Identification of Ryanodine Receptor 1 (RyR1) Interacting Protein Partners Using Liquid Chromatography and Mass Spectrometry

Ryan, Timothy

13 January 2011

Ryanodine receptor 1 (RyR1) is a homotetrameric calcium channel located in the sarcoplasmic reticulum (SR) of skeletal muscle. We employed metal affinity chromatography followed by liquid chromatography mass spectrometry from HEK-293 cells to purify affinity tagged cytosolic RyR1, with interacting proteins. In total, we identified 703 proteins with high confidence (>99%). Of the putative RyR1 interacting proteins, five candidates [calcium homeostasis endoplasmic reticulum protein (CHERP), ER-golgi intermediate compartment 53kDa protein (LMAN1), T-complex protein (TCP), phosphorylase b kinase (PHBK) and four and half LIM domains protein 1 (FHL1)], were selected for interaction studies. Immunofluorescence analysis showed that CHERP co-localizes with RyR1 in the SR of rat soleus muscle. Calcium transient assays in HEK293 cells over-expressing RyR1 with siRNA suppressed CHERP or FHL1, showed reduced calcium release via RyR1. In conclusion, we have identified RyR1 interacting proteins in CHERP and FHL1 which may represent novel regulatory mechanisms involved in excitation-contraction coupling.

Ryanodine Receptor 1

Metal affinity chromatography

Mass Spectrometry

Protein-protein interactions

0719

Identification of Ryanodine Receptor 1 (RyR1) Interacting Protein Partners Using Liquid Chromatography and Mass Spectrometry

Ryan, Timothy

13 January 2011

Ryanodine receptor 1 (RyR1) is a homotetrameric calcium channel located in the sarcoplasmic reticulum (SR) of skeletal muscle. We employed metal affinity chromatography followed by liquid chromatography mass spectrometry from HEK-293 cells to purify affinity tagged cytosolic RyR1, with interacting proteins. In total, we identified 703 proteins with high confidence (>99%). Of the putative RyR1 interacting proteins, five candidates [calcium homeostasis endoplasmic reticulum protein (CHERP), ER-golgi intermediate compartment 53kDa protein (LMAN1), T-complex protein (TCP), phosphorylase b kinase (PHBK) and four and half LIM domains protein 1 (FHL1)], were selected for interaction studies. Immunofluorescence analysis showed that CHERP co-localizes with RyR1 in the SR of rat soleus muscle. Calcium transient assays in HEK293 cells over-expressing RyR1 with siRNA suppressed CHERP or FHL1, showed reduced calcium release via RyR1. In conclusion, we have identified RyR1 interacting proteins in CHERP and FHL1 which may represent novel regulatory mechanisms involved in excitation-contraction coupling.

Ryanodine Receptor 1

Metal affinity chromatography

Mass Spectrometry

Protein-protein interactions

0719

Design Genetic Fluorescent Probes to Detect Protease Activity and Calcium-Dependent Protein-Protein Interactions in Living Cells

Chen, Ning

25 August 2008

Proteases are essential for regulating a wide range of physiological and pathological processes. The imbalance of protease activation and inhibition will result in a number of major diseases including cancers, atherosclerosis, and neurodegenerative diseases. Although fluorescence resonance energy transfer (FRET)-based protease probes, a small molecular dye and other methods are powerful, they still have drawbacks or limitations for providing significant information about the dynamics and pattern of endogenous protease activation and inhibition in a single living cell or in vivo. Currently protease sensors capable of quantitatively measuring specific protease activity in real time and monitoring activation and inhibition of enzymatic activity in various cellular compartments are highly desired. In this dissertation, we report a novel strategy to create protease sensors by grafting an enzymatic cleavage linker into a sensitive location for changing chromophore properties of enhanced green fluorescent protein (EGFP) following protease cleavage, which can be used to determine protease activity and track protease activation and inhibition with a ratiometric measurement mode in living cells. Our designed protease sensors exhibit large relative ratiometric optical signal change in both absorbance and fluorescence, and fast response to proteases. Meanwhile, these protease sensors exhibiting high enzymatic selectivity and kinetic responses are comparable or better than current small peptide probes and FRET-based protease probes. Additionally, our protease sensors can be utilized for real-time monitoring of cellular enzymogen activation and effects of inhibitors in living cells. This novel strategy opens a new avenue for developing specific protease sensors to investigate enzymatic activity in real time, to probe disease mechanisms corresponding to proteases in vitro and in vivo, and to screen protease inhibitors with therapeutic effects. Strong fluorescence was still retained in the cleaved EGFP-based protease sensors, which stimulated us to identify the EGFP fragment with fluorescence properties for further understanding chromophore formation mechanisms and investigating protein-protein interactions through fluorescence complementation of split EGFP fragments. Through fusing EF-hand motifs from calbindin D9k to split EGFP fragments, a novel molecular probe was developed to simultaneously track the calcium change or calcium signaling pathways and calcium-dependent protein-protein interaction in living cells in real time.

