BTB Domain Dimerization:Development of a Protein-protein Interaction Assay

Wang, Qingniao

22 September 2009

In the human genome, 43 BTB (Bric-à-brac, Tramtrack, and Broad Complex) containing BTB-Zinc Finger proteins have been identified, many of which are transcription factors involved in cancer and development. These BTB domains have been shown to form homodimers and heterodimers which raise DNA binding affinity and specificity for transcription factors. This project was to develop an efficient assay to systematically identify interactions between BTB domains. It combined a co-expression system, fluorescent protein tagging and Ni-NTA plate retention. It was concluded that fourteen analyzed BTB domains formed homodimers, but only certain BTB pairs formed heterodimers, such as BCL6 with Miz1 and Miz1 with RP58. To further understand the specificity of BTB domain interactions, more structural and sequence information is still needed. In conclusion, this assay provided a comprehensive detection method for BTB domain interaction mapping. The information generated provides candidates for further functional and structural studies.

BTB domain

protein-protein interaction

domain dimerziation

assay development

fluorescent protein

high throughput assay

0487

Investigation of the Mechanism and Structure of the Cage-like Complex formed by the Escherichia coli Inducible Lysine Decarboxylase LdcI and the MoxR AAA+ ATPase RavA

Liu, Kaiyin

05 December 2013

The gram-negative bacteria Escherichia coli, a neutralophile, is remarkable in its defenses against acid stress. Of interest to our laboratory is the inducible lysine decarboxylase (LdcI) system, an acid resistance system which renders acid resistance to E. coli in mild acid stress (~pH 5). It was found that this enzyme forms an extremely large (~3.3 MDa) and tight complex (Kd ~ 0.56 μM) with a MoxR AAA+ ATPase named Regulatory ATPase Variant A (RavA). The cryo-EM structure at 14 Å was determined. Through size-exclusion chromatography (SEC) experiments, the binding sites on both LdcI and RavA have been determined. It is proposed that the complex can form through both charged and hydrophobic interactions. In the course of these studies, unexpected observations led to the characterization of the LARA domain of RavA as an amyloid protein under in vitro conditions. The physiological significance of this observation is still under investigation.

Protein Purification

Protein Interaction

NMR

Gel Filtration Chromatography

Cryo-EM

Acid Stress

0487

0876

Investigation of the Mechanism and Structure of the Cage-like Complex formed by the Escherichia coli Inducible Lysine Decarboxylase LdcI and the MoxR AAA+ ATPase RavA

Liu, Kaiyin

05 December 2013

The gram-negative bacteria Escherichia coli, a neutralophile, is remarkable in its defenses against acid stress. Of interest to our laboratory is the inducible lysine decarboxylase (LdcI) system, an acid resistance system which renders acid resistance to E. coli in mild acid stress (~pH 5). It was found that this enzyme forms an extremely large (~3.3 MDa) and tight complex (Kd ~ 0.56 μM) with a MoxR AAA+ ATPase named Regulatory ATPase Variant A (RavA). The cryo-EM structure at 14 Å was determined. Through size-exclusion chromatography (SEC) experiments, the binding sites on both LdcI and RavA have been determined. It is proposed that the complex can form through both charged and hydrophobic interactions. In the course of these studies, unexpected observations led to the characterization of the LARA domain of RavA as an amyloid protein under in vitro conditions. The physiological significance of this observation is still under investigation.

Protein Purification

Protein Interaction

NMR

Gel Filtration Chromatography

Cryo-EM

Acid Stress

0487

0876

Unraveling the Role of Cellular Factors in Viral Capsid Formation

Smith, Gregory Robert

01 March 2015

Understanding the mechanisms of virus capsid assembly has been an important research objective over the past few decades. Determining critical points along the pathways by which virus capsids form could prove extremely beneficial in producing more stable DNA vectors or pinpointing targets for antiviral therapy. The inability of current experimental technology to address this objective has resulted in a need for alternative approaches. Theoretical and computational studies offer an unprecedented opportunity for detailed examination of capsid assembly. The Schwartz Lab has previously developed a discrete event stochastic simulator to model virus assembly based upon local rules detailing the geometry and interaction kinetics of individual capsid subunits. Applying numerical optimization methods to learn kinetic rate parameters that fit simulation output to in vitro static light scattering data has been a successful avenue to understand the details of virus assembly systems; however, information describing in vitro assembly processes does not necessarily translate to real virus assembly pathways in vivo. There are a number of important distinctions between experimental and realistic assembly environments that must be addressed to produce an accurate model. This thesis will describe work expanding upon previous parameter estimation algorithms for more complex data over three model icosahedral virus systems: human papillomavirus (HPV), hepatitis B virus (HBV) and cowpea chlorotic mottle virus (CCMV). Then it will consider two important modifications to assembly environment to more accurately reflect in vivo conditions: macromolecular crowding and the presence of nucleic acid about which viruses may assemble. The results of this work led to a number of surprising revelations about the variability in potential assembly rates and mechanisms discovered and insight into how assembly mechanisms are affected by changes in concentration, fluctuations in kinetic rates and adjustments to the assembly environment.

