Nicolas Sénécaut1, Gelio Alves2, Hendrik Weisser3, Laurent Lignières4, Samuel Terrier4, Lilian Yang-Crosson1, Pierre Poulain1, Gaëlle Lelandais5, Yi-Kuo Yu2, Jean-Michel Camadro1,4. 1. ≪ Mitochondria, Metals, and Oxidative Stress ≫ Group, Université de Paris-CNRS, Institut Jacques Monod, 75013 Paris, France. 2. National Center for Biotechnology Information, NLM, NIH, Bethesda, Maryland 20894, United States. 3. STORM Therapeutics Limited, Cambridge CB22 3AT, U.K. 4. ProteoSeine@IJM, Université de Paris-CNRS, Institut Jacques Monod, 75013 Paris, France. 5. Institut de Biologie Intégrative de la Cellule, 91190 Orsay, France.
Abstract
Simple light isotope metabolic labeling (SLIM labeling) is an innovative method to quantify variations in the proteome based on an original in vivo labeling strategy. Heterotrophic cells grown in U-[12C] as the sole source of carbon synthesize U-[12C]-amino acids, which are incorporated into proteins, giving rise to U-[12C]-proteins. This results in a large increase in the intensity of the monoisotope ion of peptides and proteins, thus allowing higher identification scores and protein sequence coverage in mass spectrometry experiments. This method, initially developed for signal processing and quantification of the incorporation rate of 12C into peptides, was based on a multistep process that was difficult to implement for many laboratories. To overcome these limitations, we developed a new theoretical background to analyze bottom-up proteomics data using SLIM-labeling (bSLIM) and established simple procedures based on open-source software, using dedicated OpenMS modules, and embedded R scripts to process the bSLIM experimental data. These new tools allow computation of both the 12C abundance in peptides to follow the kinetics of protein labeling and the molar fraction of unlabeled and 12C-labeled peptides in multiplexing experiments to determine the relative abundance of proteins extracted under different biological conditions. They also make it possible to consider incomplete 12C labeling, such as that observed in cells with nutritional requirements for nonlabeled amino acids. These tools were validated on an experimental dataset produced using various yeast strains of Saccharomyces cerevisiae and growth conditions. The workflows are built on the implementation of appropriate calculation modules in a KNIME working environment. These new integrated tools provide a convenient framework for the wider use of the SLIM-labeling strategy.
Simple light isotope metabolic labeling (SLIM labelipan class="Chemical">ng) is an innovative method to quantify variationpan>s inpan> the proteome based onpan> anclass="Chemical">pan> original inpan> vivo labelinpan>g strategy. Heterotrophic cells grown inpan> U-[12C] as the sole source of carbon synthesize U-[12C]-amino acids, which are incorporated into proteins, giving rise to U-[12C]-proteins. This results in a large in class="Chemical">ncrease in the intensity of the monoisotope ion of peptides and proteins, thus allowing higher identification scores and protein sequence coverage in mass spectrometry experiments. This method, initially developed for signal processing and quantification of the incorporation rate of 12C into peptides, was based on a multistep process that was difficult to implement for many laboratories. To overcome these limitations, we developed a new theoretical background to analyze bottom-up proteomics data using SLIM-labeling (bSLIM) and established simple procedures based on open-source software, using dedicated OpenMS modules, and embedded R scripts to process the bSLIM experimental data. These new tools allow computation of both the 12C abundance in peptides to follow the kinetics of protein labeling and the molar fraction of unlabeled and 12C-labeled peptides in multiplexing experiments to determine the relative abundance of proteins extracted under different biological conditions. They also make it possible to consider incomplete 12C labeling, such as that observed in cells with nutritional requirements for nonlabeled amino acids. These tools were validated on an experimental dataset produced using various yeast strains of Saccharomyces cerevisiae and growth conditions. The workflows are built on the implementation of appropriate calculation modules in a KNIME working environment. These new integrated tools provide a convenient framework for the wider use of the SLIM-labeling strategy.
Entities:
Keywords:
12C; In vivo metabolic labeling; KNIME; OpenMS; data processing workflow; light carbon isotope; quantitative proteomics; yeast