Project description:Mitochondria are known to be functional organelles, but their role as a signaling unit is increasingly being appreciated. The recent identification of a short open reading frame (sORF) in the mitochondrial DNA (mtDNA) that encodes a signaling peptide, humanin, suggests the possible existence of additional sORFs in the mtDNA that yield bioactive peptides. Here we report the identification of a sORF within the mitochondrial 12S rRNA encoding a 16-amino-acid peptide named MOTS-c (mitochondrial open-reading-frame of the twelve S rRNA -c) that regulates insulin sensitivity and metabolic homeostasis. MOTS-c is detected in various tissues and in circulation in an age-dependent manner. Its primary target organ appears to be the skeletal muscle and its cellular actions inhibit the folate cycle and its tethered de novo purine biosynthesis, causing a significant accumulation of AICAR levels concomitantly with AMPK activation. MOTS-c treatment in mice prevented age-dependent and high-fat diet-induced insulin resistance, as well as diet-induced obesity. These results suggest that mitochondria may be more actively engaged in regulating metabolic homeostasis than previously recognized, through the production of peptides encoded within its genome that act at the cellular and organismal level. Human embryonic kidney cells (HEK293 cell line) were cultured in 10-cm dishes in 7 mL of phenol-free DMEM supplemented with 10% FBS and incubated with water (controls) or the 16-amino-acid peptide mitochondrial open-reading-frame of the twelve S rRNA-c (MOTS-c, 10 uM) for 4 or 72 hours prior to RNA extraction.

Project description:A computer program was used to create random amino acid sequences based on and restricted by physical shadow masks which will be used for lithography-based synthesis of peptides. The output from this algorithm was used to create peptides that were synthesized by Sigma Aldrich, and printed onto glass slides. The arrays contained 384 peptides printed in duplicate for each of 4 different mask designs. 52 different monoclonal antibodies were incubated on these microarrays and analyzed for their propensity to bind the peptides created from each mask set. The diversity of binding served as a proxy for the 'randomness' of these peptides, and provided information about how many masks are needed to truly generate random sequence peptides. two replicates of each peptide was printed on 1 Mask peptide microarray. A minimum of Two microarrays were tested for each sample. Image was qualified using in-house metrics for quality assurance.

Project description:Mononucleotide A and T repeats are abundant in human genome. Many of A repeats are bound by Argonaute proteins (AGOs). To evaluate the role of AGOs and A repeats in gene regulation, HEK293 cells were treated with 8-amino-3,6-dioxaoctanoic acid added peptide nucleic acid (PNA) AAAAAAAAAAAAAAA oligo (OO-A(15)).

Project description:Small peptides with amino acid sequences similar to native skin proteins can beneficially affect clinical appearance (wrinkles) and architecture (collagen and elastic fibre deposition and epidermal thickness). However, the discovery of new cosmetic peptides has not been underpinned by any guiding hypothesis. As endogenous extracellular matrix (ECM)-derived peptides (matrikines) produced during tissue remodelling can influence cell activity, we hypothesised that protease cleavage site prediction can identify putative novel matrikines. This RNA-seq data is the in vivo test part of an in silico to in vivo discovery pipeline, which enables the prediction and characterisation of peptide matrikines with therapeutic potential. We use this pipeline to identify two novel ECM peptides (GPKG and LSVD) which, in combination, act in vitro to enhance the transcription of ECM organisation and cell proliferation genes and in vivo to promote epithelial and dermal remodelling. This pipeline approach can both identify new matrikines and provide insights into the mechanisms underpinning tissue repair.

Project description:Small peptides with amino acid sequences similar to native skin proteins can beneficially affect clinical appearance (wrinkles) and architecture (collagen and elastic fibre deposition and epidermal thickness). However, the discovery of new cosmetic peptides has not been underpinned by any guiding hypothesis. As endogenous extracellular matrix (ECM)-derived peptides (matrikines) produced during tissue remodelling can influence cell activity, we hypothesised that protease cleavage site prediction can identify putative novel matrikines. This RNA-seq data is the in vitro testing part of an in silico to in vivo discovery pipeline, which enables the prediction and characterisation of peptide matrikines with therapeutic potential. We use this pipeline to identify two novel ECM peptides (GPKG and LSVD) which, in combination, act in vitro to enhance the transcription of ECM organisation and cell proliferation genes and in vivo to promote epithelial and dermal remodelling. This pipeline approach can both identify new matrikines and provide insights into the mechanisms underpinning tissue repair.