Protein-protein interactions

Calcium-dependent

Fluorescence complementation

EGFP

Ratiometeric measurement

Protease sensor

Chemistry

Relating the Bulk and Interface Structure of Hyaluronan to Physical Properties of Future Biomaterials

Berts, Ida

January 2013

This dissertation describes a structural investigation of hyaluronan (HA) with neutron scattering techniques. HA is a natural biopolymer and one of the major components of the extracellular matrix, synovial fluid, and vitreous humor.  It is used in several biomedical applications like tissue engineering, drug delivery, and treatment of osteoarthritis. Although HA is extensively studied, very little is known about its three-dimensional conformation and how it interacts with ions and other molecules. The study aims to understand the bulk structure of a cross-linked HA hydrogel, as well as the conformational arrangement of HA at solid-liquid interfaces. In addition, the structural changes of HA are investigated by simulation of physiological environments, such as changes in ions, interactions with nanoparticles, and proteins etc. Small-angle neutron scattering and neutron reflectivity are the two main techniques applied to investigate the nanostructure of hyaluronan in its original, hydrated state. The present study on hydrogels shows that they possess inhomogeneous structures best described with two correlation lengths, one of the order of a few nanometers and the other in the order of few hundred nanometers. These gels are made up of dense polymer-rich clusters linked to each other. The polymer concentration and mixing governs the connectivity between these clusters, which in turn determines the viscoelastic properties of the gels. Surface-tethered HA at a solid-liquid interface is best described with a smooth varying density profile. The shape of this profile depends on the immobilization chemistry, the deposition protocol, and the ionic interactions. HA could be suitably modified to enhance adherence to metal surfaces, as well as incorporation of proteins like growth factors with tunable release properties. This could be exploited for surface coating of implants with bioactive molecules. The knowledge gained from this work would significantly help to develop future biomaterials and surface coatings of implants and biomedical devices.

hyaluronan

structure

bulk

interface

small-angle neutron scattering

neutron reflection

hydrogel

grafting

nanoparticles

protein interactions

Calmodulin Binding and Activation of Mammalian Nitric Oxide Synthases

Spratt, Donald Eric

23 April 2008

Calmodulin (CaM) is a ubiquitous cytosolic Ca2+-binding protein involved in the binding and regulation of more than three-hundred intracellular target proteins. CaM consists of two globular domains joined by a central linker region. In the archetypical model of CaM binding to a target protein, the Ca2+-replete CaM wraps its two domains around a single α-helical target peptide; however, other conformations of CaM bound to target peptides and proteins have recently been discovered. Due to its ability to bind and affect many different intracellular processes, there is significant interest in a better understanding of the structural and conformational basis of CaM’s ability to bind and recognize target proteins. The mammalian nitric oxide synthase (NOS) enzymes are bound and activated by CaM. The NOS enzymes catalyze the production of nitric oxide (•NO), a free radical involved in numerous intercellular processes such as neurotransmission, vasodilation, and immune defense. There are three different isoforms of nitric oxide synthase (NOS) found in mammals – neuronal NOS (nNOS), endothelial NOS (eNOS), and inducible NOS (iNOS). All three enzymes are homodimeric with each monomer consisting of an N-terminal oxygenase domain and a multidomain C-terminal reductase domain. A CaM-binding domain separates the oxygenase and reductase domains. There is a unique opportunity to investigate CaM’s control over •NO production by the NOS enzymes since each isoform shows a different mode of activation and control by CaM. At elevated cellular Ca2+ concentrations, CaM is able to bind and activate nNOS and eNOS. In contrast, the iNOS isozyme is transcriptionally regulated and binds to CaM in the absence of Ca2+. The focus of this thesis is to better our present understanding of the conformational and structural basis for CaM’s ability to bind and activate the three mammalian NOS isozymes with particular emphasis on the interactions between CaM and iNOS. To further investigate the differences in the association of CaM to the Ca2+-dependent and Ca2+-independent NOS isoforms, a variety of CaM mutants including CaM-troponin C chimeras, CaM EF hand pair proteins, and CaM mutants incapable of binding to Ca2+ were employed. The inherent differences in binding and activation observed using these CaM mutants is described. Differences in the binding of the N- and C-terminal domains, as well as the central linker of CaM to peptides corresponding to the CaM-binding domain of each NOS enzyme and holo-NOS enzymes was investigated. The conformation of CaM when bound to NOS peptides and holo-NOS enzymes was also studied using fluorescence (Förster) resonance energy transfer (FRET). A preliminary three-dimensional structural study of Ca2+-replete and Ca2+-deplete CaM in complex with an iNOS CaM-binding domain peptide is also described. Combining the cumulative results in this thesis, a working model for iNOS’s regulation by CaM is proposed. Future suggested experiments are described to further the characterization of CaM binding to the NOS enzymes and other CaM-target proteins. The studies described in this thesis have expanded and improved the present understanding of the CaM-dependent binding and activation of the NOS isozymes, particularly the interactions between CaM and iNOS.

