Rad 53 and Schizosaccharomyces pombe Cds1, called checkpoint kinase 2 (chk2). Complementation studies suggest that Chk2 can partially replace the function of the defective checkpoint kinase in the Cds1 deficient yeast strain. Chk2 was phosphorylated and activated in response to DNA damage in an ATM dependent manner. Its activation in response to replication blocks by hydroxyurea (HU) treatment, however, was independent of ATM. Using mass spectrometry, we found that, similar to Chk1, Chk2 can phosphorylate serine 216 in Cdc25C, a site known to be involved in negative regulation of Cdc25C. These results suggest that Chk2 is a downstream effector of the ATM-dependent DNA damage checkpoint pathway. Activation of Chk2 might not only delay mitotic entry, but also increase the capacity of cultured cells to survive after treatment with gamma-radiation or with the topoisomerase-I inhibitor topotecan.

Characterization of a truncated form of arrestin isolated from bovine rod outer segments.

The inactivation of photolyzed rhodopsin requires phosphorylation of the receptor and binding of a 48-kDa regulatory protein, arrestin. By binding to phosphorylated photolyzed rhodopsin, arrestin inhibits G protein (Gt) activation and blocks premature dephosphorylation, thereby preventing the reentry of photolyzed rhodopsin into the phototransduction pathway. In this study, we isolated a 44-kDa form of arrestin, called p44, from fresh bovine rod outer segments and characterized its structure and function. A partial primary structure of p44 was established by a combination of mass spectrometry and automated Edman degradation of proteolytic peptides. The amino acid sequence was found to be identical with arrestin, except that the C-terminal 35 residues (positions 370-404) are replaced by a single alanine. p44 appeared to be generated by alternative mRNA splicing, because intron 15 interrupts within the nucleotide codon for 369Ser in the arrestin gene. Functionally, p44 binds avidly to photolyzed or phosphorylated and photolyzed rhodopsin. As a consequence of its relatively high affinity for bleached rhodopsin, p44 blocks Gt activation. The binding characteristics of p44 set it apart from tryptic forms of arrestin (truncated at the N- and C-termini), which require phosphorylation of rhodopsin for tight binding. We propose that p44 is a novel splice variant of arrestin that could be involved in the regulation of Gt activation.

Utility of N-peracetylation of proteins for their structure determination by mass spectrometry.

Acetylation of the animo groups (N-terminus and lysine) of proteins before enzymatic or chemical cleavage was explored as an approach to provide additional information in the course of the determination of amino acid sequences. The major advantage is the ability to differentiate glutamine from lysine, because only the latter is acetylated and thus increases in mass by 42 Da. Horse heart cytochrome c could be fully N-actetylated and even on prolonged digestion with chymotrypsin underwent very little tryptic cleavage, in contrast to the native protein where this side reaction is extensive. Sperm whale myoglobin is more difficult to acetylate, but even at 40%-50% average acetylation, all 19 lysines could be identified unambiguously. A proteolytic digest of acetylated protein is thus a useful component of strategies for the determination of the primary structure of proteins by tandem mass spectrometry.

Selective detection of phosphopeptides in complex mixtures by electrospray liquid chromatography/mass spectrometry.

A mass spectrometry-based method that does not involve the use of radiolabeling was developed for selective detection of phosphopeptides in complex mixtures. Mixtures of phosphorylated and nonphosphorylated peptides at the low picomole level are analyzed by negative ion electrospray liquid chromatography/mass spectrometry using C-18 packed fused-silica columns (≤320-µm i.d.). Peptides and phosphopeptides in the chromatographic eluant undergo collision-induced dissociation in the free-jet expansion region prior to the mass analyzing quadrupole. Using relatively high collisional excitation potentials, phospho|peptides containing phosphoserine, phosphothreonine, and phosphotyrosine fragment to yield diagnostic ions at m/z 63 and 79 corresponding to PO2 (-); and PO3 (-), respectively. Chromatographic peaks containing phosphopeptides are indicated where these diagnostic ions maximize. The highest sensitivity for phosphopeptide detection is obtained using selected-ion monitoring for m/z 63 and 79. Full-scan mass spectra that exhibit the diagnostic phosphopeptide fragment ions, together with pseudomolecular ions, may be obtained by stepping the collisional excitation potential from a high value during the portion of each scan in which the low-mass-to-charge ratio diagnostic marker ions are being detected to a lower value while the upper mass-to-charge ratio range is being scanned. Good sensitivity for phosphopeptide detection was achieved using standard trifluoroacetic acid containing mobile phases for reversed-phase high-performance liquid chromatography. Data illustrating the selectivity and sensitivity of the approach are presented for mixtures of peptides and phosphopeptides containing the three commonly phosphorylated amino acids.

