Project description:In this labeled quantitative proteomics dataset we profile the proteomic changes in a transgenic line of 1 year old Xenopus laevis Tg(islet2bgfp) frogs that were left untreated (naive) or had a monocular surgery of either a left optic crush injury (crush) or a sham surgery. Matching controls of uninjured optic nerves were also collected for a control factor. The Tg(islet2bgfp) frogs were allowed to recover for 12 and 27 days post optic nerve crush before euthanasia and optic nerve collection. A protein extraction was carried by homogenization of the tissue in extraction buffer (TEAB, NaCl, SDS) via Precellys. During extraction, three internal peptide standards, named as Regen III, were spiked to measure extraction efficiency. Protein amounts were estimated and normalized across experimental samples. Samples were reduced using TCEP, alkylated with iodoacetamide and digested overnight with trypsin. TMT (Tandem Mass Tag) labelling was carried out using 3 sets of 13 tags from a 16plex TMT kit for quantification. The samples were fractionated into 8 fractions using Pierce High pH Reversed-Phase Peptide Fractionation Kit (Thermo Scientific). After fractionation and drying of all peptide samples, each TMT sample was spiked with two additional isobarically labelled human peptides to be used as an ionization control and cross-sample quantification standard (Regen II). The combination of Regen III and Regen II (Regen V) were used to compare and normalize against a future axon regeneration cohort. Untargeted liquid chromatography-mass spectrometry was performed on an Easy-nLC 1000 liquid chromatograph coupled to a QExactive mass spectrometer (LC-MS/MS). Data analysis was performed using Proteome Discoverer 3.0 and Graph Pad Prism 10. After animals were euthanized, optic nerves were collected by dissection. There were six experimental conditions and six biological replicates for each condition for a total of 36 nerves. Protein extraction was carried out by homogenizing the optic nerve tissue in TEAB, NaCl and SDS. Three synthetic bacterial peptide standards (Regen III) were added to the samples during the extraction to measure extraction efficiency. Each standard was spiked into samples for a total concentration of 48uM per standard. After extraction was carried out, protein amounts were estimated using dot blot densitometry and ImageJ and normalized to 50ug/ul. Samples were reduced using TCEP, alkylated with iodoacetamide and digested overnight with trypsin. Prior to labelling, three samples of mass spec grade pre-digested bovine serum albumin (BSA) were prepared at a concentration of 150pmol. These samples were included to account for differences in labelling efficiency between TMT batches. Three TMT batches were used to label the 36 experimental conditions, so three additional standards were prepared to be used for normalization. All samples, including the three BSA standards, were labelled using 3 sets of 13 tags from a 16plex TMT (Tandem Mass Tag) kit for quantification. Each BSA standard was labelled with a different tag. After combination and drying of all peptide samples, each combined TMT sample (including one BSA-labelled standard) was spiked with two additional human peptide standards containing isobaric labels (Regen II). The final concentration of Regen II was 54uM. These standards were spiked in directly before mass spectrometry analysis to be used as an ionization control. Additionally, all five standards, known as Regen V (Regen III + Regen II), serve as a normalization method that may be used to compare protein abundance data across multiple datasets. Raw mass spectrometry data files were analyzed using Proteome Discoverer 3.0. The mouse proteome was downloaded from UniProt and used as the target database for protein identification. Two additional local databases were created. One containing the Regen V internal standard peptide sequences, and the other containing BSA peptide sequences. The identification of the Regen V and BSA standards was run in a separate Proteome Discoverer workflow targeted to identify the internal standards separately from experimental proteins. Max missed cleavage site was set to 2 and minimum peptide length to 6. Precursor Mass Tolerance was set to 10ppm and Fragment Mass Tolerance to 0.02 Da. Post-translational modifications for experimental proteins included oxidation, acetylation, carbamidomethylation and TMTpro. Post translational modifications of the Regen II, (biotin, carbon-13 and nitrogen-15) were added during this step to ensure correct identification of the modified standards. The Normalization was set to total peptide amount and confidence to low.