Calmodulin

Nitric Oxide Synthase

Fluorescence

Protein-protein interactions

FRET

Calcium

Chemistry

Developing Dirhodium-Complexes for Protein Inhibition and Modification & Copper-Catalyzed Remote Chlorination of Alkyl-Hydroperoxides

Kundu, Rituparna

16 September 2013

The work describes the development of a new class of protein-inhibitors for protein-protein interactions, based on metallopeptides comprised of a dirhodium metal center. The metal incorporation in the peptide sequence leads to high increase in binding affinity of the inhibitors. The source of this strong affinity is the interaction of histidine on the protein surface with the rhodium center. In addition to this work, rhodium-based small molecule inhibitors for FK-506 binding proteins are investigated. Also, methodology for rhodium-catalyzed modification of proteins containing surface cysteine has been developed where a simple rhodium(II) complex catalyzes cysteine modification with diazo reagents. The reaction is marked by clean cysteine selectivity and mild reaction conditions. The resulting linkage is significantly more stable in human plasma serum, when compared to common maleimide reagents. Apart from this body of work in chemical-biology, the thesis contains the discussion of development of copper-catalyzed remote chlorination of alkyl hydroperoxides. The atom transfer chlorination utilizes simple ammonium chloride salts as the chlorine source and the internal redox process requires no external redox reagents.

metallopeptides

protein–protein interactions

inhibitors

cysteine modification

rhodium

sp3 remote C-H activation

Calmodulin Binding and Activation of Mammalian Nitric Oxide Synthases

Spratt, Donald Eric

23 April 2008

Calmodulin (CaM) is a ubiquitous cytosolic Ca2+-binding protein involved in the binding and regulation of more than three-hundred intracellular target proteins. CaM consists of two globular domains joined by a central linker region. In the archetypical model of CaM binding to a target protein, the Ca2+-replete CaM wraps its two domains around a single α-helical target peptide; however, other conformations of CaM bound to target peptides and proteins have recently been discovered. Due to its ability to bind and affect many different intracellular processes, there is significant interest in a better understanding of the structural and conformational basis of CaM’s ability to bind and recognize target proteins. The mammalian nitric oxide synthase (NOS) enzymes are bound and activated by CaM. The NOS enzymes catalyze the production of nitric oxide (•NO), a free radical involved in numerous intercellular processes such as neurotransmission, vasodilation, and immune defense. There are three different isoforms of nitric oxide synthase (NOS) found in mammals – neuronal NOS (nNOS), endothelial NOS (eNOS), and inducible NOS (iNOS). All three enzymes are homodimeric with each monomer consisting of an N-terminal oxygenase domain and a multidomain C-terminal reductase domain. A CaM-binding domain separates the oxygenase and reductase domains. There is a unique opportunity to investigate CaM’s control over •NO production by the NOS enzymes since each isoform shows a different mode of activation and control by CaM. At elevated cellular Ca2+ concentrations, CaM is able to bind and activate nNOS and eNOS. In contrast, the iNOS isozyme is transcriptionally regulated and binds to CaM in the absence of Ca2+. The focus of this thesis is to better our present understanding of the conformational and structural basis for CaM’s ability to bind and activate the three mammalian NOS isozymes with particular emphasis on the interactions between CaM and iNOS. To further investigate the differences in the association of CaM to the Ca2+-dependent and Ca2+-independent NOS isoforms, a variety of CaM mutants including CaM-troponin C chimeras, CaM EF hand pair proteins, and CaM mutants incapable of binding to Ca2+ were employed. The inherent differences in binding and activation observed using these CaM mutants is described. Differences in the binding of the N- and C-terminal domains, as well as the central linker of CaM to peptides corresponding to the CaM-binding domain of each NOS enzyme and holo-NOS enzymes was investigated. The conformation of CaM when bound to NOS peptides and holo-NOS enzymes was also studied using fluorescence (Förster) resonance energy transfer (FRET). A preliminary three-dimensional structural study of Ca2+-replete and Ca2+-deplete CaM in complex with an iNOS CaM-binding domain peptide is also described. Combining the cumulative results in this thesis, a working model for iNOS’s regulation by CaM is proposed. Future suggested experiments are described to further the characterization of CaM binding to the NOS enzymes and other CaM-target proteins. The studies described in this thesis have expanded and improved the present understanding of the CaM-dependent binding and activation of the NOS isozymes, particularly the interactions between CaM and iNOS.

