Interactions of transmembrane peptides and proteins with lipid membranes studied by mass spectrometry

The exact way in which membrane proteins are embedded in the lipid bilayer is not well understood. Only limited insight exists in the interactions of membrane proteins with the surrounding lipids and in the membrane-water interface in particular, where many interactions of membrane proteins with substrates, enzymes and ligands take place. Insight into the exact positioning of the transmembrane segments of such proteins with respect to this interface, as well as into their structural properties, are essential to understand the functioning of these proteins. An accepted way to systematically study integral membrane proteins and their interactions with the surrounding lipid membrane, is to use designed model transmembrane peptides in well-defined vesicular systems. These hydrophobic peptides are about as long as a typical transmembrane segment of such a protein and form ?-helices in lipid bilayers. In Chapters 2, 3 and 4 experiments are described using such peptides in order to study specific characteristics of these peptides in a lipid environment. Extending on this, in Chapter 5 a full-length naturally occurring integral membrane protein embedded in a lipid environment is studied. The scope of this thesis is to investigate the possibilities of mass spectrometry (MS) for studying these membrane peptides and proteins in membrane systems. In Chapter 2, it will be shown that it is possible to study the precise positioning of transmembrane peptides in lipid bilayers. Therefore, a novel method was developed to implement MS in membrane peptide and protein research, referred to as proteoliposome spraying method. By combining hydrogen/deuterium (H/D) exchange and nano-flow electrospray ionization (ESI) MS, the numbers of incorporated deuterium atoms in designed transmembrane peptides that are incorporated in lipid bilayer membranes can be analyzed. This proteoliposome spraying method involves direct introduction of the vesicle suspension into the MS-inlet. Several distinct H/D exchange rates can be observed for the exchangeable hydrogens depending on their position in the transmembrane peptides. Assignments are confirmed by collision induced dissociation (CID) MS measurements, which allow analysis of exchange of individual peptide amide linkages. In Chapter 3, this method is used to get more detailed insights into the architecture of various transmembrane peptides and into the positioning of such peptides in lipid bilayer membranes. Several variables such as (1) the influence of the length of the peptide hydrophobic core sequence, (2) the role of the flanking tryptophan residues, and (3) the influence of putative helix breakers, are investigated. The results are discussed in a biochemical and biophysical context. Chapter 4 highlights the possible complications in H/D exchange studies that might result from gas-phase migration of deuterium atoms incorporated in the peptides (referred to as scrambling). Systematic studies of this phenomenon suggest that the extent of deuterium scrambling is strongly influenced by experimental factors, such as the exact amino acid sequence of the peptide, the nature of the charge carrier and, therefore, most likely by the gas-phase structure of the peptide ion. In Chapter 5, an integral membrane protein is explored: the potassium channel KcsA. The intention was to extend the studies presented in Chapters 2 and 3 to a larger membrane protein and to investigate the interactions of this protein with lipids. In these experiments, non-covalent complexes of phospholipid molecules and KcsA are observed. Moreover, it is possible to probe preferential binding of certain classes of lipids to the protein. The results are discussed in the context of results of biochemical assays with identical protein-membrane systems. In Chapter 6, the results presented in this thesis are summarized and discussed in the context of the present literature

The lethal response to Cdk1 inhibition depends on sister chromatid alignment errors generated by KIF4 and isoform 1 of PRC1

Cyclin-dependent kinase 1 (Cdk1) is absolutely essential for cell division. Complete ablation of Cdk1 precludes the entry of G2 phase cells into mitosis, and is early embryonic lethal in mice. Dampening Cdk1 activation, by reducing gene expression or upon treatment with cell-permeable Cdk1 inhibitors, is also detrimental for proliferating cells, but has been associated with defects in mitotic progression, and the formation of aneuploid daughter cells. Here, we used a large-scale RNAi screen to identify the human genes that critically determine the cellular toxicity of Cdk1 inhibition. We show that Cdk1 inhibition leads to fatal sister chromatid alignment errors and mitotic arrest in the spindle checkpoint. These problems start early in mitosis and are alleviated by depletion of isoform 1 of PRC1 (PRC1-1), by gene ablation of its binding partner KIF4, or by abrogation of KIF4 motor activity. Our results show that, normally, Cdk1 activity must rise above the level required for mitotic entry. This prevents KIF4-dependent PRC1-1 translocation to astral microtubule tips and safeguards proper chromosome congression. We conclude that cell death in response to Cdk1 inhibitors directly relates to chromosome alignment defects generated by insufficient repression of PRC1-1 and KIF4 during prometaphase

