Stable Isotope Labeling Of Amino Acids Research Articles

Exopeptidase combination enhances the degradation of isotopically labelled gluten immunogenic peptides in humans.

Celiac disease is a common autoimmune-like enteropathy caused by an aberrant response to incompletely digested dietary gluten. Gluten immunogenic peptides including the immunodominant 33-mer are thought to be resistant to proteolytic digestion by human gastrointestinal peptidases. We developed a novel enzyme therapy approach to support gluten peptide digestion using a combination of two tandem-acting exopeptidases, AMYNOPEP, that complement the intrinsic enzymatic activity of intestinal brush border enterocytes. We evaluated the effects of AMYNOPEP supplementation on 33-mer degradation in vitro and in vivo. In a cross-over clinical study, healthy volunteers with no gastrointestinal disorders were given stable isotope (SI) labelled 33-mer peptides in the presence of varying peptide substrates and caloric loads, with and without AMYNOPEP. 33-mer degradation products (SI-labelled single amino acids) were measured in the blood plasma using LC-MS/MS. AMYNOPEP achieved rapid, complete amino-to-carboxyl terminal degradation of the 33-mer in vitro, generating single amino acids and dipeptides. In healthy volunteers, AMYNOPEP supplementation significantly increased 33-mer degradation and absorption of SI-labelled amino acids even in the presence of competing substrates. Specifically, we observed a 2.8-fold increase in the Cmax of stable isotope-labelled amino acids in the presence of wheat gluten. The absorption kinetics of labelled amino acids derived from 33-mer digestion with AMYNOPEP closely resembled that of SI-labelled X-Proline dipeptides administered without enzyme supplementation, highlighting the rapid hydrolytic activity of AMYNOPEP on polypeptides. AMYNOPEP achieved complete degradation of the 33-mer into single amino acids and dipeptides in vitro and significantly improved 33-mer degradation kinetics in healthy volunteers, as measured by labelled amino acid detection, warranting further investigation into the potential therapeutic benefits of exopeptidase combinations for patients with gluten-related health disorders including celiac disease.

Quantification and interpretation of postprandial whole-body protein metabolism using stable isotope methodology: a narrative review.

Stable isotopes are routinely applied to determine the impact of factors such as aging, disease, exercise, and feeding on whole-body protein metabolism. The most common approaches to quantify whole-body protein synthesis, breakdown, and oxidation rates and net protein balance are based on the quantification of plasma amino acid kinetics. In the postabsorptive state, plasma amino acid kinetics can easily be assessed using a constant infusion of one or more stable isotope labeled amino acid tracers. In the postprandial state, there is an exogenous, dietary protein-derived amino acid flux that needs to be accounted for. To accurately quantify both endogenous as well as exogenous (protein-derived) amino acid release in the circulation, the continuous tracer infusion method should be accompanied by the ingestion of intrinsically labeled protein. However, the production of labeled protein is too expensive and labor intensive for use in more routine research studies. Alternative approaches have either assumed that 100% of exogenous amino acids are released in the circulation or applied an estimated percentage based on protein digestibility. However, such estimations can introduce large artifacts in the assessment of whole-body protein metabolism. The preferred estimation approach is based on the extrapolation of intrinsically labeled protein-derived plasma bioavailability data obtained in a similar experimental design setting. Here, we provide reference data on exogenous plasma amino acid release that can be applied to allow a more accurate routine assessment of postprandial protein metabolism. More work in this area is needed to provide a more extensive reference data set.

SILAC analysis of Escherichia coli proteome during progression of growth from exponential to prolonged stationary phase.

The expression level of individual proteins varies markedly during the progression of the growth phase in bacteria. A set of proteins was quantified in Escherichia coli total proteome during 14 days of batch cultivation using pulse stable isotope labeled amino acids in cell culture (SILAC)-based quantitative mass spectrometry.

