Marina Edelson-Averbukh scite author profile

Maintenance of genomic stability depends on the DNA damage response, an extensive signaling network that is activated by DNA lesions such as double-strand breaks (DSBs). The primary activator of the mammalian DSB response is the nuclear protein kinase ataxia-telangiectasia, mutated (ATM), which phosphorylates key players in various arms of this network. The activation and stabilization of the p53 protein play a major role in the DNA damage response and are mediated by ATM-dependent posttranslational modifications of p53 and Mdm2, a ubiquitin ligase of p53. p53's response to DNA damage also depends on Mdm2-dependent proteolysis of Mdmx, a homologue of Mdm2 that represses p53's transactivation function. Here we show that efficient damageinduced degradation of human Hdmx depends on functional ATM and at least three sites on the Hdmx that are phosphorylated in response to DSBs. One of these sites, S403, is a direct ATM target. Accordingly, each of these sites is important for Hdm2-mediated ubiquitination of Hdmx after DSB induction. These results demonstrate a sophisticated mechanism whereby ATM fine-tunes the optimal activation of p53 by simultaneously modifying each player in the process.ataxia-telangiectasia ͉ DNA damage response ͉ p53 ͉ protein degradation

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Two-Dimensional Partial-Covariance Mass Spectrometry of Large Molecules Based on Fragment Correlations

Driver

Cooper

Ayers

et al. 2020

Phys. Rev. X

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well-established technique used for the study of mechanisms of laser-induced molecular ionization and decomposition. It measures statistical correlations between fluctuating signals of pairs of detected species (ions, fragments, electrons). A positive correlation identifies pairs of products originating from the same dissociation or ionization event. A major challenge for covariance-mapping spectroscopy is accessing decompositions of large polyatomic molecules, where true physical correlations are overwhelmed by spurious signals of no physical significance induced by fluctuations in experimental parameters. As a result, successful applications of covariance mapping have so far been restricted to low-mass systems, e.g., organic molecules of around 50 daltons (Da). Partial-covariance mapping was suggested to tackle the problem of spurious correlations by taking into account the independently measured fluctuations in the experimental conditions. However, its potential has never been realized for the decomposition of large molecules, because in these complex situations, determining and continuously monitoring multiple experimental parameters affecting all the measured signals simultaneously becomes unfeasible. We introduce, through deriving theoretically and confirming experimentally, a conceptually new type of partial-covariance mapping-self-correcting partial-covariance spectroscopy-based on a parameter extracted from the measured spectrum itself. We use the readily available total ion count as the selfcorrecting partial-covariance parameter, thus eliminating the challenge of determining experimental parameter fluctuations in covariance measurements of large complex systems. The introduced selfcorrecting partial covariance enables us to successfully resolve correlations of molecules as large as 10 3-10 4 Da, 2 orders of magnitude above the state of the art. This opens new opportunities for mechanistic studies of large molecule decompositions through revealing their fragment-fragment correlations. Moreover, we demonstrate that self-correcting partial covariance is applicable to solving the inverse problem: reconstruction of a molecular structure from its fragment spectrum, within twodimensional partial-covariance mass spectrometry.

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Gas-Phase Intramolecular Phosphate Shift in Phosphotyrosine-Containing Peptide Monoanions

et al. 2009

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Phosphotyrosine-containing peptide monoanions [M-H](-) exhibit extensive neutral loss of phosphoric acid (98 Da) upon quadrupole time-of-flight and ion-trap collision-induced dissociation (CID). In contrast, a neutral loss of metaphosphoric acid HPO(3) (80 Da) is negligible from the deprotonated phosphotyrosine peptides. The efficient H(3)PO(4) release is unexpected, given the structure of phosphotyrosine. Our study reveals that the abundant [M-H-98](-) product ions of pTyr-peptides are not a result of consecutive losses of HPO(3) and H(2)O but, rather, are induced by an intramolecular interaction of the phosphotyrosine phosphate with deprotonated peptide functions such as hydroxyl, carboxyl, and to a small extent, amide. As a result, an internal phosphotyrosine phosphate shift occurs, and the obtained phosphorylated functionalities undergo elimination of H(3)PO(4) to give rise to the [M-H-98](-) fragments. The mechanism proposed for the phosphoric acid neutral loss is based on extensive CID studies of Ala-substituted model phosphorylated peptides and oxygen-18 labeling. The proposed mechanistic pathway explains the fact that the pTyr phosphate transfer and the subsequent H(3)PO(4) neutral loss are not observed for multiply charged anions of pTyr-peptides. Monoanions of pSer-containing peptides undergo the intramolecular phosphate shift as well, although its efficiency is much lower compared to the aromatic phosphorylation sites. These observations facilitate correct identification of pSer-, pThr-, and pTyr-peptides in CID studies. This work demonstrates that the established phosphate-specific neutral loss fragmentation rules of protonated pTyr-peptides cannot be applied to the CID spectra of their [M-H](-) ions.

