Studies on the Role of Vitronectin and Plasminogen-Activator Inhibitor-1 Complexes Beyond Inhibiting Proteases: Binding to the Extracellular Matrix, Cell Interactions and Pathogenesis

Goswami, Sumit

01 August 2010

Plasminogen activator inhibitor-1 (PAI-1), a member of the serine protease inhibitor (serpin) superfamily of proteins, circulates in blood in a complex with vitronectin (VN). These two proteins are also found localized together in the extracellular matrix in many different pathophysiological conditions. Both of these proteins are involved with a number of physiologically important processes. Though PAI-1 is a well-known inhibitor of serine proteases, more emphasis is now geared towards its protease independent functions. VN, on the other hand, is a binding protein that exists in the circulation in a preferred monomeric conformation. However, in the extracellular matrix, VN exists as multimer with altered conformation. Though the exact reason for such conformational alterations and compartmentalization is unknown, there are a number of biomolecules, including PAI-1 that are proposed to cause such alterations. In last few years, sufficient experimental evidence has been gathered to confirm this protease- independent effect of PAI-1 by which it induces multimerization of VN in a concentration-dependent fashion. It has been observed also that PAI-1 remains associated with this multimeric complex for several hours. A major focus of this dissertation work was to extend our understanding of the mechanism of the interaction between these proteins and to explore the physiological relevance of the multimeric complexes formed by their interaction on cellular adhesion and migration. In our study, emphasis has been given to the presence of an appropriate microenvironment so that the role of the multimeric complexes could be investigated in a relevant biological setting. Our findings indicate the importance of the surrounding microenvironment in establishing the specific role of the VN/PAI-1 complex in cell-matrix interactions. In a previous study from our lab, it was found that vitronectin knock-out mice were more resistant to Candida infection compared to wild type C57Bl/6 mice. One of the goals of this dissertation work was to provide a mechanistic explanation for their increased survival of the vitronectin knock-out mice upon Candida infection. Another important aspect of this work was to establish biophysical methods for understanding the structural changes that happen in PAI-1 naturally or due to ligand binding.

Vitronectin

PAI-1

ECM

pathogenesis

Deciphering Substrate Promiscuity by Aminoglycoside Resistance Enzymes via a Biophysical Characterization and Dynamics of the Aminoglycoside Acetyltransferase-(3)-IIIb and the Aminoglycoside Phosphotransferase-(3′)-IIIa

Norris, Adrianne Lee

01 May 2011

Aminoglycoside antibiotics are losing their bactericidal efficacy due to the spread of enzymes that catalyze a covalent modification to them. A common property of many of these aminoglycoside modifying enzymes (AGMEs) is the capacity to modify multiple diverse aminoglycosides thus conferring resistance to these drugs among several pathogenic bacterial species. To gain a better understanding of the protein-antibiotic interactions responsible for resistance and the promiscuous nature of AGMEs, a variety of biophysical techniques including nuclear magnetic resonance (NMR), isothermal titration calorimetry (ITC), steady state kinetics, intrinsic tryptophan fluorescence, and computational modeling are employed in this work. Results and discussion presented herein are divided into two parts. In Part I, a detailed thermodynamic and kinetic characterization of the association between the aminoglycoside acetyltransferase-(3)-IIIb (AAC) and several antibiotics and/or coenzyme(s) provides insight into the global properties of the protein. AAC is shown to have a broad substrate range where antibiotic interaction occurs with a favorable enthalpy and unfavorable entropy. When coenzyme A (the non-catalytic form of the acetyl donor, acetyl coenzyme A) is present, enthalpy becomes more favored, entropy more disfavored, and antibiotic affinity significantly increases. AAC shows preference for antibiotics with amine groups at the 2′ and 6′ positions and to those possessing four or more pseudo-saccharide rings. These and other data lay the foundation for understanding AAC and lead into the next discussion wherein the source of promiscuity of AGMEs is explored in Part II. The aminoglycoside phosphotransferase-(3′)-IIIa (APH), a representative from the phosphotransferase family of AGMEs, has been well characterized previously. However, none of the data presented to date provides rationale for its promiscuity. In this work, NMR derived hydrogen-deuterium exchange experiments reveal that APH maneuvers its entire structure to accommodate diverse antibiotics. Furthermore, presence of an antibiotic creates a more stable APH conformation while coenzyme induces an antibiotic dependent increase in the flexibility of APH. For comparison, a computationally derived homology model of AAC predicts that its promiscuous nature may be due to a large flexible loop. Taken together, APH and AAC, two structurally and functionally diverse proteins, utilize different aspects of structural flexibility to facilitate a broad substrate repertoire that is key to bacterial survival.