Unraveling Antioxidative Metabolic Pathways in Multiple Myeloma: Augmenting IMiD Sensitivity through Intracellular Cysteine Biosynthesis Inhibition

Introduction Multiple myeloma (MM) patients often become unresponsive to immunomodulatory drugs (IMiDs) over time. Research has indicated that the cellular ability to counteract oxidative stress plays a crucial role in determining the sensitivity to IMiDs in MM. This study aims to comprehend the metabolic pathways responsible for MM's antioxidative capability and develop new treatments to augment the effectiveness of IMiDs. Methods We experimented using MM cells to investigate how different nutrient conditions affect cell proliferation and drug response. We utilized stable isotope-labeled amino acids and mass spectrometry to analyze the metabolites in these cells. We evaluated cell viability through the MTT assay, the CellTiter-Glo® Luminescent Assay, and direct cell counting. Furthermore, we conducted Western blots to measure the levels of various proteins expressed in MM cells grown under different nutrient conditions. To create CRBN knockout cells, we employed the CRBN CRISPR/Cas9 KO plasmid, and for the overexpression of CRBN in MM cells, we used a lentivirus system. Results Our research findings reveal that the production of cellular cysteine enhances the cell's ability to counteract oxidative damage, leading to resistance to IMiDs even with the presence of the wild-type CRBN protein. However, MM cells not producing enough cysteine rely on consuming extracellular cystine, which increases sensitivity to lenalidomide and reduces antioxidative capacity. Lenalidomide-sensitive cells acquire more cystine from the extracellular environment than resistant cells. The analysis of cysteine uptake in various MM cell lines using C13-labeled cysteine revealed that the lenalidomide-sensitive cell line, OCIMY5-CRBN, consumed more cysteine from the media, and the presence of L-glutamine further increased this uptake. Lenalidomide treatment increased the catabolism of cysteine into taurine in sensitive cell lines, confirming the link between lenalidomide's molecular action and cysteine catabolism. Our study also identified that lenalidomide treatment led to an accumulation of CDO protein, which adds molecular oxygen to cysteine, transforming it into cysteine sulfinic acid. Our study suggests that CRBN may play a role in maintaining intracellular CDO protein levels, and the accumulation of CDO protein induced by lenalidomide is the molecular factor responsible for cystine catabolism and sensitivity to IMiDs in multiple myeloma. We found that by inhibiting intracellular cysteine biosynthesis, we could improve the effectiveness of IMiD against MM. One drug that can achieve this is 5-aza-2-deoxycytidine (DAC), which acts as a DNA methylation inhibitor. Additionally, combining DAC with IMiDs improves their effectiveness, even in cell lines that are resistant to treatment. Furthermore, we attempted to inhibit cysteine biosynthesis by promoting the synthesis of methionine from homocysteine with the supplementation of 5-methyltetrahydrofolate. We discovered that treatment with 5-methyltetrahydrofolate further enhanced the sensitivity of IMiDs in resistant MM cell lines. Our results confirm that interfering with intracellular cysteine biosynthesis is a promising therapeutic approach for MM and can improve the effectiveness of IMiDs. Conclusions The biosynthesis of L-Cysteine is vital for the cellular ability to resist oxidation. Cancer cells that create high levels of cysteine within the cell from methionine generate a more significant amount of reduced cysteine, which can act as antioxidants and make MM cells resistant to IMiDs. On the other hand, cells that cannot produce enough cysteine increase their consumption of extracellular cystine and are more susceptible to IMiDs. Cells that consume an oxidized form of cystine from outside the cell require a reduction process inside the cell, which further reduces their ability to resist oxidation. Additionally, the accumulation of CDO protein induced by lenalidomide can enhance the breakdown of intracellular cysteine and cystine uptake in vulnerable cells. Overall, MM cells that rely on extracellular cysteine are sensitive to IMiDs. Therefore, interfering with intracellular cysteine biosynthesis is a better option for myeloma treatment and enhancing the sensitivity of IMiDs.

Identification of Protein Interaction Partners in Bacteria Using Affinity Purification and SILAC Quantitative Proteomics.

Affinity purification, combined with mass spectrometry (AP-MS) is considered a pivotal technique in protein-protein interaction studies enabling systematic detection at near physiological conditions. The addition of a quantitative proteomic method, like SILAC metabolic labeling, allows the elimination of non-specifically bound contaminants which greatly increases the confidence of the identified interaction partners. Compared to eukaryotic cells, the SILAC labeling of bacteria has specificities that must be considered. The protocol presented here describes the labeling of bacterial cultures with stable isotope-labeled amino acids, purification of an affinity-tagged protein, and sample preparation for MS measurement. Finally, we discuss the analysis and interpretation of MS data to identify and select the specific partners interacting with the protein of interest. As an example, this workflow is applied to the discovery of potential interaction partners of glyceraldehyde-3-phosphate dehydrogenase in the gram-negative bacterium Francisella tularensis.

