Overview of cell fractionation

Analytical subcellular fractionation of microglial BV-2 cells with peroxisomal beta-oxidation defect

Peroxisomes have gained increasing attention and are now considered vital players in normal physiological functions. To gain further insight into how peroxisomal defects influence cellular functions, we developed BV-2 microglial models featuring CRISPR/Cas9 gene-edited mutations in peroxisomal Acox1 or Abcd1 and Abcd2 genes. The Acox1-/- BV-2 cell line we generated lacks acyl-CoA oxidase 1, the key enzyme that initiates peroxisomal β-oxidation. In contrast, the double mutant Abcd1/d2-/- BV-2 cell line carries mutations in the genes encoding the membranous ABC transporters ABCD1 and ABCD2, which are responsible for transporting fatty acyl-thioesters inside peroxisome. Here, for the first time, we used analytical fractionation to compare these three genotypes. Through flow cytometry, we observed an increase in cell granularity in these mutant cells, which could be associated with alterations in peroxisome distribution and mitochondrial dynamics. Additionally, the analysis of organelle markers in microglial cells, employing differential centrifugation, exhibited an enrichment of peroxisomes particularly in both L and P fractions of these BV-2 cell line models. The use of an isopycnic Nycodenz density gradient showed that peroxisomes sedimented with a median density of 1.18 g/ml. Notably, our results revealed no significant differences in the distribution profiles of organelles when comparing microglial BV-2 Wt cells with deficient Acox1‒/‒ or Abcd1/d2-/‒ BV-2 cells, which lack peroxisomal fatty acid beta-oxidation. Our study is the first to report on the fractionation of brain-derived microglial cells, laying valuable groundwork for future proteomic and/or metabolomic analyses of peroxisome fractions.

Subcellular phosphoproteomics

Protein phosphorylation represents one of the most extensively studied post-translational modifications, primarily due to the emergence of sensitive methods enabling the detection of this modification both in vitro and in vivo. The availability of enrichment methods combined with sensitive mass spectrometry instrumentation has played a crucial role in uncovering the dynamic changes and the large expanding repertoire of this reversible modification. The structural changes imparted by the phosphorylation of specific residues afford exquisite mechanisms for the regulation of protein functions by modulating new binding sites on scaffold proteins or by abrogating protein-protein interactions. However, the dynamic interplay of protein phosphorylation is not occurring randomly within the cell but is rather finely orchestrated by specific kinases and phosphatases that are unevenly distributed across subcellular compartments. This spatial separation not only regulates protein phosphorylation but can also control the activity of other enzymes and the transfer of other post-translational modifications. While numerous large-scale phosphoproteomics studies highlighted the extent and diversity of phosphoproteins present in total cell lysates, the further understanding of their regulation and biological activities require a spatio-temporal resolution only achievable through subcellular fractionation. This review presents a first account of the emerging field of subcellular phosphoproteomics where cell fractionation approaches are combined with sensitive mass spectrometry methods to facilitate the identification of low abundance proteins and to unravel the intricate regulation of protein phosphorylation.

Glycoprotein analysis using protein microarrays and mass spectrometry

Protein glycosylation plays an important role in a multitude of biological processes such as cell-cell recognition, growth, differentiation, and cell death. It has been shown that specific glycosylation changes are key in disease progression and can have diagnostic value for a variety of disease types such as cancer and inflammation. The complexity of carbohydrate structures and their derivatives makes their study a real challenge. Improving the isolation, separation, and characterization of carbohydrates and their glycoproteins is a subject of increasing scientific interest. With the development of new stationary phases and molecules that have affinity properties for glycoproteins, the isolation and separation of these compounds have advanced significantly. In addition to detection with mass spectrometry, the microarray platform has become an essential tool to characterize glycan structure and to study glycosylation-related biological interactions, by using probes as a means to interrogate the spotted or captured glycosylated molecules on the arrays. Furthermore, the high-throughput and reproducible nature of microarray platforms have been highlighted by its extensive applications in the field of biomarker validation, where a large number of samples must be analyzed multiple times. This review covers a brief survey of the other experimental methodologies that are currently being developed and used to study glycosylation and emphasizes methodologies that involve the use of microarray platforms. This review describes recent advances in several options of microarray platforms used in glycoprotein analysis, including glycoprotein arrays, glycan arrays, lectin arrays, and antibody/lectin arrays. The translational use of these arrays in applications related to characterization of cells and biomarker discovery is also included.

Subcellular fractionation of human eosinophils: isolation of functional specific granules on isoosmotic density gradients

Subcellular fractionation has been an important tool in investigating human eosinophil structure and function, including localizing of cytokine/chemokines within granules, investigating granule protein translocation and intracellular transport during eosinophil secretion, and studying secretory mechanisms of granules. The resolution of organelles obtained by subcellular fractionation was improved considerably after the introduction of nonionic iodinated density-gradient metrizamide and Nycodenz media that, unlike sucrose, exhibit relatively low tonicity throughout the gradient. However, the structure and membrane preservation of isolated organelles were still compromised due to the lack of gradient isoosmolarity. This paper describes a detailed protocol of subcellular fractionation of nitrogen cavitated eosinophils on an isoosmotic iodinated density gradient (iodixanol - OptiPrep) and the isolation of well preserved and functional membrane-bound specific granules.