SUBSTRATE BINDING SITE FLEXIBILITY OF SMALL HEAT SHOCK PROTEINS AND FACTORS CONTRIBUTING TO EFFICIENT CHAPERONE ACTIVITY

Jaya, Nomalie Naomi

January 2009

sHSPs maintain partially denaturing substrates in a soluble sHSP-substrate complex. The heterogeneous interaction between sHSPs and substrate within the complex has prevented a detailed study of the mechanism of sHSP substrate protection. Here, purified sHSPs and heat sensitive substrates were used to investigate the mechanism of sHSP chaperone action. Results presented provide new insights into how sHSPs recognize substrates, the architecture of the sHSP-substrate complex and factors contributing to chaperone efficiency.Direct evidence defining the role of the sHSP N-terminal arm and alpha crystallin domain in sHSP-substrate interactions is limited. A photoactivatable probe was site- specifically incorporated into PsHsp18.1, and cross-linking to substrate in sHSP-substrate complexes was quantified. The structurally flexible N-terminal arm of PsHsp18.1 makes strong contacts with both substrates tested, however differences in interaction were seen in the conserved alpha crystallin domain. Regions on the sHSP showing the strongest cross-links to substrates are buried within the dodecamer, supporting the model that the sHSP oligomer undergoes rearrangement or dissociation prior to substrate interactions.The arrangement of sHSPs and substrates whithin the complex is poorly defined. Limited proteolysis and chemical modification was combined with mass spectrometry to probe the sHSP-substrate complex using multiple sHSPs and substrates. This analysis reveals that a similar partially-denatured form of substrate is protected in the complex irrespective of sHSP identity. Further, sHSP in the complex is protected from proteolysis for a longer time compared to free sHSP. These data suggest that sHSPs and substrate are distributed both internally and on the periphery of the sHSP-substrate complex.Exact properties of the sHSP N-terminal arm contributing to protection are poorly defined. A molecular dynamics (MD) study was designed to test the hypothesis that the N-terminal arm could assume multiple conformations that can readily interact with denaturing substrates. Preliminary data suggest that at increased temperatures amino acids in the N-terminal arm form specific clusters which could act as substrate interaction sites. MD simulations, mutagenesis and altering the kinetics of substrate aggregation suggest that the conformational space occupied by the N-terminal arm at increased temperatures, along with flexibility and rate of substrate aggregation contribute to differences in chaperone efficiency.

Alpha-crystallin

Chaperones

Cross-linking

Intrinsic disorder

Mass spectrometry

Protein-protein interactions

Characterization of Macromolecular Protein Assemblies by Collision-Induced and Surface-Induced Dissociation: Expanding the Role of Mass Spectrometry in Structural Biology

Jones, Christopher Michael

January 2008

This dissertation presents an investigation into the structure of macromolecular protein assemblies by mass spectrometry. The experiments described within are designed to systematically assess the analytical utility of surface-induced dissociation (SID) tandem mass spectrometry in the characterization of multi-subunit protein complexes. This is accomplished by studying the effects of ion-surface collision on the fragmentation products of protein assemblies that vary by mass, number of subunits, and protein structural features. The dissociation energetics and mechanisms of protein complexes are considered by examining the influence of ion internal energy and sub-oligomeric protein structure on the dissociation process. Conditions are first established for the preservation of “native” protein quaternary structure and applied to previously characterized systems for proof-ofconcept. These conditions are subsequently extended to determine the molecular weight and subunit stoichiometry of several small heat shock proteins. Native mass spectrometry is then combined with limited proteolysis experiments to characterize the subunit interface of a unique small heat shock protein, Hsp18.5 from Arabidopsis thaliana, identifying regions of the protein essential for preservation of the native dimer. The dissociation of non-covalent protein assemblies is then explored on a quadrupole time-of-flight (Q-TOF) mass spectrometer, modified for the study of ion-surface collisions. This instrument allows ions to be dissociated through collisions with a surface or more conventional collisions with gas atoms. The dissociation of protein complexes is explored by both activation methods beginning with specific and non-specific dimers with masses less than 40 kDa. These studies are extended to larger assemblies with as many as 14 subunits weighing over 800 kDa, and are applied to both homo- and hetero-oligomeric protein complexes. Activation of a protein complex with “n” subunits through multiple collisions with inert gas atoms results in asymmetric dissociation into a highly charged monomer and complementary (n-1)-mer regardless of protein size or subunit architecture. This process is known to occur through an unfolding of the ejected subunit, and limits the amount of structural insight that can be gleaned from such studies. Collision at a surface however, results in more charge and mass symmetric fragmentation, and in some instances reflects the substructure of the protein assembly under investigation. The differences observed between the CID and SID of protein complexes is attributed to the rapid deposition of large amounts of internal energy deposited upon collision at a more massive target such as a surface. The ion activation time-frame and energy transfer efficiency are proposed to induce dissociation on a time-scale that precedes subunit unfolding providing access to dissociation pathways that are inaccessible by traditional means of activation. The systems studied here represent the largest ions fragmented via surface collisions within a mass spectrometer, and the fragmentation products observed by SID demonstrate its promise for expanding the role of mass spectrometry in the field of structural biology.

