Phage display to identify functional resistance mutations to Rigosertib

Filipovic, Nedim

01 January 2017

In vitro protein selection has had major impacts in the field of protein engineering. Traditional screens assay individual proteins for specific function. Selection, however, analyzes a pool of mutants and yields the best variants. Phage display, a successful selection technique, also provides a reliable link between variant phenotype and genotype. It can also be coupled with high throughput sequencing to map protein mutations; potentially highlighting vital mutations in variants. We propose to apply this technique to cancer therapy. RAF, a serine/threonine kinase, is critical for cell regulation in mammals. RAF can be activated by oncogenic RAS, found in over 30% of cancers, to drive cancer proliferation. Rigosertib, a benzyl styryl sulfone in phase III clinical trials for myelodysplastic syndrome (MDS), is an inhibitor of the RAS binding domain (RBD) in RAF. Phage display can be used to select RAF mutants for RAS binding affinity, in the presence of Rigosertib. High-throughput sequencing of these variants can provide a means of anticipating, and mapping resistance to this anti-cancer drug.

Phage display

Cancer therapy

High-throughput sequencing

Rigosertib

Protein engineering

Biochemistry

Medicinal-Pharmaceutical Chemistry

Other Chemistry

Single-molecule chemistry studies with engineered alpha-hemolysin pores

Hammerstein, Anne Friederike

January 2011

Engineered protein nanopores can be used to investigate a wide range of dynamic processes in real time and at the single-molecule level, for example covalent bond making and breaking or the interaction of ligands with their cognate binding sites. The detection of such processes is accomplished by monitoring the current carried by ions through the pore in an applied potential, which is modulated as molecules of interest interact with engineered binding sites within the pore. In contrast to ensemble measurements, where the behaviour of individual molecules is obscured by averaging, single-channel recordings can identify short-lived intermediates and rare reaction pathways, thereby adding to our understanding of fundamental processes in chemistry and biology. The goal of my thesis work was to engineer alpha-hemolysin (αHL) pores to gain insight into such processes. <b>Chapter 1</b> provides an overview of common techniques used to study single- molecule processes, in particular single channel recordings. General techniques to engineer ion channels and pores are presented, followed by examples of how the alpha-HL pore has been engineered to monitor dynamic processes at the single- molecule level. <b>Chapter 2</b> describes how alpha-HL pores can be chemically modifeed with a tridentate "half-chelator" ligand. Single channel recordings show that this modifeed pore can be used to determine rates of chelation and the stability of divalent metal ion complexes. The modifeed pore can also be used as a stochastic sensor for the detection of different divalent metal ions in solution. <b>Chapter 3</b> investigates the chelate-cooperativity between two half-chelator ligands installed in close proximity in the alpha-HL pore, as they form a full complex with a single Zn²⁺ ion. The single channel recordings reveal a two step process, in which the Zn²⁺ ion must fiferst bind to one of the two half-chelators, before the second one completes the complex. The rate constants for all the major steps of the process are determined and the extent of cooperativity between the half-chelators is quantifeed. <b>Chapter 4</b> demonstrates that genetically encoded subunit dimers of alpha-HL can be used to control the subunit arrangement in the heptameric pore. Although techniques exist to prepare heteroheptameric pores, pores containing more than one type of modifeed subunit are not commonly used because it is impossible to distinguish between the permutations of the pore. By using subunit dimers, heptamers in which two defefined subunits are adjacent to each other can be formed, which increases the range of structures that can be obtained from engineered protein nanopores. <b>Chapter 5</b> explores the possibility of following the nuclease activity of a metal complex in the alpha-HL pore at the single-molecule level. The Rh(III) complex [Rh(bpy)2phzi]²⁺ binds strongly to CC mismatches in dsDNA, and on activation with UV light promotes the cleavage of one of the two strands. To follow this reaction by single channel recording, a piece of dsDNA with the bound Rh-complex was immobilised in the HL pore and the single current changes under UV irradiation were monitored. The preliminary data indicate that the rate of the photocleavage reaction can be measured.

