Project description:Determining which proteins are actively synthesised at a given point in time and being able to extract them for analysis is important to understanding plant responses to environmental or developmental stimuli, but there are few verified experimental tools to do this directly or quantitatively. In-vivo labelling with stable isotope labelled salts or amino acids allow the measurement of the synthesis rates of different proteins. However, they do not allow enrichment of newly synthesised proteins, which could increase sensitivity and would enable biochemical features of nascent protein sets to be studied and evaluated in isolation. Here we show that using the methionine (Met) analogue homopropargylglycine (HPG) enables BONCAT (Bio-Orthogonal Non-Canonical Amino acid Tagging) of proteins that are being synthesised in Arabidopsis plants or cell cultures, facilitating their enrichment for analysis using commercially-available click-chemistry kits. Importantly, the sites of HPG incorporation could be confirmed by peptide mass spectrometry at Met-sites throughout the amino acid sequence of proteins and correlation with independent studies of protein labelling with 15N verified the data. We provide evidence that HPG-based BONCAT tags nascent plant proteins in a superior manner to azidohomoalinine (AHA)-based BONCAT in Arabidopsis and show that AHA’s induction of Met metabolism and greater inhibition of cell growth rate than HPG likely limits AHA incorporation at Met sites in Arabidopsis. HPG-based BONCAT provides a verifiable method for determining which plant proteins are being synthesised at a given time point and enriches new protein molecules from the bulk protein pool for identification, quantitation and subsequent biochemical analysis.

Project description:Direct measurement of nucleosome turnover dynamics by using co-translational incorporation of the methionine (Met) surrogate azidohomoalaine (Aha) into proteins and subsequent ligation of biotin to Aha-containing proteins through the [3+2] cycloaddition reaction between the azide group of Aha and an alkyne linked to biotin. To measure turnover rates, we treat cells briefly with Aha, couple biotin to nucleosomes containing newly incorporated histones, affinity purify with strepavidin, wash stringently to remove non-histone proteins and H2A/H2B dimers, and analyze the affinity-purified DNA using tiling microarrays. We call this strategy 'CATCH-IT' for Covalent Attachment of Tags to Capture Histones and Identify Turnover. Keywords: Chromatin affinity-purification on microarray

Project description:In this study, we explored the use of BONCAT in Synechococcus sp. – a globally important cyanobacteria. We characterized the growth and microscopically quantified HPG uptake under a range of HPG concentrations in marine Synechococcus sp. Further, we examined changes in protein expression of Synechococcus sp. grown under normal and nitrate-stressed conditions relative to a non-HPG control.

Project description:Neural plasticity requires protein synthesis, but the identity of newly synthesized proteins generated in response to plasticity-inducing stimuli remains unclear. We used in vivo bio-orthogonal noncanonical amino acid tagging (BONCAT) with the methionine analog azidohomoalanine (AHA) combined with the multidimensional protein identification technique (MudPIT) to identify proteins that are synthesized in the tadpole brain over 24 hr. We induced conditioning-dependent plasticity of visual avoidance behavior, which required N-methyl-D-aspartate (NMDA) and Ca(2+)-permeable alpha-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors, alphaCaMKII, and rapid protein synthesis. Combining BONCAT with western blots revealed that proteins including alphaCaMKII, MEK1, CPEB, and GAD65 are synthesized during conditioning. Acute synthesis of CPEB during conditioning is required for behavioral plasticity as well as conditioning-induced synaptic and structural plasticity in the tectal circuit. We outline a signaling pathway that regulates protein-synthesis-dependent behavioral plasticity in intact animals, identify newly synthesized proteins induced by visual experience, and demonstrate a requirement for acute synthesis of CPEB in plasticity.

Project description:Direct measurement of nucleosome turnover dynamics by using co-translational incorporation of the methionine (Met) surrogate azidohomoalaine (Aha) into proteins and subsequent ligation of biotin to Aha-containing proteins through the [3+2] cycloaddition reaction between the azide group of Aha and an alkyne linked to biotin. To measure turnover rates, we treat cells briefly with Aha, couple biotin to nucleosomes containing newly incorporated histones, affinity purify with strepavidin, wash stringently to remove non-histone proteins and H2A/H2B dimers, and analyze the affinity-purified DNA using tiling microarrays. We call this strategy 'CATCH-IT' for Covalent Attachment of Tags to Capture Histones and Identify Turnover. Keywords: Chromatin affinity-purification on microarray All experiments were done using strepavidin pulldown DNA cohybridized with total input DNA to the same array. Two channels per array, Cy5 and Cy3, were used in each experiment.

