Last data update: Dec 09, 2024. (Total: 48320 publications since 2009)
Records 1-6 (of 6 Records) |
Query Trace: Pierce CL[original query] |
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Accurate and selective quantification of anthrax protective antigen in plasma by immunocapture and isotope dilution mass spectrometry
Solano MI , Woolfitt AR , Boyer AE , Lins RC , Isbell K , Gallegos-Candela M , Moura H , Pierce CL , Barr JR . Analyst 2019 144 (7) 2264-2274 Anthrax protective antigen (83 kDa, PA83) is an essential component of two major binary toxins produced by Bacillus anthracis, lethal toxin (LTx) and edema toxin (ETx). During infection, LTx and ETx contribute to immune collapse, endothelial dysfunction, hemorrhage and high mortality. Following protease cleavage on cell receptors or in circulation, the 20 kDa (PA20) N-terminus is released, activating the 63 kDa (PA63) form which binds lethal factor (LF) and edema factor (EF), facilitating their entry into their cellular targets. Several ELISA-based PA methods previously developed are primarily qualitative or semi-quantitative. Here, we combined protein immunocapture, tryptic digestion and isotope dilution liquid chromatography-mass spectrometry (LC-MS/MS), to develop a highly selective and sensitive method for detection and accurate quantification of total-PA (PA83 + PA63) and PA83. Two tryptic peptides in the 63 kDa region measure total-PA and three in the 20 kDa region measure PA83 alone. Detection limits range from 1.3-2.9 ng mL-1 PA in 100 muL of plasma. Spiked recovery experiments with combinations of PA83, PA63, LF and EF in plasma showed that PA63 and PA83 were quantified accurately against the PA83 standard and that LF and EF did not interfere with accuracy. Applied to a study of inhalation anthrax in rhesus macaques, total-PA suggested triphasic kinetics, similar to that previously observed for LF and EF. This study is the first to report circulating PA83 in inhalation anthrax, typically at less than 4% of the levels of PA63, providing the first evidence that activated PA63 is the primary form of PA throughout infection. |
Quantification of Influenza Neuraminidase Activity by Ultra-High Performance Liquid Chromatography and Isotope Dilution Mass Spectrometry
Solano MI , Woolfitt AR , Williams TL , Pierce CL , Gubareva LV , Mishin V , Barr JR . Anal Chem 2017 89 (5) 3130-3137 Mounting evidence suggests that neuraminidase's functionality extends beyond its classical role in influenza virus infection and that antineuraminidase antibodies offer protective immunity. Therefore, a renewed interest in the development of neuraminidase (NA)-specific methods to characterize the glycoprotein and evaluate potential advantages for NA standardization in influenza vaccines has emerged. NA displays sialidase activity by cleaving off the terminal N-acetylneuraminic acid on α-2,3 or α-2,6 sialic acid containing receptors of host cells. The type and distribution of these sialic acid containing receptors is considered to be an important factor in transmission efficiency of influenza viruses between and among host species. Changes in hemagglutinin (HA) binding and NA specificity in reassortant viruses may be related to the emergence of new and potentially dangerous strains of influenza. Current methods to investigate neuraminidase activity use small derivatized sugars that are poor models for natural glycoprotein receptors and do not provide information on the linkage specificity. Here, a novel approach for rapid and accurate quantification of influenza neuraminidase activity is achieved utilizing ultra-high performance liquid chromatography (UPLC) and isotope dilution mass spectrometry (IDMS). Direct LC-MS/MS quantification of NA-released sialic acid provides precise measurement of influenza neuraminidase activity over a range of substrates. The method provides exceptional sensitivity and specificity with a limit of detection of 0.38 μM for sialic acid and the capacity to obtain accurate measurements of specific enzyme activity preference toward α-2,3-sialyllactose linkages, α-2,6-sialyllactose linkages, or whole glycosylated proteins such as fetuin. |
Immunocapture isotope dilution mass spectrometry in response to a pandemic influenza threat
Pierce CL , Williams TL , Santana WI , Levine M , Chen LM , Cooper HC , Solano MI , Woolfitt AR , Marasco WA , Fang H , Donis RO , Barr JR . Vaccine 2017 35 (37) 5011-5018 As a result of recent advances in mass spectrometry-based protein quantitation methods, these techniques are now poised to play a critical role in rapid formulation of pandemic influenza vaccines. Analytical techniques that have been developed and validated on seasonal influenza strains can be used to increase the quality and decrease the time required to deliver protective pandemic vaccines to the global population. The emergence of a potentially pandemic avian influenza A (H7N9) virus in March of 2013, prompted the US public health authorities and the vaccine industry to initiate production of a pre-pandemic vaccine for preparedness purposes. To this end, we evaluated the feasibility of using immunocapture isotope dilution mass spectrometry (IC-IDMS) to evaluate the suitability of the underlying monoclonal and polyclonal antibodies (mAbs and pAbs) for their capacity to isolate the H7 hemagglutinin (HA) in this new vaccine for quantification by IDMS. A broad range of H7 capture efficiencies was observed among mAbs tested by IC-IDMS with FR-545, 46/6, and G3 A533 exhibiting the highest cross-reactivity capabilities to H7 of A/Shanghai/2/2013. MAb FR-545 was selected for continued assessment, evaluated by IC-IDMS for mAb reactivity against H7 in the H7N9 candidate vaccine virus and compared with/to reactivity to the reference polyclonal antiserum in allantoic fluid, purified whole virus, lyophilized whole virus and final detergent-split monovalent vaccine preparations for vaccine development. IC-IDMS assessment of FR-545 alongside IC-IDMS using the reference polyclonal antiserum to A/Shanghai/2/2013 and with the regulatory SRID method showed strong correlation and mAb IC-IDMS could have played an important role in the event a potential surrogate potency test was required to be rapidly implemented. |
