Literatura académica sobre el tema "Protein isotopic labelling"

For most biophysical techniques, characterization of protein–protein interactions is challenging; this is especially true with methods that rely on a physical phenomenon that is common to both of the interacting proteins. Thus, for example, in IR spectroscopy, the carbonyl vibration (1600–1700 cm−1) associated with the amide bonds from both of the interacting proteins will overlap extensively, making the interpretation of spectral changes very complicated. Isotope-edited infrared spectroscopy, where one of the interacting proteins is uniformly labelled with 13C or 13C,15N has been introduced as a solution to this problem, enabling the study of protein–protein interactions using IR spectroscopy. The large shift of the amide I band (approx. 45 cm−1 towards lower frequency) upon 13C labelling of one of the proteins reveals the amide I band of the unlabelled protein, enabling it to be used as a probe for monitoring conformational changes. With site-specific isotopic labelling, structural resolution at the level of individual amino acid residues can be achieved. Furthermore, the ability to record IR spectra of proteins in diverse environments means that isotope-edited IR spectroscopy can be used to structurally characterize difficult systems such as protein–protein complexes bound to membranes or large insoluble peptide/protein aggregates. In the present article, examples of application of isotope-edited IR spectroscopy for studying protein–protein interactions are provided.

Studies evaluating the protein nutritive value of beans labelled with 15N, ussing nitrogen balance and the quantitation of faecal and urinary endogenous nitrogen, determined by isotopic dilution, have been extensively used. The objective of this research was to verify if the isotopic labelling of raw, freeze dried beans (Phaseolus vulgaris L., cultivar Piratã 1) with 1.394 atoms%15N, resulted in the same abundance of the whole flour and of the protein fractions extracted from the beans with 0.5 mol L-1 NaCl. The isotopic abundance found in the whole bean flour, in the protein extract, in the globulin and albumin fractions were respectively: 1.394 ± 0.011; 1.403 ± 0.012; 1.399 ± 0.007 and 1.399 ± 0.028 atoms % of 15N, presenting no difference (P > 0.05). However, a difference was found (P < 0.05) between the above mentioned abundances and the isotopic abundance found in the nitrogen of the proteins in the extraction residue, which was 0.969 ± 0.084. Since the abundances did not differ, the protein nutritive indexes, such as digestibility and biological value, determined from the nitrogen balance and corrected for isotopic dilution, would not be affected by extracting the proteins from the beans with 0.5 mol L¹ NaCl. If working with the nitrogen balance of the residual proteins after extraction and even with the whole flours, these indexes could present incorrect values, since the isotopic labelling of the residual proteins was less than that of the protein fractions.

Neutron reflectometry (NR) is a large-facility technique used to examine structure at interfaces. In this brief review an introduction to the utilisation of NR in the study of protein–lipid interactions is given. Cold neutron beams penetrate matter deeply, have low energies, wavelengths in the Ångstrom regime and are sensitive to light elements. High differential hydrogen sensitivity (between protium and deuterium) enables solution and sample isotopic labelling to be utilised to enhance or diminish the scattering signal of individual components within complex biological structures. The combination of these effects means NR can probe buried structures such as those at the solid–liquid interface and encode molecular level structural information on interfacial protein–lipid complexes revealing the relative distribution of components as well as the overall structure. Model biological membrane sample systems can be structurally probed to examine phenomena such as antimicrobial mode of activity, as well as structural and mechanistic properties peripheral/integral proteins within membrane complexes. Here, the example of the antimicrobial protein α1-purothionin binding to a model Gram negative bacterial outer membrane is used to highlight the utilisation of this technique, detailing how changes in the protein/lipid distributions across the membrane before and after the protein interaction can be easily encoded using hydrogen isotope labelling.