Project description:A quantitative proteomic profiling was performed on PTEN deletion-induced optic nerve regeneration mouse models and controls. At postnatal day 28 (week 4), PTENloxP/loxP mice were subjected to intravitreal injection (2-3ul) of adeno-associated viruses expressing Cre (AAV2-Cre) or control placenta alkaline phosphatase (AAV2-PLAP). Optic Nerve crush was performed 2 weeks post AAV injections at three times points (0, 7, 14 days post injury) and collected for proteomics analysis. A protein extraction was carried out by homogenization of the tissue in extraction buffer (TEAB, NaCl and SDS). During extraction, three internal peptide standards, named as Regen III, were spiked to measure extraction efficiency. Protein amounts were estimated and normalized across experimental samples. Samples were reduced using TCEP, alkylated with iodoacetamide and digested overnight with trypsin. TMT (Tandem Mass Tag) labelling was carried out using 1 sets of 18 tags from a 18plex TMT kit for quantification. After combination and drying of all peptide samples, each TMT sample was spiked with two additional isobarically labelled human peptides to be used as an ionization control and cross-sample quantification standard (Regen II). Overall, Regen V standards (refers to a combination of Regen III and Regen II, for extraction and ionization normalization) were used to compare and normalize against any future axon regeneration sample cohort. Untargeted liquid chromatography-mass spectrometry was performed on an Easy-nLC 1000 liquid chromatograph coupled to a QExactive mass spectrometer (LC-MS/MS). Data analysis was performed using Proteome Discoverer 3.0 and Graph Pad Prism 10. After animals were euthanized, optic nerves were collected by dissection. There were 6 experimental conditions and three biological replicates for each condition for a total of 18 nerves. Protein extraction was carried out by homogenizing the optic nerve tissue in TEAB, NaCl and SDS. Three synthetic bacterial peptide standards (Regen III) were added to the samples during the extraction to measure extraction efficiency. Each standard was spiked into samples for a total concentration of 18uM per standard. After extraction was carried out, protein amounts were estimated using dot blot densitometry and ImageJ and normalized to 50ug/ul. Samples were reduced using TCEP, alkylated with iodoacetamide and digested overnight with trypsin. All samples were labelled using 1 set of 18 tags from a 18plex TMT (Tandem Mass Tag) kit for quantification. After combination and drying of all peptide samples, the samples were fractionated via Pierce High pH Reversed-Phase Peptide Fractionation Kit (Thermo Fisher). Each combined TMT sample was spiked with two additional human peptide standards containing isobaric labels (Regen II). The final concentration of Regen II was 54uM. These standards were spiked in directly before mass spectrometry analysis to be used as an ionization control. Additionally, all five standards, known as Regen V (Regen III + Regen II), serve as a normalization method that may be used to compare protein abundance data across multiple datasets. Raw mass spectrometry data files were analyzed using Proteome Discoverer 3.0. The mouse proteome was downloaded from UniProt and used as the target database for protein identification. Two additional local databases were created. One contains the Regen V internal standard peptide sequences, and the other contains BSA peptide sequences. The identification of the Regen V and BSA standards was run in a separate Proteome Discoverer workflow targeted to identify the internal standards separately from experimental proteins. Max missed cleavage site was set to 2 and minimum peptide length to 6. Precursor Mass Tolerance was set to 10ppm and Fragment Mass Tolerance to 0.02 Da. Post-translational modifications for experimental proteins included oxidation, acetylation, carbamidomethylation and TMTpro. Post translational modifications of the Regen II, (biotin, carbon-13 and nitrogen-15) were added during this step to ensure correct identification of the modified standards. The Normalization was set to total peptide amount and confidence to low.