Measuring muscle protein synthesis in humans and the influence of nutritional state.

In 1982 and 2011, Clinical Science published papers that used infusion of stable isotope-labeled amino acids to assess skeletal muscle protein synthesis in the fasted and fed state and before and after a period of increased intake of omega-3 fatty acids, respectively; both of these papers have been highly cited. An overview of the study designs, key findings and novel features, and a consideration of the lasting impact of these two papers is presented. The earlier paper introduced stable isotope tracer approaches in humans that showed consuming a meal will increase whole body oxidation, synthesis, and breakdown of protein, but that protein synthesis is greater than breakdown resulting in net accumulation of protein. The paper also demonstrated that consuming a meal promotes net protein synthesis in skeletal muscle. The later paper introduced the concept that omega-3 polyunsaturated fatty acids are able to improve anabolism by reporting that 8 weeks consumption of high-dose omega-3 fatty acids by healthy young and middle-aged adults increased skeletal muscle protein synthesis during a hyperaminoacidemic-hyperinsulinemic clamp compared with what was seen during the clamp at study entry. Omega-3 fatty acids also increased the phosphorylation of important signaling proteins in muscle, including mammalian target of rapamycin, p70s6k, and Akt, during the clamp. These two papers remain relevant because they offer experimental approaches to study human (patho)physiology in different contexts, they present novel insights into the impact of nutritional state (feeding) and specific nutrients (omega-3 fatty acids) on muscle protein synthesis, and they suggest ways to explore the potential of interventions to help prevent and reverse the age-, disease-, and disuse-associated decline in muscle mass.

Cardiac Myosin Filaments are Maintained by Stochastic Protein Replacement

Myosin and myosin-binding protein C are exquisitely organized into giant filamentous macromolecular complexes within cardiac muscle sarcomeres, yet these proteins must be continually replaced to maintain contractile fidelity. The overall hypothesis that myosin filament structure is dynamic and allows for the stochastic replacement of individual components was tested in vivo, using a combination of mass spectrometry– and fluorescence-based proteomic techniques. Adult mice were fed a diet that marked all newly synthesized proteins with a stable isotope-labeled amino acid. The abundance of unlabeled and labeled proteins was quantified by high-resolution mass spectrometry over an 8-week period. The rates of change in the abundance of these proteins were well described by analytical models in which protein synthesis defined stoichiometry and protein degradation was governed by the stochastic selection of individual molecules. To test whether the whole myosin filaments or the individual components were selected for replacement, cardiac muscle was chemically skinned to remove the cellular membrane and myosin filaments were solubilized with ionic solutions. The composition of the filamentous and soluble fractions was quantified by mass spectrometry, and filament depolymerization was visualized by real-time fluorescence microscopy. Myosin molecules were preferentially extracted from ends of the filaments in the presence of the ionic solutions, and there was only a slight bias in the abundance of unlabeled molecules toward the innermost region on the myosin filaments. These data demonstrate for the first time that the newly synthesized myosin and myosin-binding protein C molecules are randomly mixed into preexisting thick filaments in vivo and the rate of mixing may not be equivalent along the length of the thick filament. These data collectively support a new model of cardiac myosin filament structure, with the filaments being dynamic macromolecular assemblies that allow for replacement of their components, rather than rigid bodies.