Milk and yogurt constitute a major source of dietary protein. The nutritive value of dietary proteins is linked to subsequent postprandial amino acid availability in the portal blood (Rérat, 1988). Portal absorption of nutrients cannot be studied in humans, but pigs provide a valid model for studying protein digestion in humans (Rowan et al. 1994).Since stable isotopes are suitable to distinguish the exogenous from endogenous protein fraction in the intestinal lumen, intrinsic isotopic labelling of milk proteins has been considered a useful technique for nutritional investigations (Gaudichon et al. 1995; Gaudichon et al. 1999; Mahé et al. 1994). Recently, the use of 15N-labelled milk proteins were used to distinguish exogenous from endogenous N fractions in the human intestine after ingestion of 15N-milk or 15N-yogurt (Gaudichon et al. 1995). These authors pointed out that the jejunal flux of 15N was different for milk and yogurt. It is known that milk proteins and lactose undergo preliminary hydrolysis during lactic fermentation (Tamine & Deeth, 1980). It is also suggested that lactic fermentation enhances the nutritional value of milk proteins (Vass et al. 1984).

SUMMARYMonensin (Mon) is an anticoccidial polyether ionophore widely used to control coccidiosis. The extensive use of polyether ionophores on poultry farms resulted in widespread resistance, but the underlying resistance mechanisms are unknown in detail. For analysing the mode of action by which resistance against polyether ionophores is obtained, we induced in vitro Mon resistance in Toxoplasma gondii-RH strain (MonR-RH) and compared it with the sensitive parental strain (Sen-RH). The proteome assessment of MonR-RH and Sen-RH strains was obtained after isotopic labelling using stable isotope labelling by amino acid in cell culture. Relative proteomic quantification between resistant and sensitive strains was performed using liquid chromatography-mass spectrometry/mass spectrometry. Overall, 1024 proteins were quantified and 52 proteins of them were regulated. The bioinformatic analysis revealed regulation of cytoskeletal and transmembrane proteins being involved in transport mechanisms, metal ion-binding and invasion. During invasion, actin and microneme protein 8 (MIC8) are seem to be important for conoid extrusion and forming moving junction with host cells, respectively. Actin was significantly upregulated, while MIC8 was downregulated, which indicate an invasion reduction in the resistant strain. Resistance against Mon is not a simple process but it involves reduced invasion and egress activity of T. gondii tachyzoites while intracellular replication is enhanced.

The metabolic response to injury includes major alterations in protein metabolism; however, little is known about alterations in the synthesis of individual proteins and their role in the stress response. Our aim was to study how individual proteins in liver and muscle are altered by abdominal surgery. Changes produced in mRNA and proteins by abdominal surgery were studied in rats using RAP (random arbitrary priming)-PCR, to investigate mRNA alterations, and standard or isotopic (with in vivo radioactive labelling of proteins) two-dimensional electrophoresis/MS proteomic analyses, to study differential expression of proteins. Many of the differentially expressed proteins identified in blood were specifically synthesized by the liver to participate in the stress response. The hepatic proteins (antioxidant proteins, serine protease inhibitors, acute-phase proteins and transport proteins) were secreted into the bloodstream to produce a systemic action, indicating the central role of the liver in the stress response. Overexpressed proteins identified in liver were associated with the glycolytic processes and the folding of nascent proteins, confirming the high metabolic activity of the liver after surgery. The role of skeletal muscle protein as an amino acid donor to fuel the processes involved in the stress response was shown by the decrease in high-molecular-mass myofibrillar proteins. Combined use of the three techniques studied, differential RAP-PCR and standard and isotopic proteome analysis, provided complementary information on the differentially expressed proteins in a rat model of surgical stress.

A procedure for obtaining rat mast-cell histidine decarboxylase in greater than 50% yield in cell-free extracts was developed. The enzyme was found in the supernatant fractions from a 3,500 g and a 105,000 g centrifugation step and was demonstrated to be sensitive to inhibition by alpha-fluoromethylhistidine but not by phenylalanine. Although the enzyme shows a half-life of only 3 h in cell-free extract, the initial high recovery of activity allowed for active-site labelling of the enzyme by [3H]histidine and NaBH4. Labelled protein migrated on non-denaturing polyacrylamide-gradient-gel electrophoresis as a 55,000 Da species.