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Phosphate Group-Driven Fragmentation of Multiply Charged Phosphopeptide Anions. Improved Recognition of Peptides Phosphorylated at Serine, Threonine, or Tyrosine by Negative Ion Electrospray Tandem Mass Spectrometry

2006

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The nanoelectrospray product ion spectra of multiply charged phosphopeptide anions reveal the occurrence of phosphate-specific high-mass fragment ions of the type [M - nH - 79](n-1)-. These so far unrecognized fragments, which are observed for phosphoserine-, phosphothreonine-, and phosphotyrosine-containing peptides, are the counterparts of the established inorganic phosphopeptide marker ion found at m/z 79 = [PO3]-. The high-mass marker ions are formed with high efficiency at moderate collision offset values and are particularly useful for sensitive recognition of pSer-, pThr-, and pTyr-peptides due to the low background level in MS/MS spectra at m/z values above those of the precursor ions. By virtue of this feature, the detection of the new phosphorylation-specific fragment ions appears to be more sensitive than the detection of the low-mass phosphate marker ion at m/z 79, where a higher interference by nonspecific background signals is generally observed. The number of phosphate groups within a phosphopeptide can also be estimated on the basis of the [M - nH - 79](n-1)- ions, since these exhibit an effective, sequential neutral loss of H3PO4 of the residing phosphate groups. A mechanistic explanation for the formation of the [M - nH - 79](n-1)- ions from multiply charged phosphopeptides is given. The high-mass marker ions are proposed to originate from phosphopeptide anions, which carry two negative charges located at the phosphate group. A new search tool denominated "variable m/z gain analysis", which utilizes these newly recognized high-mass fragments for spotting of phosphopeptides in a negative ion parent scan, is proposed. The findings strengthen the value of negative ion ESI-MS/MS for analysis of protein phosphorylation.

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Iodoacetamide‐alkylated methionine can mimic neutral loss of phosphoric acid from phosphopeptides as exemplified by nano‐electrospray ionization quadrupole time‐of‐flight parent ion scanning

Krüger

Hung

Edelson-Averbukh

et al. 2005

Rapid Comm Mass Spectrometry

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Formation of S-carbamidomethylmethionine (camMet) occurs as a side reaction during cysteine alkylation with iodoacetamide (IAA). In collision-induced dissociation, peptides with camMet show an abundant neutral loss of 2-(methylthio)acetamide (C3H7NOS = 105.025 Da) at moderate collision offset values which are similar to those optimal for loss of phosphoric acid (H3PO4 = 97.977 Da). Neutral loss analysis is used for spotting of phosphopeptides which contain phosphoserine (pSer) or phosphothreonine (pThr) residues. In the case where precursor ions cannot be accurately assigned in the survey spectrum (e.g. due to low ion abundance or signal overlap), the mass accuracy of a neutral loss tandem mass spectrometry (MS/MS) analysis depends on the precursor ion isolation window. For the charge states 2+, 3+ or 4+, a typical 3.5 Da precursor isolation window results in neutral loss windows of 7, 10.5 or 14 Da, respectively. Consequently, neutral loss of 105 Da from alkylated methionine residues can mimic the phosphoserine/phosphothreonine-specific neutral loss of 98 Da. In the evaluation of quadrupole time-of-flight (QTOF) parent ion scan data for neutral loss of H3PO4, this interference was frequently observed. It is illustrated in this study using the analysis of ovalbumin phosphorylation as an example. The +80 Da molecular weight shift connected with phosphorylation at serine or threonine may also be mimicked by carbamidomethylation of methionine through a combination with sodium adduction (+57 Da +22 Da = +79 Da). For highly sensitive neutral loss analysis of serine and threonine phosphorylation, careful data inspection is recommended if reduction and alkylation by IAA is employed.