Project description:In this labeled quantitative proteomics dataset, we profile the proteomic changes in the tectum, retina, chiasm, and optic nerve in transgenic lines of 1 year old Xenopus laevis Tg(islet2bgfp). The frogs had monocular surgery of either a left optic crush injury (crush) or sham surgery (sham) and the matching controls of uninjured optic nerves were collected as a control factor. The Tg(islet2bgfp) frogs were allowed to recover for 12 and 27 days post optic nerve crush before euthanasia and tissue collection. Protein extraction was carried by homogenization of the tissue in extraction buffer (TEAB, NaCl, SDS) via Precellys. During extraction, three internal peptide standards were spiked to measure extraction efficiency. Protein amounts were estimated and normalized across experimental samples. Samples were reduced using TCEP, alkylated with iodoacetamide and digested overnight with trypsin. TMT (Tandem Mass Tag) labelling was carried out using 6 sets of 17 tags from a 18plex TMT kit for quantification. The samples were fractionated into 9 fractions using Pierce High pH Reversed-Phase Peptide Fractionation Kit (Thermo Scientific). After fractionation and drying of all peptide samples, each TMT sample was spiked with two additional isobarically labelled peptides to be used as an ionization control and cross-sample quantification standard. The combination internal peptides were used to compare and normalize against a future axon regeneration cohort. Untargeted liquid chromatography-mass spectrometry was performed on an Easy-nLC 1000 liquid chromatograph coupled to a QExactive mass spectrometer (LC-MS/MS). Data analysis was performed using Proteome Discoverer 3.0 and Graph Pad Prism 10. After animals were euthanized, optic nerves were collected by dissection. There were six experimental conditions and six biological replicates per tissue for a total of 102 samples. Protein extraction was carried out by homogenizing the optic nerve tissue in TEAB, NaCl and SDS. Three synthetic peptide standards were added to the samples during the extraction to measure extraction efficiency. Each standard was spiked into samples for a total concentration of 48uM per standard. After extraction was carried out, protein amounts were estimated using dot blot densitometry and ImageJ and normalized to 50ug/ul. Samples were reduced using TCEP, alkylated with iodoacetamide and digested overnight with trypsin. All samples were labelled using 6 sets of 17 tags from a 18plex TMT (Tandem Mass Tag) kit for quantification. After combination and drying of all peptide samples, each combined TMT sample was spiked with two additional peptide standards containing isobaric labels. The final concentration of the post extraction peptides was 54uM per plex or 324uM for all six plex's. These standards were spiked in directly before mass spectrometry analysis to be used as an ionization control. Additionally, all five standards serve as a normalization method that may be used to compare protein abundance data across multiple datasets. Raw mass spectrometry data files were analyzed using Proteome Discoverer 3.0. The frog proteome was downloaded from UniProt and used as the target database for protein identification. Max missed cleavage site was set to 2 and minimum peptide length to 6. Precursor Mass Tolerance was set to 10ppm and Fragment Mass Tolerance to 0.02 Da. Post-translational modifications for experimental proteins included oxidation, acetylation, carbamidomethylation and TMTpro. The Normalization was set to total peptide amount and confidence to low.

Project description:To demonstrate the usability of our SIL peptides (JPT GmbH)on an MS application, 4 standard peptides were synthesized at 95% purity and each spiked at an amount 133 fmol into protein extracts of wild type HEK cells and EZH2-knockout cells, respectively. The spiked peptides in this experiment are histone H3 K27-containing heavy-arginine versions of the peptide ARKSAPATGGVKKPH-R, where K27 was synthetically modified to carry either no methylation, or one or two or three (me3) methyl groups, respectively. Previously to trypsination, the HEK samples were spiked with the 4 SIL peptides. Because the standards have 10 Da greater mass given by the heavy R*, they can be distinguished from their light natural versions in the MS1 spectra. Furthermore, the standards were each spiked at a concentration of 133 fmol and thus, their MS intensities were used to normalize the intensities of the endogenous peptides and quantify them in absolute terms.

Project description:This labeled quantitative proteomics dataset was collected from a transgenic channel rhodopsin mouse model (Chr2) subjected to light stimulation after traumatic optic nerve crush (ONC) was performed. Mouse models expressing channel rhodopsin were subjected to therapeutic light stimulation promoting axon regeneration of retinal ganglion cell (RGC) axons post optic nerve crush. Experimental mice and wild type control mice were euthanized, and optic nerves were collected. A protein extraction was carried out by careful mincing of the tissue in extraction buffer (TEAB, NaCl and SDS). Protein amount normalization across samples was achieved using dot blot densitometry using ImageJ software. Samples were labelled using a modified 16plex TMT (Tandem Mass Tag) kit for quantification after overnight trypsin digestion. Untargeted liquid chromatography-mass spectrometry was performed on an Easy-nLC 1000 liquid chromatograph coupled to a QExactive mass spectrometer (LC-MS/MS). Data analysis was performed using Proteome Discoverer 2.5.

Project description:Here we present quantitative proteomics data used in the evaluation of quantitative accuracy. A human cell line, MCF7 was split into 9 aliquotes that were spiked with a dilution series of 57 protein standards of known amounts spanning 5 orders of magnitude. The protein extracts were trypsinized, and the peptides were analysed by LC-MS using either a label-free or a label-based (TMT 6-plex and iTRAQ 8-plex) quantification approach. The iTRAQ- and TMT-labelled samples were co-analysed and separated by HiRIEF (high resolution isoelectric focusing) prior LC-MS. Raw MS data was identified and quantified under the software platform Proteome Discoverer 1.3.0.339 (Thermo Fisher Scientific Inc.) or MaxQuant software (version 1.2.0.18) (label-free data). For both protein identification and quantification at least 1 unique (i.e. a peptide that occurs in not more than one database entry) peptide was required. The false discovery rate (FDR) for peptide identification was set to 5% in all analyses. For the iTRAQ and TMT labeled samples, all MS/MS spectra were searched by SEQUEST combined with the Percolator algorithm (version 2.0) for PSM search optimization. Searches were performed against a custom made database consisting of SwissProt human sequences(uniprot.org 2012-01-17, 20242 entries), and the spiked in protein standards (57 protein sequences). Peptide FDR was calculated by a target – decoy approach.