Calmodulin

Nitric Oxide Synthase

Fluorescence

Protein-protein interactions

FRET

Calcium

Chemistry

Analysis and Error Correction in Structures of Macromolecular Interiors and Interfaces

Headd, Jeffrey John

January 2009

<p>As of late 2009, the Protein Data Bank (PDB) has grown to contain over 70,000 models. This recent increase in the amount of structural data allows for more extensive explication of the governing principles of macromolecular folding and association to complement traditional studies focused on a single molecule or complex. PDB-wide characterization of structural features yields insights that are useful in prediction and validation of the 3D structure of macromolecules and their complexes. Here, these insights lead to a deeper understanding of protein--protein interfaces, full-atom critical assessment of increasingly more accurate structure predictions, a better defined library of RNA backbone conformers for validation and building 3D models, and knowledge-based automatic correction of errors in protein sidechain rotamers. </p><p>My study of protein--protein interfaces identifies amino acid pairing preferences in a set of 146 transient interfaces. Using a geometric interface surface definition devoid of arbitrary cutoffs common to previous studies of interface composition, I calculate inter- and intrachain amino acid pairing preferences. As expected, salt-bridges and hydrophobic patches are prevalent, but likelihood correction of observed pairing frequencies reveals some surprising pairing preferences, such as Cys-His interchain pairs and Met-Met intrachain pairs. To complement my statistical observations, I introduce a 2D visualization of the 3D interface surface that can display a variety of interface characteristics, including residue type, atomic distance and backbone/sidechain composition. </p><p>My study of protein interiors finds that 3D structure prediction from sequence (as part of the CASP experiment) is very close to full-atom accuracy. Validation of structure prediction should therefore consider all atom positions instead of the traditional Calpha-only evaluation. I introduce six new full-model quality criteria to assess the accuracy of CASP predictions, which demonstrate that groups who use structural knowledge culled from the PDB to inform their prediction protocols produce the most accurate results. </p><p>My study of RNA backbone introduces a set of rotamer-like "suite" conformers. Initially hand-identified by the Richardson laboratory, these 7D conformers represent backbone segments that are found to be genuine and favorable. X-ray crystallographers can use backbone conformers for model building in often poor backbone density and in validation after refinement. Increasing amounts of high quality RNA data allow for improved conformer identification, but also complicate hand-curation. I demonstrate that affinity propagation successfully differentiates between two related but distinct suite conformers, and is a useful tool for automated conformer clustering. </p><p>My study of protein sidechain rotamers in X-ray structures identifies a class of systematic errors that results in sidechains misfit by approximately 180 degrees. I introduce Autofix, a method for automated detection and correction of such errors. Autofix corrects over 40% of errors for Leu, Thr, and Val residues, and a significant number of Arg residues. On average, Autofix made four corrections per PDB file in 945 X-ray structures. Autofix will be implemented into MolProbity and PHENIX for easy integration into X-ray crystallography workflows.</p> / Dissertation

