Organizations Partner to Enhance the Development of Analytical
As part of the research collaboration, Waters and BTI will develop a glycosphingolipid (GSL) head group database containing glucose unit (GU) retention times1 and collision cross-section (CCS) values in an effort to compile an experimental library for disease-related GSL glycans together with a glycan/MS spectral library.
GSLs are highly complex structures in which glycan head groups are attached to fatty acyl moieties. Analyzing their molecular composition involves detailing the sequence, anomericity, branching, and linkage positions of the oligosaccharides as well as their fatty acyl motifs. GSLs are critical for cell growth, interaction, and signaling and alterations to their structure may result in diseases or promote the development of different types of cancer. The analysis of the glycan head groups poses a particular analytical challenge for glycoscience because isomeric structures are not easily differentiated by either liquid chromatography (LC) or mass spectrometry (MS) technologies when used alone.
“Collaborating with Waters will enable BTI to apply its expertise in
glycomics to develop analytical methods and a library of information on
GSLs that doesn’t yet exist today. This will allow us to probe for
potential clinical markers and to provide insights into disease
progression and regression following therapeutic intervention. We
anticipate our science will advance human health while at the same time
address some of the needs of the biopharmaceutical industry,” said
scientific lead Dr.
“By taking our partnership to a new level, we will empower BTI to
further develop novel analytical methods and establish a comprehensive
experimental glycan spectral library for cancer glycobiology focusing on
glycosphingolipids. Together, we want to advance methods to study GSL
glycosylation in cancer classification and biomarker discovery,” said
As part of this collaboration, Waters will be contributing scientific expertise and the use of a Waters®SYNAPT® G2-S High Definition Mass Spectrometry® System. The instrument features ion mobility mass spectrometry technology that rapidly separates molecular ions by not only their size and mass-to-charge ratio, but by their shape as well. A collisional cross-section (CCS) value is a precise physicochemical property of an ion related to its size, shape, and charge in the gas phase. The ability to determine the separation of molecules based on a CCS value for each glycan head group reveals insights into their unique chemical structure, which in turn can be used as an additional descriptor for the GSL in question, thus providing a higher degree of specificity than using just mass-to-charge ratio alone.
First established in 2014, Waters’ collaborative relationship with BTI initially focused on evaluating the performance of a new N-linked glycan label aimed at biopharmaceutical applications, the GlycoWorks™ RapiFluor-MS™ Glycan Kit, and its complete workflow – from sample preparation to analysis – for glycosylation profiling.
1. Albrecht, S.; Vainauskas, S.;
Waters, SYNAPT, High-Definition Mass Spectrometry, GlycoWorks, and RapiFluor-MS
are trademarks of
Brian J. Murphy, +1 508-482-2614