biological modeling

computational biology

physical virology

virus assembly

RNA-protein interaction

macromolecular crowding

On the Effect of Binding on Ubiquitin Dynamics

Peters, Jan Henning

02 April 2013

No description available.

571.4

Ubiquitin

Molecular Dynamics

Protein-Protein Interaction

Binding

Conformational Dynamics

Biologie (PPN619462639)

Post-translational Regulations of FUSCA3 in Arabidopsis thaliana

Tsai, Allen Yi-Lun

13 August 2013

Seed formation consists of two major stages: embryo pattern formation and maturation. During seed maturation, the embryo accumulates storage material, acquires desiccation tolerance, and enters a stage of dormancy. Genetic analyses have identified several master regulators that orchestrate late embryogenesis, including the B3-domain transcription factor FUSCA3 (FUS3). In Arabidopsis, FUS3 has been shown to be a central regulator of hormonal pathways; it positively regulates late embryogenesis by increasing abscisic acid (ABA) level while repressing gibberellin (GA) synthesis. In turn, FUS3 protein level is positively and negatively regulated by ABA and GA, respectively. However, the mechanism of how this regulation occurs has not been well characterized. In this study, FUS3 has been shown to be an unstable protein rapidly degraded by the proteasome through a PEST instablility motif. To further characterize the mechanisms involved in FUS3 homeostasis, FUS3-interacting proteins were identified. The SnRK1 kinase AKIN10 was shown to interact with and phosphorylate FUS3 at its N-terminus. Furthermore, overexpression of AKIN10 delays FUS3 degradation, suggesting AKIN10 positively regulates FUS3 protein accumulation. Overexpression of AKIN10 delays developmental phase transitions, and causes defects in lateral organ development. These defects were partially rescued by the loss-of-function fus3-3 mutation, suggesting FUS3 and AKIN10 genetically interact to regulate these developmental processes. SnRK1/AMPK/Snf1 kinases are regulators of energetic stress responses. Overexpression studies suggest both FUS3 and AKIN10 positively regulate ABA signaling, but differ in sugar responses during germination; AKIN10 mediates glucose sensitivity, while FUS3 regulates osmotic stress responses. Overexpression of AKIN10 and FUS3 results in glucose and osmotic stress hypersensitivities, respectively, both of which are partially dependent on de novo ABA synthesis. Thus, FUS3 and AKIN10 act in overlapping pathways and combine different environmental signals to generate a common ABA-dependent response. In summary, novel mechanisms that regulate FUS3 homeostasis and function were identified. A model explaining the interaction between FUS3 and AKIN10 during embryonic and vegetative development, and the function of these two central developmental regulators in hormonal and stress signaling pathways is discussed.