Profiling the ubiquitinated proteome in human cells

Ubiquitination is a post‐translational modification that determines the half‐life of many cellular proteins by conjugating a chain of the small protein ubiquitin to a target protein. The ubiquitin chain is then recognized by the 26S proteasome, and subsequently, the ubiquitinated protein is degraded. This ubiquitin‐proteosome system (UPS) contains various components that function cooperatively to determine the ubiquitination status of cellular proteins that play key roles in biological events. It has become clear that mis‐regulation of protein ubiquitination can lead to diverse human diseases, and multiple UPS components have been identified as promising drug targets. To facilitate studies that define roles of the UPS components in protein ubiquitination, a method that probes the ubiquitination status of the whole proteome in human cells is necessary. Tandem ubiquitin binding entities (TUBEs) is a synthetic protein that binds poly‐ubiquitin chains with a dissociation constant in the nanomolar range. Therefore, TUBEs can recognize the poly‐ubiquitinated protein and enrich them from human cell lysate. Combining the TUBE‐dependent affinity precipitation, stable isotope labeling by amino acids in cell culture (SILAC), and mass spectrometry, we are establishing a method for quantitatively accessing the ubiquitinated proteome in human cells. To preserve the poly‐ubiquitinated protein, HEK293 cells were treated with bortezomib, a proteosome inhibitor, to prevent the ubiquitinated proteins from degradation. To perform the affinity precipitation, the recombinant TUBE was conjugated to biotin and immobilized on resin via the Streptavidin‐biotin interaction. The lysate of the bortezomib‐treated cells was incubated with the immobilized BiotinTUBE to enrich poly‐ubiquitinated proteins, which were then digested by the trypsin protease. Following the trypsin digestion, ubiquitinated proteins generated peptides with the Lys‐ɛ‐Gly‐Gly (K‐ɛ‐GG) remnant, which was further immunoprecipitated by antibodies specifically recognizing the K‐ɛ‐GG remnant and identified by mass spectrometry. To probe proteins with different ubiquitination status under different conditions, SILAC was used to grow one cell sample in normal (light) media and the other cell sample in (heavy) media containing stable isotope labeled amino acids. By comparing the abundance of the light versus heavy peptides from the same ubiquitinated protein, changes in the ubiquitination status of each detected protein can be determined. We anticipate that this method will help profile changes in the ubiquitinated proteome when the UPS components are mutated or interfered by drugs.

Untargeted Metabolomics Uncovers the Essential Lysine Transporter in Toxoplasma gondii.

Apicomplexan parasites are responsible for devastating diseases, including malaria, toxoplasmosis, and cryptosporidiosis. Current treatments are limited by emerging resistance to, as well as the high cost and toxicity of existing drugs. As obligate intracellular parasites, apicomplexans rely on the uptake of many essential metabolites from their host. Toxoplasma gondii, the causative agent of toxoplasmosis, is auxotrophic for several metabolites, including sugars (e.g., myo-inositol), amino acids (e.g., tyrosine), lipidic compounds and lipid precursors (cholesterol, choline), vitamins, cofactors (thiamine) and others. To date, only few apicomplexan metabolite transporters have been characterized and assigned a substrate. Here, we set out to investigate whether untargeted metabolomics can be used to identify the substrate of an uncharacterized transporter. Based on existing genome- and proteome-wide datasets, we have identified an essential plasma membrane transporter of the major facilitator superfamily in T. gondii—previously termed TgApiAT6-1. Using an inducible system based on RNA degradation, TgApiAT6-1 was depleted, and the mutant parasite’s metabolome was compared to that of non-depleted parasites. The most significantly reduced metabolite in parasites depleted in TgApiAT6-1 was identified as the amino acid lysine, for which T. gondii is predicted to be auxotrophic. Using stable isotope-labeled amino acids, we confirmed that TgApiAT6-1 is required for efficient lysine uptake. Our findings highlight untargeted metabolomics as a powerful tool to identify the substrate of orphan transporters.

The functional significance of ATM phosphorylation of Bub3 on Serine 135 in sensitivity to DNA damaging agents.

e15048 Background: Identification of biomarkers to assess and modify the sensitivity of cancer cells to radiotherapy and chemotherapy is critical to improve cancer treatment outcome. Budding uninhibited by benzimidazoles 3 (Bub3) is a mitotic checkpoint protein, and it is frequently overexpressed in many cancers and associated with low survival rates. Bub3 is involved in the repair of DNA damage induced by radiotherapy and chemotherapy. We recently identified that the ATM kinase phosphorylated Bub3 on Serine 135 (S135) via the stable isotope labeled amino acid in cell culture -mass spectrometry analysis. This study aims to explore the mechanism of ATM-phosphorylated Bub3 in the DNA damage response (DDR) and its effect on tumor sensitivity to DNA damaging agents. Methods: The radiosensitivity of the cells was detected by clonal formation assay, the proliferation ability of the cells was detected by the MTS assay. The expression of DDR protein γ-H2AX in the nucleus was detected by immunofluorescence assay. Genomic instability was observed by multinuclear formation. Co-immunoprecipitation and Western Blot were used to explore the internal mechanism of ATM phosphorylation of Bub3 in DDR. Results: We showed that ionizing radiation (IR) could induce Bub3 S/TQ (the specific ATM consensus motif) phosphorylation in an ATM dependent manner. Mutation of Bub3 Serine 135 to alanine (S135A) led to a phosphorylation defect. Phenotypic experiments showed hypersensitivity to IR in cells expressing Bub3 S135A. Bub3 S135A prolonged existence of γ-H2AX foci and increased the proportion of cells containing micronuclei. Further, we found that Ku70 and Ku80 showed a significant increase after IR in their interactions with Bub3, while Bub3 S135A mutation significantly reduced the interaction, leading to impaired DNA repair. Conclusions: We demonstrate that Bub3 S135 phosphorylation mediated by ATM is essential for an optimal DDR and disruption of this pathway increases tumor sensitivity to DNA damaging agents.

