Protein identification and peptide sequencing by tandem mass spectrometry requires knowledge of how peptides fragment in the gas phase, specifically which bonds are broken and where the charge(s) resides in the products. For many peptides, cleavage at the amide bonds dominate, producing a series of ions that are designated b and y. For other peptides, enhanced cleavage occurs at just one or two amino acid residues. Surface-induced dissociation, along with gas-phase collision-induced dissociation performed under a variety of conditions, has been used to refine the general 'mobile proton' model and to determine how and why enhanced cleavages occur at aspartic acid residues and protonated histidine residues. Enhanced cleavage at acidic residues occurs when the charge is unavailable to the peptide backbone or the acidic side-chain. The acidic H of the side-chain then serves to initiate cleavage at the amide bond immediately C-terminal to Asp (or Glu), producing an anhydride. In contrast, enhanced cleavage occurs at His when the His side-chain is protonated, turning His into a weak acid that can initiate backbone cleavage by transferring a proton to the backbone. This allows the nucleophilic nitrogen of the His side-chain to attack and form a cyclic structure that is different from the 'typical' backbone cleavage structures.
Vanadate and pervanadate (the complexes of vanadate with hydrogen peroxide) are two commonly used general protein-tyrosine phosphatase (PTP) inhibitors. These compounds also have insulin-mimetic properties, an observation that has generated a great deal of interest and study. Since a careful kinetic study of the two inhibitors has been lacking, we sought to analyze their mechanisms of inhibition. Our results show that vanadate is a competitive inhibitor for the protein-tyrosine phosphatase PTP1B, with a K i of 0.38 ؎ 0.02 M. EDTA, which is known to chelate vanadate, causes an immediate and complete reversal of the inhibition due to vanadate when added to an enzyme assay. Pervanadate, by contrast, inhibits by irreversibly oxidizing the catalytic cysteine of PTP1B, as determined by mass spectrometry. Reducing agents such as dithiothreitol that are used in PTP assays to keep the catalytic cysteine reduced and active were found to convert pervanadate rapidly to vanadate. Under certain conditions, slow time-dependent inactivation by vanadate was observed; since catalase blocked this inactivation, it was ascribed to in situ generation of hydrogen peroxide and subsequent formation of pervanadate. Implications for the use of these compounds as inhibitors and rationalization for some of their in vivo effects are considered.Protein-tyrosine phosphorylation plays a central role in regulating a variety of fundamental cellular processes (1-3). The tyrosyl phosphorylation state of a protein in the cell reflects the balance between the competing activities of the protein-tyrosine kinases and the protein tyrosine phosphatases (PTPs).
A comprehensive analysis of both the molecular genetic and phenotypic responses of any organism to the space flight environment has never been accomplished because of significant technological and logistical hurdles. Moreover, the effects of space flight on microbial pathogenicity and associated infectious disease risks have not been studied. The bacterial pathogen Salmonella typhimurium was grown aboard Space Shuttle mission STS-115 and compared with identical ground control cultures. Global microarray and proteomic analyses revealed that 167 transcripts and 73 proteins changed expression with the conserved RNA-binding protein Hfq identified as a likely global regulator involved in the response to this environment. Hfq involvement was confirmed with a ground-based microgravity culture model. Space flight samples exhibited enhanced virulence in a murine infection model and extracellular matrix accumulation consistent with a biofilm. Strategies to target Hfq and related regulators could potentially decrease infectious disease risks during space flight missions and provide novel therapeutic options on Earth.
The influence of acid−base interactions on the gas-phase dissociation of a series of protonated peptides was investigated. Peptides containing both acidic residues [aspartic (D), glutamic (E), and cysteic acid (C*)] and basic residues [arginine (R)] were dissociated by different activation methods that allow different time frames for dissociation. The synthetic peptides investigated differ systematically in the number and position of arginine residue(s) and include R LDIFSDF R , R LEIFSEF R , R LDIFSDF, LDIFSDF R , LEIFSEF R , LDIFSDF, R LCIFSCF R , R LAIFSCF R , R LCIFSAF R , R LC*IFSC*F R , R LAIFSC*F R , and R LC*IFSAF R (where C* denotes cysteic acid). It was observed that the number of ionizing protons relative to the number of basic residues in peptides containing acidic residues is a contributing factor in the fragmentation behavior. Nonselective cleavages along the peptide backbone occur when the number of ionizing protons exceeds the number of arginine residues, while dominant cleavages adjacent to the acidic residues predominate when the number of ionizing protons equals the number of arginine residues. In particular, enhanced b7/y2, and y6, y2 singly charged fragment ions were detected for the doubly protonated R LDIFSDF R and singly protonated LDIFSDF R precursor ions, respectively. These are the result of enhanced cleavage of the DF bond in the doubly protonated R LDIFSDF R and the DI plus DF bonds in the singly protonated LDIFSDF R . Abundant d and b-H2SO3 product ions indicative of specific cleavages adjacent to C* were observed in the cysteic acid-containing peptides when the number of ionizing protons equaled the number of arginine residues. Dominant cleavages at glutamic acid(s) were also observed for doubly protonated R LEIFSEF R and singly protonated LEIFSEF R when longer dissociation times were available. Preferential cleavage(s) at the acidic residue(s) occurs on the microsecond time scale for aspartic acid and greater than microsecond time scale for glutamic acid. This different behavior for aspartic vs glutamic acid is likely to have important implications in mass spectrometry-based sequencing strategies. However, the product ion spectra of most of the peptides investigated ( R LDIFSDF R , R LDIFSDF, LDIFSDF R , LEIFSEF R , and LDIFSDF) were found to be very similar under the array of activation methods used. These included surface-induced dissociation in a quadrupole tandem mass spectrometer, high-energy collision-induced dissociation in a hybrid sector/time-of flight mass spectrometer, and sustained off-resonance irradiation in a Fourier transform mass spectrometer. The unique fragmentation of peptides containing basic and acidic residues is rationalized as evidence for the existence of gas-phase intramolecular solvation that strongly influences their fragmentation. We propose that it is the available acidic proton(s) on the acidic residue(s) not involved in solvating the protonated arginine that is initiating the dominant cleavage(s). Electrospray ionization/SID frag...