The kinetics of blood free amino acids (AA) transfer into milk casein were compared in goats (n 4) at 61 (SE5)d (Expt 1; post-peak, 4.51 (SE 0.26) kg milk/d) and at 180 (SE 6) d (Expt 2; late, 2.36 (SE 0.16) kg milk/d) of lactation during non-primed, continuous (Expt 1, 12 h; Expt 2, 16 h) intravenous infusions of mixtures of L-[1-13C]leucine and L-[1-13C]phenylalanine with either L-[1-13C]valine (Expt 1) or L-[5-13Cmethionine (Expt 2). The 13C enrichments of blood free and casein-bound AA were fitted to a single exponential model to estimate isotopic plateaux and the fractional rate constant for milk casein labelling. Milk protein output and its contribution to whole-body flux was higher in Expt 1 (post-peak) than in Expt 2 (late lactation), but the kinetics of 13C labelling of the casein-bound AA were similar for all AA tracers in both experiments. At both stages of lactation the delay (6–8 h) between the attainment of isotopic plateau for the blood free AA and the corresponding attainment of plateau for the casein-bound AA indicated that the blood free pool was not the immediate precursor pool for milk casein biosynthesis. Plateau enrichments of casein-bound AA were generally higher than those for the corresponding blood free AA in both experiments. These results indicate that the relative contributions of different AA sources to the immediate precursor pool for milk casein biosynthesis are similar at different stages of lactation despite major changes in the partitioning of whole-body flux towards milk protein output. Non-milk protein fluxes were also similar in post-peak and late lactation.

Les chaperonines sont des chaperonnes moléculaires indispensables pour le repliement de certaines protéines dans les cellules. La taille et la complexité de ces machineries biologiques rendent complexes l'étude de leurs propriétés structurales et fonctionnelles. La spectroscopie RMN permet de suivre des changements structuraux et dynamiques en temps réel avec une résolution atomique. Cependant, l'étude par RMN de protéines ou de complexes de haut poids moléculaires a été un challenge pendant de nombreuses années. Dans la première partie de cette thèse, il a été montré que la combinaison de marquage spécifique des groupements méthyles, d'expériences RMN optimisées et de microscopie électronique peut être utilisée pour suivre différents états du cycle fonctionnel d'une chaperonine de 1 MDa. Pour étudier ce mécanisme, la chaperonine native a été reconstituée avec un marquage des groupements méthyles des méthionines et valines. Les résidus méthionines ont pu être utilisés comme des sondes pour identifier les spectres RMN correspondant aux états intermédiaires et aux espèces actives du cycle fonctionnel. Grâce à ces sondes il a été possible de suivre en temps réel les réarrangements structuraux correspondant aux différentes conformations de la chaperonine durant son cycle fonctionnel. La seconde partie traite de la caractérisation de l'interaction de la chaperonine avec une protéine cliente dépliée. L'observation de la stabilisation de l'état déplié de la protéine par la chaperonine a permis de mettre en évidence une activité de "holdase" de la chaperonine. En utilisant une combinaison astucieuse de différents marquages de groupements méthyles et d'expériences RMN optimisés pour des assemblages de haut poids moléculaire, il a été possible d'observer le repliement de cette protéine par la chaperonine et les effets de la présence d'une protéine dépliée sur le cycle fonctionnel de la chaperonine en action
Chaperonins are essential molecular chaperons for the refolding of proteins in the cells. Size and complexity of these biological machineries make complex the study of their structural and functional properties. NMR spectroscopy offers an unique ability to monitor structural and dynamic changes in real-time and at atomic resolution. However, the NMR studies of large proteins and complexes has been a real challenge for a long time. In the first part of this thesis, it has been shown that the combination of methyl specific labeling, optimized NMR spectroscopy for large assemblies and electron microscopy can be used to monitor the different states of the functional cycle of a 1 MDa chaperonin. To study this mechanism, the native chaperonin was reconstituted with a labeling of the methionines and valines methyl groups. Methionines residues have been used as probes to identify the NMR spectra corresponding to intermediates states and active species of the functional cycle. Thanks to theses probes, it has been possible to follow in real time the structural rearrangements corresponding to the different conformations of the chaperonin during its functional cycle. The second part deals with the characterization of the interaction between the chaperonin and an unfolded protein. Observation of the stabilization of the unfolded protein by the chaperonin allowed to identify the holdase activity of the chaperonin. Using a clever combination of a differential methyl labeling and optimized NMR spectroscopy for large assemblies, it has been possible to follow the refolding of the unfolded protein by the chaperonin and the effects of the unfolded protein on the functional cycle of the chaperonin in action