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Analysis of Protein Phosphorylation in the Regions of Consecutive Serine/Threonine Residues by Negative Ion Electrospray Collision-Induced Dissociation. Approach to Pinpointing of Phosphorylation Sites

2007

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Pinpointing of phosphorylation sites by positive ion collision-induced dissociation (CID) in phosphopeptides containing consecutive Ser/Thr residues (Ser/Thr clusters) is frequently hampered by the lack of backbone cleavage between adjacent Ser/Thr or pSer/pThr sites. In this study, we demonstrate that in negative ion collision-induced dissociation phosphorylated and unmodified residues of Ser/Thr clusters exhibit a very selective behavior toward cleavage of their N-Calpha bonds. Ser/Thr clusters were defined as two and more consecutive serine or threonine residues in phosphopeptide sequences. Dissociation reactions at pSer are significantly more abundant than those of unmodified sites. Thr residues exhibit the same effect, but the cleavages occurring at pThr are generally less prominent than those at pSer. The correlation observed between the facility of the amine backbone bond dissociation of phosphopeptides and the presence of the phosphate group on the side chain residues of Ser and Thr is attributed to the different magnitudes of electron density on the Calpha atoms of the amino acid in phosphorylated and unmodified forms. The results of this study indicate that the intensity ratio of the fragments generated by N-Calpha bond cleavage within the phosphopeptide Ser/Thr clusters represents a reliable and general marker for pinpointing of phosphorylation sites. The presented data illustrate that negative ion electrospray CID is superior over the standard positive ion mode approach for the localization of protein phosphorylation inside Ser/Thr clusters.

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Discrimination Between Peptide O-Sulfo- and O-Phosphotyrosine Residues by Negative Ion Mode Electrospray Tandem Mass Spectrometry

Edelson-Averbukh

Shevchenko

Pipkorn

et al. 2011

J. Am. Soc. Mass Spectrom.

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Unambiguous differentiation between isobaric sulfated and phosphorylated tyrosine residues (sTyr and pTyr) of proteins by mass spectrometry is challenging, even using high resolution mass spectrometers. Here we show that upon negative ion mode collision-induced dissociation (CID), pTyr- and sTyr-containing peptides exhibit entirely different modification-specific fragmentation patterns leading to a rapid discrimination between the isobaric covalent modifications using the tandem mass spectral data. This study reveals that the ratio between the relative abundances of [M-H-80](-) and [M-H-98](-) fragment ions in ion-trap CID and higher energy collision dissociation (HCD) spectra of singly deprotonated +80 Da Tyr-peptides can be used as a reliable indication of the Tyr modification group nature. For multiply deprotonated +80 Da Tyr-peptides, CID spectra of sTyr- and pTyr-containing sequences can be readily distinguished based on the presence/absence of the [M-nH-79]((n-1)-) and [M-nH-79-NL]((n-1)-) (n=2, 3) fragment ions (NL=neutral loss).

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Intramolecular electrophilic aromatic substitution in gas‐phase‐protonated difunctional compounds containing one or two arylmethyl groups

Edelson-Averbukh¹,

Mandelbaum²

2003

J. Mass Spectrom.

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A variety of dibenzyl esters and ethers undergo a rearrangement process upon isobutane chemical ionization and collision-induced dissociation of their MH(+) ions, whereby a new bond is formed between the two benzyl groups, giving rise to abundant [C(14)H(13)](+) (m/z 181) ions. This rearrangement has been explained as an intramolecular electrophilic substitution in the gas phase occurring in an ion-neutral complex formed by the cleavage of one of the benzyl-oxygen bonds. A similar highly efficient intramolecular electrophilic substitution takes place in di-alpha- and beta-naphthylmethyl adipates affording m/z 281 [C(22)H(17)](+) ions, but not in the sterically hindered di-9-anthracylmethyl adipate. An analogous efficient rearrangement occurs in benzyl alpha- and beta-naphthylmethylcyclohexane-1,4-dicarboxylates and in benzyl alpha- and beta-phenylethylcyclohexane-1,4-dimethanol ethers. The analogous rearrangement is much less efficient in benzylallyl, benzylpropargyl and benzyl-9-anthracylmethyl derivatives, even less in benzylisopropyl and benzylacetyl analogs, and it is absent in benzyltetrahydropyranyl derivatives. The distinctive behavior of the protonated difunctional benzyl derivatives is interpreted in terms of the energy requirements of the O-R bond heterolysis of the protonated functionalities, the ability of the neutral R' groups (non-dissociated from the oxygen atom) to play the role of the nucleophile in the intramolecular electrophilic substitution processes and the electrophilicity of the R(+) ions.

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