Shining light on the subcellular proteome

Uncovering relevant protein targets and new biomarkers at the exact point of a key cellular interaction is a challenge with existing methods. To understand the cell’s intricate inner workings, researchers need tools that can resolve details at the suborganelle level. Recent innovations in spatial proteomics have enabled researchers to map protein compositions from the smallest and most elusive subcellular structures, offering insights into how their spatial dynamics influence signaling, development, and disease.

Download this application note compendium to learn:

• High-specificity proteomic strategies for identifying novel proteins in stress granules
• Precision photolabeling techniques to extract proteomes from nanoscopic organelles such as primary cilia
• How spatial proteomics supports the discovery of cellular mechanisms underlying stress response, signaling, and intracellular transport

Uncovering relevant protein targets and new biomarkers at the exact point of a key cellular interaction is a challenge with existing methods. To understand the cell’s intricate inner workings, researchers need tools that can resolve details at the suborganelle level. Recent innovations in spatial proteomics have enabled researchers to map protein compositions from the smallest and most elusive subcellular structures, offering insights into how their spatial dynamics influence signaling, development, and disease.

Download this application note compendium to learn:

• High-specificity proteomic strategies for identifying novel proteins in stress granules
• Precision photolabeling techniques to extract proteomes from nanoscopic organelles such as primary cilia
• How spatial proteomics supports the discovery of cellular mechanisms underlying stress response, signaling, and intracellular transport