Kit containing SILAC Protein Quantitation reagents with RPMI and dialyzed FBS media

Stable isotope labeling using amino acids in cell culture (SILAC) is a robust and efficient method for MS-based quantitative proteomics. The SILAC method uses metabolic labeling strategy to incorporate "heavy" 13C- or 15N-labeled amino acids in vivo into proteins during translation. It can be widely applied for comprehensive identification, characterization, and quantitation of proteins, and complex biomarker discovery.

See SILAC selection guide

Thermo Fisher Scientific offers the broadest portfolio of liquid and powdered SILAC media and SILAC amino acids. The media and amino acids are available in kits, or as stand-alone reagents, for labeling proteins expressed in a wide variety of mammalian cell lines, including HeLa, 293T, COS7, U2OS, A549, NIH 3T3, Jurkat, and others.
 

Selection guide for SILAC reagents

The SILAC Protein Quantitation kits contain all reagents required for quantitation of protein expression levels from differentially treated cell populations using SILAC.

Learn more about SILAC kits

MediaAmino acidsProductUnit size*Cat. No.
DMEML-Lysine (heavy)
[13C6 L-Lysine-2HCl]
SILAC Protein Quantitation Kit (LysC), DMEM1 kitA33969
DMEM:F-12SILAC Protein Quantitation Kit (LysC), DMEM:F-121 kitA33970
RPMI 1640SILAC Protein Quantitation Kit (LysC), RPMI 16401 kitA33971
DMEML-Lysine (heavy)
[13C615N2 L-Lysine-2HCl]
SILAC Protein Quantitation Kit (Trypsin), DMEM1 kitA33972
RPMI 1640L-Arginine (heavy)
13C6 15N4 L-Arginine-HCl
SILAC Protein Quantitation Kit (Trypsin), RPMI 16401 kitA33973

*Each kit contains reagents for 1 experiment (One control and one treated sample).

The SILAC Protein Quantitation kits contain all reagents required for quantitation of protein expression levels from differentially treated cell populations using SILAC.

Learn more about SILAC kits

MediaAmino acidsProductUnit size*Cat. No.
DMEML-Lysine (heavy)
[13C6 L-Lysine-2HCl]
SILAC Protein Quantitation Kit (LysC), DMEM1 kitA33969
DMEM:F-12SILAC Protein Quantitation Kit (LysC), DMEM:F-121 kitA33970
RPMI 1640SILAC Protein Quantitation Kit (LysC), RPMI 16401 kitA33971
DMEML-Lysine (heavy)
[13C615N2 L-Lysine-2HCl]
SILAC Protein Quantitation Kit (Trypsin), DMEM1 kitA33972
RPMI 1640L-Arginine (heavy)
13C6 15N4 L-Arginine-HCl
SILAC Protein Quantitation Kit (Trypsin), RPMI 16401 kitA33973

*Each kit contains reagents for 1 experiment (One control and one treated sample).

SILAC kits

The SILAC Protein Quantitation kits enable successful isotope metabolic protein labeling for relative quantitation of protein abundance in different cell treatments, and expression profiling of normal vs. disease cells. Two types of kits are available that have been optimized for use with LysC or trypsin for protein digestion.

  • LysC SILAC Kits are supplied with "heavy" L-Lysine (13C6 L-Lysine-2HCl) to label and quantify lysine-containing peptides from LysC protein digests. LysC SILAC kits can be converted to a trypsin SILAC kit by substituting "light" L-arginine, with "heavy" L-arginine, 13C6 L-Arginine-HCl or 13C6 15N4 L-Arginine-HCl.
  • Trypsin SILAC kits are supplied with "heavy" L-Lysine (13C6 15N2 L-Lysine-2HCl) and "heavy" L-arginine (13C6 15N4 L-Arginine-HCl) to label and quantify lysine-containing and arginine-containing peptides from trypsin protein digests.

Compared to "light" peptides, +2 ionized, heavy isotope peptides containing 13C6 L-Lysine or 13C6 15N4 L-Arginine get shifted by 3 and 5 m/z (Figure 1).

MS spectra of Proliferating cell nuclear antigen PCNA generated using SILAC

Figure 1. Representative MS spectra generated using SILAC. Light and heavy (13C6) L-lysine-containing peptides (AEDNADTLALVFEAPNQEK) from Proliferating cell nuclear antigen (PCNA) were analyzed by MS. Mass spectra of heavy peptides containing 13C6 L-lysine have an increased mass of 6 Da and are shifted to the right of light peptide spectra by a mass to charge ratio (m/z) of 3 caused by a +2 ionization of peptides.

SILAC workflow

Normalized protein extracts isolated from cells are combined, reduced, alkylated, and digested overnight. For the in-gel workflow, samples are run on an SDS-PAGE gel, excised, digested, and cleaned up while for the in-solution workflow, samples are digested, fractionated, and cleaned up. Samples are then analyzed by high-resolution Orbitrap LC-MS/MS (Figure 2).

SILAC amino acids and media

The heavy and light amino acids are used to specifically analyze protein expression by mass spectrometry using stable isotope labeling with amino acids in cell culture (SILAC) quantification kits.