572

Variable domain orientations in antigen receptors

Dunbar, James

January 2014

Specific recognition of pathogenic molecules by the immune system is mediated by proteins known as antigen receptors. One such component is the antibody. Binding properties of natural and engineered antibodies can be understood by studying the structure of their variable domains, VH and VL. In this thesis we investigate how the two variable domains orientate with respect to one another and therefore influence the geometry of the antigen binding site which is formed between them. We describe a method which fully characterises the VH-VL orientation in a consistent and absolute sense using five angles and a distance. The ABangle method is used to investigate variable domain orientation in structures collected by our database SAbDab. Using the ABangle method we compare VH-VL orientation to the corresponding property in a different component of the immune system, the T-cell receptor (TCR). Despite having similar individual domain structures the variable domain orientations of antibodies and TCRs are found to be distinct. This is found to affect an antibody’s ability to mimic TCR specificity. ABangle's characterisation is used to find determinants of the VH-VL orientation. We identify sequence and structural properties that influence the variable domain pose. A feature based method for predicting VH-VL orientation is presented and assessed. Future directions of this research and its application to the development of antibody therapeutics are described.

616.07

Development of Orthogonal Split-Kinase and Split-Phosphatase Systems for Interrogating and Rewiring Signal Transduction

Castillo-Montoya, Javier, Castillo-Montoya, Javier

January 2016

The function of most proteins is regulated by post-translational modifications, of which phosphorylation in particular has been shown to be ubiquitous and of paramount importance to cell signaling. Two enzyme families, protein kinases and phosphatases, regulate phosphorylation, and aberrant activities of family members have been implicated in many diseases such as cancer and neurological disorders. Thus, understanding the function of these enzymes in living cells is important for understanding their biology and for designing new therapies, but a challenging task due to their highly conserved architecture. The major focus of the dissertation is on the development of a new approach to selectively turn-on multiple specific kinases and/or phosphatases using orthogonal ligands as chemical inducers of dimerization (CIDs). Specific kinases or phosphatases were dissected at particular sites into two inactive fragments or split-proteins. The split fragments are attached to interacting protein pairs of CID systems, such that upon addition of the specific ligand they heterodimerize with subsequent reassembly of the split-protein and concomitant activity. We demonstrated the in vitro and in cellulo feasibility of this approach using three orthogonal CIDs, rapamycin, abscisic acid, and gibberellic acid, to turn-on members of the tyrosine kinase group such as Lyn and Src, and of the tyrosine phosphatase group such as PTP1B and SHP1. We have also developed a new synthetic photocleavable di-trimethoprim CID that allows for ligand-gated turn-on of desired kinases in live cells. The new CID can be cleaved or turned-off by UV irradiation which results in a turn-off of kinase activity. Small molecule controlled split-proteins allow for developing logic gates and we demonstrate that the systems we have developed can be used to construct 7 out of the 10 basic, circuit-type Boolean phosphorylation-based logic gates in living cells. These post-translational logic gates may have interesting applications in synthetic biology. Finally, we present an initial approach to use redesigned kinases and redesigned ligands as potential scaffolds for developing new CIDs. Thus, we provide and extend new methodologies that potentially allow for posttranslational control over the activity of user defined split-kinases and split-phosphatases for interrogating and redesigning signaling pathways. The last section of this work focuses on understanding small-molecule selectivity toward protein kinases. We systematically analyzed different reported kinase screens to further understand the reliability of large scale data in the kinome field as the design of selective inhibitors is one the most useful approaches for understanding the function of enzymes or the development of drugs in a natural setting such as a primary cell or an organism.

Kinases

Ligand-Gated Phosphorylation

Protein Engineering

Split-Kinase

Split-Phosphatase

Chemical Inducer of Dimerization

A Redesigned Hydrophobic Core of a Symmetric Protein Superfold with Increased Primary Structure Symmetry

Brych, Stephen Robert

Unknown Date

Human acidic fibroblast growth factor (FGF-1) is a member of the £]-trefoil superfamily and exhibits a characteristic three-fold tertiary structure symmetry. However, evidence of this symmetry is not readily apparent at the level of the primary structure. This suggests that while selective pressures may exist to retain (or converge upon) a symmetric tertiary structure, other selective pressures have resulted in divergence of the primary structure during evolution. Using intra-chain and homologue sequence comparisons for 19 members of this family of proteins, we have designed mutants of FGF-1 that constrain a subset of core-packing residues to three-fold symmetry at the level of the primary structure. The consequences of these mutations upon structure, stability, folding and unfolding kinetics have been evaluated using a combination of x-ray crystallography, differential scanning calorimetry, isothermal equilibrium denaturation and stopped flow protein refolding/unfolding kinetics. An alternative core packing group has been introduced into FGF-1. The alternative core is very similar from the wild type (WT) core with regard to structure, stability, folding and unfolding kinetics. The remaining asymmetry within the protein core is related to asymmetry in the tertiary structure. The removal of tertiary structure asymmetry greatly increases protein stability and results in a conversion from three-state to a two-state folding pathway. The tertiary structure asymmetry is intimately linked to functional regions of the protein. Surprisingly, upon deletion of the functional insertions, the mutant protein is approximately 80 times more potent than the wild type form as determined by functional bioassays. The results show that the ƒÒ-trefoil superfold is compatible with a three-fold symmetric constraint upon the core region, as might be the case if the superfold arose as a result of gene duplication/fusion events. Furthermore, this new protein arrangement can form the basis of a structural "building block" that can greatly simplify the de novo design of ƒÒ-trefoil proteins by utilizing symmetric structural complementarity. This study implies that a symmetric architecture of the £]-trefoil fold is kinetically and thermodynamically ¡§fit¡¨. / Dissertation / PhD

