Mass Spectrometry-based Neuroproteomics : Deciphering the Human Brain Proteome

Musunuri, Sravani

January 2016

Mammalian brain is challenging to study due to its heterogeneity and complexity. However, recent advances in molecular imaging, genomics and proteomics have contributed significantly to achieve insights into molecular basis of brain function and pathogenesis of neurological disorders. Efficient sample preparation is an integral part of a successful mass spectrometry (MS)-based proteomics. Apart from the identification, quantification of proteins is needed to investigate the alterations between proteome profiles from different sample sets. Therefore, this thesis investigates optimizing and application of the MS compatible sample preparation techniques for the identification and quantification of proteins from brain tissue. The central objective of this thesis was (i) to improve the extraction of proteins as well as membrane proteins (MPs) from the brain tissue and (ii) to apply the optimized method along with the stable isotope dimethyl labeling (DML) and label-free (LF) MS approaches for the relative quantification of the brain proteome profiles during neurological conditions such as Alzheimer’s disease (AD) and traumatic brain injury (TBI).  First study described in this thesis is focused on the qualitative aspects for the brain tissue sample preparation. The optimized extraction buffers from first study containing n-octyl-β-glucopyranside or triton X-114 were used in the further quantitative studies to extract the proteins from patient (AD or TBI) and control human brain samples. Triton X-114 has additional advantage of separating MPs into a micellar phase. Therefore we also investigated the possibility to apply this in combination with DML quantitation approach for enrichment of low abundant MPs from AD brains. AD and TBI causes severe socio-economic burden on the society and therefore there is a need to develop diagnostic markers to detect the early changes in the pathology of the disease. Analytical tools and techniques applied and discussed in this thesis for neuroproteomics applications proved to be powerful and reliable for analyzing complex biological samples to generate high-throughput screening and unbiased identification and quantitation of disease-specific proteins that are of great importance in understanding the disease pathology.

Brain

Proteomics

Mass spectrometry

Alzheimer's disease

Traumatic brain injury

Membrane proteins

Sample preparation

Regulations of export and chain length of extracellular bacterial polysaccharides

Huang, Hexian

January 2013

Many Gram-positive and Gram-negative bacteria produce an additional thick layer of carbohydrate polymers on the cell wall surface. These capsules (capsular polysaccharides; CPS) play critical roles in interactions between bacteria and their environments (Whitfield, 2006). This is especially important in infection processes since for both Gram-negative and Gram-positive pathogens CPS is the point of first contact with the host immune system (Whitfield, 2006). However, the details of CPS biosynthesis and assembly mechanisms are still unclear. Therefore, we embarked on structural and kinetic studies of the proteins Wzc, Wza and Wzb/ Cps4B from the Wzy-dependent pathway, as well as the protein WbdD from the ATP-binding cassette (ABC) transporter dependent system. Full-length Wzc failed to crystallise due to the presence of large disordered regions and the overall difficulty of membrane protein crystallisation. A truncated version of Wzc (1-480) without the C-terminal tyrosine kinase domain was crystallised and diffracted to 15 Å in house. A previous study suggested Wza and Wzc form a functional complex (Whitfield, 2006), so Wza was also studied. Since the full-length Wza structure is available (C. Dong et al., 2006), Pulsed electron–electron double resonance spectroscopy (PELDOR) was used to study the conformational change. The PELDOR spectroscopy distance fingerprint of Wza was determined. These data also confirmed that PELDOR is a powerful tool to study large, highly symmetrical membrane proteins and can be used to study other complex membrane protein systems, such as ion channels or transporters. The crystal structure of Wzb the cognate phosphatase of Wzc was determined to 2.2 Å. Also Cps4B, which is a functional homologue of Wzb but has a completely unrelated sequence, was crystallised in two crystal forms. Form I and II Cps4B crystals diffracted to 2.8 Å and 1.9 Å resolution in house, respectively. The full-length WbdD failed to crystallise due to the presence of large disordered regions. Therefore, a shorter construct, WbdD₅₅₆ (1-556) was cloned and crystallised. The structure was determined to 2.2 Å. WbdD is a bifunctional enzyme consisting of a methyltransferase (MTase) and a kinase domain. In order to better understand the function of this protein, a variety of techniques were used, such as the ADP-Glo kinase assay, Nuclear magnetic resonance (NMR) spectroscopy, small angle X-ray scattering (SAXS) and X-ray crystallography. The various findings in the current projects provide meaningful insights towards a better understanding of the CPS biosynthesis and assembly mechanisms, which may contribute to a more intensive study identifying inhibitors and beginning to unravel the mechanism of chain length regulation.