General features of heavy and light amino acids for SILAC labeling:

  • Efficient—100% label incorporation into proteins of living cells
  • Flexible—different isotopes of heavy and/or light amino acids for arginine, lysine, leucine, and proline enable the quantitation of peptides derived from MS-grade proteases
  • Multiplex capabilities—several alternative isotopes of arginine and lysine are available that allow the analysis of multiple treatment conditions in each experiment
  • High-quality isotope enrichment—heavy amino acids with > 99% isotope purity

Heavy and light amino acids for SILAC are used together with specialized cell culture media that are deficient in essential amino acids. Heavy and light L-lysine and L-arginine are the most common amino acids used for SILAC analysis of tryptic peptides. Up to 3 different experimental conditions can be readily analyzed with different isotopes of lysine and arginine. For lysine 3-plex experiments, 4,4,5,5-D4 L-lysine and 13C6 15N2 L-lysine are used to generate peptides with 4 Da and 8 Da mass shifts, respectively, compared to peptides generated with light lysine. For arginine 3plex experiments, 13C6 L-arginine and 13C6 15N4 L-arginine are used to generate peptides with 6 Da and 10 Da mass shifts, respectively, compared to peptides generated with light arginine. L-leucine, a common amino acid found in protein sequences is also used for SILAC labeling. Proline, a non-essential amino acid is sometimes added to SILAC media to prevent the metabolic conversion of heavy arginine to heavy proline in mammalian cell lines with high arginine dehydrogenase activity.

Table 1. List of SILAC isotopes of amino acids for multiplex experiments

Amino acidLightD4*13C6D8*13C15N213C15N4
Mass shift0 Da+4 Da+6 Da+8 Da+8 Da+10 Da
L-Arginine HCL

89989 (50 mg)

88427 (500 mg)

N/A

89210 (50 mg)

88433 (500 mg)

N/AN/A

89990 (50 mg)

88434 (500 mg)

L-Leucine88428 (500 mg)N/A

88435 (50 mg)

88436 (500 mg)

N/AN/AN/A
L-Lysine 2HCl

89987 (50 mg)

88429 (500 mg)

88437 (50 mg)

88438 (500 mg)

89988 (50 mg)

88431 (500 mg)

A33613 (50 mg)

A33614 (500 mg)

88209 (50 mg)

88432 (500 mg)

N/A
L-Proline

88211

88430 (500mg)

N/AN/AN/AN/AN/A

*Deuterium

Protein turnover using SILAC

Cellular protein turnover is the net result of protein synthesis and degradation, and is crucial to maintain protein homeostasis and cellular function under steady-state conditions and to enable cells to remodel their proteomes upon a perturbation.

The kinetics and dynamics of protein turnover helps us understand how cells regulate essential processes such as growth, differentiation, and stress response. The quantitative approach to study proteome turnover is called dynamic SILAC which involves only two SILAC channels, "light" and "heavy". Briefly, cells are switched from unlabeled medium to a medium containing isotopically labeled amino acids, still typically heavy lysine and/or arginine [1]. Samples are then measured via liquid chromatography coupled to tandem mass spectrometry (LCMS/MS) over a time course. The ratio of heavy to light peptide signal thus directly reflects protein turnover (Figure 3) [2].

Ideally, quantitative analyses of proteome turnover and protein half-lives include data on both protein synthesis and degradation rates separately. The second strategy to measure protein production and degradation separately and track their changes upon perturbation is to combine dynamic SILAC with isobaric labeling (dynamic SILAC-TMT, Figure 3) [3,4,5,6]. Combining isobaric labels and dynamic SILAC facilitates direct quantification of heavy and light isotope–derived peaks, and also enables multiplexed analyses [3,4,5,6].

Dynamic SILAC has been performed in human A549 adenocarcinoma cells [1], rat neurons, and glia [7]. In vivo proteome turnover rates have been elucidated by feeding isotopically-labeled amino acids to whole animals such as C. elegans [8, 9], Drosophila [10], Zebrafish [11,12] and mice [13,14,15].

Workflow and data analysis of two-channel dynamic SILAC-TMT experiment

Figure 3. The dynamic SILAC workflow. (A) Sample prep for a standard two-label dynamic SILAC experiment. Cultures are plated in unlabeled media, which is swapped with media containing stable isotope–labeled amino acids (e.g., 13C6 ,15N4-Arg “heavy” arginine). Samples are collected and harvested over a time course. After sample digestion and purification, isobaric TMT labeling can be done to multiplex samples from different conditions and time points of interest. A fully labeled sample using a third stable isotope, typically a "semi-heavy /medium-heavy" isotope (e.g., 13C6-Arg), can also be generated as normalization standard for data analysis. (B) Data acquisition by LC-MS/MS. Direct monitoring of "light" (red) and "heavy" (green) peptide signals, corresponding to pre-existing and newly synthesized proteins is shown. In dynamic SILAC-TMT experiments, relative quantification of each sample is completed at the MS2 level (far right). In 3-channel designs, the signal from the constant "semi-heavy"-labeled sample (yellow) spike-in provides an internal normalization standard between different mass spectrometry measurements, allowing for relative signal from "light" and "heavy" channels to be quantitated. (C) Data analysis. Protein was measured from a 2-channel dynamic SILAC (left), a 3-channel dynamic SILAC (middle), and a combined 2-channel dynamic SILAC-TMT experiment (right). In the case of the latter, all the "heavy" (H) and "light" (L) signals are measured in the same run, which allows for separate synthesis and degradation curves.