aminoglycoside

NMR

acetyltransferase

phosphotransferase

dynamics

promiscuity

Structural Studies on PP2A and Methods in Protein Production

Magnúsdóttir, Auður

January 2008

PP2A is a major phosphatase in the cell that participates in multiple cell signaling pathways. It is a heterotrimer of a core dimer and variable regulatory subunits. Details of its structure, function and regulation are slowly emerging. Here, the structure of two regulators of PP2A are de-scribed; PTPA and B56γ. PTPA is a highly conserved enzyme that plays a crucial role in PP2A activity but whose biochemical function is still unclear. B56γ is a PP2A regulatory subunit linked to cancer and the structure presented here of B56γ in its free form is particularly valuable in light of the recent structures of the PP2A holoenzyme and core dimer. Protein production is a major bottleneck in structural genomic projects. Here, we describe two novel methods for improved protein production. The first is a colony based screening method where any DNA library can be screened for soluble expression of recombinant proteins in E.coli. The second method involves improvements of the well established IMAC purification method. We have seen that a low molecular weight component of E.coli lysate decreases the binding capacity of IMAC columns and by removing the low molecular weight components, recombinant proteins only present at low levels in E.coli lysate can be purified, which has previously been believed to be unfeasible.

PP2A

PTPA

B56γ

Protein Production

Structural biology

Strukturbiologi

Expanding the Role of Electron Cryomicroscopy in Structural Analysis of Asymmetrical Protein Complexes

Keating, Shawn

18 March 2013

Single particle electron cryomicroscopy (cryo-EM) is a rapidly developing structural biology technique for the study of macromolecular protein complexes. Presently, cryo-EM fills an important niche by facilitating acquisition of 3-D structures of protein complexes not amenable to structure determination by other techniques. Expansion of cryo-EM beyond this niche requires continued improvement in the types of specimens that can be studied as well as the final resolutions achieved. Two studies were undertaken to address these issues. The first examined resolution limitations by quantifying the effect of beam-induced motion in images of beam-sensitive paraffin crystals. The second explored the possibility of using cryo-EM to study the interaction of small effector proteins with a large multi-protein complex, V-ATPase. The results of these studies exposed the fact that fundamental aspects of the imaging and specimen preparation processes remain poorly understood and must be addressed to facilitate future improvements in cryo-EM structure determination.

Structural Biology

V-ATPase

Cryo-EM

Protein Purification

0786

0307

31P NMR of Backbone Conformation and Dynamics in DNA at Cre Binding Site in Terms of Sequence Context

Garton, Kelly A.

23 April 2012

The Cre sequence (ACGT) is a site responsible for the binding of specific transcription factors that determine the activation of genes. Due to its major role in gene transcription, it has become a subject of immense research. The binding of transcription factors to the Cre binding site has been determined to be dependent on DNA conformation. In this study, the effects of flanking sequence around the Cre binding site on the conformation and the dynamics of DNA were investigated. The Cre binding site was studied in its native form with differing flanking sequences to determine the BI/BII profile (conformation) and the magnitude of the energy transition barrier (dynamics) between the BI and BII conformations of each phosphate step of the following three dodecamer sequences: CreACAG, CreGGAG, and CreTATA. In order to obtain the BI/BII profile of each phosphate step, 2D 31P-NMR NOESY and HSQC experiments at various temperatures were utilized. Based of the basic principles of kinetics, the lower the energy barrier between the two conformations, the easier the transition between the BI and BII conformation. Therefore, it was hypothesized that low and high %BII character lead to a large energy barrier (high ∆G‡ values), whereas average %BII character leads to a small energy barrier (low ∆G‡ values). The results of the 2D 31P-NMR experiments of the three dodecamer sequences confirmed this relationship between the %BII character and the magnitude of the energy barrier (∆G‡). However, further conformation and dynamics studies must be conducted to further understand the correlation.