Simultaneous identification and susceptibility determination to multiple antibiotics of Staphylococcus aureus by bacteriophage amplification detection combined with mass spectrometry
Rees JC , Pierce CL , Schieltz DM , Barr JR . Anal Chem 2015 87 (13) 6769-77 The continued advance of antibiotic resistance in clinically relevant bacterial strains necessitates the development and refinement of assays that can rapidly and cost-effectively identify bacteria and determine their susceptibility to a panel of antibiotics. A methodology is described herein that exploits the specificity and physiology of the Staphylococci bacteriophage K to identify Staphylococcus aureus (S. aureus) and determine its susceptibility to clindamycin and cefoxitin. The method uses liquid chromatography-mass spectrometry to monitor the replication of bacteriophage after it is used to infect samples thought to contain S. aureus. Amplification of bacteriophage K indicates the sample contains S. aureus, for it is only in the presence of a suitable host that bacteriophage K can amplify. If bacteriophage amplification is detected in samples containing the antibiotics clindamycin or cefoxitin, the sample is deemed to be resistant to these antibiotics, respectively, for bacteriophage can only amplify in a viable host. Thus, with a single work flow, S. aureus can be detected in an unknown sample and susceptibility to clindamycin and cefoxitin can be ascertained. This Article discusses implications for the use of bacteriophage amplification in the clinical laboratory. |
Viable Staphylococcus aureus quantitation using 15N metabolically-labeled bacteriophage amplification coupled with a multiple reaction monitoring proteomic workflow
Pierce CL , Rees JC , Fernandez FM , Barr JR . Mol Cell Proteomics 2011 11 (1) M111 012849 A multiple reaction monitoring liquid chromatography (LC) method with tandem mass spectrometric detection (MS/MS) for quantitation of Staphylococcus aureus via phage amplification detection (PAD) is described. This PAD method enables rapid and accurate quantitation of viable S. aureus by detecting an amplified capsid protein from a specific phage. A known amount of metabolically-labeled (15)N reference bacteriophage, utilized as the input phage and as the internal standard for quantitation, was spiked into S. aureus samples. Following a 2-h incubation, the sample was subjected to a 3-min rapid trypsin digest and analyzed by high-throughput LC-MS/MS targeting peptides unique to both the (15)N (input phage) and (14)N (progeny phage) capsid proteins. Quantitation was achieved by comparing peak areas of target peptides from the metabolically labeled (15)N bacteriophage peptide internal standard with that of the wild-type (14)N peptides that were produced by phage amplification and subsequent digestion when the host bacteria was present. This approach is based on the fact that a labeled species differs from the unlabeled one in terms of its mass but exhibits almost identical chemical properties such as ion yields and retention times. A 6-point calibration curve for S. aureus concentration was constructed with standards ranging from 5.0x10(4) CFU mL(-1) to 2.0x10(6) CFU mL(-1), with the (15)N reference phage spiked at a concentration of 1.0x10(9) PFU mL(-1). Amplification with (15)N bacteriophage coupled with LC-MS/MS detection offers speed (3 h total analysis time), sensitivity (LOD: < 5.0 x 10(4) CFU mL(-1)), accuracy, and precision for quantitation of S. aureus. |
Detection of Staphylococcus aureus using (15)N-labeled bacteriophage amplification coupled with matrix-assisted laser desorption/ionization-time-of-flight mass spectrometry
Pierce CL , Rees JC , Fernandez FM , Barr JR . Anal Chem 2011 83 (6) 2286-93 A novel approach to rapid bacterial detection using an isotopically labeled (15)N bacteriophage and matrix-assisted laser desorption/ionization-time-of-flight mass spectrometry (MALDI-TOF MS) is introduced. Current phage amplification detection (PAD) via mass spectrometric analysis is limited because host bacteria must be inoculated with low phage titers in such a way that initial infecting phage concentrations must be below the detection limit of the instrument, thus lengthening incubation times. Additionally, PAD techniques cannot distinguish inoculate input phage from output phage which can increase the possibility of false positive results. Here, we report a rapid and accurate PAD approach for identification of Staphylococcus aureus via detection of bacteriophage capsid proteins. This approach uses both a wild-type (14)N and a (15)N-isotopically labeled S. aureus-specific bacteriophage. High (15)N phage titers, above our instrument's detection limits, were used to inoculate S. aureus. MALDI-TOF MS detection of the (14)N progeny capsid proteins in the phage-amplified culture indicated the presence of the host bacteria. Successful phage amplification was observed after 90 min of incubation. The amplification was observed by both MALDI-TOF MS analysis and by standard plaque assay measurements. This method overcomes current limitations by improving analysis times while increasing selectivity when compared to previously reported PAD methodologies. |
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