For label-free expression profiling of tissue proteomes, efficient protein extraction, thorough and quantitative sample cleanup and digestion procedures, as well as sufficient and reproducible chromatographic separation, are highly desirable but remain challenging. However, optimal methodology has remained elusive, especially for proteomes that are rich in membrane proteins, such as the mitochondria. Here we describe a straightforward and reproducible sample preparation procedure, coupled with a highly selective and sensitive nano-LC/Orbitrap analysis, which enables reliable and comprehensive expression profiling of tissue mitochondria. The mitochondrial proteome of swine heart was selected as a test system. Efficient protein extraction was accomplished using a strong buffer containing both ionic and non-ionic detergents. Overnight precipitation was used for cleanup of the extract, and the sample was subjected to an optimized 2-step, on-pellet digestion approach. In the first step, the protein pellet was dissolved via a 4 h tryptic digestion under vigorous agitation, which nano-LC/LTQ/ETD showed to produce large and incompletely cleaved tryptic peptides. The mixture was then reduced, alkylated, and digested into its full complement of tryptic peptides with additional trypsin. This solvent precipitation/on-pellet digestion procedure achieved significantly higher and more reproducible peptide recovery of the mitochondrial preparation, than observed using a prevalent alternative procedure for label-free expression profiling, SDS-PAGE/ingel digestion (87% vs. 54%). Furthermore, uneven peptide losses were lower than observed with SDS-PAGE/in-gel digestion. The resulting peptides were sufficiently resolved by a 5 h gradient using a nano-LC configuration that features a low-void-volume, high chromatographic reproducibility, and an LTQ/Orbitrap analyzer for protein identification and quantification. The developed method was employed for label-free comparison of the mitochondrial proteomes of myocardium from healthy animals vs. those with hibernating myocardium. Each experimental group consisted of a relatively large number of animals (n=10), and samples were analyzed in random order to minimize quantitative false-positives. Using this approach, 904 proteins were identified and quantified with high confidence, and those mitochondrial proteins that were altered significantly between groups were
Taxol (paclitaxel) is a diterpenoid anticancer agent undergoing intensive human clinical evaluation. The poor aqueous solubility of taxol necessitates administration in excipients causing a variety of adverse effects, including anaphylactoid hypersensitivity reactions. Recently, taxol has been formulated in better-tolerated drug carriers such as liposomes. We investigated the conformation of taxol and the interaction of taxol with dipalmitoylphosphatidylcholine (DPPC) liposomes using fluorescence, circular dichroism, differential scanning calorimetry, fluorescence polarization, and X-ray diffraction. The conformation of taxol in DPPC membranes was similar to that observed in nonpolar solvents such as chloroform. Taxol was found to partition into the bilayer, perturbing the hydrocarbon chain conformation. The taxol C13 side chain was found to be fluorescent, and it displays an environment-sensitive shift in emission spectrum; taxol fluorescence was used to confirm the insertion of the drug into the bilayer. Taxol induces a broadening of the DPPC phase transition, and the location of the drug in the bilayer depends on drug concentration. Incorporation of taxol affects other physical properties of the bilayer such as the lipid order parameter, and this fluidizing effect was also observed upon incorporation of taxol in biological membranes isolated from basolateral plasma membranes of rat liver. These studies demonstrate that taxol incorporated into liposomes penetrates into the acyl chain domain of the bilayer and alters the physical properties of both artificial and biological membranes.
Many bacteria use nonribosomal peptide synthetase (NRPS) proteins to produce peptide antibiotics and siderophores. The catalytic domains of the NRPS proteins are usually linked in large multidomain proteins. Often, additional proteins are coexpressed with NRPS proteins that modify the NRPS peptide products, ensure the availability of substrate building blocks, or play a role in the import or export of the NRPS product. Many NRPS clusters include a small protein of ϳ80 amino acids with homology to the MbtH protein of mycobactin synthesis in Mycobacteria tuberculosis; no function has been assigned to these proteins. Pseudomonas aeruginosa utilizes an NRPS cluster to synthesize the siderophore pyoverdine. The pyoverdine peptide contains a dihydroxyquinoline-based chromophore, as well as two formyl-N-hydroxyornithine residues, which are involved in iron binding. The pyoverdine cluster contains four modular NRPS enzymes and 10 -15 additional proteins that are essential for pyoverdine production. Coexpressed with the pyoverdine synthetic enzymes is a 72-amino acid MbtH-like family member designated PA2412. We have determined the three-dimensional structure of the PA2412 protein and describe here the structure and the location of conserved regions. Additionally, we have further analyzed a deletion mutant of the PA2412 protein for growth and pyoverdine production. Our results demonstrate that PA2412 is necessary for the production or secretion of pyoverdine at normal levels. The PA2412 deletion strain is able to use exogenously produced pyoverdine, showing that there is no defect in the uptake or utilization of the iron-pyoverdine complex.Iron is an essential cofactor for many proteins, playing both catalytic and structural roles (1-3). Because of the low solubility of free Fe 3ϩ , many bacteria produce siderophores that bind to iron. The iron-siderophore complex is then actively transported into the cell. Although some small molecules like citrate or salicylate are able to function as lower affinity siderophores, many specialized peptides with extremely high affinity for iron are produced nonribosomally by bacteria. These compounds are produced by nonribosomal peptide synthetases (NRPSs) 2 that exist as modular proteins with multiple catalytic domains joined in a single protein. Often expressed with NRPS genes are other genes that encode proteins involved in additional essential steps including the synthesis of building blocks, siderophore export, import of the Fe 3ϩ -siderophore complex, or the removal Fe 3ϩ from the imported siderophore (4, 5). Pseudomonas aeruginosa is a bacterial pathogen that commonly causes infections in patients with cystic fibrosis (6). The siderophore pyoverdine (Fig. 1) is synthesized by P. aeruginosa (3) and has been correlated with virulence (7). Pyoverdine contains a cyclic peptide chain as well as a chemically modified dihydroxyquinoline-based chromophore that is responsible for iron binding. The peptide backbone of pyoverdine is synthesized by four large, multi-module NRPS proteins. The ...