O oxigênio molecular singlete (1O2) é formado em sistemas biológicos e reage com diferentes biomoléculas. Proteínas representam um dos principais alvos de oxidação, devido as suas altas concentrações em organismos. Em pH fisiológico 1O2 reage com His, Tyr, Met, Cys e Trp. Neste trabalho investigamos a oxidação causada pelo 1O2 e a formação de dimerização em uma proteína modelo, a lisozima. A identificação dos principais produtos de oxidação e dimerização foi realizada por sequenciamento de peptídeos através de nano cromatografia acoplada a espectrometria de massas (nLC-MS/MS). A geração de 1O2 foi realizada por fotossensibilização utilizando luz e rosa bengala como fotossensibilizador, e pela decomposição térmica de endoperóxidos derivado do naftaleno DHPN16O2 e DHPN18O2, uma fonte limpa de 1O2 no meio reacional. Os resultados demonstraram que a reação do oxigênio singlete com lisozima acarreta oxidação dos resíduos de Met, His e Trp. A caracterização da estrutura primária por nLC-MS/MS dos aminoácidos confirmou a adição de átomos de oxigênio marcado (18O). A lisozima é constituída apenas de um resíduo de histidina (His15) e as oxidações identificadas foram adições de massas de +14 Da (descrita como 2-oxo-histidina), +16 e +32 Da. Os resíduos de metionina (Met12 e Met105) foram identificados como sulfóxidos (MetSO - adição de massas de +16 Da). Para os resíduos de triptofano foram identificados a formação de quinurenina (adição de massas de +4 Da), +16 e +32 Da. As oxidações levaram a formação de dimerização na proteína caracterizada por eletroforese em gel e nLC-MS/MS. O objetivo principal do trabalho foi analisar a ligação cruzada entre o resíduo de histidina 2-oxohistidina na lisozima. Entretanto, foram identificadas ligações cruzadas entre 2- oxo-histidina e resíduos de lisina, além de ligações cruzadas com resíduos de triptofano oxidado. Em consequência dos resultados obtidos com a proteína modelo, avaliamos as oxidações e formação de dímeros em proteínas extraídas do cristalino do olho bovino. Diferentes tipos de modificações foram observados, além da formação de dímeros entre resíduos de histidina (2-oxoHis-His) caracterizados por nLC-MS/MS e bioinformática. Os dados obtidos neste trabalho, fornecem evidências da ocorrência simultânea de formação de ligações cruzadas entre diferentes proteicas após exposição a 1O2. O trabalho resultou na identificação e sequenciamento através de nLC-MS/MS de peptídeos oxidados por 1O2 a partir de uma proteína modelo. Esses resultados reiteram o importante papel do 1O2 em reações com proteínas além do seu envolvimento no desenvolvimento de condições patológicas. A dimerização formada na ligação cruzada em 2-oxo-His-His representa um possível novo biomarcador para o 1O2 em sistemas biológicos
Singlet molecular oxygen (1O2) can be generated in biological systems, reacting with different biomolecules. Proteins are major target for oxidants due to higher concentration in organisms. At physiological pH, 1O2 may react with the following aminoacids: His, Tyr, Met, Cys and Trp. Here, we investigated oxidation and dimerization reactions of proteins exposed to 1O2 using lysozyme as a model. Modifications of lysozyme by 1O2 were investigated using mass spectrometry approaches. Identification of the main oxidation and dimerization products were performed by peptide sequencing by nano-chromatography coupled to mass spectrometry (nLC-MS/MS). Singlet oxygen was generated using visible light and rose Bengal as photosensitizer, and from the decomposition of thermolabile endoperoxides DHPN16O2 e DHPN18O2, clean sources of 1O2. Experimental findings showed oxidation of Met, His, and Trp residuesin lysozyme. Structural characterization by nLC-MS/MS of the oxidative modifications in lysozyme tryptic peptides showed the addition of [18O]-labeled atoms in different amino acid residues. Lysozyme has in its structure a single histidine residue (His15). We identified shifts of +14 Da (described as oxohistidine), +16 and +32 Da in this residue. Methionine residues (Met12 and Met105) were oxidized to sulfoxides (MetSO mass shift of +16 Da). Modifications in tryptophan residues were identified as kynurenine (shift mass of +4 Da), +16 and + 32 Da. Oxidized lysozyme subjected to SDS-Page showed dimmers formation. The main aim was to analyze cross-linking formation between 2-oxo-histidine residues in lysozyme. However, cross-links between 2- oxo-histidine and lysine residues, and cross-links between oxidized tryptophan residues have been identified. Following results obtained with the protein model, we evaluated oxidation and the dimers formation in proteins extracted from the lens of the bovine eye. Analysis performed in nLC-MS/MS and bioinformatics identified different types of modifications, including formation of dimers with histidine residues (2-oxo-His-His). The data provided evidence for simultaneous occurrence of protein cross-linking on exposure 1O2. These results demonstrated the important role of 1O2 in protein reactions beyond its involvement in developing of pathological conditions. In conclusion, dimerization of proteins through 2-oxo-His residues may be a possible new biomarker for 1O2 in biological systems.