Produção, caracterização cinética e engenharia de proteína Asparaginase 1 de Saccharomyces cerevisiae para avaliação de seu uso como biofármaco / Production, kinetic characterization and engineering of asparaginase 1 protein from Saccharomyces cerevisiae to evaluate its use as a biopharmaceutical.

Costa, Iris Munhoz

23 October 2015

A L-asparaginase (EC 3.5.1.1) é uma enzima importante para o tratamento da leucemia linfoblástica aguda (LLA), neoplasia mais frequente em crianças e adolescentes. A L-asparaginase hidrolisa a L-asparagina resultando em ácido aspártico e amônio, impedindo que as células tumorais utilizem esse aminoácido para síntese proteica, ocasionando a morte celular apoptótica. Atualmente a enzima é obtida a partir de Escherichia coli e Erwinia chrysanthemi; no entanto, ambas as formulações estão associadas a um alto índice de efeitos adversos que comprometem a evolução e eficácia do tratamento. A levedura Saccharomyces cerevisiae tem o gene ASP1 responsável pela produção de L-asparaginase 1 (Sc_ASPase1) que tem sido pouco estudada. Para elucidar as características de Sc_ASPase1 nós expressamos a proteína em E. coli BL21(DE3) e a purificamos por cromatografia de afinidade. Sc_ASPase1 tem uma atividade especifica de 195,4 U/mg para L-asparagina e de 0,36 U/mg para L-glutamina, e um comportamento alostérico com um K0.5 de 75 &#181;M para L-asparagina. Por meio de mutação sitio dirigida demonstramos a importância dos resíduos Thr64-Thy78-Th141-Lys215 para a catálise. As isoformas mutantes da proteína A331D, K335E, Y243S, S301N e &#916;G77 não apresentaram melhoria nos parâmetros cinéticos ou atividade específica. Construímos e clonamos Sc_ASPase1 com a deleção dos primeiros 52 aminoácidos, porém nas condições testadas a proteína foi expressa na forma insolúvel. Demonstramos que Sc_ASPase1 possui potencial antineoplásico, pois com 10 U/mL de enzima foi capaz causar a 85% de mortalidade da linhagem leucêmica MOLT-4. Na mesma concentração, a enzima de E. coli é capaz de matar 95% de células dessa mesma linhagem. / L-Asparaginase (EC 3.5.1.1) is an important enzyme for the treatment of acute lymphoblastic leukemia (ALL), the most common malignancy in children and adolescents. L-asparaginase hydrolyzes L-asparagine resulting in ammonium and aspartic acid, preventing tumor cells of using such amino acid for protein synthesis, leading to apoptotic cell death. Currently, the enzyme is obtained from Escherichia coli and Erwinia chrysanthemi; however, both formulations are associated with a high incidence of side effects that compromise the progress and effectiveness of treatment. The yeast Saccharomyces cerevisiae has ASP1 gene responsible for the production of L-asparaginase 1 (Sc_ASPase1) that has been poor studied. To elucidate the characteristics of Sc_ASPase1, we expressed the protein in E. coli BL21 (DE3) cells and purified it by affinity chromatography. Sc_ASPase1 has a specific activity of 195.4 U/mg for L-asparagine and 0.36 U/mg for L-glutamine, and an allosteric behavior with a K0.5 of 75 &#181;M for L-asparagine. Through site directed mutation, we demonstrated the importance of Thr64-Thy78-Th141-Lys215 residues for catalysis. The mutant protein isoforms A331D, K335E, Y243S, S301N and &#916;G77 showed no improvement in kinetic parameters or specific activity. We build and cloned Sc_ASPase1 with the deletion of the first 52 amino acids, but under the conditions tested the protein was expressed in insoluble form. Sc_ASPase1 have demonstrated potential antineoplastic activityc, since 10 U/mL of enzyme lead to 85% of mortality in leukemia cell line MOLT-4. At the same concentration, the E. coli enzyme kills 95% of the cells of the same line.

