Effects of Mechanochemical Conditions on Protein Rheology and Biophysical Properties

Crain, Jazmine

January 2022

No description available.

Biomechanics

Mechanochemistry

Protein Mechanics

Mechanical Stress

Protein Stability

Biomechanics

Biochemistry

Identification and Regulatory Role of E3 Ligases in the Time-Dependent Degradation of the Circadian Factor Period 2

Liu, Jingjing

20 June 2016

Circadian rhythms are self-sustained, 24h, biological oscillatory processes that are present in organisms ranging from bacteria to human. Circadian rhythms, which can be synchronized by external cues, are important for organisms to adjust their behavior, physiological activity, and metabolic reactions to changes in environmental conditions. Another well-established oscillatory mechanism that shares common organizational and regulatory features with the circadian system, is the cell division cycle. Recent findings reveal that some essential regulators are common to both the cell cycle and the circadian clock. The first half of my thesis (Chapter 2-3) focuses on the function of Period 2 (Per2), a key regulatory component of the negative feedback arm of the clock and tumor suppressor protein, as a modulator of cell cycle response. We found that Per2 binds the C-terminus end of the tumor suppressor p53 thus forming a trimeric complex with p53's negative regulator Mdm2 and preventing Mdm2-mediated p53's ubiquitination and degradation. Thus, Per2 stabilizes p53 under unstressed conditions allowing for basal levels of the protein to exist and be available for a rapid response to take place in case of any stressed signals. Our experiments prove that Per2 plays an indispensible role in p53 signaling pathway. The second half of my thesis (Chapter 4-5) focuses on how Mdm2 and Per2 interplay regulate Per2 availability and its impact on circadian clock function. My research found that Mdm2 targets Per2 for ubiquitination as Mdm2 depletion stabilizes Per2 and, conversely, Mdm2 ectopic expression shorten Per2's half-life. Accordingly, association of Per2 to Mdm2 maps C-terminus of the p53 binding region in Mdm2 and thus, the RING domain remains accessible. Next, we tested the hypothesis that Mdm2-dependent ubiquitination of Per2 directly impacts circadian clock period length. Accordingly, addition of sempervirine nitrate (SN), a specific molecular inhibitor of Mdm2, to MEF cells abrogated Per2 ubiquitination leading to the accumulation of a stable pool of Per2. By recording the oscillatory behavior of the Per2:Luc reporter system in MEF cells treated with SN at different circadian times, we found that inhibition of Mdm2 E3 ligase activity promoted phase advance only when treatment took place during the degradation period. This is in agreement with our findings that radiation, but not light pulses, causes the same phase behavior. Considering the established role of both Mdm2 and p53 in the response of cells to genotoxic stress and Per2 in modulating the clock, the existence of the Mdm2-Per2-p53 complex opens the possibility of various stimuli triggering regulatory mechanisms converging in a critical node. Overall, our work provides a holistic view of how signals are integrated at multiple levels to ensure that environmental signals are sense and responses triggered timely. / Ph. D.

Circadian rhythm

Period 2

ubiquitination

Mdm2

Protein stability

p53

The Development of High-Throughput and Miniaturized Differential Scanning Calorimeter for Thermodynamic Study of Bio-Molecules