572

Generation of recombinant influenza A virus without M2 ion channel protein by introducing a point mutation at the 5' end of viral intron

Cheung, Kai-wing.

January 2004

published_or_final_version / abstract / Microbiology / Master / Master of Philosophy

Mutation (Biology)

Influenza viruses.

Membrane proteins - Genetics.

Ion channels.

Introns.

Viral genetics.

From protein production to genome evolution in Escherichia coli

Schlegel, Susan

January 2013

The aim of my Ph.D. studies was to improve production yields of membrane- and secretory proteins in the widely used E. coli protein production strain BL21(DE3). In this strain expression of the gene encoding the protein of interest is driven by the powerful T7 RNA polymerase (T7 RNAP) whose gene is located on the chromosome and under control of the strong, IPTG-inducible lacUV5 promoter. Unfortunately, the production of many membrane and secretory proteins is 'toxic' to BL21(DE3), resulting in poor growth and low production yields. To understand this ‘toxicity’, the BL21(DE3) derived mutant strains C41(DE3) and C43(DE3) were characterized. Somehow, these strains can efficiently produce many ‘toxic’ membrane and secretory proteins. We showed that mutations weakening the lacUV5 promoter are responsible for this. These mutations result in a slower onset of protein production upon the addition of IPTG, which avoids saturating the Sec-translocon capacity. The Sec-translocon is a protein-conducting channel in the cytoplasmic membrane mediating the biogenesis of membrane proteins and translocation of secretory proteins. Next, we constructed a BL21(DE3)-derivative, Lemo21(DE3), in which the activity of T7 RNAP can be precisely controlled by titrating in its natural inhibitor T7 lysozyme using the rhamnose promoter system. In Lemo21(DE3), the expression level of genes encoding membrane and secretory proteins can be set such that the Sec-translocon capacity is not saturated. This is key to optimizing membrane and secretory protein production yields. Finally, reconstructing the evolution of C41(DE3) from BL21(DE3) in real time showed that during its isolation C41(DE3) had acquired mutations critical for surviving the starvation conditions used, and provided insight in how the mutations in the lacUV5 promoter had occurred. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 3: Manuscript.</p>

Escherichia coli

BL21(DE3)

protein production

membrane proteins

secretory proteins

genome evolution

Structure and lipid interactions of membrane-associated glycosyltransferases : Cationic patches and anionic lipids regulate biomembrane binding of both GT-A and GT-B enzymes

Szpryngiel, Scarlett

January 2016

This thesis concerns work on structure and membrane interactions of enzymes involved in lipid synthesis, biomembrane and cell wall regulation and cell defense processes. These proteins, known as glycosyltransferases (GTs), are involved in the transfer of sugar moieties from nucleotide sugars to lipids or chitin polymers. Glycosyltransferases from three types of organisms have been investigated; one is responsible for vital lipid synthesis in Arabidopsis thaliana (atDGD2) and adjusts the lipid content in biomembranes if the plant experiences stressful growth conditions. This enzyme shares many structural features with another GT found in gram-negative bacteria (WaaG). WaaG is however continuously active and involved in synthesis of the protective lipopolysaccharide layer in the cell walls of Escherichia coli. The third type of enzymes investigated here are chitin synthases (ChS) coupled to filamentous growth in the oomycete Saprolegnia monoica. I have investigated two ChS-derived MIT domains that may be involved in membrane interactions within the endosomal pathway. From analysis of the three-dimensional structure and the amino-acid sequence, some important regions of these very large proteins were selected for in vitro studies. By the use of an array of biophysical methods (e.g. Nuclear Magnetic Resonance, Fluorescence and Circular Dichroism spectroscopy) and directed sequence analyses it was possible to shed light on some important details regarding the structure and membrane-interacting properties of the GTs. The importance of basic amino-acid residues and hydrophobic anchoring segments, both generally and for the abovementioned proteins specifically, is discussed. Also, the topology and amino-acid sequence of GT-B enzymes of the GT4 family are analyzed with emphasis on their biomembrane association modes. The results presented herein regarding the structural and lipid-interacting properties of GTs aid in the general understanding of glycosyltransferase activity. Since GTs are involved in a high number of biochemical processes in vivo it is of outmost importance to understand the underlying processes responsible for their activity, structure and interaction events. The results are likely to be useful for many applications and future experimental design within life sciences and biomedicine. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 2: Manuscript.</p>