NMR

Cre

DNA

dynamics

conformation

Identification of Phosphorylase Kinase Alpha Subunit Binding Partners in Skeletal Muscle

Archila, Soleil

01 January 2004

IDENTIFICATION OF PHOSPHORYLASE KINASE ALPHA SUBUNIT BINDING PARTNERS IN SKELETAL MUSCLE Soleil Archila August 2004 67 Pages Directed by: Nancy A. Rice, Sigrid Jacobshagen, and Claire A. Rinehart Department of Biology Western Kentucky University Phosphorylase kinase (PhK) integrates neural, hormonal, and metabolic signals in skeletal muscle to tightly regulate glycogen breakdown and energy production. Structurally, PhK is among the largest and most complex kinases known with a stoichiometry of (αβγδ)4 and a mass of 1.3x106 Da. The catalytic γ subunit is allosterically controlled through alterations in quaternary structure initiated by the regulatory α, β and δ subunits. In this study we have chosen to examine the largest regulatory subunit, α. In addition to participating in intramolecular interactions within PhK, α is hypothesized to associate extrinsically with skeletal muscle proteins due to its peripheral location in the holoenzyme. To identify potential muscle protein interactors, the C-terminus of α , amino acid residues 1060-1237, was screened against a rabbit skeletal muscle cDNA library via a yeast two-hybrid assay. Interactions were selected by auxotrophic growth of yeast in the absence of leucine and by expression of β-galactosidase activity. Thirtyseven potential positive clones were initially observed. Secondary selections resulted in 13 putative clones being isolated of which 8 were identified as thyroid hormone receptor interacting protein 10 (TRIP10). TRIP10, also known as Cdc42 interacting protein 4 (CIP4), is highly expressed in skeletal muscle and is thought to act as a regulator of the actin cytoskeleton. The remaining 5 clones were identified as tetratricopeptide repeat protein 1 (TPR1). TPR1 is an adaptor protein that functions in a wide array of cellular processes and is considered a highly specific adaptor. The results reported herein are intriguing given that PhK is associated with the sarcoplasmic reticulum in the A-band / actin filament overlap zone and has previously been shown to interact with the thin filament protein nebulin. To our knowledge, this is the first report to identify TRIP10 as a potential sarcomeric protein, and these findings further suggest a role for PhK in muscle assembly and architecture.

Muscle

skeletal; Protein kinases

Local Motion And Local Accuracy In Protein Backbone

Davis, Ian Wheeler

09 1900

Proteins are chemically simple molecules, being unbranched polymers of uncomplicated organic compounds. Nonetheless, they fold up into a dazzling variety of complex and beautiful configurations with a dizzying array of structural, regulatory, and catalytic functions. Despite great progress, we still have very limited ability to predict the folded conformation of an amino acid sequence, and limited understanding of its dynamics and motions. Thus, this work presents a quartet of interrelated studies that address some aspects of the detailed local conformations and motions of protein backbone. First, I used a density-dependent smoothing algorithm and a high-quality, B-filtered data set to construct highly accurate conformational distributions for protein backbone (Ramachandran plots) and sidechains (rotamers). These distributions are the most accurate and restrictive produced to date, with improved discrimination between rare-but-real conformations and artifactual ones. Second, I analyzed hundreds of alternate conformations in atomic resolution crystal structures, and discovered that dramatic conformational change in a protein sidechain is often coupled to a subtle but very common mode of conformational change in its backbone -- the backrub motion. Examination of other biophysical data further supports the ubiquity of this motion. Third, I applied a model of backrub motion to protein design calculations. Although experimental characterization of the designs showed them to be unstable and/or inactive, the computational results proved to be very sensitive to changes in the backbone. Finally, I describe how MolProbity uses my conformational distributions together with all-atom contacts and other tools to validate protein structures, and how those quality metrics can be combined visually or analytically to provide "multi-criterion" validation summaries. / dissertation

