Mikkel Nissum

Mammalian Proteasome Subpopulations with Distinct Molecular Compositions and Proteolytic Activities

The proteasome-dependent protein degradation participates in multiple essential cellular processes. Modulation of proteasomal activities may alter cardiac function and disease phenotypes. However, cardiovascular studies reported thus far have yielded conflicting results. We hypothesized that a contributing factor to the contradicting literature may be caused by existing proteasome heterogeneity in the myocardium. In this investigation, we provide the very first direct demonstration of distinct proteasome subpopulations in murine hearts. The cardiac proteasome subpopulations differ in their molecular compositions and proteolytic activities. Furthermore they were distinguished from proteasome subpopulations identified in murine livers. The study was facilitated by the development of novel protocols for in-solution isoelectric focusing of multiprotein complexes in a laminar flow that support an average resolution of 0.04 pH units. Utilizing these protocols, the majority of cardiac proteasome complexes displayed an isoelectric point of 5.26 with additional subpopulations focusing in the range from pH 5.10 to 5.33. In contrast, the majority of hepatic 20 S proteasomes had a pI of 5.05 and focused from pH 5.01 to 5.29. Importantly proteasome subpopulations degraded specific model peptides with different turnover rates. Among cardiac subpopulations, proteasomes with an approximate pI of 5.21 showed 40% higher trypsin-like activity than those with pI 5.28. Distinct proteasome assembly may be a contributing factor to variations in proteolytic activities because proteasomes with pI 5.21 contained 58% less of the inducible subunit β2i compared with those with pI 5.28. In addition, dephosphorylation of 20 S proteasomes demonstrated that besides molecular composition posttranslational modifications largely contribute to their pI values. These data suggest the possibility of mixed 20 S proteasome assembly, a departure from the currently hypothesized two subpopulations: constitutive and immuno forms. The identification of multiple distinct proteasome subpopulations in heart provides key mechanistic insights for achieving selective and targeted regulation of this essential protein degradation machinery. Thus, proteasome subpopulations may serve as novel therapeutic targets in the myocardium.

Application of free-flow IEF to identify protein candidates changing under microgravity conditions.

Using antibody‐related methods, we recently found that human thyroid cells express various proteins differently depending on whether they are cultured under normal gravity (1g) or simulated microgravity (s‐μg). In this study, we performed proteome analysis in order to identify more gravity‐sensitive thyroid proteins. Cells cultured under 1g or s‐μg conditions were sonicated. Proteins released into the supernatant and those remaining in the cell fragments were fractionated by free‐flow IEF. The fractions obtained were further separated by SDS‐gel electrophoresis. Selected gel pieces were excised and their proteins were determined by MS. A total of 235 different proteins were found. Out of 235 proteins, 37 appeared to be first identifications in human thyroid cells. Comparing SDS gel lanes of equally numbered free‐flow IEF fractions revealed similar patterns with a number of identical bands if proteins of a distinct cell line had been applied, irrespective of whether the cells had been cultured under 1g or s‐μg. Most of the identical band pairs contained identical proteins. However, the concentrations of some types of proteins were different within the two pieces of gel. Proteins that concentrated differently in such pieces of gel are considered as candidates for further investigations of gravitational sensitivity.

Proteomic analysis of the secretome of human umbilical vein endothelial cells using a combination of free-flow electrophoresis and nanoflow LC-MS/MS

Human umbilical vein endothelial cells are the most widely used in vitro model for endothelial cells. Their secreted proteins, however, have not been comprehensively analysed so far. In this study, we accomplished to map the secretome of human umbilical vein endothelial cells by combining free‐flow electrophoresis with nanoflow LC‐MS/MS. This comprehensive analysis provides a basis for future comparative studies of protein secretion by endothelial cells in response to cardiovascular risk factors and is available on our website http://www.vascular‐proteomics.com.

Free-flow electrophoresis for top-down proteomics by Fourier transform ion cyclotron resonance mass spectrometry.

High‐efficiency prefractionation of complex protein mixtures is critical for top‐down proteomics, i.e., the analysis of intact proteins by MS. Free‐flow electrophoresis (FFE) can be used for IEF to separate proteins within a pH gradient according to their pIs. In an FFE system, this separation is performed entirely in the liquid phase, without the need for particulate chromatographic media, gels, or membranes. Herein, we demonstrated the compatibility of IEF‐FFE with ESI‐Fourier transform ICR MS (ESI‐FTICR‐MS) for top‐down experiments. We demonstrated that IEF‐FFE of intact proteins were highly reproducible between FFE instruments, between laboratories, and between analyses. Applying native (0.2% hydroxypropylmethyl cellulose) IEF‐FFE to an enzyme resulted in no decrease in enzyme activity; applying either native or denaturing (8u2005M urea) IEF‐FFE to a four‐protein mixture with different pIs resulted in isolation of each protein into separate fractions in a 96‐well plate. After desalting, each protein was sequenced by top‐down MS/MS. As an application of this technique, chicken erythrocyte histone H2A‐IV and its major modified forms were enriched by IEF‐FFE. Top‐down analysis revealed Lys‐5 to be a major acetylation site, in addition to N‐terminal acetylation.

