HILIC-IM-MS for Simultaneous Lipid and Metabolite Profiling of Bacteria.

Although MALDI-ToF platforms for microbial identifications have found great success in clinical microbiology, the sole use of protein fingerprints for the discrimination of closely related species, strain-level identifications, and detection of antimicrobial resistance remains a challenge for the technology. Several alternative mass spectrometry-based methods have been proposed to address the shortcomings of the protein-centric approach, including MALDI-ToF methods for fatty acid/lipid profiling and LC-MS profiling of metabolites. However, the molecular diversity of microbial pathogens suggests that no single "ome" will be sufficient for the accurate and sensitive identification of strain- and susceptibility-level profiling of bacteria.

A rapid single-phase extraction for polar staphylococcal lipids.

The lipid membrane is gaining appreciation as a critical factor in the emergence of antibiotic resistance, both for antibiotics that target lipid synthesis or the membrane directly and for cell-wall-targeting antibiotics. The methods used to study the emergence of antibiotic resistance in vitro can generate a large number of samples that may be low in volume and in cell density. As in eukaryotic/mammalian lipidomics, two-phase liquid-liquid extractions are the most commonly used approach to recover lipids from bacteria.

Revealing Fatty Acid Heterogeneity in Staphylococcal Lipids with Isotope Labeling and RPLC-IM-MS.

Up to 80% of the fatty acids in membrane lipids are branched, rather than straight-chain, fatty acids. The branched fatty acids (BCFAs) may have either an even or odd number of carbons, and the branch position may be at the penultimate carbon () or the antepenultimate () carbon of the tail. This results in two sets of isomeric fatty acid species with the same number of carbons that cannot be resolved by mass spectrometry.

Recent applications of mass spectrometry in bacterial lipidomics.

The popularity of mass spectrometry-based lipidomics has soared in the past decade. While the majority of the lipidomics work is being performed in mammalian and other eukaryotic systems, there is also a growing rise in the exploration of bacterial lipidomics. The lipids found in bacteria can be substantially different from those in eukaryotic systems, but they are equally important for maintaining the structure of the bacteria and providing protection from the surrounding environment.