Resources
References
  1. Doherty M.K., Hammond D.E., Clague M.J., et al. Turnover of the human proteome: determination of protein intracellular stability by dynamic SILAC. J Proteome Res, 2009. 8(1):104–112. 
  2. Ross A.B., Langer J.D., Jovanovic M. Proteome Turnover in the Spotlight: Approaches, Applications, and Perspectives. Mol Cell Proteomics, 2021. 20:100016. 
  3. Welle K.A., Zhang T., Hryhorenko J.R., et al. Time-resolved Analysis of Proteome Dynamics by Tandem Mass Tags and Stable Isotope Labeling in Cell Culture (TMT-SILAC) Hyperplexing. Mol Cell Proteomics, 2016. 15(12):3551–3563. 
  4. Zecha J., Meng C., Zolg D.P., et al. Peptide Level Turnover Measurements Enable the Study of Proteoform Dynamics. Mol Cell Proteomics, 2018. 17(5):974–992. 
  5. Savitski M.M., Zinn N., Faelth-Savitski M., et al. Multiplexed Proteome Dynamics Profiling Reveals Mechanisms Controlling Protein Homeostasis. Cell, 2018. 173(1):260–274. 
  6. Jayapal K.P., Sui S., Philp R.J., et al. Multitagging proteomic strategy to estimate protein turnover rates in dynamic systems. J Proteome Res, 2010. 9(5):2087–2097. 
  7. 7. Dörrbaum A.R., Schuman E.M., Langer J.D. Dynamic SILAC to Determine Protein Turnover in Neurons and Glia. Methods Mol Biol, 2023. 2603:1–17. 
  8. Visscher M., De Henau S., Wildschut M.H.E., et al. Proteome-wide Changes in Protein Turnover Rates in C. elegans Models of Longevity and Age-Related Disease. Cell Rep, 2016. 16(11):3041–3051. 
  9. Dhondt I., Petyuk V.A., Bauer S., et al. Changes of Protein Turnover in Aging Caenorhabditis elegans. Mol Cell Proteomics, 2017. 16(9):1621–1633. 
  10. Rosenberger F.A., Atanassov I., Moore D., et al. Stable Isotope Labeling of Amino Acids in Flies (SILAF) Reveals Differential Phosphorylation of Mitochondrial Proteins Upon Loss of OXPHOS Subunits. Mol Cell Proteomics, 2021. 20:100065.
  11. Westman-Brinkmalm A., Abramsson A., Pannee J., et al. SILAC zebrafish for quantitative analysis of protein turnover and tissue regeneration. J. Proteomics, 2011. 75(2), 425–434. 
  12. Nolte H., Hölper S., Housley M.P. et al. Dynamics of zebrafish fin regeneration using a pulsed SILAC approach. Proteomics, 2015. 15(4), 739–751. 
  13. Mandad S., Rahman R.U., Centeno T.P., et al. The codon sequences predict protein lifetimes and other parameters of the protein life cycle in the mouse brain. Sci Rep, 2018. 8(1), 16913. 
  14. Fornasiero E.F., Mandad S., Wildhagen H., et al. Precisely measured protein lifetimes in the mouse brain reveal differences across tissues and subcellular fractions. Nat Commun, 2018. 9(1), 4230. 
  15. Alevra M., Mandad, S., Ischebeck, T., et al. A mass spectrometry workflow for measuring protein turnover rates in vivo. Nat. Protoc, 2019. 14(12), 3333–3365. 
Stylesheet for Classic Wide Template adjustments
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 SILAC™ Protein Quantitation KitsSILAC™ Protein ID & Quantitation Media KitSILAC™ Phosphoprotein ID & Quantitation KitSILAC™ Membrane Protein ID & Quantitation Kit
ApplicationTotal protein expression analysisTotal protein expression analysisPhosphoprotein expression analysisMembrane protein expression analysis
Media configuration2 x 500 mL2 x 1 L2 x 1 L2 x 1 L
Heavy lysine, light L-lysine and L-arginine included?YesYesYesYes
L-glutamine, glucose and phenol redComplete formulationsWithout glucose and phenol redWithout L-glutamine, glucose, and phenol redWithout L-glutamine, glucose, and phenol red
Dialyzed FBSYesYesYesYes
Membrane lysis bufferNo

No

NoYes
Phosphoprotein lysis buffer and PiMAC ResinNoNoYesNo
Media options

RPMI 1640

DMEM

DMEM:F12

RPMI 1640

DMEM

DMEM:F12

IMDM

RPMI 1640

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RPMI 1640

DMEM Flex Media

For Research Use Only. Not for use in diagnostic procedures.