A Testis-Specific Chaperone and the Chromatin Remodeler ISWI Mediate Repackaging of the Paternal Genome

During spermatogenesis, the paternal genome is repackaged into a non-nucleosomal, highly compacted chromatin structure. Bioinformatic analysis revealed that Drosophila sperm chromatin proteins are characterized by a motif related to the high-mobility group (HMG) box, which we termed male-specific transcript (MST)-HMG box. MST77F is a MST-HMG-box protein that forms an essential component of sperm chromatin. The deposition of MST77F onto the paternal genome requires the chaperone function of tNAP, a testis-specific NAP protein. MST77F, in turn, enables the stable incorporation of MST35Ba and MST35Bb into sperm chromatin. Following MST-HMG-box protein deposition, the ATP-dependent chromatin remodeler ISWI mediates the appropriate organization of sperm chromatin. Conversely, at fertilization, maternal ISWI targets the paternal genome and drives its repackaging into de-condensed nucleosomal chromatin. Failure of this transition in ISWI mutant embryos is followed by mitotic defects, aneuploidy, and haploid embryonic divisions. Thus, ISWI enables bi-directional transitions between two fundamentally different forms of chromatin

Subunits of the Histone Chaperone CAF1 Also Mediate Assembly of Protamine-Based Chromatin

One of the most dramatic forms of chromatin reorganization occurs during spermatogenesis, when the paternal genome is repackaged from a nucleosomal to a protamine-based structure. We assessed the role of the canonical histone chaperone CAF1 in Drosophila spermatogenesis. In this process, CAF1 does not behave as a complex, but its subunits display distinct chromatin dynamics. During histone-to-protamine replacement, CAF1-p180 dissociates from the DNA while CAF1-p75 binds and stays on as a component of sperm chromatin. Association of CAF1-p75 with the paternal genome depends on CAF1-p180 and protamines. Conversely, CAF1-p75 binds protamines and is required for their incorporation into sperm chromatin. Histone removal, however, occurs independently of CAF1 or protamines. Thus, CAF1-p180 and CAF1-p75 function in a temporal hierarchy during sperm chromatin assembly, with CAF1-p75 acting as a protamine-loading factor. These results show that CAF1 subunits mediate the assembly of two fundamentally different forms of chromatin

Improvement of ubiquitylation site detection by Orbitrap mass spectrometry

Ubiquitylation is an important posttranslational protein modification that is involved in many cellular events. Immunopurification of peptides containing a K-ε-diglycine (diGly) remnant as a mark of ubiquitylation combined with mass spectrometric detection has resulted in an explosion of the number of identified ubiquitylation sites. Here, we present several significant improvements to this workflow, including fast, offline and crude high pH reverse-phase fractionation of tryptic peptides into only three fractions with simultaneous desalting prior to immunopurification and better control of the peptide fragmentation settings in the Orbitrap HCD cell. In addition, more efficient sample cleanup using a filter plug to retain the antibody beads results in a higher specificity for diGly peptides and less non-specific binding. These relatively simple modifications of the protocol result in the routine detection of over 23,000 diGly peptides from HeLa cells upon proteasome inhibition. The efficacy of this strategy is shown for lysates of both non-labeled and SILAC labeled cell lines. Furthermore, we demonstrate that this strategy is useful for the in-depth analysis of the endogenous, unstimulated ubiquitinome of in vivo samples such as mouse brain tissue. This study presents a valuable addition to the toolbox for ubiquitylation site analysis to uncover the deep ubiquitinome. Significance: A K-ε-diglycine (diGly) mark on peptides after tryptic digestion of proteins indicates a site of ubiquitylation, a posttranslational modification involved in a wide range of cellular processes. Here, we report several improvements to methods for the isolation and detection of diGly peptides from complex biological mixtures such as cell lysates and brain tissue. This adapted method is robust, reproducible and outperforms previously published methods in terms of number of modified peptide identifications from a single sample. In-depth analysis of the ubiquitinome using mass spectrometry will lead to a better understanding of the roles of protein ubiquitylation in cellular events

The dual role of LSD1 and HDAC3 in STAT5-dependent transcription is determined by protein interactions, binding affinities, motifs and genomic positions

STAT5 interacts with other factors to control transcription, and the mechanism of regulation is of interest as constitutive active STAT5 has been reported in malignancies. Here, LSD1 and HDAC3 were identified as novel STAT5a interacting partners in pro-B cells. Characterization of STAT5a, LSD1 and HDAC3 target genes by ChIP-seq and RNA-seq revealed gene subsets regulated by independent or combined action of the factors and LSD1/HDAC3 to play dual role in their activation or repression. Genes bound by STAT5a alone or in combination with weakly associated LSD1 or HDAC3 were enriched for the canonical STAT5a GAS motif, and such binding induced activation or repression. Strong STAT5 binding was see