Development

Protein-protein interaction

Phosphorylation

Phase transition

Plant hormone

Protein degradation

0309

Post-translational Regulations of FUSCA3 in Arabidopsis thaliana

Tsai, Allen Yi-Lun

13 August 2013

Seed formation consists of two major stages: embryo pattern formation and maturation. During seed maturation, the embryo accumulates storage material, acquires desiccation tolerance, and enters a stage of dormancy. Genetic analyses have identified several master regulators that orchestrate late embryogenesis, including the B3-domain transcription factor FUSCA3 (FUS3). In Arabidopsis, FUS3 has been shown to be a central regulator of hormonal pathways; it positively regulates late embryogenesis by increasing abscisic acid (ABA) level while repressing gibberellin (GA) synthesis. In turn, FUS3 protein level is positively and negatively regulated by ABA and GA, respectively. However, the mechanism of how this regulation occurs has not been well characterized. In this study, FUS3 has been shown to be an unstable protein rapidly degraded by the proteasome through a PEST instablility motif. To further characterize the mechanisms involved in FUS3 homeostasis, FUS3-interacting proteins were identified. The SnRK1 kinase AKIN10 was shown to interact with and phosphorylate FUS3 at its N-terminus. Furthermore, overexpression of AKIN10 delays FUS3 degradation, suggesting AKIN10 positively regulates FUS3 protein accumulation. Overexpression of AKIN10 delays developmental phase transitions, and causes defects in lateral organ development. These defects were partially rescued by the loss-of-function fus3-3 mutation, suggesting FUS3 and AKIN10 genetically interact to regulate these developmental processes. SnRK1/AMPK/Snf1 kinases are regulators of energetic stress responses. Overexpression studies suggest both FUS3 and AKIN10 positively regulate ABA signaling, but differ in sugar responses during germination; AKIN10 mediates glucose sensitivity, while FUS3 regulates osmotic stress responses. Overexpression of AKIN10 and FUS3 results in glucose and osmotic stress hypersensitivities, respectively, both of which are partially dependent on de novo ABA synthesis. Thus, FUS3 and AKIN10 act in overlapping pathways and combine different environmental signals to generate a common ABA-dependent response. In summary, novel mechanisms that regulate FUS3 homeostasis and function were identified. A model explaining the interaction between FUS3 and AKIN10 during embryonic and vegetative development, and the function of these two central developmental regulators in hormonal and stress signaling pathways is discussed.

Development

Protein-protein interaction

Phosphorylation

Phase transition

Plant hormone

Protein degradation

0309

Subcellular localization and protein-protein interactions of two methyl recycling enzymes from Arabidopsis thaliana

Lee, Sanghyun

08 December 2010

This thesis documents the subcellular localization and protein-protein interactions of two methyl recycling enzymes. These two enzymes, adenosine kinase (ADK) and S-adenosyl-L-homocysteine hydrolase (SAHH), are essential to sustain the hundreds of S-adenosyl-L-methionine (SAM)-dependent transmethylation reactions in plants. Both ADK and SAHH are involved in the removal of a competitive inhibitor of methyltransferases (MTs), S-adenosyl-L-homocysteine (SAH), that is generated as a by-product of the each transfer of a methyl group from SAM to a substrate. This research focused on understanding how SAH is metabolized in distinct cellular compartments to maintain MT activities required for plant growth and development. Localization studies using green fluorescent protein (GFP) fusions revealed that both ADK and SAHH localize to the cytoplasm and the nucleus, and possibly to the chloroplast, despite the fact that the primary amino acid sequence of neither protein contains detectable targeting signals. This suggested the possibility that these methyl-recycling enzymes may be targeted by specific protein-protein interactions. Moreover, deletion analysis of SAHH1 indicated that the insertion region (IR) of 41 amino acids (Gly150-Lys190), which is present only in plants and parasitic protozoan SAHHs among eukaryotes, is essential for nuclear targeting. This result suggested that the surface-exposed IR loop may serve as a binding domain for interactions with other proteins that may direct SAHH to the nucleus. To investigate protein-protein interactions, several methods were performed including co-immunoprecipitation, bimolecular fluorescence complementation, and pull-down assays. These results not only revealed that ADK and SAHH possibly interact through the IR loop of SAHH in planta, but also suggested that this interaction is either dynamic or indirect, requiring a cofactor/another protein(s) or post-translational modifications. Moreover, possible interactions of both ADK and SAHH with a putative Arabidopsis mRNA cap methyltransferase (CMT), which is localized predominantly in the nucleus, were also confirmed. These results support the hypothesis that the nuclear targeting of both SAHH and ADK can be mediated by the interaction with CMT. In addition, purification of Strep-tagged SAHH1 expressed in Arabidopsis identified a novel interaction between SAHH and aspartate-semialdehyde dehydrogenase (ASDH), an enzyme that catalyzes the second step of the aspartate-derived amino acid biosynthesis pathway. Analysis of ASDH-GFP fusions revealed that ASDH localizes to the chloroplast and the stromule-like structure that emanates from chloroplasts. Moreover the mutation in three amino acids (Pro164-Asp165-Pro166) located within the IR loop of SAHH disrupted its binding to ASDH which affected the plastid localization of SAHH, suggesting that the interaction between SAHH and ASDH is required for plastid-targeting of SAHH. Taken together, this thesis demonstrated that the localization of ADK and SAHH in or between compartments is possibly mediated by specific protein interactions, and that the surface-exposed IR loop of SAHH is crucial for these interactions.