Collision-Induced Dissociation

Ion Activation

Mass Spectrometry

Protein Complexes

Protein Interactions

Surface-Induced Dissociation

PROBING GAS-PHASE PEPTIDE STRUCTURE AND PROTEIN-PROTEIN INTERACTIONS USING MASS SPECTROMETRIC TECHNIQUES

Perkins, Brittany

January 2009

Presented in this dissertation are studies on the gas-phase structural features of peptides and peptide fragment ions using mass spectrometry (MS), hydrogen/deuterium (H/D) exchange, infrared multiphoton dissociation (IRMPD) spectroscopy, and computational modeling. Additional studies are presented on the mechanism of hydrogen/deuterium exchange using a model amino acid system. The application of chemical cross-linking to investigate the interaction between two proteins, LexA and RecA, is also presented. Gas-phase structural features can be probed using a number of techniques, and several of the studies presented in this dissertation involve the use of gas-phase H/D exchange. Although the basic mechanism for exchange has been determined, the factors that affect the rate and extent of exchange are not well understood. A computational modeling study of the exchange behavior of asparagine and its methyl ester demonstrated that exchange will occur preferentially at sites of more similar basicity. The distinctive exchange behavior of a model histidine-containing pentapeptide, HAAAA, prompted further studies into the structural features that result in five fast exchanging hydrogens and one slower exchange. Peptide analogues were used to identify the sites of exchange, and IRMPD spectroscopy combined with computational modeling indicated that exchange may occur because interaction with water at those sites results in lower energy structures compared to the other sites. Structural studies were also performed to determine whether the b₂⁺ ion from HAAAA is an oxazolone or diketopiperazine. Although the IRMPD spectrum matched that of a diketopiperazine, H/D exchange and fragmentation studies revealed the presence of both a diketopiperazine and oxazolone structure. Protein-protein interactions perform a vital role in regulating cellular processes. Despite extensive mutational analysis, the binding interaction between LexA and RecA, two proteins involved in the SOS response, is unclear. Chemical cross-linking experiments were undertaken to help target future mutational studies, and these studies identified two possible interactions. The first potential binding interaction is located in the cleft of RecA, and the second interaction may be caused by a LexA dimer binding across the RecA helical groove. The presence of two different binding interactions suggests that LexA may have redundant binding modes for RecA interaction.

chemical cross-linking

gas-phase structure

H/D exchange

mass spectrometry

protein-protein interactions

In vitro studies of protein interactions on substrate supported artificial membranes