Project description:Protein synthesis underpins many biological processes, yet tracking time-dependent proteomic changes remains challenging. Bioorthogonal noncanonical amino acid tagging (BONCAT) offers a targeted approach for labeling and identifying newly synthesized proteins within defined time windows of interest. Here, we present the first such application of BONCAT in larval zebrafish, a model organism that has seen widespread use because of its genetic tractability and utility in developmental biology and neuroscience. We successfully enriched, using click chemistry, and identified, via mass spectrometry, azidohomoalanine (AHA)-labeled proteins after labeling durations as short as 12 hours. Proteomic analysis of BONCAT-enriched proteins demonstrated significant signal above background compared to unlabeled controls after both 48 h and 12 h of labeling. As a proof of concept, we investigated proteomic changes in response to heat shock in zebrafish larvae. BONCAT analysis revealed the upregulation of heat shock-induced proteins with greater sensitivity than whole lysate proteomics. Gene set enrichment analysis confirmed that known heat shock response proteins were significantly enriched in the BONCAT dataset but not in the whole lysate dataset, highlighting the ability of BONCAT to detect transient molecular responses otherwise masked in conventional whole lysate approaches. Beyond the expected changes in synthesis of heat shock proteins, BONCAT identified differentially expressed proteins implicated in stress responses, lipid metabolism, and neural regulation, offering insights into the zebrafish heat shock response. These findings establish BONCAT as a powerful tool for time-resolved proteomic analysis in zebrafish. Its ability to enhance signal specificity and resolve protein dynamics opens new avenues for studying molecular underpinnings of behavior, stress, and development in this versatile model organism.

Project description:Autophagy is an intracellular degradation mechanism in response to nutrient starvation. Via autophagy, some non-essential cellular constituents are degraded in a lysosome-dependent manner to generate biomolecules that can be utilized for maintaining the metabolic homeostasis. Although it is known that under starvation, the global protein synthesis is significantly reduced mainly due to suppression of mechanistic target of rapamycin (MTOR), there is emerging evidence demonstrating that de novo protein synthesis is involved in the autophagic process. However, characterizing these de novo proteins has been an issue with current techniques. Here, we developed a novel method to identify newly synthesized proteins during starvation-mediated autophagy by combining bio-orthogonal non-canonical amino acid tagging (BONCAT) and isobaric tags for relative and absolute quantitation (iTRAQ). Using bio-orthogonal metabolic tagging, L-azidohomoalanine (AHA) was incorporated into newly synthesized proteins which were then enriched with avidin beads after a click reaction between alkyne bearing biotin and AHA’s bio-orthogonal azide moiety. The enriched proteins were subjected to iTRAQ labeling for protein identification and quantification using liquid chromatography-tandem mass spectrometry (LC-MS/MS). A total of 711 proteins were identified. The characterized functional profiles of these newly synthesized proteins by bioinformatics analysis suggest their roles in ensuring the pro-survival outcome of autophagy. Finally, we performed validation assays for some selected proteins and found that knockdown of some genes has a significant impact on starvation-induced autophagy and cell death. Thus, the BONCAT-iTRAQ approach is effective in the identification of newly synthesized proteins and provides useful insights to the molecular mechanisms and biological functions of autophagy.

Project description:This dataset elucidates the remodeling of the nascent proteome before and upon global translation attenuation in response to transient mitochondrial depolarization by carbonyl cyanide m-chlorophenyl hydrazine (CCCP). During and following CCCP treatment, nascent proteome in short (30min) time windows was metabolically labelled with L-azidehomoalanine (AHA) using the BioOrthogonal Non-Canonical Amino acid Tagging (BONCAT) methodology. AHA incorporation sites were further derivatized with biotin-PEG4-alkyne by click chemistry upon cell lysis, proteins were digested with trypsin, nascent biotinylated peptides enriched and quantified.

Project description:In homeostatic scaling, the cellular mechanisms that detect the offset from the set-point, the duration of the offset and implement a cellular response are not well-understood. To understand the time-dependent dynamics,we manipulated activity for 2 hrs to induce the process of up or down-scaling and metabolically labelled nascent proteins using BONCAT. We analyzed the newly synthesized proteins that exhibited significant increases or decreases in expression in response to activity manipulations and identified 168 proteins. Then, to obtain a temporal trajectory of the cellular response, we compared the proteins synthesized within 2 and 24 hrs of an activity manipulation. Surprisingly, there was little overlap in the significantly regulated newly synthesized proteins identified in the early- and late-response datasets. There was, however, overlap in the functional categories that are modulated early and late, indicating that within protein function groups, different proteomic choices can be made to effect early and late homeostatic responses.

Project description:AHA-proteomics (enriching for newly synthesized proteins) of M. smegmatis mc2 155 cells expressing MSMEG_4448 (MazF-ms) after 4.5h. Runs: QE07865-QE07867 (Uninduced), QE07868-QE07870 (induced).