Acute lymphoblastic leukemia

Engenharia de proteína

L-asparaginase

L-asparaginase

Leucemia linfoblástica aguda

Protein engineering

Saccharomyces

Saccharomyces

Combined Fermentation and Recovery Using Expanded Bed Chromatography

Cochran, Keith Jacob

18 August 2006

"Expanded Bed Chromatography (EBC) is rapidly becoming the preferred choice for initial product recovery from crude process streams as it enables direct protein recovery from culture broths after appropriate dilution. However, the process is time intensive, and there are still some difficulties with very high cell density cultures in the 500 g/L range. Problems include in-column clogging and poor column efficiency. With the development of a new prototype EBC column capable of product recovery from undiluted culture broth, it is proposed in this study to combine the fermentation with EBC recovery. This strategy was tested using a wild type, non-producing strain of Pichia pastoris. Culture broths were spiked with 200 mg/L lysozyme to mimic an actual production fermentation. Key parameters for the process were identified and tested independently to better assess system performance: potential toxic effects of the resin on the culture, nutrient deprivation of the cells as they pass through the column and binding of the target protein from whole broth. The cation exchanger had a negligible effect on cell proliferation in shake flask studies using YNB Medium. Isolation of the culture from the fermenter for up to two hours appeared to have minimal effect on overall cell viability and the ability to metabolize methanol. The dynamic binding capacity for lysozyme was 50 mg/mL in buffer, and 20 mg/mL in undiluted fermentation broth containing 500 g/L cells. When harvested undiluted fermentation broth was allowed to recirculate through the EBC column, the binding capacity was increased to 30 mg/mL. The combination of the fermentation and recovery process allowed for a binding capacity of 30-40 mg/mL, with no dramatic effects on biomass accumulation or metabolic rate."

expanded bed chromatography

Pichia pastoris

Protein engineering

Pichia pastoris

Chromatographic analysis

Engineering Biomolecular Interfaces for Applications in Biotechnology

Bulutoglu, Beyza

January 2017

Protein interactions occurring through biomolecular interfaces play an important role in the circle of life. These interactions are responsible for cellular function, including RNA transcription, protein translation, cell division and cell death among many others. There are different types of interactions based on the strength and the duration of the association. Transient interactions govern most steps of the cellular metabolism, where the associations between two or more molecules are responsive to environmental cues. Among the participants of transient interactions, intrinsically disordered proteins are employed in signaling and other regulatory events within the cell. These proteins exhibit allosteric regulation and gain secondary structure when they bind other proteins or small molecules. In this doctoral thesis work, the biochemical and biophysical principals governing protein associations are investigated and using protein engineering tools, novel biomolecular interfaces are engineered, with potential applications in different areas of biotechnology. The first part of the thesis (Chapter 2) focuses on the investigation of supramolecular enzyme association among tricarboxylic acid cycle enzymes, specifically between citrate synthase and mitochondrial malate dehydrogenase. In this study, the interactions between these enzymes are examined, both among their natural and synthetically produced recombinant versions. In addition, mutational analysis of the amino acid residues at the complex interface was performed to explore the importance of the positively charged patch connecting the active sites of the enzymes. It was discovered that the channeling of the negatively charged intermediate is severely impaired upon mutation of surface residues contributing to the electrostatic channeling. This work provides an important insight into understanding the coupled reaction-transport systems and metabolon formation in general. In addition, it constitutes a great example for substrate channeling in leaky systems, which are relevant to most biological processes. The next section of the thesis (Chapter 3) focuses on an intrinsically disordered peptide, the β-roll. This peptide is isolated from the Block V repeats-in-toxin (RTX) domain of adenylate cyclase from Bordetella pertussis. It is disordered in the absence of calcium and it folds into a β-roll secondary structure composed of two parallel β-sheet faces upon binding to calcium ions. This way, the peptide can transition between its unfolded state and the β-roll structure in a reversible way. We have utilized the allosteric regulation of this domain as a tool to engineer new protein interfaces. In its folded state, the peptide has two faces, serving as binding surfaces available for interaction with other proteins. Our work involved the alteration of the residues, which form these faces upon calcium binding, via combinatorial protein design techniques. The potential of this peptide is evaluated as a cross-linking domain for hydrogel formation. By rationally engineering the two faces of the folded β-roll to contain leucine residues, we have created hydrophobic interfaces, serving as environmentally-responsive cross-linking domains. When there is no calcium, the β-roll domains remain unstructured, delocalizing the leucine rich patches. After calcium binding, the β-rolls fold and the leucine rich faces are exposed creating a hydrophobic driving force for self-assembly. This way, we showed that the β-roll peptide can function as a biomaterials building block capable of proteinaceous hydrogel formation, only in the presence of calcium. The next study (Chapter 4) demonstrates the utilization of this peptide as an alternative scaffold for biomolecular recognition applications. A library of mutant β-rolls was constructed by randomizing the amino acid residues on one of the β-sheet forming faces. Mutant peptides demonstrating an affinity for hen egg white lysozyme were selected, which was chosen as a model target molecule. The thermodynamic parameters of the interactions between the β-roll mutants and the lysozyme were quantified. Upon performing further protein engineering (e.g. concatenation of the single mutants on the DNA level), a mutant with mid-nanomolar affinity was identified. Affinity chromatography experiments showed that this mutant was capable of capturing the target, in the presence of calcium. The captured target was easily released upon removal of the calcium ions. The reversibility of the calcium binding allowed the engineered molecular interface to be controllable. Throughout this study, the β-roll peptide was explored as an allosterically-regulated protein switch for on/off biomolecular recognition, which can be mediated by simply changing the calcium concentration, allowing control over the binding behavior between molecules. The last part of the thesis (Chapter 5) expands on the calcium dependent network formation study. A hydrogel construct was genetically built by fusing the cross-linking β-roll domain and the lysozyme binding β-roll mutant, resulting in a smart biomaterial with dual-functionality. The network-assembly and target capture functions of this construct were tested by various assays including hydrogel erosion experiments. This allosterically-regulated biomaterial exhibited promising results, where calcium-dependent lysozyme entrapment within the assembled network and lysozyme capture on the hydrogel surface were demonstrated. The work presented in this thesis demonstrates different approaches to understand and engineer molecular interfaces in both natural and recombinant systems. In the future, these approaches and the knowledge gained from these studies can be further built upon for different biotechnological applications and can also be applied to other synthetic systems.

