Molecular investigation of chemical-assisted protein rescue in ocular protein folding diseases. / CUHK electronic theses & dissertations collection

January 2010

In the study of alphaA-crystallin (CRYAA), G98R CRYAA was cloned into a mammalian expression vector pcDNA6-His/myc version B and the sequence was confirmed by direct sequencing. Following lipophilic transfection to lens epithelial B3 cells, the recombinant mutated CRYAA protein was highly insoluble upon 0.5% Triton X-100 (Tx) extraction. It was retained and formed aggregation, and distributed in the endoplasmic reticulum (ER) along with the ER resident protein (protein disulfide isomerise). The wild-type (WT) CRYAA was found to be soluble and diffusely distributed in the cytoplasm. The accumulation of G98R mutant induced ER stress, and the affected cells were prone to apoptosis. After treatment with a small chemical molecule, the natural osmolyte trimethylamine N oxide (TMAO), the Tx insolubility of mutant protein was reduced in dose- and time-dependent manners. It was also prone to be degraded via ubiquitin proteasome pathway (UPP). In mutant-expressing cells, the mutant protein aggregation was decreased after treatment. The ER stress and the rate of apoptosis were also alleviated, probably mediated by heat shock response, as demonstrated by the effect of TMAO on heat shock protein 70 expression. / The third eye gene model was myocilin (MYOC ), the first identified gene responsible for primary open angle glaucoma. The aim of this study was to investigate if glaucoma-causing MYOC variants, including D384N MYOC, could be correctable. D384N MYOC was identified in a Chinese family diagnosed with high tension juvenile-onset primary open-angle glaucoma. Disease causing mutations in MYOC (R82C, C245Y, Q368X P370L, T377M, D380A, D384N, R422C, R422H, C433R, Y437H, I477N, I477S and N480K) were cloned into mammalian expression vector p3XFLAG-myc-CMV"-25 and the sequences confirmed by direct sequencing. Following lipophilic transfection to human trabecular meshwork (HTM) cells, the Tx solubility and secretion of MYOC and cell apoptosis were examined in the presence or not with small chemical treatments. 4-PBA, TMAO and deuterium oxide (D2O), reduced the portion of insoluble fractions to various extents in the mutant proteins. The osmolytes TMAO and D2O were more effective than 4-PBA in improving MYOC solubility. TMAO was further shown to improve the secretion and ER-Golgi trafficking of D384N MYOC, thereby reducing the ER stress and rescuing cells from apoptosis. (Abstract shortened by UMI.) / The truncated G165fsX8 gammaD-crystallin ( CRYGD) variant was studied to further examine the effects of small chemical-assisted protein rescue of a CRYGD mutant that causes congenital cataract. G165fsX8 CRYGD was identified in a Chinese family with nuclear type of congenital cataract. The mutation was cloned into a mammalian expression vector p3XFLAG-myc-CMV"-25 and sequence was confirmed by direct sequencing. Following lipophilic transfection to COS-7 cells, the G165fsX8 CRYGD mutant protein was significantly insoluble upon 0.5% Tx extraction and was mistrafficked to the nuclear envelope with co-localization with nuclear lamins, whereas WT protein was Tx soluble and nuclear located. Treatment with small chemical sodium 4-phenylbutyrate (4-PBA) substantially reduced the Tx insolubility and reversed the mutant protein to nuclear localization. This correction has resulted in better cell survival, probably via a heat-shock response, as demonstrated by heat-shock protein 70 up-regulation. / To date, many genes and mutations are identified to cause various ocular diseases. Some of them result in a disruption of protein folding, an important cause of disease pathogenesis and progression. In my laboratory, novel mutations of crystallins and myocilin have been identified to segregate with congenital cataract and primary open-angle glaucoma, respectively. In this thesis, I reported molecular investigations of the resultant protein variants and their altered cellular functions in relation to the clinical phenotypes that contributed to new understanding of the roles of these genes in ocular tissues. / Gong, Bo. / Adviser: Chi-Pui Pang. / Source: Dissertation Abstracts International, Volume: 73-02, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 163-188). / 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.