Examination of micro-tip reversed-phase liquid chromatographic extraction of peptide pools for mass spectrometric analysis.

Mass spectrometry occupies a central position in most current protein identification schemes. So-called 'mass fingerprinting' techniques rely on composite mass patterns of proteolytic fragments, or dissociation products thereof, to query databases. Keys to successful analysis of ever smaller amounts are sensitivity and complete spectral information, both of which depend for a large part on proper sample preparation. Clean-up and concentration of peptide mixtures over eppendorf gel loading tips filled with chromatographic media (i.e. 'micro-tips') are believed to be quite useful in this regard. We have studied quantitative and qualitative aspects of polypeptide extraction using these small manual devices. Optimization of sample volume and additives, micro-tip bed volume, and eluent composition and volume, all contribute to effective recovery (approximately 65-70%, on average). Improper digest conditions can, in fact, lead to far bigger losses, suggesting the need for at least trace amounts of Zwittergent 3-16. Of particular interest is our finding that partial fractionation, obtained by two-step micro-tip elution, generally results in more and better signals during subsequent mass analysis. Thus, by using optimized micro-tips, in combination with adequate sample handling and instrumentation, direct mass spectrometric identification can be routinely and successfully done in any resource facility type setting.

Detailed study of oxidative esterification and elimination reactions undergone by a steroidal 17 alpha-benzoyloxy-20-oxo-21-aldehyde.

The reaction of 17 alpha-benzoyloxy-11 beta-hydroxy-3,20-dioxo-1, 4-pregnadien-21-al as the hemiacetal (1) with methanol:acetic acid:potassium cyanide:manganese dioxide followed by acetylation and preparative HPLC of the reaction mixture afforded 11 crystalline products. These products can be conveniently divided into three categories representing side-chain cleavage and oxidative esterification with or without elimination of the benzoyloxy group. Of special interest was the stereospecific formation of the C-17 cyanohydrin acetate 4a and the cis delta 17(20) enol acetate methyl ester 5. On the other hand, nonstereospecific addition of HCN to the side chain gave the C-20 epimeric cyanohydrin acetates 7a and 7b. The use of activated versus nonactivated MnO2 plays a major role in determining the quantitative distribution of the products. It was also discovered that even in the absence of MnO2, the reaction goes to completion. A proposed mechanism which explains the formation of all products is presented.

Isolation and identification of a mouse brain protein recognized by antisera to heart fatty acid-binding protein.

Although a novel brain-specific fatty acid-binding protein (B-FABP) was recently cloned, the identity of a second fatty acid-binding protein detected with antibodies to the heart (H-FABP) has not been clearly resolved. The present investigation, using matrix-assisted laser desorption mass spectrometry, showed that this protein was a form of H-FABP whose N-terminal amino acid was neither methionine nor was it acetylated. Furthermore, isoelectric focusing revealed two major isoforms, a major band pl 7.4 and a minor band pl 6.4, in a distribution pattern opposite to that observed for H-FABP in the heart. Tryptic peptide mass maps of the in-gel digested SDS polyacrylamide gel electrophoresis protein bands showed that the two isoforms differed only in a single peptide corresponding to residues 97-106 of the heart H-FABP sequence. This peptide had an [M + H]+ ion of either 1205.62 (pl 7.4) or 1206.53 (pl 6.4), consistent with a single amino acid substitution, Asp98 or Asn98. Whereas it is well established that both H-FABP and B-FABP interact with polyunsaturated fatty acids, we showed that they also significantly alter plasma membrane cholesterol dynamics in a manner opposite to that of another brain lipid-binding protein, sterol carrier protein-2. In summary, the data demonstrated for the first time that the H-FABP from brain, while nearly identical to H-FABP from heart, differed significantly in isoform distribution and in amino terminal structure from heart H-FABP. This suggests that the brain and heart H-FABP may not necessarily function identically in these tissues.

The essential role of mass spectrometry in characterizing protein structure: mapping posttranslational modifications.