glycosyltransferase

monotopic membrane proteins

galactolipids

NMR

chitin synthase

DGD2

LPS

WaaG

MIT domain

Computational studies of transmembrane helix insertion and association

Chetwynd, Alan

January 2011

Membrane proteins perform a variety of functions essential for the viability of the cell, including transport and signalling across the membrane. Most membrane proteins are formed from bundles of transmembrane helices. In this thesis molecular dynamics simulations have been used to investigate helix insertion into bilayers and helix association within bilayers. The potentials of mean force for the insertion of helices derived from the cystic fibrosis transmembrane conductance regulator into lipid bilayers were calculated using coarse-grained molecular dynamics simulations. The results showed that the insertion free energy increased with helix length and bilayer hydrophobic width. The insertion free energies obtained were significantly larger than comparable quantities obtained from translocon- mediated insertion experiments, consistent with a variety of previous studies. The implications of this observation for the interpretation of in vivo translocon-mediated insertion experiments, and the function of the translocon, are discussed. Coarse-grained and atomistic molecular dynamics simulations of the transmembrane region of the receptor tyrosine kinase EphA1 suggested that the transmembrane helix dimer was most stable when interacting via the glycine zipper motif, in agreement with a structure obtained by NMR spectroscopy. Coarse-grained simulations of the transmembrane region of EphA2 suggested that the dimer has two stable orientations, interacting via a glycine zipper or a heptad motif. Both structures showed right-handed dimers, although an NMR structure of the transmembrane region of EphA2 shows a left-handed dimer interacting via the heptad motif. Both structures obtained from coarse-grained simulations proved unstable when simulated at an atomistic level of detail. The potentials of mean force for dissociating the EphA1 and EphA2 dimers were calcu- lated using coarse-grained molecular dynamics calculations. Convergence of the detailed structure of the profiles was not conclusively shown, although association free energies cal- culated from the profiles were consistent over a variety of simulation times. The association free energies were slightly larger than experimental values obtained for comparable sys- tems, but consistent with similar computational calculations previously reported. However, direct comparisons are difficult owing to the influence of environmental factors on reported association free energies. The potential of mean force profiles showed that the interaction via the glycine zipper motif for EphA1 was significantly more stable than any other confor- mation. For EphA2 the potential of mean force profiles suggested that interaction via the glycine zipper and heptad motifs both provided stable or metastable conformations, with the interaction via the glycine zipper motif probably at least as stable as that via the heptad motif.

572.696

Generation of chimeric P-glycoprotein for functional and structural investigations