Morick, Daniela

23 January 2013

Da eine Vielzahl von Proteininteraktionen innerhalb zellulärer Organismen an der Grenzfläche zu Membranen stattfindet, ist die Untersuchung dieser Prozesse von gro-ßem wissenschaftlichem Interesse. Ziel dieser Arbeit war es Modellsysteme basierend auf artifiziellen Membranen zu entwickeln, mit deren Hilfe die Untersuchung ausge-wählter Proteininteraktionen ermöglicht werden konnte. Im ersten Abschnitt dieser Arbeit (Kapitel 4-6) wurde ein Biosensorassay basierend auf festköperunterstützten Membranen entwickelt, der die Quantifizierung der Interaktion von C-Polycystin-2 (cPC2) mit seinen Interaktionspartnern C-Polycystin-1 (cPC1) und PIGEA14 mittels der Quarzmikrowaagetechnik ermöglichte. Aufgrund der Tatsache, dass die Affinität von cPC2 zu cPC1 in Anwesenheit von Ca2+ dreifach höher war, wurde eine Ca2+ abhängige Trimerisierung von cPC2 postuliert. Die Unterschiede der ermittelten kinetischen Koeffizienten führten zur Entwicklung eines Bindunsgmodells, welches die dreistufige Adsorption von cPC2 an cPC1 in Abwesenheit bzw. einstufige Adsorption in Anwesenheit von Ca2+ implizierte. Im Falle der Interaktion von cPC2 mit PIGEA14 wurde die Abhänigkeit der cPC2 Bindung von der Pseudophosphorylie-rung des Proteins an Ser812 untersucht. Es wurde festgestellt, dass die Affinität der pseudophosphorylierten Mutante cPC2S812D zu PIGEA14 zweifach niedriger war, als die von cPC2wt. Im zweiten Abschnitt der Arbeit (Kapitel 7 und 8) wurde die spezifische Wechselwir-kung von filamentösem Aktin (F-Aktin) mit festkörperunterstützten und porenüber-spannenden Membranen untersucht. Die kontrollierte Anbindung von F-Aktin in und auf porösen Aluminiumoxidfilmen konnte mit Hilfe verschiedener Funktionalisie-rungsstrategien erzielt werden. Der Einfluss eines F-Aktin Netzwerks auf die Span-nung und viskoelastischen Eigenschaften porenüberspannender Membranen wurde mittels kraftmikroskopischer Studien untersucht. Es wurde nachgewiesen, dass der Einfluss von gebundenem F-Aktin auf die Membranspannung gering war, aber erst durch die F-Aktin Adhäsion viskoelastische Membraneigenschaften induziert wurden.

540

protein-protein interactions

artificial membranes

Polycystin-2

F-actin

Chemie  (PPN62138352X)

Membrane-mimetic systems : Novel methods and results from studies of respiratory enzymes

Nordlund, Gustav

January 2013

The processes localized to biological membranes are of great interest, both from a scientific and pharmaceutical point of view. Understanding aspects such as the detailed mechanism and regulation of these processes requires investigation of the structure and function of the membrane-bound proteins in which they take place. The study of these processes is often complicated by the need to create in vitro systems that mimic the environment in which these proteins are normally found in vivo. This thesis describes some of the methods available for membrane-protein studies in membrane-mimetic systems, as well as our work aimed at developing such systems. Furthermore, results from studies using these systems are described. In the first two studies, described in Papers I &amp; II, we investigated the use of silica particle-supported lipid bilayers, both for membrane-protein studies and as possible drug-delivery vehicles. Successful reconstitution of a multisubunit proton-pump, cytochrome c oxidase is described and characterized. Initial attempts to develop drug-delivery systems with two different targeting peptides are also described in the thesis. The second part of this thesis revolves around our work with membraneprotein dependent pathways. Results from studies of systems where the proton- pump bo3 oxidase and ATP synthase work in concert are described. The results show a surprising lipid-composition dependence for the coupled bo3- ATP-synthase activity (Paper III). Finally, a new system utilizing synaptic vesicle-fusion proteins for coreconstitution of membrane proteins is described, showing successful coreconstitution of a small respiratory chain, delivery of soluble proteins to preformed liposomes and reconstitution of ATP synthase in native membranes (Paper IV). / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 4: Manuscript.</p>

Lipids

membrane proteins

method development

respiration

reconstitution

supported membranes

SNAREs

liposome fusion

lipid-protein interactions

Role and Regulation of Starch Phosphorylase and Starch Synthase IV in Starch Biosynthesis in Maize Endosperm Amyloplasts