Project description:Small peptides with amino acid sequences similar to native skin proteins can beneficially affect clinical appearance (wrinkles) and architecture (collagen and elastic fibre deposition and epidermal thickness). However, the discovery of new cosmetic peptides has not been underpinned by any guiding hypothesis. As endogenous extracellular matrix (ECM)-derived peptides (matrikines) produced during tissue remodelling can influence cell activity, we hypothesised that protease cleavage site prediction can identify putative novel matrikines. This RNA-seq data is the in vitro testing part of an in silico to in vivo discovery pipeline, which enables the prediction and characterisation of peptide matrikines with therapeutic potential. We use this pipeline to identify two novel ECM peptides (GPKG and LSVD) which, in combination, act in vitro to enhance the transcription of ECM organisation and cell proliferation genes and in vivo to promote epithelial and dermal remodelling. This pipeline approach can both identify new matrikines and provide insights into the mechanisms underpinning tissue repair.

Project description:Display technologies, e.g., phage, ribosome, mRNA, bacterial, and yeast-display, combine high content peptide libraries with appropriate screening strategies to identify functional peptide sequences. Construction of large peptide library and display-screen system in intact mammalian cells will facilitate the development of peptide therapeutics targeting transmembrane proteins. Our previous work established linear-double-stranded DNAs (ldsDNAs) as innovative biological parts to implement AND gate genetic circuits in mammalian cell line. In the current study, we employ ldsDNA with terminal NNK degenerate codons as AND gate input to build highly diverse peptide library in mammalian cells. Only PCR reaction and cell transfection experiments are needed to construct the library. High-throughput sequencing (HTS) results reveal that our new strategy could generate peptide library with both amino acid sequence and peptide length diversities. Our work establishes ldsDNA as biological parts for building highly diverse peptide library in mammalian cells, which shows great application potential in developing therapeutic peptides targeting transmembrane proteins.

Project description:We investigated the transcriptome profile of HEK293T cells transfected with a plasmid encoding 9J10, a peptide isolated in a phenotypic screen from a library of peptides derived from bacterial and archaeal genomes. The peptide was identified in a screen for FOXO3a reactivation and has been shown to interact with 14-3-3 proteins and induce relocalisation of FOXO3a from the cytoplasm to the nucleus. A peptide with a single amino acid mutation does not interact with 14-3-3 and was included as a control. A constitutively active FOXO3a mutant was also included as a control.

Project description:Protein samples were analyzed by Multidimensional Protein Identification Technology (MudPIT), as described previously. Briefly, precipitated proteins were resuspended in 30uL of 100mM Tris pH 8.5 with 8M urea to denature proteins. Cysteines were reduced and alkylated prior to digestion with recombinant LysC and modified trypsin. Reactions were quenched by the addition of formic acid to the final concentration of 5%. After digestion, peptide samples were pressure-loaded onto 100 um fused silica microcapillary columns packed first with 9 cm of reverse phase material, followed by 3 cm of 5um Strong Cation Exchange material, followed by 1 cm of 5um C18 RP. The loaded microcapillary columns were placed in-line with a 1260 Quartenary HPLC. The application of a 2.5 kV distal voltage electrosprayed the eluting peptides directly into Elite orbi-trap mass spectrometers equipped with a custom-made nano-LC electrospray ionization source. Full MS spectra were recorded on the eluting peptides over a 400 to 1600 m/z range at 60,000 resolution, followed by fragmentation in the ion trap on the first to 15th most intense ions selected from the full MS spectrum. Dynamic exclusion was enabled for 90 s. Mass spectrometer scan functions and HPLC solvent gradients were controlled by the XCalibur data system. RAW files were extracted into .ms2 file format using RawDistiller v. 1.0, in-house developed software. RawDistiller D(g, 6) settings were used to abstract MS1 scan profiles by Gaussian fitting and to implement dynamic offline lock mass using six background polydimethylcyclosiloxane ions as internal calibrants. MS/MS spectra were first searched using ProLuCID with a mass tolerance of 10 ppm for peptide and fragment ions. Trypsin specificity was imposed on both ends of candidate peptides during the search against a protein database. Human protein database contained 81592 human proteins (NCBI 2020-11-23 release), as well as 426 common contaminants such as human keratins, IgGs and proteolytic enzymes. C. elegans protein data base included 28,127 C. elegans proteins (NCBI 2020-05-30 release), as well as 426 common contaminants. To estimate false discovery rates (FDR), each protein sequence was randomized (keeping the same amino acid composition and length) and the resulting "shuffled" sequences were added to the database, for a total search space of 163,860 amino acid sequence for human datasets and 57,106 amino acid sequences for C. elegans datasets. Masses of 57.0215 Da was differentially added to cysteine residues to account for alkylation by CAM and 15.9949 Da were differentially added to methionine residues. DTASelect v.1.9 was used to select and sort peptide/spectrum matches (PSMs) passing the following criteria set: PSMs were only retained if they had a DeltCn of at least 0.08; minimum XCorr values of 1.8 for singly-, 2.1 for doubly-, and 2.5 for triply-charged spectra; peptides had to be at least 7 amino acids long. Results from each sample were merged and compared using CONTRAST. Combining all replicate runs, proteins had to be detected by at least 2 peptides and/or 2 spectral counts. Proteins that were subsets of others were removed using the parsimony option in DTASelect on the proteins detected after merging all runs. Proteins that were identified by the same set of peptides (including at least one peptide unique to such protein group to distinguish between isoforms) were grouped together, and one accession number was arbitrarily considered as representative of each protein group. NSAF7 was used to create the final reports on all detected peptides and non-redundant proteins identified across the different run