Pluchino, Kristen Marie

January 2015

A major challenge in cancer treatment is acquired or intrinsic multidrug resistance (MDR) to chemotherapeutics. A notorious mediator of MDR is P-glycoprotein (P-gp, ABCB1), product of the human MDR1 gene, which actively effluxes cytotoxic drugs from cancer cells, resulting in sub-therapeutic intracellular concentrations. Understanding how P-gp interacts with drugs has been severely limited by the lack of high-resolution structures of P-gp. Although numerous efforts to obtain an X-ray crystal structure of P-gp have been attempted, human P-gp has never been crystallized. However, mouse P-gp (87% homologous to human P-gp) has been crystallized, and several structures of mouse P-gp have been recently reported. Despite a high degree of homology, it is currently unknown why mouse P-gp can be crystallized while human P-gp cannot. The studies presented in this thesis describe the creation of novel chimeras of mouse and human P-gp as an approach to investigate whether specific protein domains are responsible for differences in the ability to form crystals between mouse and human P-gp. A range of chimeras, created by protein domain swapping, were expressed in mammalian cells and all were found to retain MDR transport function demonstrating that P-gp can tolerate major structural changes. High-level expression of all chimeras was achieved by baculovirus-mediated heterologous protein expression. Chimeric proteins were purified by a multi-step process including immobilized metal affinity chromatography and size exclusion chromatography. Crystallization screening obtained protein crystals for two of the chimeras, indicating the approach adopted is a successful strategy, and an advance along the path towards a high-resolution structure of human P-gp.

616.99

Structural insights into membrane proteins, membrane protein-lipid interactions and drug metabolites in the gas-phase from ion mobility mass spectrometry

Reading, Eamonn

January 2014

Investigating the structures of membrane proteins and their interactions with lipids remains challenging for well-established biophysical techniques. In this thesis the use of mass spectrometry (MS) and ion mobility (IM) spectrometry were explored for the interrogation of membrane proteins, their stoichiometry, stability and interactions with lipids. The techniques used were also applied to the identification of drug metabolites. In the first two chapters reviews of both mass spectrometry methods, and membrane protein biogenesis and membrane protein-lipid interactions are presented. The first challenge for studying membrane proteins by MS was to optimise solution conditions. A detergent screening strategy was developed for this purpose (Chapter 3). The various detergent environments studied revealed dramatic differences in mass spectral quality permitting investigation of membrane protein-lipid interactions. Changes were observed in the electrospray charging of membrane proteins and trends were established from an extensive collection of membrane proteins ejected from a wide variety of detergent environments. The physicochemical principles behind the MS of membrane proteins were deduced and are presented (Chapter 4). The results of these experiments led to a deeper understanding of the ionisation processes and the influence of detergent micelles on both charge state and release mechanisms. Experiments from a range of different micelles also allowed the influence of charge and its effects on the preservation of native-like membrane protein conformations to be monitored by IM-MS. By resolving lipid-protein interactions, and by monitoring the effects of lipid binding on the unfolding of three diverse membrane protein complexes, substantial differences in the selectivity of membrane proteins for different lipids were revealed (Chapter 5). Interestingly lipids that stabilised membrane proteins in the gas-phase were found to induce modifications in structure or function thus providing an approach to assess direct lipid contributions, and to rank order lipids based on their ability to modulate membrane proteins. Using the MS approaches developed here also enabled study of the diversity of oligomeric states of the mechanosensitive channel of large conductance (MscL) (Chapter 6). Results revealed that the oligomeric state of MscL is sensitive to deletions in its C-terminal domain and to its detergent-lipid environment. Additionally, a case study with GlakoSmithKline (GSK) was undertaken using IM-MS technology but in this case applied to the identification of drug metabolites (Chapter 7). The results showed that IM-MS and molecular modelling could inform on the identity of different drug metabolites and highlights the potential of this approach in understanding the structure of various drug metabolites.

572

Development of a suite of bioinformatics tools for the analysis and prediction of membrane protein structure

Togawa, Roberto Coiti

January 2006

This thesis describes the development of a novel approach for prediction of the three-dimensional structure of transmembrane regions of membrane proteins directly from amino acid sequence and basic transmembrane region topology. The development rationale employed involved a knowledge-based approach. Based on determined membrane protein structures, 20x20 association matrices were generated to summarise the distance associations between amino acid side chains on different alpha helical transmembrane regions of membrane proteins. Using these association matrices, combined with a knowledge-based scale for propensity for residue orientation in transmembrane segments (kPROT) (Pilpel et al., 1999), the software predicts the optimal orientations and associations of transmembrane regions and generates a 3D structural model of a gi ven membrane protein, based on the amino acid sequence composition of its transmembrane regions. During the development, several structural and biostatistical analyses of determined membrane protein structures were undertaken with the aim of ensuring a consistent and reliable association matrix upon which to base the predictions. Evaluation of the model structures obtained for the protein sequences of a dataset of 17 membrane proteins of detennined structure based on cross-validated leave-one-out testing revealed generally high accuracy of prediction, with over 80% of associations between transmembrane regions being correctly predicted. These results provide a promising basis for future development and refinement of the algorithm, and to this end, work is underway using evolutionary computing approaches. As it stands, the approach gives scope for significant immediate benefit to researchers as a valuable starting point in the prediction of structure for membrane proteins of hitherto unknown structure.

