Abstract
Cerebrospinal fluid (CSF) is in direct contact with the central nervous system. This makes human CSF an attractive source of potential biomarkers for neurologic diseases. Similarly to blood plasma, proteomic analysis of CSF is complicated by a high dynamic range of individual protein concentrations and by the presence of several highly abundant proteins. To deal with the abundant human CSF proteins, methods developed for blood plasma/serum are routinely used. Multiple affinity removal systems and protein enrichment of less abundant proteins using a combinatorial peptide ligand library are among the most frequent approaches. However, their relative impact on CSF proteome coverage has never been evaluated side-by-side in a single study. Therefore, we explored the effect of CSF depletion using MARS 14 cartridge and ProteoMiner ligand library on the number of CSF proteins identified in subsequent LC–MS/MS analysis. LC–MS/MS analysis of crude (non-treated) CSF provided roughly 500 identified proteins. Depletion of CSF by MARS 14 cartridge increased the number of identifications to nearly 800, while treatment of CSF using ProteoMiner enabled identification of 600 proteins. To explore the potential losses of CSF proteins during the depletion process, we also analyzed the “waste” fractions generated by both methods, i.e., proteins retained by the MARS 14 cartridge, and the molecules present in the flow-through fraction from ProteoMiner. More than 250 proteins were bound to MARS 14 cartridge, 100 of those were not identified in the corresponding depleted CSF. Similarly, analysis of the waste fraction in ProteoMiner workflow provided almost 70 unique proteins not found in the CSF depleted by the ligand library. Both depletion strategies significantly increased the number of identified CSF proteins compared to crude CSF. However, MARS 14 depletion provided a markedly higher number of identified proteins (773) compared to ProteoMiner (611). Further, we showed that CSF proteins are lost due to co-depletion (MARS 14) or exclusion (ProteoMiner) during the depletion process. This suggests that the routinely discarded “waste” fractions contain proteins of potential interest and should be included in CSF biomarker studies.
Highlights
Proteomic analysis of human body fluids is a promising tool for the identification and detection of disease biomarkers
We assessed the impact of multiple affinity removal system (MARS) 14 cartridge and ProteoMiner immobilized library on the number of proteins identified in triplicate cerebrospinal fluid (CSF) samples by a standard LC–liquid chromatography—tandem mass spectrometry (MS/MS)
In addition to the key fractions of interest, i.e., depleted CSF samples, we determined the number of proteins present in the “waste” fractions, which are routinely discarded
Summary
Proteomic analysis of human body fluids is a promising tool for the identification and detection of disease biomarkers. Human cerebrospinal fluid (CSF) is in direct contact with the central nervous system (CNS) and serves multiple functions including mechanic protection of the brain tissue, homeostasis maintenance, delivery of nutrients to the CNS, removal of waste and active regulation of CNS via hormones, neuropeptides, and other regulatory molecules. The composition of CSF reflects the physiological or pathological status of CNS and makes CSF an attractive source of potential biomarkers for neurologic diseases. Abundances of several CSF proteins have been approved as diagnostic or prognostic markers in clinical practice. Total tau protein concentration, phospho-tau concentration and presence of 42 amino acid form of β-amyloid are indicative of Alzheimers disease [1]. For most diseases of the CNS, there are currently no reliable biomarkers with diagnostic, prognostic or therapeutic significance.
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