Subasinghe, Renuka

17 January 2013

Storage starch is synthesized in sub-cellular organelles called amyloplasts in higher plants. The synthesis of the starch granule is a result of the coordinated activity of several groups of starch biosynthetic enzymes. There are four major groups of these enzymes, ADP-glucose pyrophosphorylase (AGPase), starch synthases (SS), starch branching enzymes (SBE), and starch debranching enzymes (SDE). Starch phosphorylase (SP) exists as both dimeric and tetrameric forms in plastids in developing cereal endosperm and catalyses the reversible transfer of glucosyl units from glucose-1-phosphate to the non-reducing end of α-1-4 linked glucan chains, although the precise role in the pathway remains unclear. The present study was conducted to investigate the role and regulation of SP and SSIV in starch biosynthesis in developing maize endosperm. The results of this study showed that the tetrameric form of SP accounts for the majority of measurable catalytic activity, with the dimeric form being barely active and the monomer catalytically inactive. A catalytically active recombinant maize SP was heterologously expressed and used as an affinity ligand with amyloplast lysates to test protein-protein interactions in vitro. Results showed that the different multimeric status of SP influenced interactions with other enzymes of starch synthesis. Tetrameric SP interacted with SBEI and SSIIa, whilst the dimeric form of the enzyme interacted with SBEI, SBEIIb. All of these interactions were enhanced when amyloplasts were pre-treated with ATP, and broken following treatment with alkaline phosphatase (APase), indicating these interactions are regulated by protein phosphorylation. In addition, the catalytic activity of SSIV was reduced following treatment with APase, indicating a role for protein phosphorylation in the regulation of SSIV activity. Protein-protein interaction experiments also suggested a weak interaction between SSIV and SP. Multimeric forms of SP regulated by protein-protein interactions and protein phosphorylation suggested a role for SP in starch biosynthesis in maize endosperm.

RNA Backbone Validation, Correction, and Implications for RNA-Protein Interfaces

Kapral, Gary Joseph

January 2013

<p>RNA is the molecular workhorse of nature, capable of doing many cellular tasks, from genetic data storage and regulation, to enzymatic synthesis--even to the point of self-catalyzing its own replication. While RNA can act as a catalyst on its own, as in the hammerhead ribozyme, the added efficiency of proteins is often a necessity; the ribosome--the large ribozyme responsible for peptide chain formation, is aided by proteins which ensure correct assembly and structural stability. These complexes of RNA and proteins feature in many essential cellular processes, including the RISC silencing complex and in the spliceosome. Despite its enormous utility, structural determination of RNA is notoriously difficult--particularly in the backbone, since a nucleotide standardly has 12 torsion angles (including &#967;) and 12 non-hydrogen atoms, compared to 4 torsions (including &#967;1) and 4 non-H atoms in a typical amino acid. The abundance of backbone atoms, their conformational flexibility, and experimental resolution limitations often result in systematic errors that can have a significant impact on the interpretation. False trails due to structural errors can lead to significant loss of time and effort, especially with such high-profile complexes as the ribosome and the RISC complex. </p><p>My research has focused on harnessing the recently discovered ribosome structures and the Richardsons' RNA dataset to find trends in RNA backbone conformations and motifs that were then used to develop structural validation techniques and provide improved diagnosis and correction techniques for RNA backbone. Methods for fixing RNA structure have been developed for both NMR and X-ray crystallography. For NMR structures, a method for assigning RNA backbone structure based on NOE data was developed, leading to improved identification and building of RNA backbone conformation in NMR ensembles. For crystallography, our method of diagnosing the correct ribose pucker from clear observables allows reliable assessment of pucker in validation or refinement. Observed differences in bond-lengths, bond-angles, and dihedrals have been categorized by sugar pucker in the PHENIX refinement package. I have shown that this improves the refinement behavior of both pucker and geometry. </p><p>There have also been improvements in identifying structural motifs. Many previously identified structural motifs have now been defined in terms of backbone suitestrings, a series of 2-character code divisions of RNA backbone that show the best clustering of dihedral angle correlations. Combined with a BLAST-like alignment program called SuiteAlign, these suitestrings were quickly and easily identified in a number of structures, eventually leading to the discovery of multiple instances of T&#968;C-loop structures in the ribosome.</p><p>To facilitate error diagnosis and corrections in RNA-protein complexes, as well as to expand the knowledge base of the scientific community as a whole, a database of RNA-protein interaction motifs has been developed. This database is rooted in the quality-filtering, visualization, and analysis techniques of the Richardson lab, particularly those developed by Laura Murray specifically for RNA structures.</p><p>The consensus backbone conformers, pucker diagnosis, and all-atom contacts have been combined to develop first manual and then automated tools for RNA structure correction. I have applied all these techniques to improve the accuracy of a number of important RNA and RNA/protein complex structures.</p> / Dissertation

Biochemistry

Ribosome

RNA

RNA motif

RNA-protein interactions

Structural Biology

Suite

Characterization of NP22 and its Potential Role in NMDA Receptor-mediated Transmission