572.696028

Single-molecule chemistry studied using the protein pore -α-hemolysin

Choi, Lai-Sheung

January 2012

Single-molecule detection has provided insights into how molecules behave. Without the averaging effect of ensemble measurements, the stochastic behaviour of single molecules can be observed and intermediate steps in multistep transformations can be clearly detected. The single-molecule reactants range from small molecules (e.g. propene) to proteins of several tens of kDa (e.g. myosin). One single-molecule detection technique is single-channel electrical recording. This approach is based on the measurement of the transmembrane ionic current flowing through a nanoscale transmembrane pore under an applied potential. In this thesis, the protein α-hemolysin was employed as a nanoreactor. α-Hemolysin is a toxin secreted by Staphylococcus aureus. Its transmembrane pore (~100 Å in length and ≥14 Å in diameter) allows ions, water and small molecules to pass through its lumen. Under an applied potential, chemical changes in reactants attached to the internal wall of the pore modulate the flow of ions, leading to changes in the transmembrane ionic current. Analysis of this current provides information about the reaction kinetics and mechanisms. Chapter 1 – Single-Molecule Chemistry and α-Hemolysin is an introductory chapter that is divided into two parts. Section 1.1 provides an overview of the different techniques for the detection of chemical reactions at the single-molecule level. Section 1.2 gives a brief review of the protein pore α-hemolysin, including its structure, properties and various applications. Chapter 2 – S-Nitrosothiol Chemistry applies cysteine-containing α-hemolysins to study the biologically relevant chemistry of S-nitrosothiols (RSNO). RSNO are important molecules involved in cell signalling, which control physiological processes such as vasodilation and bronchodilation. Three reactions, namely transnitrosation (the transfer of the ‘NO’ group from RSNO to a thiol), S-thiolation (the formation of a disulfide from RSNO and thiol) and S-sulfonation (the generation of an S-sulfonate (RSSO₃⁻) from RSNO and sulfite ion), were investigated at the single-molecule level. The pH-dependency of the two competing reactions (transnitrosation and S-thiolation), the lifetime of the proposed transnitrosation intermediate, and nature of the chemical reaction between RSNO and sulfite (a bronchoconstrictor) were determined. Chapter 3 – Silver(I)-thiolate and cadmium(II)-thiolate complexes describes the kinetics of the formation and breakdown of these two metal-thiolate complexes. Ag⁺ and Cd²⁺ are commonly used in probing the membrane topology and gating properties of ion channels using the scanning cysteine accessibility method (SCAM). The binding of two Ag⁺ ions per thiol group and the stepwise build-up and dissociation of Cd²⁺-glutathione complexes were unambiguously characterized. Chapter 4 – Copper(II)-Catalyzed Diels-Alder Reactions reports the attempt to carry out copper(II)-catalyzed Diels-Alder reactions inside an engineered α-hemolysin. An iminodiacetate ligand was covalently attached within the lumen of the α-hemolysin pore. This ligand chelates Cu²⁺ ion, which can bind bidentate dienophiles and activate them towards Diels-Alder reaction with dienes. However, due to the ‘slow’ reaction rate of the Diels-Alder reaction (rate constant ~10⁻¹ M⁻¹s⁻) relative to the time-scale of the single-molecule experiment, we failed to observed chemical conversion at the single-molecule level. Nevertheless, the engineered metal-binding α-hemolysin may be useful for sensing molecules bearing metal-coordinating groups.

541.39