Le nombre croissant de médicaments protéiques utilisés en thérapeutique a créé des besoins dans le domaine de leur quantification, principalement dans le plasma, un milieu de composition protéique complexe. Le dosage, essentiel aux études pharmacocinétique/pharmacodynamique, ainsi qu’à l’optimisation de ces traitements, est compliqué par la nature protéique de ces médicaments et par les faibles concentrations auxquelles ils sont attendus dans ces milieux complexes. La méthodologie proposée se démarque des méthodes de dosage usuelles par son caractère universel. Elle fait appel à la spectrométrie de masse adaptée à la quantification des protéines grâce à l’utilisation d’un marquage isotopique différentiel des peptides : après enrichissement et protéolyse, l’échantillon à doser est marqué sur les lysines par la version légère d’un réactif de dérivation. En parallèle, les peptides de la protéine médicament pure marqués par la version lourde du réactif, servent d’étalon interne. La possibilité de quantifier la protéine à partir de plusieurs de ses peptides améliore la fiabilité du dosage. Appliquée à l’epoetin beta aux concentrations attendues en thérapeutique (autour de 0,5 femtomole/µL de plasma), la stratégie proposée permet de situer la limite de quantification à environ 50 attomoles d’epoetin beta/µL de plasma avec une méthodologie de spectrométrie de masse nano-LC-ESI-Q-TRAP fonctionnant en mode MRM. Pour étendre l’universalité de cette approche au champ des protéines médicaments pégylées, une seconde molécule a été étudiée. Il s’agit de l’interféron alfa-2b pégylé qui a permis de mettre en place une stratégie d’extraction spécifique du médicament utilisant sa pégylation
The growing number of therapeutic proteins has created needs in the field of their quantification, mainly in plasma, which is a complex protein environment. Quantitative analysis of these proteins is essential for pharmacokinetics/pharmacodynamics studies, and for the optimization of treatments. However, the nature itself of the analyte and the low concentrations that are expected in plasma complicate the quantitative analysis. The proposed methodology differs from usual methods on its universal applicability. It relies on mass spectrometry adapted to the quantification of proteins by using peptides differential isotope labelling : after enrichment and proteolysis, the therapeutic protein and the plasmatic proteins are labelled on lysine residues by the light reagent. In parallel, peptides of the pure therapeutic protein, labelled by heavy version of reagent, are used as internal standard. The ability to quantify the protein with several of its peptides improves the reliability of the analysis. When applied to epoetin beta at expected therapeutic concentrations (about 0.5 femtomole/µL of plasma), the proposed strategy leads to a quantification limit close to 50 attomoles of epoetin beta/µL plasma, with a nano-LC-ESI-Q-TRAP mass spectrometry methodology operating in MRM. To extend the universal character of this approach to the field of pegylated protein drugs, a second therapeutic protein model has been studied. This model is a pegylated interferon alfa-2b which allowed developing a strategy for specific extraction of the drug relying on its pegylation