Basal protein synthesis rates differ between vastus lateralis and rectus abdominis muscle.

Background In vivo muscle protein synthesis rates are typically assessed by measuring the incorporation rate of stable isotope labelled amino acids in skeletal muscle tissue collected from vastus lateralis muscle. It remains to be established whether muscle protein synthesis rates in the vastus lateralis are representative of muscle protein synthesis rates of other muscle groups. We hypothesized that post‐absorptive muscle protein synthesis rates differ between vastus lateralis and rectus abdominis, pectoralis major, or temporalis muscle in vivo in humans.MethodsTwenty‐four patients (62 ± 3 years, 42% female), scheduled to undergo surgery, participated in this study and underwent primed continuous intravenous infusions with l‐[ring‐13C6]‐phenylalanine. During the surgical procedures, serum samples were collected, and muscle tissue was obtained from the vastus lateralis as well as from the rectus abdominis, pectoralis major, or temporalis muscle. Fractional mixed muscle protein synthesis rates (%/h) were assessed by measuring the incorporation of l‐[ring‐13C6]‐phenylalanine into muscle tissue protein.ResultsSerum l‐[ring‐13C6]‐phenylalanine enrichments did not change throughout the infusion period. Post‐absorptive muscle protein synthesis rates calculated based upon serum l‐[ring‐13C6]‐phenylalanine enrichments did not differ between vastus lateralis and rectus abdominis (0.032 ± 0.004 vs. 0.038 ± 0.003%/h), vastus lateralis and pectoralis major, (0.025 ± 0.003 vs. 0.022 ± 0.005%/h) or vastus lateralis and temporalis (0.047 ± 0.005 vs. 0.043 ± 0.005%/h) muscle, respectively (P > 0.05). When fractional muscle protein synthesis rates were calculated based upon tissue‐free l‐[ring‐13C6]‐phenylalanine enrichments as the preferred precursor pool, muscle protein synthesis rates were significantly higher in rectus abdominis (0.089 ± 0.008%/h) compared with vastus lateralis (0.054 ± 0.005%/h) muscle (P < 0.01). No differences were observed between fractional muscle protein synthesis rates in vastus lateralis and pectoralis major (0.046 ± 0.003 vs. 0.041 ± 0.008%/h) or vastus lateralis and temporalis (0.073 ± 0.008 vs. 0.083 ± 0.011%/h) muscle, respectively.ConclusionsPost‐absorptive muscle protein synthesis rates are higher in rectus abdominis when compared with vastus lateralis muscle. Post‐absorptive muscle protein synthesis rates do not differ between vastus lateralis and pectoralis major or temporalis muscle. Protein synthesis rates in muscle tissue samples obtained during surgery do not necessarily represent a good proxy for appendicular skeletal muscle protein synthesis rates.

Respective, Time‐dependent Phosphorylation Modules Shaping Phosphoproteome Abundance and Turnover