Yu, Shifeng

19 February 2019

Biomolecular interactions are fundamentally important for a wide variety of biological processes. Understanding the temperature dependence of biomolecular interactions is hence critical for applications in fundamental sciences and drug discovery. Micro-Electro-Mechanical Systems (MEMS) technology holds great potential in facilitating temperature-dependent characterization of biomolecular interactions by providing on-chip microfluidic handling with drastically reduced sample consumption, and well controlled micro- or nanoscale environments in which biomolecules are effectively and efficiently manipulated and analyzed. This dissertation is focused on a high-through and miniaturized differential scanning calorimeter for thermodynamic study of bio-molecules using MEMS techniques. The dissertation firstly introduces the overall design and operation principles. This miniaturized DSC was fabricated based on a polyimide (PI) thin film. Highly temperature sensitive vanadium oxide was used as the thermistor material. A PDMS (Polydimethylsiloxane) microfluidic chamber was separately fabricated and then bonded firmly with the PI substrate by a stamp-and-stick method. Meanwhile, the micro heater design was optimized to reach better uniformity. A heating stage was constructed for fast and reliable scanning. In this study, we used syringes to deliver the 0.63 μL liquid sample into both the sample and reference chambers. All the testing processes were functionalized using the LabVIEW programs. The sensing material was also characterized. To seek a higher temperature coefficient of resistance (TCR) and less resistive behavior, explorations about various PVD (physical vapor deposition) parameters and annealing conditions were conducted for optimization. In this research, we found vanadium oxide deposited under certain conditions leads to the highest TCR value (a maximum of 2.51%/oC). To better understand the material’s property, we also did the XRD (X-ray Diffraction), SEM (Scanning electron microscope). The micro calorimeter was calibrated using a step thermal response. The time constant was around 3s, the thermal conductance was 0.6mW/K, and the sensitivity was 6.1V/W. The static power resolution of the device at equilibrium is 100 nW, corresponding to 250 nJ/K. These performances confirmed the design and material to be appropriate for both good thermal isolation and power sensitivity. We demonstrated the miniaturized DSC’s performance on several different kinds of protein samples: lysozyme, and mAb (monoclonal antibody) and a DVD IgG (double variable domain immunoglobulin G). The results were found to be reasonable by comparing it with the commercial DSC’s tests. Finally, this instrument may be ideal for incorporation into high throughput screening workflows for the relative comparison of thermal properties between large numbers of proteins when only small quantities are available. The micro-DSC has the potential to characterize the thermal stability of the protein sample with significantly higher throughput and less sample consumption, which could potentially reduce the time and cost for the drug formulation in the pharmaceutical industry. / Ph. D. / Virtually all biological phenomena depend on molecular interactions, which is either intra-molecular as protein folding/unfolding or intermolecular as in ligand binding. A basic biology problem is to understand the folding and denaturation processes of a protein: the kinetics, thermodynamics and how a protein unfolds and folds back into its native state. Both folding/unfolding and denaturation processes are associated with enthalpy changes. The thermodynamics of binding compounds helps a great deal to understand the nature and potency of such molecules and is essential in drug discovery. As a label-free and immobilization-free method, calorimetry can evaluate the Gibbs free energy, enthalpy, entropy, specific heat, and stoichiometry, and thus provides a fundamental understanding of the molecular interactions. Calorimetric systems including isothermal titration calorimeters (ITC) and differential scanning calorimeters (DSC) are the gold standard for characterizing molecular interactions. In this research, a micro DSC is developed for direct thermodynamic study of bio-molecules. Compared with the current commercial DSC, it is on a much smaller scale. It consumes much less sample and time in each DSC measurement. It can enable comprehensive high-content thermodynamics study in the early stage of drug discovery and formulation. It also enables direct, precise, and rapid evaluation of the folding and unfolding of the large biomolecules like proteins, DNAs, and enzymes without labeling or immobilization. It can also be used as a powerful tool to study the membrane proteins, which is often impractical or impossible before.

MEMS

Differential Scanning Calorimeter

Thermodynamic

Protein Stability

Transition Temperature

Characterization of Inosine triphosphate pyrophosphatase, an important protein involved in purine metabolism

Björklund, Sam

January 2015

The enzyme inosine triphosphate pyrophosphatase (ITPase) is responsible for controlling the levels of the by-products guanosine monophosphate (GMP) and adenosine monophosphate (AMP) through their precursor inosine monophosphate (IMP). ). Human ITPase consists of a 194-amino acid homodimer which relies upon either an Mg2+ ion or a Mn2+ ion for catalytic activity, and orthologs of this protein have been found in many different organisms. The purpose of this project was to try out methods learned throughout the education and to use this knowledge to gather new data about the human protein inosine triphosphate pyrophosphatase (ITPase). The protein was expressed in BL21/DE3 cells from a pre-made vector. Experiments performed during this project include secondary- and tertiary stability measurements, tryptophan fluorescence spectra, binding curve and thermic stability to ITPase with ANS and methotrexate. The Tm-value of human ITPase was examined with Trp-Fluorescence, ANS-fluorescence and Near-UV and Far-UV circular dichroism (CD). The stability of ITPase monitored by Near-UV as well as Far-UV coincides, indicating that secondary- and tertiary-unfolding occur simultaneously without any intermediates. The results of Trp-fluorescence showed that the tryptophans were already exposed and thus it did not yield a reliable result. The binding properties of ANS and MTX to ITPase were also examined.