Biotechnology

Protein-protein interactions

Protein engineering

Enzymes

Peptides

Biomolecules

Chemical engineering

Biomedical engineering

Development of imine reductases and reductive aminases for chiral amine synthesis

Aleku, Godwin

January 2017

Novel biocatalysts for the enantioselective reduction of imines and reductive amination of a broad range of carbonyl compounds have been developed. Unlike other imine reductases (IREDs), the IRED from Amycolaptosis orientalis (AoIRED) features an aprotic "catalytic" residue Asn171 and as such became an interesting candidate for detailed mechanistic, specificity and stereoselectivity studies. AoIRED has been shown to be an efficient catalyst for the enantioselective reduction of imines and iminium ions to yield the corresponding chiral amines in high conversions and good to excellent enantioselectivity. The enzyme exhibits unusual stereoselective properties, displaying a selectivity switch for structurally similar substrates and in certain cases for the same substrate depending on the age of the enzyme. Mutagenesis studies have highlighted important residues that may play key roles in the substrate specificity and stereoselectivity of the enzyme. The reductive aminase from Aspergillus oryzae (AspRedAm) is a multifunctional catalyst that efficiently catalyses i) the reductive coupling of carbonyl compounds and amine nucleophiles, ii) the enantioselective reduction of prochiral cyclic and preformed imines or iii) the oxidative deamination of amines towards kinetic resolution of racemic amines. Detailed kinetic studies have led to the construction of a kinetic model/mechanism and based on structure guided investigation of conserved active site residues, a putative catalytic mechanism has been proposed. It has also been possible to engineer wild-type AspRedAm for improved stereoselectivity as well as to invert the enzyme's enantioselectivity towards a range of substrates. Using AspRedAm as a catalyst, efficient systems have been developed that allow the kinetic resolution of several racemic amines. This thesis has been organised into separate chapters each addressing a specific theme. Chapter 1 gives an overview of recent advances in the field of amine biocatalysis with emphasis on biocatalytic imine reduction and reductive amination; it also outlines the objectives of this project. Chapter 2 describes methods and materials used in these studies while Chapters 3-7 present and discuss results from different projects that constitute the work in this thesis. Initial discovery and characterisation studies of IREDs are described in Chapter 3. Chapter 4 describes detailed characterisation of AoIRED with particular emphasis on stereoselectivity and synthetic applicability while Chapter 5 presents and discusses results from the study of the reductive aminase (AspRedAm) from Aspergillus oryzae. Chapters 6 and 7 respectively describe the engineering of AoIRED and AspRedAm, and the application of AspRedAm in kinetic resolution of racemic amines. The results from these chapters have been summarised and discussed in Chapter 8 and recommendations for future directions in this field have been offered.

540

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