La compréhension de la fonction des protéines et des systèmes biologiques passe par une connaissance fine des mécanismes moléculaires sous-jacents. La cristallographie et la résonance magnétique nucléaire permettent d'appréhender ces mécanismes au niveau atomique en fournissant des informations sur la structure et sur la dynamique des macromolécules biologiques. Nous nous sommes ainsi intéressés à deux protéines, la lipase lip2 de la levure Yarrowia lipolytica et la protéine membranaire OmpA de la bactérie Klebsiella pneumoniae. Nous avons recherché des conditions d'expression de la protéine lip2 marquée uniformément ou spécifiquement sur une boucle (appelée " lid ") afin d'en étudier la dynamique. Des conditions de marquage uniforme à l'azote 15 de lip2 recombinante dans Yarrowia lipolytica ont été mises au point, mais le marquage acide aminé spécifique n'a pu être réalisé à cause de phénomènes de dilution isotopique trop importants dans cette levure. Nous avons résolu par cristallographie aux rayons X la structure du domaine C-terminal de la protéine OmpA et étudié sa dynamique en solution par RMN (techniques de relaxation 15N). Nous avons caractérisé la dynamique de son domaine N-terminal membranaire reconstitué en liposomes par RMN du solide : en utilisant la rotation à l'angle magique à 60kHz et à la détection 1H sur un spectromètre 1 GHz, nous avons pu attribuer une majorité des résonances du tonneau ? et établir un profil de paramètre d'ordre des vecteurs NH. Des expériences de protéolyse ménagée ont révélé par ailleurs un site de coupure unique à la trypsine au sein de la boucle extracellulaire L3. Enfin, une première caractérisation de la protéine complète exprimée dans la membrane externe d'Escherichia coli a été entreprise par RMN du solide sur membranes externes natives
Understanding the function of proteins and biological systems requires an accurate knowledge of the underlying molecular mechanisms. Crystallography and nuclear magnetic resonance provide a detailed description of these mechanisms, with an atomic resolution, by providing data on both structures and motions. We investigated two proteins, the lip2 lipase from the yeast Yarrowia lipolytica and the membrane protein OmpA from the bacteria Klebsiella pneumoniae. We tried to produce lip2 with uniform and amino-acid specific stable isotope labelling on its functional loop (the lid) for NMR experiments. The homologous recombinant expression in Yarrowia lipolytica turned out to be the most efficient for uniform labelling but failed for specific labelling due to extensive isotope scrambling. We solved the structure of OmpA C-terminal domain by X-ray crystallography, and analyzed its dynamics in solution by NMR (15N relaxation techniques). We characterized its transmembrane N-terminal domain in proteoliposomes by solid state NMR: using state of the art ultra-fast MAS (60 kHz), 1H detection and a 1 GHz spectrometer, we could assign most ?-barrel resonances and establish a NH order parameter profile. In a complementary approach, we used proteolysis to reveal a unique trypsin cleavage site on the extracellular loop 3. Finally, a first characterization of the full-length protein expressed in the outer membrane of Escherichia coli was initiated by solid state NMR on intact outer membranes