protein interaction

transmethylation

methyl recycling

subcellular localization

Adenosine kinase

adenosylhomocysteine hydrolase

Biology

Property-controlling Enzymes at the Membrane Interface

Ge, Changrong

January 2011

Monotopic proteins represent a specialized group of membrane proteins in that they are engaged in biochemical events taking place at the membrane interface. In particular, the monotopic lipid-synthesizing enzymes are able to synthesize amphiphilic lipid products by catalyzing two biochemically distinct molecules (substrates) at the membrane interface. Thus, from an evolutionary point of view, anchoring into the membrane interface enables monotopic enzymes to confer sensitivity to a changing environment by regulating their activities in the lipid biosynthetic pathways in order to maintain a certain membrane homeostasis. We are focused on a plant lipid-synthesizing enzyme DGD2 involved in phosphate shortage stress, and analyzed the potentially important lipid anchoring segments of it, by a set of biochemical and biophysical approaches. A mechanism was proposed to explain how DGD2 adjusts its activity to maintain a proper membrane. In addition, a multivariate-based bioinformatics approach was used to predict the lipid-binding segments for GT-B fold monotopic enzymes. In contrast, a soluble protein Myr1 from yeast, implicated in vesicular traffic, was also proposed to be a membrane stress sensor as it is able to exert different binding properties to stressed membranes, which is probably due to the presence of strongly plus-charged clusters in the protein. Moreover, a bacterial monotopic enzyme MGS was found to be able to induce massive amounts of intracellular vesicles in Escherichia coli cells. The mechanisms involve several steps: binding, bilayer lateral expansion, stimulation of lipid synthesis, and membrane bending. Proteolytic and mutant studies indicate that plus-charged residues and the scaffold-like structure of MGS are crucial for the vesiculation process. Hence, a number of features are involved governing the behaviour of monotopic membrane proteins at the lipid bilayer interface. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 5: Manuscript.

monotopic membrane protein

lipid-protein interaction

membrane curvature

glycosyltransferase

Rossmann fold

Biochemistry

Biokemi

Molecular mechanism of cancer related to urokinase receptor: DNAzyme-mediated inhibition and Novel protein interactors of urokinase receptor

Lin, Zhen, St George Clinical School, UNSW

January 2007

The urokinase receptor (uPAR) plays a central role in metastatic process. It???s evident uPAR is overexpressed across a variety of tumour cells and leads to the increased aggressiveness and poor prognosis of cancer. Inhibition of uPAR expression can block metastatic potential in many tumours. In addition, besides uPA, there are several other proteins which have been confirmed to interact with uPAR, such as vitronectin and integrins. These interactions also contribute to signal transduction and the functions of uPAR complex. Therefore, downregulation of uPAR expression by targeting uPAR mRNA or protein, or by regulating the uPAR partners would be potential therapeutic strategies for prevention of cancer metastasis. There are two main aspects contained in this thesis. Firstly, three specific DNAzymes targeting uPAR mRNA were designed to downregulate uPAR expression in vitro and their effects to decrease cancer cell invasion studied in a human osteosarcoma cell line Saos-2. The results showed that two of them (Dz483 and Dz720) cleaved uPAR transcript in vitro with high efficacy and specificity and the Dz720 inhibited uPAR protein levels by 55% in Saos-2 cells. Besides, the Dz720 significantly suppressed Saos-2 cell invasion using an in vitro matrigel assay. Secondly, two potential uPAR partners from yeast two-hybrid screening, a heat shock protein MRJ and an anti-apoptosis protein HAX-1, were characterised and their functions binding with uPAR investigated. The interactions were confirmed by co-immunoprecipitation, GST-pull down assay and confocal microscopy in cancer cells. In addition, there was a 50% increase in cell adhesion after transfection with MRJ. This increase in adhesion is dependent on the uPAR/full length MRJ interaction as cells transfected with the mutant construct containing only N-terminal region or C-terminal region of MRJ had no increase in cell adhesion. The observed increase in adhesion to vitronectin by MRJ was also blocked by an anti-uPAR domain I antibody suggesting that the induced adhesion is at least in part contributed by uPAR on the cell surface. Together, the identification of both MRJ and HAX-1 as uPAR interactors provides further insight into the intricate relationship between uPAR and other proteins which may develop potential approaches for cancer therapy.

Urokinase receptor.

DNAzyme.

Heat shock protein MRJ.

HAX-1.

Protein interaction.

Inhibition.