Functional and Complementary Phosphorylation State Attributes of Human Insulin-like Growth Factor-Binding Protein-1 (IGFBP-1) Isoforms Resolved by Free Flow Electrophoresis

Fetal growth restriction (FGR) is a common disorder in which a fetus is unable to achieve its genetically determined potential size. High concentrations of insulin-like growth factor-binding protein-1 (IGFBP-1) have been associated with FGR. Phosphorylation of IGFBP-1 is a mechanism by which insulin-like growth factor-I (IGF-I) bioavailability can be modulated in FGR. In this study a novel strategy was designed to determine a link between IGF-I affinity and the concomitant phosphorylation state characteristics of IGFBP-1 phosphoisoforms. Using free flow electrophoresis (FFE), multiple IGFBP-1 phosphoisoforms in amniotic fluid were resolved within pH 4.43–5.09. The binding of IGFBP-1 for IGF-I in each FFE fraction was determined with BIAcore biosensor analysis. The IGF-I affinity (KD) for different IGFBP-1 isoforms ranged between 1.12e−08 and 4.59e−07. LC-MS/MS characterization revealed four phosphorylation sites, Ser(P)98, Ser(P)101, Ser(P)119, and Ser(P)169, of which Ser(P)98 was new. Although the IGF-I binding affinity for IGFBP-1 phosphoisoforms across the FFE fractions did not correlate with phosphopeptide intensities for Ser(P)101, Ser(P)98, and Ser(P)169 sites, a clear association was recorded with Ser(P)119. Our data demonstrate that phosphorylation at Ser119 plays a significant role in modulating affinity of IGFBP-1 for IGF-I. In addition, an altered profile of IGFBP-1 phosphoisoforms was revealed between FGR and healthy pregnancies that may result from potential site-specific phosphorylation. This study provides a strong basis for use of this novel approach in establishing the linkage between phosphorylation of IGFBP-1 and FGR. This overall strategy will also be broadly applicable to other phosphoproteins with clinical and functional significance.

Free-Flow Electrophoresis System for Plasma Proteomic Applications

This chapter describes the technology of free flow electrophoresis (FFE) and protocols to separate human plasma for proteome analysis. FFE is a highly versatile technology applied in the field of proteomics because of its continuous processing of sample and high resolution in separation of most kinds of charged or chargeable particles including ions, proteins peptides, organelles, and whole cells. FFE is carried out in an aqueous medium without inducing any solid matrix, such as acrylamide, so that it simplifies complex sample for the downstream analysis. Two FFE protocols are described to separate human plasma proteins under native and denaturing conditions. Plasma separated under native conditions was pooled into acidic-, alkaline-, and albumin- fractions that were furthered for gel-based analysis. Under denaturing condition plasma proteins were separated into 96 fractions. Each fraction can be supplied for in-solution digestion and further LC-MS/MS analysis. From a single FFE fraction 46 different proteins (protein family) have been identified, demonstrating FFE as a high efficient separation tool for human plasma proteome studies.

Resolution of adiponectin oligomers in human plasma using free flow electrophoresis

Adiponectin is an important adipocytokine hormone which circulates in blood as homo-oligomers (trimer, hexamer and high molecular weight (HMW) forms) as well as a truncated form corresponding to the globular domain. Free flow electrophoresis (FFE) used in zone electrophoresis mode revealed the presence of isoforms within these oligomeric forms in plasma. HMW adiponectin oligomer showed two isoforms which carry different charge density at pH 4.7, only one of which is susceptible to dissociation by SDS. The adiponectin hexamer was shown to consist of a doublet and also shown to have at least two isoforms. A truncated form of adiponectin was identified as the main constituent of adiponectin in plasma and appeared to circulate bound to a basic protein, potentially one of the chemokines reported to bind to the globular domain. Analysis of the monomer composition of the oligomers revealed differences in monomeric isoforms used to build up the oligomers.

Free-Flow Electrophoresis of the Human Urinary Proteome

Prefractionation of complex protein samples prior to mass spectrometry provides a method for the isolation of low-abundance proteins into specific fractions thereby enabling their identification. Free-flow electrophoresis in the isoelectric focusing mode (IEF-FFE) presents a complementary approach to established prefractionation methodologies. Proteins are separated in solution according to their isoelectric point (pI) with a high throughput of sample volume. The separation may be performed under denaturing or nondenaturing conditions and detergents may be added to promote protein solubilization. A protocol covering the pH range from pH 3 to 9 under denaturing conditions was used to illustrate the method of IEF-FFE including sample preparation prior to reversed-phase liquid chromatography and tandem mass spectrometry. The IEF-FFE separation was applied to a sample of human urine.