Gulersen, Moti

08 December 2011

N-methyl D-aspartate (NMDA) receptors represent integral signal transducers for excitatory glutamate neurotransmission. While NMDA receptors are critical for synaptic plasticity, the molecular events underlying this process are not fully elucidated. The potential role of NP22, a novel neuronal protein, as a downstream mediator of NMDA receptor function is explored. NP22 protein expression in genetic and pharmacological models of NMDA receptor hypofunction is examined and no significant changes are reported. Characterization of the NP22 protein complex via tandem-affinity and FLAG-purification coupled with mass spectrometry was used and no novel protein interactions are reported. GFP-tagged NP22 colocalization with F-actin decreases in cell processes of transiently transfected HEK293 cells in response to elevated intracellular calcium, while similar colocalization reductions are not seen in stably transfected HEK293 under a comparable treatment regiment. Changes in intracellular calcium affecting NP22 biology can be useful in the ongoing characterization of this novel protein.

NMDA

neuroscience

protein interactions

NP22

synaptic plasticity

affinity purification

0419

0383

Characterization of PilP from the Type IV Pilus System of Pseudomonas aeruginosa

Tammam, Stephanie

16 December 2013

Pathogenic bacteria employ a number of mechanisms to induce infection and survive in host tissues, including toxin secretion and the formation of protective multicellular structures called biofilms. Type IV Pili (T4P) are highly conserved organelles essential for both the establishment of infection and biofilm maturation. The goal of this research is to gain a molecular level understanding of the function of the highly dynamic T4P of Pseudomonas aeruginosa. The pilMNOPQ operon encodes 5 members of a transmembrane complex that facilitates pilus function. While PilQ is the putative outer membrane secretin through which the pilus exits the cell, the roles of the PilM/N/O/P proteins are less well defined. Using both in vivo and in vitro techniques our characterization of PilP has provided significant insight into organization of the apparatus. PilP is an inner membrane lipoprotein essential for T4P function, but lipidation is dispensable, suggesting that its interactions with other T4P components are sufficient for PilP function. We showed that PilN/O/P form a stable heterotrimer when expressed in E. coli, and we suggest that they form a similar subcomplex in P. aeruginosa. Additionally we were able to show that PilP is also able to interact with a periplasmic fragment of the outer membrane pore protein PilQ. Structural and bioinformatics studies suggest that the organization of PilN/O/P/Q complex is similar to that of the transenvelope complex of another important Gram-negative virulence factor – the Type II Secretion System (T2SS). Our structural and functional characterization of PilP, the PilN/O/P complex and the striking similarities between the T4P and T2S systems, as well as important differences that make each molecular machine unique, will be presented.

P. aeruginosa

virulence factors

protein-protein interactions

Type IV Pili

0306

0410

0307

Characterization of PilP from the Type IV Pilus System of Pseudomonas aeruginosa

Tammam, Stephanie

16 December 2013

Pathogenic bacteria employ a number of mechanisms to induce infection and survive in host tissues, including toxin secretion and the formation of protective multicellular structures called biofilms. Type IV Pili (T4P) are highly conserved organelles essential for both the establishment of infection and biofilm maturation. The goal of this research is to gain a molecular level understanding of the function of the highly dynamic T4P of Pseudomonas aeruginosa. The pilMNOPQ operon encodes 5 members of a transmembrane complex that facilitates pilus function. While PilQ is the putative outer membrane secretin through which the pilus exits the cell, the roles of the PilM/N/O/P proteins are less well defined. Using both in vivo and in vitro techniques our characterization of PilP has provided significant insight into organization of the apparatus. PilP is an inner membrane lipoprotein essential for T4P function, but lipidation is dispensable, suggesting that its interactions with other T4P components are sufficient for PilP function. We showed that PilN/O/P form a stable heterotrimer when expressed in E. coli, and we suggest that they form a similar subcomplex in P. aeruginosa. Additionally we were able to show that PilP is also able to interact with a periplasmic fragment of the outer membrane pore protein PilQ. Structural and bioinformatics studies suggest that the organization of PilN/O/P/Q complex is similar to that of the transenvelope complex of another important Gram-negative virulence factor – the Type II Secretion System (T2SS). Our structural and functional characterization of PilP, the PilN/O/P complex and the striking similarities between the T4P and T2S systems, as well as important differences that make each molecular machine unique, will be presented.

P. aeruginosa

virulence factors

protein-protein interactions

Type IV Pili

0306

0410

0307