Protein phosphorylation mediates protein-protein interactions and alters protein structure, stability, and subcellular localization—frequently in a modification site-specific manner. However, how phosphorylation impacts protein lifetime remains to be illustrated. We have devised a proteomic method, DeltaSILAC, to quantitatively assess the influence of site-specific phosphorylation on the turnover of thousands of proteins in live cells (1). We discovered many phosphosites prolonging protein lifetime, challenging the previous notion that phosphorylation mostly accelerates protein degradation. Extending this research analyzing steady-state cells, we herein aimed to characterize how the timing and duration of phosphorylation signaling dedicate cell phenotypes. In a classic signaling system, the differential stimulation of epidermal and nerve growth factors (EGF and NGF) can determine the cell fate. Whereas EGF “transiently” stimulates the mitogen-activated protein (MAP) kinases, ERK1 and ERK2, and provokes cellular proliferation, NGF stimulation induces “sustained” activation of MAPKs and cell differentiation. Herein, we applied both DeltaSILAC and label-free phosphoproteomics. We developed DeltaSILAC with a pulse labeling using stable isotope-labeled amino acids in cells (pSILAC) accompanying the EGF and NGF stimulations on PC12 cells. Our time-course design embraced both short- and long-term points: 0-sec, 15-sec, 30-sec, 1-min, 2-min, 5-min, 10-min, 30-min, 1-hour, 2 hour, 4-hour, 8-hour, 12-hour, 24-hour, 48-hour, and 72-hour. We also generated matching protein- and mRNA- profiles after 30 mins following stimulations, so that phosphorylation regulations can be dissected from gene expression dynamics. We utilized a novel peptide-level matching algorithm so that both abundance and lifetime can be measured and resolved for each phosphosite. By using a reproducible mass spectrometry method named data-independent acquisition (DIA-MS), collectively, we quantified 40,000 phosphopeptides and 9,000 proteins throughout the experiment, both globally recapitulated the “transient” and “sustained” patterns of EGF and NGF signaling. We discovered specific tyrosine phosphorylation as early as 15-30 seconds. Interesting EGFR phosphosites activated by NGF treatment were ascribed to P38 kinase activity. The modeling of our unique time-series datasets of long-term time points indicates that phosphosites involved in EGF/NGF signaling transduction and mRNA processing shortened the corresponding protein lifetime, whereas phosphosites in the apoptotic process stabilized protein expression. We conclude that while early phosphorylation events initiate signaling functions through phosphate-dependent transfer, the longer-lasting phosphorylation events could shape proteome stability and proteostasis in cell fate determination.1. C. Wu et al., Global and Site-Specific Effect of Phosphorylation on Protein Turnover . Developmental cell 10.1016/j.devcel.2020.10.025 (2020).

Comprehensive assessment of post-prandial protein handling by the application of intrinsically labelled protein in vivo in human subjects.

All human tissues are in a constant state of remodelling, regulated by the balance between tissue protein synthesis and breakdown rates. It has been well-established that protein ingestion stimulates skeletal muscle and whole-body protein synthesis. Stable isotope-labelled amino acid methodologies are commonly applied to assess the various aspects of protein metabolism in vivo in human subjects. However, to achieve a more comprehensive assessment of post-prandial protein handling in vivo in human subjects, intravenous stable isotope-labelled amino acid infusions can be combined with the ingestion of intrinsically labelled protein and the collection of blood and muscle tissue samples. The combined application of ingesting intrinsically labelled protein with continuous intravenous stable isotope-labelled amino acid infusion allows the simultaneous assessment of protein digestion and amino acid absorption kinetics (e.g. release of dietary protein-derived amino acids into the circulation), whole-body protein metabolism (whole-body protein synthesis, breakdown and oxidation rates and net protein balance) and skeletal muscle metabolism (muscle protein fractional synthesis rates and dietary protein-derived amino acid incorporation into muscle protein). The purpose of this review is to provide an overview of the various aspects of post-prandial protein handling and metabolism with a focus on insights obtained from studies that have applied intrinsically labelled protein under a variety of conditions in different populations.

Quantitative proteomics of epigenetic histone modifications in MCF-7 cells under estradiol stimulation.

Estrogen exposure has already been considered to be associated with tumorigenesis and breast cancer progression. To study the epigenetic regulation mechanism in MCF-7 cells under estrogen exposure, which normally results in cell proliferation and malignancy, a stable isotope labeling of amino acid (SILAC) based quantitative proteomics strategy was used to analyse histone post-translational modifications (PTMs) and protein differential expressions. In total, we have unambiguously identified 49 histone variants and quantified 42 of them, in which two differentially expressed proteins were found to be associated with breast cancers. Through the quantitative analysis of 470 histone peptides with a combination of different PTM types, including methylation (mono-, di-, and tri-), acetylation and phosphorylation, 150 of them were found to be differentially expressed. Through the biological analysis of the quantification results of both histone PTMs and proteins in MCF-7 cells, we found that (1) the histone variants H10 and H2AV have an effect on the adjustment of the nucleosome or chromatin structure and activate target genes; (2) after estrogen receptor (ER) activation by estrogen, the recruitment of histone acetyltransferase KAT7 might affect the acetylation at the N terminal of H4 (K5, K8 and K12) and also result in cross-talk between different acetylation sites; (3) different expression of histone deacetylase HDAC2 and its nucleo-cytoplasmic transportation process is important in the regulation of histone acetylation in MCF-7 cells under estrogen exposure.