Biology, Bioinformatics

Chemistry, Biochemistry

automation

prediction

protein folding

protein

protein interactions

RNA

structural bioinformatics

Analysis and Redesign of Protein-Protein Interactions: A Hotspot-Centric View

Layton, Curtis James

January 2010

<p><p>One of the most significant discoveries from mutational analysis of protein interfaces is that often a large percentage of interface residues negligibly perturb the binding energy upon mutation, while residues in a few critical "hotspots" drastically reduce affinity when mutated. The organization of protein interfaces into hotspots has a number of important implications. For example, small interfaces can have high affinity, and when multiple binding partners are generated to the same protein, they are predisposed to binding the same regions and often have the same hotspots. Even small molecules that bind to interfaces and disrupt protein-protein interactions (PPIs) tend to bind at hotspots. This suggests that some hotspot-forming sites on protein surfaces are <italic>intrinsically</italic> more apt to form protein interfaces. These observations paint a hotspot-centric picture of PPI energetics, and present a question of fundamental importance which remains largely unanswered: <italic>why are hotspots hot?</italic></p></p><p><p>In order to gain insight into the nature of hotspots I experimentally examined the small, but high-affinity interface between the synthetically evolved ankyrin repeat protein Off7 with E. coli maltose binding protein by characterization of mutant variants and redesigned interfaces. In order to characterize many mutants, I developed two high-throughput assays to measure protein-protein binding that integrate with existing technology for the high-throughput fabrication of genes. The first is an ELISA-based method using in vitro expressed protein for semi-quantitative analysis of affinity. Starting from DNA encoding protein partners, binding data is obtained in just a few hours; no exogenous purification is required. For the second assay, I develop data fitting methods and thermodynamic framework for determination of binding free energies from binding-induced shifts in protein thermal stability monitored with Sypro Orange.</p></p><p><p>Analysis of Off7/MBP variants using these methods reveals that conservative mutagenesis or local computational repacking is tolerated for many residues in the interface without drastic loss of affinity, except for a single essential hotspot. This hotspot contains a Tyr-His-Asp hydrogen bonding network reminiscent of a common catalytic motif. Substitution of the tyrosine with phenylalanine shows that a single hydrogen bond across the interface is critical for binding. Analysis of the protein database by structural bioinformatics shows that, although rare, this motif is present in other naturally evolved interfaces. Such a triad was found in the homodimeric interface of PH0642 from Pyrococcus horikoshii, and is conserved between many homologues in the nitrilase superfamily, meeting one of the key criteria by which potential hotspots can be identified. This analysis supports a number of analogies between hotspot residues and catalytic residues in enzyme active sites, and raises the intriguing possibility that hotspots may be associated with other structural motifs that could be used for identification or design of PPIs.</p></p> / Dissertation

Biochemistry

Biophysics

Hotspot

Interface

Off7

Protein-Protein Interactions

Sypro Orange

Thermofluor

Characterization of E coli Hfq structure and its RNA binding properties

Sun, Xueguang

07 December 2005

Hfq is a bacterial RNA-binding protein recently shown to contain the Sm motif, a characteristic of Sm proteins that function in RNA processing in archaea and eukaryotes. Hfq plays a major role in RNA-RNA interactions regulating translation. Comparative structural modeling and amino acid sequence alignment were used to predict the 3-D structure of Hfq and the model was in excellent agreement with the crystal structure which determined for S. aureus Hfq. The evolution of Hfq was explored by a BLAST search of microbial genomes followed by phyletic analysis. About half of the genomes examined contain at least one gene coding for Hfq. The presence and absence of Hfq closely followed major bacterial clades. The potential RNA binding residues on the two surfaces of the Hfq hexamer were proposed based on the bioinformatics studies and the mutant Hfq proteins with either single or double mutations on the two surfaces of the Hfq hexamer were generated. Their RNA binding properties was biophysically studied by gel-shift assay, fluorescence anisotropy and fluorescence quenching techniques. Results indicated that 1) point mutations on the distal surface of the Hfq hexamer, Y25A and K31A, have a major effect on A18 binding. Both reduce binding by about 1000 fold. Mutations on the proximal surface have a small or no influence on A18 binding. 2) Two mutations, F39A and R16A, on the proximal surface of the Hfq structure reduce binding to the DsrA domain II by 10 fold. Other mutations reduce binding by less than 2 fold. 3) An amino acid covariance was observed in L12 and F39. Mutation L12F can partially restore F39A in DsrA RNA binding. 4) It appears that two Hfq hexamers cooperatively bind one RNA for both DsrADII and A18.

Hfq

Structure

RNA binding

RNA-protein interactions

Genetic transcription

Microbial genomes