2 research outputs found
Developing New Isotope-Coded Mass Spectrometry-Cleavable Cross-Linkers for Elucidating Protein Structures
Structural characterization of protein
complexes is essential for
the understanding of their function and regulation. However, it remains
challenging due to limitations in existing tools. With recent technological
improvements, cross-linking mass spectrometry (XL-MS) has become a
powerful strategy to define protein–protein interactions and
elucidate structural topologies of protein complexes. To further advance
XL-MS studies, we present here the development of new isotope-coded
MS-cleavable homobifunctional cross-linkers: <i>d</i><sub>0</sub>- and <i>d</i><sub>10</sub>-labeled dimethyl disuccinimidyl
sulfoxide (DMDSSO). Detailed characterization of DMDSSO cross-linked
peptides further demonstrates that sulfoxide-containing MS-cleavable
cross-linkers offer robust and predictable MS2 fragmentation of cross-linked
peptides, permitting subsequent MS3 analysis for simplified, unambiguous
identification. Concurrent usage of these reagents provides a characteristic
doublet pattern of DMDSSO cross-linked peptides, thus aiding in the
confidence of cross-link identification by MS<sup><i>n</i></sup> analysis. More importantly, the unique isotopic profile permits
quantitative analysis of cross-linked peptides and therefore expands
the capability of XL-MS strategies to analyze both static and dynamic
protein interactions. Together, our work has established a new XL-MS
workflow for future studies toward the understanding of structural
dynamics of protein complexes
Developing New Isotope-Coded Mass Spectrometry-Cleavable Cross-Linkers for Elucidating Protein Structures
Structural characterization of protein
complexes is essential for
the understanding of their function and regulation. However, it remains
challenging due to limitations in existing tools. With recent technological
improvements, cross-linking mass spectrometry (XL-MS) has become a
powerful strategy to define protein–protein interactions and
elucidate structural topologies of protein complexes. To further advance
XL-MS studies, we present here the development of new isotope-coded
MS-cleavable homobifunctional cross-linkers: <i>d</i><sub>0</sub>- and <i>d</i><sub>10</sub>-labeled dimethyl disuccinimidyl
sulfoxide (DMDSSO). Detailed characterization of DMDSSO cross-linked
peptides further demonstrates that sulfoxide-containing MS-cleavable
cross-linkers offer robust and predictable MS2 fragmentation of cross-linked
peptides, permitting subsequent MS3 analysis for simplified, unambiguous
identification. Concurrent usage of these reagents provides a characteristic
doublet pattern of DMDSSO cross-linked peptides, thus aiding in the
confidence of cross-link identification by MS<sup><i>n</i></sup> analysis. More importantly, the unique isotopic profile permits
quantitative analysis of cross-linked peptides and therefore expands
the capability of XL-MS strategies to analyze both static and dynamic
protein interactions. Together, our work has established a new XL-MS
workflow for future studies toward the understanding of structural
dynamics of protein complexes