Toward High-Throughput Cryogenic IR Fingerprinting of Mobility-Separated Glycan Isomers

Infrared (IR) spectroscopy is a powerful tool used to infer detailed structural information on molecules, often in conjunction with quantum-chemical calculations. When applied to cryogenically cooled ions, IR spectra provide unique fingerprints that can be used for biomolecular identification. This is particularly important in the analysis of isomeric biopolymers, which are difficult to distinguish using mass spectrometry. However, IR spectroscopy typically requires laser systems that need substantial user attention and measurement times of tens of minutes, which limits its analytical utility. We report here the development of a new high-throughput instrument that combines ultrahigh-resolution ion-mobility spectrometry with cryogenic IR spectroscopy and mass spectrometry, and we apply it to the analysis of isomeric glycans. The ion mobility step, which is based on structures for lossless ion manipulations (SLIM), separates glycan isomers, and an IR fingerprint spectrum identifies them. An innovative cryogenic ion trap allows multiplexing the acquisition of analyte IR fingerprints following mobility separation, and using a turn-key IR laser, we can obtain spectra and identify isomeric species in less than a minute. This work demonstrates the potential of IR fingerprinting methods to impact the analysis of isomeric biomolecules and more specifically glycans.

A New Strategy Coupling Ion-Mobility-Selective CID and Cryogenic IR Spectroscopy to Identify Glycan Anomers

Priyanka Bansal, Ahmed Ben Faleh, Eduardo Carrascosa Casado, Robert Paul Pellegrinelli, Thomas Rizzo, Stephan Warnke, Lei Yue

Determining the primary structure of glycans remains challenging due to their isomeric complexity. While high-resolution ion mobility spectrometry (IMS) has recently allowed distinguishing between many glycan isomers, the arrival-time distributions (ATDs) frequently exhibit multiple peaks, which can arise from positional isomers, reducing-end anomers, or different conformations. Here, we present the combination of ultrahigh-resolution ion mobility, collision-induced dissociation (CID), and cryogenic infrared (IR) spectroscopy as a systematic method to identify reducing-end anomers of glycans. Previous studies have suggested that high-resolution ion mobility of sodiated glycans is able to separate the two reducing-end anomers. In this case, Y-fragments generated from mobility-separated precursor species should also contain a single anomer at their reducing end. We confirm that this is the case by comparing the IR spectra of selected Y-fragments to those of anomerically pure mono- and disaccharides, allowing the assignment of the mobility-separated precursor and its IR spectrum to a single reducing-end anomer. The anomerically pure precursor glycans can henceforth be rapidly identified on the basis of their IR spectrum alone, allowing them to be distinguished from other isomeric forms.

2022

A gas phase approach for glycan analysis: Combining ultrahigh-resolution ion mobility spectrometry with cryogenic vibrational spectroscopy

Ahmed Ben Faleh

The last decades have been punctuated by the development of revolutionary analytical technologies that have enabled the analysis of biomolecular structures and unraveled the roles they play in biological systems. However, certain classes of biomolecules remain less understood than others. In fact, despite being among the most abundant molecules on our planet, glycans remain among the least understood class of biological macromolecules due to their highly complex structure. The complexity of glycan molecules arises from their isomeric nature, which poses a significant challenge to classical analytical tools. The advent of ionization methods such as ESI and MALDI has led to an unprecedented expansion of gas phase techniques for the analysis of biomolecules. Compared to condensed phase approaches, gas phase analysis allows for isolating specific molecules and collecting highly accurate and specific structural information. In this work, we present an analytical approach for the analysis of glycan molecules based on the combination of different gas phase techniques. A central part of this thesis is the development, design, and characterization of two new instruments that have the capabilities to identify glycan isomers unambiguously. Our experimental approach is based on the combination of high-resolution ion mobility spectrometry with cryogenic IR spectroscopy. Ion mobility spectrometry allows to separate charged molecules in the gas phase according to their overall shape, serving as an isomer-selective prefilter to the IR spectroscopic interrogation process. While IMS provides a way to separate glycan isomers, vibrational spectroscopy is used to identify the mobility-separated molecules. The IR absorptions characteristic of glycan molecules lead to distinct spectroscopic fingerprints, which are perfectly suited for the identification of glycan isomers. In the first part of this work, we report the modification of an existing instrument that combined drift tube IMS with IR spectroscopy. We replaced the drift tube section by IMS device employing a relatively novel technique called SLIM, which provides the highest mobility resolution reported to date while ensuring a minimum loss of ions. This prototype instrument was used in a series of proof-of-concept experiments where we successfully demonstrate that our approach provides highly accurate results, comparable to sophisticated double-resonance spectroscopic schemes. We also describe an analytical protocol that serves to identify the isomeric content of disaccharide and tetrasacharide mixtures unambiguously, using a database approach. Furthermore, we report a series of experiments in which we separate and identify the anomers of disaccharides. In the second part of the thesis, we describe a second-generation instrument based on the same approach. The design of this instrument was aimed at maximizing its sensitivity and throughput while adding more analytical functionalities. It includes a CID section, as well as a cryogenic multi-trap allowing for the multiplexed spectroscopic analysis of glycan isomers. We hereby report the characterization results highlighting the instrument capabilities in terms of ion transmission and IMS resolution. We also report the first rapid, multiplexed, IR spectral acquisition of two tetrasacharide isomers, which emphasizes the unique capabilities of this home-built instrument.

EPFL2021

Cryogenic IR spectroscopy combined with ion mobility spectrometry for the analysis of human milk oligosaccharides

Michael Zachary Kamrath, Neelam Khanal, Chiara Masellis, Thomas Rizzo

We report here our combination of cryogenic, messenger-tagging, infrared (IR) spectroscopy with ion mobility spectrometry (IMS) and mass spectrometry (MS) as a way to identify and analyze a set of human milk oligosaccharides (HMOs) ranging from trisaccharides to hexasaccharides. The added dimension of IR spectroscopy provides a diagnostic fingerprint in the OH and NH stretching region, which is crucial to identify these oligosaccharides, which are difficult to distinguish by IMS alone. These results extend our previous work in demonstrating the generality of this combined approach for distinguishing subtly different structural and regioisomers of glycans of biologically relevant size.

2018

A gas phase approach for glycan analysis: Combining ultrahigh-resolution ion mobility spectrometry with cryogenic vibrational spectroscopy

Ahmed Ben Faleh

EPFL2021