Liquid chromatography (LC)/mass spectrometry (MS) in selected-reactions-monitoring (SRM) mode provides a powerful tool for targeted protein quantification. However, efficient, high-throughput strategies for proper selection of signature peptides (SP) for protein quantification and accurate optimization of their SRM conditions remain elusive. Here we describe an on-the-fly, orthogonal array optimization (OAO) approach that enables rapid, comprehensive, and reproducible SRM optimization of a large number of candidate peptides in a single nanoflow-LC/MS run. With the optimized conditions, many peptide candidates can be evaluated in biological matrices for selection of the final SP. The OAO strategy employs a systematic experimental design that strategically varies product ions, de-clustering energy and collision energy in a cycle of 25 consecutive SRM trials, which accurately reveals the effects of these factors on the single-to-noise ratio of a candidate peptide, and optimizes each. As proof of concept, we developed a highly sensitive, accurate, and reproducible method for the quantification of carbonyl reductases CBR1 and CBR3 in human liver. Candidate peptides were identified by nano-LC/LTQ/Orbitrap, filtered using a stringent set of criteria, and subjected to OAO. After evaluating both sensitivity and stability of the candidates, two SP were selected for quantification of each protein. As a result of the accurate OAO of assay conditions, sensitivities of 80 and 110 amol were achieved for CBR1 and CBR3, respectively. The method was validated and used to quantify the CBRs in 33 human liver samples. The mean level of CBR1 was 93.4±49.7 (range: 26.2–241) ppm of total protein, and for CBR3 was 7.69±4.38 (range: 1.26–17.9) ppm. Key observations of this study are that: i) evaluation of peptide stability in the target matrix is essential for final selection of the SP; ii) utilization of two unique SP contributes to high reliability of target protein quantification; and iii) it is beneficial to construct calibration curves using standard proteins of verified concentrations to avoid severe biases that may result if synthesized peptides alone are used. Overall, the OAO method is versatile and adaptable to high-throughput quantification of validated biomarkers identified by proteomic discovery experiments.
Lipid vesicles (liposomes) containing pH-sensitive fluorophores were used as probes for the study of liposome entry and intracellular fate. Pyranine [8-hydroxy-1,3,6-pyrenetrisulfonate (HPTS)] was entrapped in the liposome aqueous core during preparation to provide a means of detecting internalization into living cells. HPTS is highly water soluble and shows a strong pH-dependent shift in its fluorescence excitation spectrum. Fluorescence emission (FEM) is slightly pH dependent with excitation (lambda EX) at 350-415 nm but highly pH dependent with lambda EX at 450 nm. Liposomes bearing a net negative charge bound rapidly to CV-1 cells and underwent endocytosis. One hour after liposome addition, high FEM with lambda EX at 413 nm and low FEM with lambda EX at 450 nm suggest that most cell-associated liposomes had been internalized and resided at a mean pH of approximately 6.6. Collapse of cellular H+ gradients with NH4Cl or monensin treatment rapidly and reversibly increased FEM with lambda EX at 450 nm. Direct examination by fluorescence microscopy corroborates the fluorometric data on internalization; over time, FEM remained high with lambda EX at 350-405 nm but decreased with lambda EX at 450-490 nm, showing that all lipid vesicles were internalized within 40 min at 37 degrees C. Acidification of intracellular liposomes increased over 3 h, reaching a minimum value of approximately pH 5.5. HPTS persisted within acidic cellular vesicles for 2-3 days, and cytoplasmic dye was observed infrequently, suggesting that liposome fusion with cellular membranes seldom occurs. Material delivered to the endocytic pathway via lipid vesicles labeled an assortment of intracellular organelles of varying motility and morphology, including dynamic tubular structures whose lumen is acidic.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.