Over the last few years we have developed mass spectrometry-based approaches for selective identification of a variety of posttranslational modifications, and for sequencing the modified peptides. These methods do not involve radiolabeling or derivatization. Instead, modification-specific fragment ions are produced by collision-induced dissociation (CID) during analysis of peptides by ESMS. The formation and detection of these marker ions on-the-fly during the LC-ESMS analysis of a protein digest is a powerful technique for identifying posttranslationally modified peptides. Using the marker ion strategy in an orthogonal fashion, a precursor ion scan can detect peptides which give rise to a diagnostic fragment ion, even in an unfractionated protein digest. Once the modified peptide has been located, the appropriate precursor ion can be sequenced by tandem MS. The utility and interplay of this approach to mapping PTM is illustrated with examples that involve protein glycosylation and phosphorylation.

Phosphopeptide analysis by matrix-assisted laser desorption time-of-flight mass spectrometry.

In this paper we present methods for identifying and sequencing phosphopeptides in simple mixtures, such as HPLC fractions, at the subpicomole level by (+) ion matrix-assisted laser desorption time-of-flight mass spectrometry (MALDI-MS). Data are presented which indicate that when a reflectron time-of-flight mass spectrometer is used, MALDI can distinguish tyrosine phosphorylation from serine and threonine phosphorylation for peptides containing a single phosphate group. Phosphopeptides are identified in the (+) ion MALDI reflector spectrum by the presence of [MH-H3PO4]+ and [MH-HPO3]+ fragment ions formed by metastable decomposition. An abundant [MH-H3PO4]+ ion, accompanied by a weaker [MH-HPO3]+ ion indicates that the peptide is most likely phosphorylated on serine or threonine. In contrast, phosphotyrosine-containing peptides generally exhibit [MH-HPO3]+ fragment ions and little, if any [MH-H3PO4]+. Ambiguities do arise, most often with phosphopeptides that contain residues which readily lose water (such as unmodified serine), but these can often be resolved by recording a complete metastable fragment ion (postsource decay) spectrum. Postsource decay is shown here to be a viable technique for sequencing phosphopeptides. It can be used to distinguish between serine/ threonine and tyrosine phosphorylation and in many cases can be used to determine the exact site of phosphorylation in a peptide sequence. Nearly complete sequence coverage and phosphorylation site mapping is generally possible using approximately 300 fmol of peptide.

Overview of peptide and protein analysis by mass spectrometry.

One goal of this introductory overview is to try and dispel the still widely held, but now mistaken, belief that mass spectrometry is beyond the technical resources of the typical laboratory or facility engaged in the structural characterization or synthesis of peptides and proteins. Over the last five years, mass spectrometers and associated data systems have become available that can be operated by anyone capable of running a modern amino acid analyzer or Edman sequencer, yet are powerful enough to handle the most demanding analyses that the peptide or protein investigator might require. The remaining goals of this article are to familiarize peptide and protein chemists with the types of mass spectrometers that are appropriate for the majority of their analytical needs, to describe the kinds of experiments that can be performed with these instruments on a routine basis, and to discuss the kinds of information that these experiments provide. The emphasis here is on established tools and techniques that can realistically be used for problem solving. As a result, many useful instruments and techniques employed by the trained mass spectroscopist are not discussed here, because they do not satisfy these criteria or are not yet widely available; however, a few of these are briefly mentioned at the end of the unit. The overview concludes with a tutorial discussion on the meaning and practical importance of a number of fundamental experimental and performance-related issues that have important implications for interpretation and use of mass spectral data, such as mass accuracy and resolution.

Overview of peptide and protein analysis by mass spectrometry.

The goals of this unit are to familiarize peptide and protein chemists with the types of mass spectrometers that are appropriate for the majority of their analytical needs, to describe the kinds of experiments that can be performed with these instruments on a routine basis, and to discuss the kinds of information that these experiments provide. The emphasis here is on established tools and techniques that can realistically be used for problem solving. As a result, many useful instruments and techniques employed by the trained mass spectroscopist are not discussed here, because they do not satisfy these criteria or are not yet widely available. A few of these are briefly mentioned at the end of this introductory overview. The overview concludes with a tutorial discussion on the meaning and practical importance of a number of fundamental experimental and performance-related issues that have important implications for interpretation and use of mass spectral data, such as mass accuracy and resolution.