Project description:Protein samples were analyzed by Multidimensional Protein Identification Technology (MudPIT), as described previously. Briefly, precipitated proteins were resuspended in 30uL of 100mM Tris pH 8.5 with 8M urea to denature proteins. Cysteines were reduced and alkylated prior to digestion with recombinant LysC and modified trypsin. Reactions were quenched by the addition of formic acid to the final concentration of 5%. After digestion, peptide samples were pressure-loaded onto 100 um fused silica microcapillary columns packed first with 9 cm of reverse phase material, followed by 3 cm of 5um Strong Cation Exchange material, followed by 1 cm of 5um C18 RP. The loaded microcapillary columns were placed in-line with a 1260 Quartenary HPLC. The application of a 2.5 kV distal voltage electrosprayed the eluting peptides directly into orbitrap Elite mass spectrometers equipped with a custom-made nano-LC electrospray ionization source. Full MS spectra were recorded on the eluting peptides over a 400 to 1600 m/z range, followed by fragmentation in the ion trap on the first to fifth most intense ions selected from the full MS spectrum. Dynamic exclusion was enabled for 90 s. Mass spectrometer scan functions and HPLC solvent gradients were controlled by the XCalibur data system. RAW files were extracted into .ms2 file format using RawDistiller v. 1.0, in-house developed software. RawDistiller D(g, 6) settings were used to abstract MS1 scan profiles by Gaussian fitting and to implement dynamic offline lock mass using six background polydimethylcyclosiloxane ions as internal calibrants. MS/MS spectra were first searched using ProLuCID with a mass tolerance of 10 ppm for peptide and fragment ions. Trypsin specificity was imposed on both ends of candidate peptides during the search against a protein database containing 90240 human proteins (NCBI 2021-11-23 release) and 8311 Toxoplasma gondii proteins (NCBI 2021-11-05) , as well as 426 common contaminants such as human keratins, IgGs and proteolytic enzymes. To estimate false discovery rates (FDR), each protein sequence was randomized (keeping the same amino acid composition and length) and the resulting "shuffled" sequences were added to the database, for a total search space of 180482 amino acid sequences. Masses of 57.0215 Da was differentially added to cysteine residues to account for alkylation by CAM and 15.9949 Da were differentially added to methionine residues. DTASelect v.1.9 was used to select and sort peptide/spectrum matches (PSMs) passing the following criteria set: PSMs were only retained if they had a DeltCn of at least 0.08; minimum XCorr values of 1.8 for singly-, 2.1 for doubly-, and 2.5 for triply-charged spectra; peptides had to be at least 7 amino acids long. Results from each sample were merged and compared using CONTRAST. Combining all replicate runs, proteins had to be detected by at least 2 peptides and/or 2 spectral counts. Proteins that were subsets of others were removed using the parsimony option in DTASelect on the proteins detected after merging all runs. Proteins that were identified by the same set of peptides (including at least one peptide unique to such protein group to distinguish between isoforms) were grouped together, and one accession number was arbitrarily considered as representative of each protein group. NSAF7 was used to create the final reports on all detected peptides and non-redundant proteins identified across the different run.