Inosine triphosphate pyrophosphatase

acute lymfoblastic leukemia

circular dichroism

fluorescence

methotrexate

protein stability

Intra a intermolekularni interakce v proteinech / Intramolecular and intermolecular interactions in proteins

Fačkovec, Boris

January 2012

Folding free energy of a protein is a delicate balance between stabilizing and destabilizing non-covalent itneractions. In this work, we decompose folding free energy into physically meaningful contributions, in which we aim to find general trends. Empirical potential is used to calculate interaction energy between all protein fragments, which are classified based on their dominant term in multipolar expansion. Calculations are done using 1200 non-redundant structures from PDB database. Based on the general trends found in interactions between these fragments, we attempt to better understand relationships between interaction energies calculated using computational chemistry methods and their corresponding free energy contributions on stabilization. 1

Surface charges contribution to protein stability of Thermococcus celer L30e. / CUHK electronic theses & dissertations collection

January 2010

Electrostatic interaction has long been proposed to be an important factor for stabilizing protein. Charge-charge interaction may especially be important to the thermostability of protein, as having more surface electrostatic interactions is one of the common structural features found in thermophilic proteins when compared to their mesophilic homologues. In order to quantitatively investigate the electrostatic contribution to protein stability, two complementary approaches, namely the double mutant cycle approach and pKa shift approach, were carried out. / In the double mutant cycle approach, the coupling free energies of two salt bridges (E6/R92 and K46/E62) and one a long range ion pair (E90/R92) were estimated by using circular dichroism, to find out the thermodynamic parameters of the protein model Thermococcus celer L30e and its charge-to-neutral mutants. It was found that the coupling free energy was temperature independent and was about 3 kJ mol-1 per salt bridge. By using a novel analysis of double mutant cycle of DeltaC p, it was also found that the interaction of salt bridge plays an important role in the reduction of DeltaCp. The temperature independency of coupling free energy and the effect of reducing DeltaCp could explain the general observation very well that thermophilic proteins have highly up-shifted protein stability curves is due to its elevated electrostatic interactions when compared with their mesophilic homologs. / In the pKa shift approach, the native state pKa values of acidic residues were obtained by fitting the side chain carboxyl 13C chemical shifts to microscopic model or global fitting of titrational event (GloFTE), whereas the denatured state pKa values were obtained by conventional pH titration of terminal protected 5-residue glycine-based model peptide. It was found that the surface charge-charge interactions, either attractive or repulsive, were strong and complicated because of the high surface charge density of T. celer L30e. However, the fact that most of the acidic residues have significantly downshifted native state pK a values indicated the surface charge distribution of T. celer L30e is optimized for stabilizing the protein. In addition, we have shown that temperature has negligible effect on pKa values in both native state and denatured state, therefore temperature can only marginally amplify the stabilizing effect in linear manner. / To overcome the unwanted crystallization problem of wild-type T. celer L30e in the low ionic strength neutral pH NMR conditions, which were essential for the pKa shift approach, a quintuple Arg-to-Lys variant was designed to dramatically improve the crystalline solubility, while the surface charges, as well as the structural, thermodynamic, and electrostatic properties, were conserved. It has also shown that electrostatic interaction played a critical role in crystallization at low ionic strength conditions, and arginine residue was especially important in crystal packing because of its high ability of forming salt bridges and hydrogen bonds. / Wild-type T. celer L30e has also shown to have no observable residual structure in the guanidine HC1-induced denatured state, indicating that denatured state of T. celer L30e should not have large effect on the overall protein stability. / Chan, Chi Ho. / Adviser: Kam Bo Wong. / Source: Dissertation Abstracts International, Volume: 73-01, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 202-218). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [201-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.

Electrostatics

Protein engineering

Proteins--Analysis

Proteins--Conformation

Protein Conformation

Protein Stability

Static Electricity

Properties of HIV-1 env and human seminal fluid that determine virus inhibition by antibodies and microbicides

Johnson, Jacklyn

01 August 2019

Human immunodeficiency virus type 1 (HIV-1) establishes a persistent infection that leads to acquired immunodeficiency syndrome (AIDS). Approximately 36 million people worldwide are living with HIV-1, which is commonly acquired through sexual contact. Antiviral therapies control disease progression, but do not eliminate this virus from the host. Thus, global efforts are focused on developing vaccines that prevent HIV-1 transmission. Such vaccines are based on eliciting the production of protective antibodies that target the envelope glycoproteins (Envs) of this virus. Unfortunately, HIV-1 immunization trials have shown limited efficacy. A better understanding of the antibody-mediated inactivation process is needed to improve vaccine strategies. In this work we describe two novel factors that contribute to HIV-1 inactivation. First, we show that structural stability of the Env protein determines its sensitivity to vaccine-elicited antibodies. Different interactions within Env contribute to its stability. Perturbation of the Env-stabilizing interactions by physical and chemical treatments enhances sensitivity of HIV-1 to antibodies. Second, we found that the chemical composition of the transmission medium affects Env inhibition by antibodies and other inhibitory agents. Semen is the most common vehicle for HIV-1 transmission. This medium contains high concentrations of the sugar fructose. We found that semen fructose competitively blocks binding of antiviral agents that target sugar residues on Env. Together, this work advances our understanding of the mechanism that underlies HIV-1 inactivation by vaccine-elicited antibodies and provides novel strategies to enhance their potency.