The correct molecular weight of myoglobin, a common calibrant for mass spectrometry.

Myoglobins from horse heart muscle, horse skeletal muscle and sperm whale are widely used as calibration standards or test compounds for various mass spectrometric methodologies. In all such cases reported in the literature, a molecular weight value is used (16,950.5 and 17,199, respectively) which is based on the assumption that amino acid 122 in this 153 amino-acid-long protein is asparagine, overlooking a published suggestion that it is aspartic acid instead. Since the mass assignment accuracy for matrix-assisted laser desorption mass spectrometry is reported to be +/- 0.01% and for electrospray ionization +/- 0.0025%, and error of one mass unit in approximately 17,000 would be significant. The mass-to-charge ratio of ions of the tryptic peptide encompassing amino acid 122 derived from commercially available horse heart and horse skeletal myoglobins, the apomyoglobin of the latter, and the tryptic and chymotryptic peptide of sperm whale myoglobin proved that in both proteins amino acid 122 is indeed aspartic acid, rather than asparagine. This finding was further confirmed by the collision-induced dissociation spectra of the [M + H]+ ions of the tryptic peptides from the horse myoglobins and the chymotriptic peptide from sperm whale myoglobin. Thus, the correct molecular weight of horse myoglobin is 16,951.49 and that of the sperm whale protein is 17,199.91.

Selective detection and sequencing of phosphopeptides at the femtomole level by mass spectrometry.

We describe a new procedure that enables selective detection and sequencing of Ser-, Thr-, and Tyr-phosphopeptides at the low femtomole level in protein digests. Radiolabeling with 32P is not required, nor is prior chromatographic separation of the peptide mixture. One to two microliters of the unfractionated protein digest is infused at basic pH into an electrospray mass spectrometer at a flow rate of 20-40 nl/min using an ultra-low flow sprayer. A precursor-ion scan of m/z 79 (PO-3) produces a mass spectrum containing only the molecular ions of the phosphopeptides that are present in the sample. In cases where the protein sequence is known, the peptide molecular weights obtained are often sufficient to identify the specific sequences that are phosphorylated. If the protein sequence is not known, tandem MS with collision-induced dissociation of phosphopeptide precursor-ions may be used to obtain the amino acid sequences including the site(s) of phosphorylation. We demonstrate that phosphopeptides may be selectively detected using as little as 3 fmol of a 10 fmol/microl solution and that sequence information for a phosphopeptide in the mixture may be obtained using as little as 3 femtomole of the same solution. In addition, we show that the stoichiometry of phosphorylation at specific sites may be estimated from the ratio of the ion signals for the respective forms of the peptides observed in the normal full-scan mass spectra of the digest. These procedures are illustrated here to identify and sequence phosphopeptides from alpha-casein, a milk-derived protein possessing up to nine phosphorylation-sites. Numerous MS and tandem MS experiments were carried out on a single, 250 fmol/microl loading of the phosphoprotein digest. Phosphopeptides derived from an unexpected variant of the protein were also observed.

Matrix-assisted laser desorption ionization with a magnetic mass spectrometer.

Matrix-assisted laser desorption ionization has been carried out with a high mass double-focusing magnetic mass spectrometer. The pulsed ion signal, generated by irradiation of the sample (substance P, ubiquitin, and cytochrome c) embedded in 2,5-dihydroxybenzoic acid with a XeF excimer laser (353 nm, 12 ns pulse, 10-160 Hz), was recorded with an integrating array detector. Good resolution of 2600 (full width at half maximum) and high sensitivity (a few pmol) were obtained. The loss of small neutral fragments was observed, supporting the notion that the peak broadening observed in the time-of-flight mass spectrometers commonly used for this ionization mode is due to such metastable decomposition.

Detection and structural characterization of amino polyaromatic hydrocarbon-deoxynucleoside adducts using fast atom bombardment and tandem mass spectrometry.