Apres avoir montre que les racines de secheresse sont mises en place de facon endogene par une reactivation meristematique du pericycle, leur devenir cytophysiologique est suivi au cours de la phase de deshydratation. L'aptitude des racines courtes a reprendre le metabolisme des acides nucleiques et des proteines lors de la levee de la contrainte hydrique est examinee par marquage isotopique

NMR spectroscopy is offering increasing possibilities to obtain structural and dynamic information about macromolecules at atomic resolution. In recent years, it has been extended to the investigation of biological macromolecules in their physiological environment. In-cell NMR spectroscopy allows obtaining physiologically relevant structural and functional information inside living cells through the direct observation of several processes such as protein folding and interaction, metal ion binding, and drugs screening. This thesis aims to widen the application of in-cell NMR for the characterization of the structural and functional properties of proteins as well as their interactions. In a first study, we investigated the folding and the redox state of three human disulphidecontaining proteins (Mia40, Cox17, and SOD1) in the cytoplasm of human and bacterial cells. We successfully determined their redox-state distribution in isolation and with cofactors or redox partners, and found that it is controlled by specific proteins and pathways. In a second study, we employed in vitro and in-cell NMR to characterize the effect of a potential drug (ebselen) on SOD1 mutants. The results revealed that ebselen promotes the correct folding of destabilized SOD1 mutants in cells, and restores their dimerization towards the proper maturation pathway in vitro. Finally, we worked on sample preparation to increase the range of applications of in-cell NMR. On the one hand, we studied several protein systems (CytC, PFN1 and MNK6) in bacterial cells through MAS solid state NMR in order to detect intracellular soluble proteins that are not detectable with canonical experiments of solution NMR. On the other hand, we sought to expand the existing methods of solution in-cell NMR in order to study protein-protein interactions in human cells. In particular, we worked to combine DNA transfection and the delivery of an isotope-labelled recombinant protein to maximize the selectivity of protein labelling inside cells, and minimize the signals of cellular background in the NMR spectra.

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Cytochrome P450 (CYP) is one of the most important drug-metabolizing enzyme families, which participates in the biotransformation of many endogenous and exogenous compounds. Quantitative analysis of CYP expression levels is important when studying the efficacy of new drug molecules and assessing drug-drug interactions in drug development. At present, chemical probe-based assay is the most widely used approach for the evaluation of CYP activity although there are cross-reactions between the isoforms with high sequence homologies. Therefore, quantification of each isozyme is highly desired in regard to meeting the ever-increasing requirements for carrying out pharmacokinetics and personalized medicine in the academic, pharmaceutical, and clinical setting. Herein, an absolute quantification method was employed for the analysis of the seven isoforms CYP1A2, 2B6, 3A4, 3A5, 2C9, 2C19, and 2E1 using a proteome-derived approach in combination with stable isotope dilution assay. The average absolute amount measured from twelve human liver microsomes samples were 39.3, 4.3, 54.0, 4.6, 10.3, 3.0, and 9.3 (pmol/mg protein) for 1A2, 2B6, 3A4, 3A5, 2C9, 2C19, and 2E1, respectively. Importantly, the expression level of CYP3A4 showed high correlation (r = 0.943, p < 0.0001) with the functional activity, which was measured using bufalin-a highly selective chemical probe we have developed. The combination of MRM identification and analysis of the functional activity, as in the case of CYP3A4, provides a protocol which can be extended to other functional enzyme studies with wide application in pharmaceutical research.