Tandem mass tag

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Tandem Mass Tag (TMT) is a chemical labeling technique used in mass spectrometry-based proteomics to enable the quantification and identification of proteins in complex biological samples. This method allows for the simultaneous analysis of multiple samples by labeling them with different chemical tags that can be distinguished in a mass spectrometer. TMT is particularly useful in comparative proteomics, where the relative abundance of proteins across different samples, such as diseased vs. healthy tissue, can provide insights into biological processes and disease mechanisms.

Overview[edit | edit source]

TMT labeling involves the covalent attachment of tags to the peptides generated from protein digestion. These tags consist of three regions: a mass reporter, a cleavable linker, and an amine-reactive group. The amine-reactive group attaches to the N-terminus of peptides and the side chain of lysine residues, ensuring that each peptide is labeled. The cleavable linker connects the mass reporter to the peptide and is designed to break upon collision-induced dissociation (CID) during mass spectrometry analysis, releasing the mass reporter ions. The mass reporter ions, which differ slightly in mass among the tags, are detected in the mass spectrometer, allowing for the quantification of peptides and, by extension, the proteins from which they were derived.

Applications[edit | edit source]

TMT is widely used in proteomics research for various applications, including:

  • Disease biomarker discovery: Identifying proteins that are differentially expressed in diseased vs. healthy states.
  • Cell signaling studies: Investigating the changes in protein expression or modification in response to signaling events.
  • Drug discovery: Assessing the impact of drug treatment on protein expression levels in target cells or tissues.

Advantages[edit | edit source]

The main advantages of TMT labeling include:

  • High multiplexing capability: TMT can simultaneously analyze up to 16 samples, increasing throughput and reducing experimental variability.
  • Improved sensitivity and accuracy: The use of isobaric tags reduces sample complexity and improves the detection of low-abundance proteins.
  • Quantitative accuracy: TMT provides precise quantitative information, essential for comparative proteomics studies.

Limitations[edit | edit source]

Despite its advantages, TMT also has some limitations:

  • Isobaric tag interference: Co-isolated peptides can lead to quantification inaccuracies due to the co-fragmentation of peptides with different tags.
  • Cost: The high cost of TMT reagents can be a limiting factor for some laboratories.
  • Complexity: The data analysis process for TMT-labeled samples is complex and requires specialized software and expertise.

Conclusion[edit | edit source]

Tandem Mass Tag technology has revolutionized the field of proteomics by enabling the high-throughput, accurate quantification of proteins across multiple samples. Its application in biomarker discovery, cell signaling studies, and drug discovery highlights its importance in biomedical research. Despite its limitations, ongoing advancements in mass spectrometry and data analysis are continually improving the performance and accessibility of TMT-based proteomics.


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Contributors: Prab R. Tumpati, MD