Fast atom bombardment (FAB) and tandem mass spectrometry (MS/MS) are shown to be useful methods for the detection and structural characterization of nanogram amounts of amino polyaromatic hydrocarbon-nucleoside DNA adducts. The positive ion spectra of four aromatic amine guanosine adducts were studied in detail. The FAB spectra of these adducts exhibit an [MH]+ ion and a more abundant aglycon fragment ion, [AH2]+, which results from the loss of the deoxyribose sugar. The sensitivity of the adducts to FAB was enhanced by preparing trimethylsilyl (TMS) ether derivatives. High-quality full-scan spectra could be obtained on less than 70 ng of the derivatized adducts without signal averaging. With a B/E-linked scan of the [MH]+ ion for the TMS2 species, these same adducts could be detected by examination of their metastable ion spectra at levels as low as 4-5 ng (S/N greater than 10). Collision-induced dissociation (CID) of the [MH]+ ion yields the aglycon fragment and an ion, S1, which results from cleavage through the sugar. The CID spectrum of the aglycon [AH2]+ ion is much more useful, providing structural information relating to the base, the polyaromatic hydrocarbon, and, possibly, the site of covalent attachment. Differentiation of isomeric aminophenanthrene-guanine adducts was demonstrated on the basis of the CID spectra of their respective [AH2]+ ions. The use of TMS derivatives also improves the sensitivity of these methods.

Matrix-assisted laser desorption using a fast-atom bombardment ion source and a magnetic mass spectrometer.

A conventional fast-atom bombardment (FAB) ion source was used to achieve matrix-assisted laser desorption (MALD) in a high-mass, double-focusing, magnetic mass spectrometer. The pulsed ion signals generated by irradiation of a mixture of sample and matrix (2,5-dihydroxybenzoic acid) with either a XeF excimer laser (353 nm) or a nitrogen laser (337 nm) were recorded with a focal-plane detector. A resolution (full-width at half maximum) of 4500 was achieved at m/z 1347.7 (the peptide substance P), 2500 for CsI cluster ions at m/z 10,005.7, and 1250 for the isotope cluster of the small protein cytochrome c (horse) [M+H]+ = m/z 12,360 (average). Sensitivity is demonstrated with 11 fmol of substance P. A survey scan is taken to locate the m/z of the sample molecular ion. The segment that contains the sample can then be integrated for a longer time to produce a better signal-to-noise ratio. In addition to higher sensitivity and lower matrix interference, the advantage of MALD over FAB is the former's lower susceptibility to the presence of salts, and competition between hydrophobic and hydrophilic components of a mixture. This feature is demonstrated by the complete MALD spectrum of a crude partial tryptic digest of sperm-whale apomyoglobin, containing 24 peptides, representing the entire sequence of this protein.

Trace detection of modified DNA bases via moving-belt liquid chromatography-mass spectrometry using electrophoric derivatization and negative chemical ionization.

Electrophoric derivatives of 5-methylcytosine and 5-hydroxymethyluracil nucleobases are determined using high-performance liquid chromatography-mass spectrometry coupled via a moving-belt interface. Standards as well as samples derived from DNA are analysed. As little as 9.9 pg (signal-to-noise ratio 5) and 180 fg (signal-to-noise ratio 10) of the respective nucleobases are detected in the electron-capture negative chemical ionization mode, and linear responses are observed over a moderate dynamic range. In a comparison study, liquid chromatography-electron-capture negative chemical ionization mass spectrometry is found to have a sensitivity comparable to gas chromatography-electron-capture negative chemical ionization mass spectrometry for 5-hydroxymethyluracil. A detection limit of 60 fg (signal-to-noise ratio 5) by gas chromatography-mass spectrometry is only three-fold better than the amount detected by liquid chromatography-mass spectrometry using the same mass spectrometer.

Selection of electrophoric derivatives of 1-aminopyrene and 2-aminofluorene for determination by gas chromatography with electron-capture negative-ion mass spectrometry.

Several electrophoric derivatives of 1-aminopyrene and 2-aminofluorene were prepared. Reagents such as heptafluorobutyryl chloride, pentafluorobenzoyl chloride, pentafluorobenzyl bromide and pentafluorobenzaldehyde, alone and in certain combinations, were employed. The ease of formation, yield, stability and fragmentation by gas chromatography with electron-capture negative-ion (ECNI) mass spectrometry of the derivatives were compared. This allowed the most promising ones to be selected for future work on the sensitive detection of aminopolyaromatics by this detection technique. Pentafluorobenzylidene (first choice) and N-pentafluorobenzyl-N-heptafluorobutyryl (second choice) derivatives emerged as the best ones. The origins of losses of HF and 2HF from some of the derivatives were elucidated in the ECNI mass spectra by studies of deuterium-labeled analogues.