Project description:To test our peak detection and label-free quantitation algorithm, practical applications of AB3D for LC-MS data sets were evaluated using a standard peptide mixture consisting of bovine serum albumin (BSA) peptides with different concentrations, peptides derived from four standard proteins (data set 1), and complex peptide samples derived from HeLa cells and BSA (data set 2).

Project description:Isobaric peptide termini labeling (IPTL) is an attractive protein quantification method, because it provides more accurate and reliable quantification information than traditional isobaric labelling methods (TMT, iTRAQ) by making use of the entire fragment ion series instead of only a single reporter ion. The multiplexing capacity of published IPTL implementations is, however, limited to three. Here, we present a selective maleylation-directed isobaric peptide termini labelling (SMD-IPTL) approach for quantitative proteomics of LysC protein digests. SMD-IPTL extends the multiplexing capacity to 4-plex with the potential for higher levels of multiplexing using commercially available 13C/15N-labelled amino acids. SMD-IPTL is achieved in a one-pot reaction in three consecutive steps: 1) selective maleylation at the N-terminus; 2) labelling at the ԑ-NH2 group of the C-terminal Lys with isotopically labelled acetyl alanine; 3) thiol Michael addition of an isotopically labelled acetyl cysteine at the maleylated N-terminus. The isobarically labelled peptides are fragmented into sets of b- and y-ion clusters upon LC-MS/MS, which not only convey sequence information but also quantitative information for every labelling channel and avoid the issue of ratio distortion observed with reporter-ion-based approaches. We demonstrate the SMD-IPTL approach with a 4-plex labelled sample of BSA and yeast lysates mixed at different ratios. Utilizing SMD-IPTL for labelling and a narrow precursor isolation window of 0.8 Th with an offset of -0.2 Th, accurate ratios were measured across a 10-fold mixing range of BSA in a background of yeast proteome. With the yeast proteins mixed at ratios of 1:5:1:5, BSA was detected at ratios 0.94:2.46:4.70:9.92 when spiked at 1:2:5:10 ratios with an average standard deviation of peptide ratios of 0.34.

Project description:Quantifying proteins based on peptide-coupled reporter-ions is a leading multiplexed quantitative strategy in proteomics that significantly alleviates the problem of ratio distortion caused by peptide co-fragmentation, as commonly observed in other reporter-ion based approaches, such as TMT and iTRAQ. Fueled by improvements in mass spectrometry and data processing, data-independent acquisition (DIA) is an attractive alternative to data dependent acquisition (DDA) due to its better reproducibility. While multiplexed labeling is widely used in DDA, it is rarely used in DIA, presumably because current approaches lead to more complex MS2 spectra or to a reduction in quantification accuracy and precision. Herein, we present a versatile acetyl-alanine-glycine (Ac-AG) tag which conceals quantitative information in isobarically labeled peptides and reveals it upon tandem MS in the form of peptide-coupled reporter-ions. Since the peptide-coupled reporter-ion is precursor-specific while fragment ions of the peptide backbone originating from different labeling channels are same, the Ac-AG tag is compatible with both the widely adopted DDA as well as with the DIA mode. By isolating the monoisotopic peak of the precursor ion in DDA, intensities of the peptide-coupled reporter-ions simply represent the relative ratios between constituent samples. While in DIA, the ratio can be inferred after deconvoluting peptide-coupled reporter-ions. The proteome quantification capability of the Ac-AG tag was demonstrated by triplex labeling of a yeast proteome spiked with bovine serum albumin (BSA) over a 10-fold dynamic range. Within a complex proteomics background, the BSA spiked at 1:5:10 ratios was detected at ratios of 1.00 : 4.87 : 10.13 in DDA and 1.16 : 5.20 : 9.64 in DIA.

Project description:We used whole mouse genome microarrays to the effects of γ-TmT on global gene expression in the prostate TRAMP and age-matched C57BL/6 mice were administered either 600 mg/kg of γ-TmT or a control vehicle via oral gavage. Twelve hours after dosing, prostate tissues were collected for RNA extraction.