Stable Isotope Labeling of Amino Acids in Flies (SILAF) Reveals Differential Phosphorylation of Mitochondrial Proteins Upon Loss of OXPHOS Subunits

Drosophila melanogaster has been a workhorse of genetics and cell biology for more than a century. However, proteomic-based methods have been limited due to the complexity and dynamic range of the fly proteome and the lack of efficient labeling methods. Here, we advanced a chemically defined food source into direct stable-isotope labeling of amino acids in flies (SILAF). It allows for the rapid and cost-efficient generation of a large number of larvae or flies, with full incorporation of lysine-[13C6] after six labeling days. SILAF followed by fractionation and enrichment gave proteomic insights at a depth of 7196 proteins and 8451 phosphorylation sites, which substantiated metabolic regulation on enzymatic level. We applied SILAF to quantify the mitochondrial phosphoproteome of an early-stage leucine-rich PPR motif-containing protein (LRPPRC)-knockdown fly model of mitochondrial disease that almost exclusively affects protein levels of the oxidative phosphorylation (OXPHOS) system. While the mitochondrial compartment was hypo-phosphorylated, two conserved phosphosites on OXPHOS subunits NDUFB10 and NDUFA4 were significantly upregulated upon impaired OXPHOS function. The ease and versatility of the method actuate the fruit fly as an appealing model in proteomic and posttranslational modification studies, and it enlarges potential metabolic applications based on heavy amino acid diets.

The Effect of Interferons on Presentation of Defective Ribosomal Products as HLA Peptides

A subset of class I major histocompatibility complex (MHC)-bound peptides is produced from immature proteins that are rapidly degraded after synthesis. These defective ribosomal products (DRiPs) have been implicated in early alert of the immune system about impending infections. Interferons are important cytokines, produced in response to viral infection, that modulate cellular metabolism and gene expression patterns, increase the presentation of MHC molecules, and induce rapid degradation of proteins and cell-surface presentation of their derived MHC peptides, thereby contributing to the battle against pathogen infections. This study evaluated the role of interferons in the induction of rapid degradation of DRiPs to modulate the repertoire of DRiP-derived MHC peptides. Cultured human breast cancer cells were treated with interferons, and the rates of synthesis and degradation of cellular protein and their degradation products were determined by LC-MS/MS analysis, following the rates of incorporation of heavy stable isotope–labeled amino acids (dynamic stable isotope labeling by amino acids in cell culture, dynamic SILAC) at several time points after the interferon application. Large numbers of MHC peptides that incorporated the heavy amino acids faster than their source proteins indicated that DRiP peptides were abundant in the MHC peptidome; interferon treatment increased by about twofold their relative proportions in the peptidome. Such typical DRiP-derived MHC peptides were from the surplus subunits of the proteasome and ribosome, which are degraded because of the transition to immunoproteasomes and a new composition of ribosomes incorporating protein subunits that are induced by the interferon. We conclude that degradation of surplus subunits induced by the interferon is a major source for DRiP–MHC peptides, a phenomenon relevant to coping with viral infections, where a rapid presentation of MHC peptides derived from excess viral proteins may help alert the immune system about the impending infection.

Quantitative Proteomics in Drosophila with Holidic Stable-Isotope Labeling of Amino Acids in Fruit Flies (SILAF).

Protein-focused research has been challenging in Drosophila melanogaster due to few specific antibodies for Western blotting and the lack of effective labeling methods for quantitative proteomics. Herein, we describe the preparation of a holidic medium that allows stable-isotope labeling of amino acids in fruit flies (SILAF). Furthermore, in this chapter, we provide a protocol for mitochondrial enrichments from Drosophila larvae and flies together with a procedure to generate high-quality peptides for further analysis by mass spectrometry. Samples obtained following this protocol can be used for various functional studies such as comprehensive proteome profiling or quantitative analysis of posttranslational modifications upon enrichment. SILAF is based on standard fly routines in a basic wet lab environment and provides a flexible and cost-effective tool for quantitative protein expression analysis.