Semi-quantitative proteomics of mammalian cells upon short-term exposure to nonionizing electromagnetic fields

The potential effects of non-ionizing electromagnetic fields (EMFs), such as those emitted by power-lines (in extremely low frequency range), mobile cellular systems and wireless networking devices (in radio frequency range) on human health have been intensively researched and debated. However, how exposure to these EMFs may lead to biological changes underlying possible health effects is still unclear. To reveal EMF-induced molecular changes, unbiased experiments (without a priori focusing on specific biological processes) with sensitive readouts are required. We present the first proteome-wide semi-quantitative mass spectrometry analysis of human fibroblasts, osteosarcomas and mouse embryonic stem cells exposed to three types of non-ionizing EMFs (ELF 50 Hz, UMTS 2.1 GHz and WiFi 5.8 GHz). We performed controlled in vitro EMF exposures of metabolically labeled mammalian cells followed by reliable statistical analyses of differential protein-and pathway-level regulations using an array of established bioinformatics methods. Our results indicate that less than 1% of the quantitated human or mouse proteome responds to the EMFs by small changes in protein abundance. Further network-based analysis of the differentially regulated proteins did not detect significantly perturbed cellular processes or pathways in human and mouse cells in response to ELF, UMTS or WiFi exposure. In conclusion, our extensive bioinformatics analyses of semi-quantitative mass spectrometry data do not support the notion that the short-time exposures to non-ionizing EMFs have a consistent biologically significant bearing on mammalian cells in culture

DNA damage-induced histone H1 ubiquitylation is mediated by HUWE1 and stimulates the RNF8-RNF168 pathway

The DNA damage response (DDR), comprising distinct repair and signalling pathways, safeguards genomic integrity. Protein ubiquitylation is an important regulatory mechanism of the DDR. To study its role in the UV-induced DDR, we characterized changes in protein ubiquitylation following DNA damage using quantitative di-Gly proteomics. Interestingly, we identified multiple sites of histone H1 that are ubiquitylated upon UV-damage. We show that UV-dependent histone H1 ubiquitylation at multiple lysines is mediated by the E3-ligase HUWE1. Recently, it was shown that poly-ubiquitylated histone H1 is an important signalling intermediate in the double strand break response. This poly-ubiquitylation is dependent on RNF8 and Ubc13 which extend pre-existi

Proteomic analysis of FOXP proteins reveals interactions between cortical transcription factors associated with neurodevelopmental disorders

FOXP transcription factors play important roles in neurodevelopment, but little is known about how their transcriptional activity is regulated. FOXP proteins cooperatively regulate gene expression by forming homo- and hetero-dimers with each other. Physical as

Detection of alpha-toxin and other virulence factors in biofilms of staphylococcus aureus on polystyrene and a human epidermalmodel

Background & Aim: The ability of Staphylococcus aureus to successfully colonize (a)biotic surfaces may be explained by biofilm formation and the actions of virulence factors. The aim of the present study was to establish the presence of 52 proteins, including virulence factors such as alpha-toxin, during biofilm formation of five different (methicillin resistant) S. aureus strains on Leiden human epidermal models (LEMs) and polystyrene surfaces (PS) using a competitive Luminex-based assay. Results: All five S. aureus strains formed biofilms on PS, whereas only three out of five strains formed biofilms on LEMs. Out of the 52 tested proteins, six functionally diverse proteins (ClfB, glucosaminidase, IsdA, IsaA, SACOL0688 and nuclease) were detected in biofilms of all strains on both PS and LEMs. At the same time, four toxins (alpha-toxin, gamma-hemolysin B and leukocidins D and E), two immune modulators (formyl peptide receptor-like inhibitory protein and Staphylococcal superantigen-like protein 1), and two other proteins (lipase and LytM) were detectable in biofilms by all five S. aureus strains on LEMs, but not on PS. In contrast, fibronectinbinding protein B (FnbpB) was detectable in biofilms by all S. aureus biofilms on PS, but not on LEMs. These data were largely confirmed by the results from proteomic and transcriptomic analyses and in case of alpha-toxin additionally by GFP-reporter technology. Conclusion: Functionally diverse virulence factors of (methicillin-resistant) S. aureus are present during biofilm formation on LEMs and PS. These results could aid in identifying novel targets for future treatment strategies against biofilm-associated infections