Selective Gas-Phase Cleavage at the Peptide Bond C-Terminal to Aspartic Acid in Fixed-Charge Derivatives of Asp-Containing Peptides
This study focuses on the molecular level interpretation of the selective gas-phase cleavage at aspartic acid residues (Asp) in protonated peptides. A phi3P+CH2C(=O)group (phi = 2,4,6-trimethoxyphenyl) is attached to the N-terminal nitrogen of the selected peptides LDIFSDF and LDIFSDFR, via solid-phase synthesis, to "mimic" the tightly held charge of a protonated arginine (Arg) residue. Collision-induced dissociation in a quadrupole ion trap instrument and surface-induced dissociation in a dual quadrupole instrument were performed for electrospray-generated ions of the fixed-charge peptide derivatives. Selective cleavages at Asp-Xxx are observed for those ions with charge provided only by the fixed charge or for those with a fixed charge and one Arg plus one added proton. This supports a previously proposed mechanism which suggests that the cleavages at Asp-Xxx, initiated by the acidic hydrogen of the Asp residue, become significant when ionizing protons are strongly bound by Arg in the protonated peptides. It is clear that the fixed charge is indeed serving as a "mimic" of protonated Arg and that a protonated Arg side chain is not required to interact with the Asp to induce cleavage at Asp-Xxx. When the number of protons exceeds the number of Arg in a peptide containing Arg and Asp, nonselective cleavages occur. The fragmentation efficiency of the peptides is consistent with the idea that these nonselective cleavages are promoted by a mobile proton. The peptide with a fixed charge and one added proton, [phi3P+CH2C(=O)-LDIFSDF + H]2+, fragments much more efficiently than the corresponding peptide with a fixed charge, an Arg and one added proton, [phi3P+CH2C(=O)-LDIFSDFR + H]2+; both of these fragment more efficiently than the peptide with a fixed charge and no added proton, phi3P+CH2C(=O)-LDIFSDF. MS/MS/MS (i.e., MS3) experimental results for bn ions formed at Asp-Xxx from phi3P+CH2C(=O)-LDIFSDF and its H/D exchange derivative, phi3P+CH2C(=O)-LDIFSDF-d11, are consistent with the bn ions formed at Asp-Xxx having a succinic anhydride cyclic structure. MS/MS experiments were also carried out for phi3P+CH2C(=O)-AAAA, a peptide derivative containing active hydrogens only at amide nitrogens plus the C-terminus, and its active H/D exchange product, phi3P+CH2C(=O)-AAAA-d5. The results show that a hydrogen originally located at an amide nitrogen is transferred away in the formation of a cyclic charge remote b ion.
Newly generated plant tissue is inherently sensitive to infection. Yet, when pea (Pisum sativum) roots are inoculated with the pea pathogen, Nectria haematococca, most newly generated root tips remain uninfected even though most roots develop lesions just behind the tip in the region of elongation. The resistance mechanism is unknown but is correlated spatially with the presence of border cells on the cap periphery. Previously, an array of .100 extracellular proteins was found to be released while border cell separation proceeds. Here we report that protein secretion from pea root caps is induced in correlation with border cell separation. When this root cap secretome was proteolytically degraded during inoculation of pea roots with N. haematococca, the percentage of infected root tips increased from 4% 6 3% to 100%. In control experiments, protease treatment of conidia or roots had no effect on growth and development of the fungus or the plant. A complex of .100 extracellular proteins was confirmed, by multidimensional protein identification technology, to comprise the root cap secretome. In addition to defense-related and signaling enzymes known to be present in the plant apoplast were ribosomal proteins, 14-3-3 proteins, and others typically associated with intracellular localization but recently shown to be extracellular components of microbial biofilms. We conclude that the root cap, long known to release a high molecular weight polysaccharide mucilage and thousands of living cells into the incipient rhizosphere, also secretes a complex mixture of proteins that appear to function in protection of the root tip from infection.
The spaceflight environment is relevant to conditions encountered by pathogens during the course of infection and induces novel changes in microbial pathogenesis not observed using conventional methods. It is unclear how microbial cells sense spaceflight-associated changes to their growth environment and orchestrate corresponding changes in molecular and physiological phenotypes relevant to the infection process. Here we report that spaceflight-induced increases in Salmonella virulence are regulated by media ion composition, and that phosphate ion is sufficient to alter related pathogenesis responses in a spaceflight analogue model. Using whole genome microarray and proteomic analyses from two independent Space Shuttle missions, we identified evolutionarily conserved molecular pathways in Salmonella that respond to spaceflight under all media compositions tested. Identification of conserved regulatory paradigms opens new avenues to control microbial responses during the infection process and holds promise to provide an improved understanding of human health and disease on Earth.
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