Global and Site-Specific Effect of Phosphorylation on Protein Turnover.

To date, the effects of specific modification types and sites on protein lifetime have not been systematically illustrated. Here, we describe a proteomic method, DeltaSILAC, to quantitatively assess the impact of site-specific phosphorylation on the turnover of thousands of proteins in live cells. Based on the accurate and reproducible mass spectrometry-based method, a pulse labeling approach using stable isotope-labeled amino acids in cells (pSILAC), phosphoproteomics, and a unique peptide-level matching strategy, our DeltaSILAC profiling revealed a global, unexpected delaying effect of many phosphosites on protein turnover. We further found that phosphorylated sites accelerating protein turnover are functionally selected for cell fitness, enriched in Cyclin-dependent kinase substrates, and evolutionarily conserved, whereas the glutamic acids surrounding phosphosites significantly delay protein turnover. Our method represents a generalizable approach and provides a rich resource for prioritizing the effects of phosphorylation sites on protein lifetime in the context of cell signaling and disease biology.

Quantitative nascent proteome profiling by dual-pulse labelling with O-propargyl-puromycin and stable isotope-labelled amino acids.

Monitoring translational regulation in response to environmental signals is crucial for understanding cellular proteostasis. However, only limited approaches are currently available for quantifying acute changes in protein synthesis induced by stimuli. Recently, a clickable puromycin analogue, O-propargyl-puromycin (OPP), was developed and applied to label the C-termini of nascent polypeptide chains (NPCs). Following affinity purification via a click reaction, OPP allows for a proteomic analysis of NPCs. Despite its advantage, the affinity purification of NPCs using magnetic beads or resins inherently suffers from significant non-specific protein binding, which hinders accurate quantification of the nascent proteins. To address this issue, we employed dual-pulse labelling of NPCs with both OPP and stable isotope-labelled amino acids to distinguish bona fide NPCs from non-specific proteins, thereby enabling the accurate quantitative profiling of NPCs. We applied this method to dissecting translation responses upon transcriptional inhibition and quantified ∼3,000 nascent proteins. We found that the translation of a subset of ribosomal proteins (e.g. RPSA, RPLP0) as well as signalling proteins (e.g. BCAR3, EFNA1, DUSP1) was significantly repressed by transcription inhibition. Together, the present method provides an accurate and broadly applicable nascent proteome profiling for many biological applications at the level of translation.

A novel mass spectrometry method for the absolute quantification of several cytochrome P450 and uridine 5'-diphospho-glucuronosyltransferase enzymes in the human liver.

Cytochrome P450 (CYP450) and 5'-diphosphate glucuronosyltransferases (UGT) are the two major families of drug-metabolizing enzymes in the human liver microsome (HLM). As a result of their frequent abundance fluctuation among populations, the accurate quantification of these enzymes in different individuals is important for designing patient-specific dosage regimens in the framework of precision medicine. The preparation and quantification of internal standards is an essential step for the quantitative analysis of enzymes. However, the commonly employed stable isotope labeling-based strategy (QconCAT) suffers from requiring very expensive isotopic reagents, tedious experimental procedures, and long labeling times. Furthermore, arginine-to-proline conversion during metabolic isotopic labeling compromises the quantification accuracy. Therefore, we present a new strategy that replaces stable isotope-labeled amino acids with lanthanide labeling for the preparation and quantification of QconCAT internal standard peptides, which leads to a threefold reduction in the reagent costs and a fivefold reduction in the time consumed. The absolute amount of trypsin-digested QconCAT peptides can be obtained by lanthanide labeling and inductively coupled plasma-optical emission spectrometry (ICP-OES) analysis with a high quantification accuracy (%RE < 20%). By taking advantage of the highly selective and facile ICP-OES procedure and multiplexed large-scale absolute target protein quantification using biological mass spectrometry, this strategy was successfully used for the absolute quantification of drug-metabolizing enzymes. We obtained good linearity (correlation coefficient > 0.95) over concentrations spanning 2.5 orders of magnitude with improved sensitivity (limit of quantification = 2fmol) in nine HLM samples, indicating the potential of this method for large-scale absolute target protein quantification in clinical samples. Graphical abstract.