Biophysics, General

Structural biology

Bioinformatics

Backrub

Protein backbone

Validation

Strukturelle Untersuchungen zum Velvet-Komplex aus Aspergillus nidulans / Structural studies on the Velvet-Complex from Aspergillus nidulans

Ahmed, Yasar Luqman

26 March 2012

Die Regulation des sekundären Metabolismus und der Entwicklung in Aspergillus nidulans sind zwei miteinander verbundene Prozesse. Ihre Regulation geschieht in Abhängigkeit von Licht. Die molekulare Grundlage dieser Verbindung ist ein Komplex bestehend aus den beiden Velvet-Proteinen VeA, VelB und der putativen Methyltransferase LaeA. Ein weiteres Protein der Velvet-Familie ist VosA, dass in Verbindung mit VelB eine essenzielle Rolle in der Sporogenese und Biosynthese von Trehalose spielt. Bisheriges Wissen über die generelle Funktion der einzelnen Proteine basiert überwiegend auf in vivo Analysen. Unbekannt hingegen ist die molekulare Funktionsweise sowie Struktur dieser Proteine. Zu diesem Zweck wurde in der vorliegenden Arbeit versucht dieses Defizit durch eine röntgenkristallographische Strukturanalyse der Proteine aufzuheben.

570

Structural biology

xray

crystallography

Aspergillus nidulans

Biologie (PPN619462639)

Structural and functional characterization of E2A:KIX interactions in leukemia

Denis, Christopher

15 September 2012

The E2A proteins are transcription factors critical for B-lymphopoiesis. A chromosomal translocation involving the E2A gene promotes acute lymphoblastic leukemia (ALL) through expression of the oncoprotein E2A-PBX1. Two activation domains of E2A-PBX1, AD1 and AD2, have been implicated in transcription mediated by recruitment of the transcriptional co-activator CBP/p300. A motif has been identified within AD1 that is important for recruiting CBP/p300, known as PCET. This recruitment requires an interaction between the activation domains of E2A-PBX1 and the KIX domain of CBP/p300. The KIX domain recognizes a generic ΦXXΦΦ sequence (Φ corresponds to a hydrophobic residue) found in the activation domains of numerous transcription factors. Mutation of leucine 20 in PCET has been shown to abrogate ex vivo immortalization of murine bone marrow and oncogenesis in a murine bone marrow transplantation model. A similar sequence is also found in AD2 and is implicated in E2A transcriptional activity and recruitment of CBP/p300. The structural details of these interactions remain largely unknown. NMR spectroscopy was used to determine the solution structure of the PCET:KIX complex, and the functional consequences of the Leu20Ala mutation were structurally rationalized. Other PCET mutations informed by this structure were tested and correlations were found between in vitro binding affinities and both transcriptional activation and immortalization. The binding site of the ΦXXΦΦ-containing E2A AD2 peptide was mapped to the same site on the KIX domain used by the PCET motif. A model of this complex was generated and mutations were tested using a similar approach as was used for PCET. E2A AD2 binds the KIX domain with lower affinity than the PCET motif and is not required for immortalizing bone marrow. A mutation that increases the affinity of E2A AD2 for the KIX domain to levels approaching that seen for the PCET:KIX interaction restores transcriptional activation and immortalization, demonstrating that immortalization by E2A-PBX1 is an affinity dependent process involving the KIX domain of CBP/p300. These studies indicate that the activation domains of E2A-PBX1 serve to support the in vivo function of the oncoprotein and that the PCET:KIX complex is a potential target for novel therapeutics in E2A-PBX1+ leukemia. / Thesis (Ph.D, Biochemistry) -- Queen's University, 2012-09-13 13:30:48.848

leukemia

protein-protein interactions

NMR spectroscopy

structural biology

Structural basis of TraD and sbmA recognition by TraM of F-like plasmids

Wong, Joyce JW

Unknown Date

No description available.

F plasmid

conjugation

structural biology

bacteria

x-ray crystallography