Antibody neutralization

Envelope Glycoprotein

Human Immunodeficiency Virus (HIV)

Protein stability

Microbiology

Protein Folding Studies on the Ribosomal Protein S6: the Role of Entropy in Nucleation

Lindberg, Magnus

January 2005

One of the most challenging tasks remaining in the field of biochemistry is the one of understanding how the information within the amino acid sequence of proteins translates into a unique structure. Solving this problem would lead to endless possibilities for application in the medical and biotechnology industry. Many decades ago scientists realized that the process that facilitates the folding of a polypeptide chain could not be random and happen by chance; there needs to be direction in the folding free energy landscape. This landscape is defined by the thermodynamic factors entropy and enthalpy. The contribution made by enthalpy i.e. the contact energies from intra- and intermolecular interactions have been extensively investigated by various mutational studies. The influence of entropy on the other hand, is less well understood. My work focuses on the effect of altering the entropic components of forming the various parts of a known protein scaffold. This is done by genetic engineering in combination with biophysical characterisation and analysis. The results show effects on protein folding rates as well as on the pathway for nucleation and emphasis the ability of the folding landscape to readjust to entropic variations. Proteins are therefore not required to fold along a unique route to their final structure but can do so in several ways. The folding pathways we observe today have hence likely evolved as an adaptation to biological demands.

Biochemistry

protein folding

circular permutation

topology

connectivity

entropy

protein stability

chevron plot

Biokemi

Biochemistry

Biokemi

Molecular Mechanisms of p63-Derived Ectodermal Dysplasia

Lustig, Daniel

20 March 2012

Molecular defects in the p63 gene give rise to severe physiological abnormalities in patients with ectodermal dysplasia, however the mechanisms by which p63 mutations disrupt p63 function are unknown. In this study we examined four ΔNp63α mutants; Ectrodactyly-Ectodermal Dysplasia with Clefting (EEC) R204W, R304W and Ankyloblepharon-Ectodermal Dysplasia with Clefting (AEC) mutants, L514F and G530V, and characterized DNA binding, transcription factor activity, oligomerization with wild-type p63 and changes in protein stability/nuclear localization. We also investigated the putative OD-SAM interaction in p63 and p73. We demonstrated that both the EEC and AEC mutants cannot transcriptionally activate the PERP promoter and can hetero-oligomerize forming dominant negative complexes with wild-type p63. We show that both EEC mutants and AEC L514F mutants are more stable which is not due to aberrant degradation by the E3 ligase Itch. Finally, we discovered that a novel interaction between the p73 OD and SAM domain is absent in p63.

p63

Ectodermal Dysplasia

p53 Family

Protein Stability

Transactivation

Itch

PERP

EEC

0487

Molecular Mechanisms of p63-Derived Ectodermal Dysplasia

Lustig, Daniel

20 March 2012

Molecular defects in the p63 gene give rise to severe physiological abnormalities in patients with ectodermal dysplasia, however the mechanisms by which p63 mutations disrupt p63 function are unknown. In this study we examined four ΔNp63α mutants; Ectrodactyly-Ectodermal Dysplasia with Clefting (EEC) R204W, R304W and Ankyloblepharon-Ectodermal Dysplasia with Clefting (AEC) mutants, L514F and G530V, and characterized DNA binding, transcription factor activity, oligomerization with wild-type p63 and changes in protein stability/nuclear localization. We also investigated the putative OD-SAM interaction in p63 and p73. We demonstrated that both the EEC and AEC mutants cannot transcriptionally activate the PERP promoter and can hetero-oligomerize forming dominant negative complexes with wild-type p63. We show that both EEC mutants and AEC L514F mutants are more stable which is not due to aberrant degradation by the E3 ligase Itch. Finally, we discovered that a novel interaction between the p73 OD and SAM domain is absent in p63.

p63

Ectodermal Dysplasia

p53 Family

Protein Stability

Transactivation

Itch

PERP

EEC

0487