Eye--Diseases--Molecular aspects

Protein folding

Eye Diseases--genetics

Protein Folding

Folding and Stability Studies on Amyotrophic Lateral Sclerosis-Associated apo Cu, Zn Superoxide dismutases

Vassall, Kenrick

January 2009

Amyotrophic lateral sclerosis (ALS) is a debilitating, incurable, neurodegenerative disease characterized by degradation of motor neurons leading to paralysis and ultimately death in ~3-5 years. Approximately 10% of ALS cases have a dominant inheritance pattern, termed familial ALS (fALS). Mutations in the gene encoding the dimeric superoxide scavenger Cu, Zn superoxide dismutase (SOD), were found to be associated with ~20% of fALS cases. Over 110 predominantly missense SOD mutations lead to fALS by an unknown mechanism; however, it is thought that mutant SOD acquires a toxic gain of function. Mice as well as human post mortem studies have identified mutant SOD-rich aggregates in affected neurons, leading to the hypothesis that mutations in SOD increase the tendency of the protein to form toxic aggregates. SOD has a complex maturation process whereby the protein is synthesized in an apo or demetalated state, followed by formation of an intramolecular disulfide bond and binding of Zn2+ and Cu2+. Each of these post-translational modifications increases the stability of the protein. SOD has been shown to aggregate more readily from destabilized immature states, including the apo state both with and without the disulfide bond, highlighting the importance of these states. Thermal unfolding monitored by differential scanning calorimetry (DSC) and chemical denaturation monitored by optical spectroscopy were used to elucidate the folding mechanism and stability of both the apo SOD disulfide-intact and disulfide-reduced states. Chemically and structurally diverse fALS-associated mutants were investigated to gain insights into why mutant SODs may be more prone to misfold and ultimately aggregate. The mutations were introduced into a pseudo wild-type (PWT) background lacking free cysteines, resulting in highly reversible unfolding amenable to accurate thermodynamic analysis. Similarly to what was previously described for fully metallated (holo) SODs, chemical denaturation of the apo disulfide-intact SODs is well described by a 3-state dimer mechanism with native dimer, monomeric intermediate and unfolded monomer populated at equilibrium. Although removal of metals has a relatively small effect on the stability of the dimer interface, the stability of the monomer intermediate is dramatically reduced. Thermal unfolding of some disulfide-intact apo SOD mutants as well as PWT is well described by a 2-state dimer mechanism, while others unfold via a 3-state mechanism similar to chemical denaturation. All but one of the studied disulfide-intact apo mutations are destabilizing as evidenced by reductions in ΔG of unfolding. Additionally, several mutants show an increased tendency to aggregate in thermal unfolding studies through increased ratios of van’t Hoff to calorimetric enthalpy (HvH/ Hcal ). The effects of the mutations on dimer interface stability in the apo disulfide-intact form were further investigated by isothermal titration calorimetry (ITC) which provided a quantitative measure of the dissociation constant of the dimer (Kd). ITC results revealed that disulfide-intact apo SOD mutants generally have increased Kd values and hence favor dimer dissociation to the less stable monomer which has been proposed to be a precursor to toxic aggregate formation. Reduction of the disulfide bond in apo SOD leads to marked destabilization of the dimer interface, and both thermal unfolding and chemical denaturation of PWT and mutants are well described by a 2-state monomer unfolding mechanism. Most mutations destabilize the disulfide-reduced apo SOD to such an extent that the population of unfolded monomer under physiological conditions exceeds 50%. The disulfide-reduced apo mutants show increased tendency to aggregate relative to PWT in DSC experiments through increased HvH /Hcal, low or negative change in heat capacity of unfolding and/or decreased unfolding reversibility. Further evidence of enhanced aggregation tendency of disulfide-reduced apo mutants was derived from analytical ultracentrifugation sedimentation equilibrium experiments that revealed the presence of weakly associated aggregates. Overall, the results presented here provide novel insights into SOD maturation and the possible impact of stability on aggregation.

Chemistry

Folding and Stability Studies on Amyotrophic Lateral Sclerosis-Associated apo Cu, Zn Superoxide dismutases

Vassall, Kenrick

January 2009

Amyotrophic lateral sclerosis (ALS) is a debilitating, incurable, neurodegenerative disease characterized by degradation of motor neurons leading to paralysis and ultimately death in ~3-5 years. Approximately 10% of ALS cases have a dominant inheritance pattern, termed familial ALS (fALS). Mutations in the gene encoding the dimeric superoxide scavenger Cu, Zn superoxide dismutase (SOD), were found to be associated with ~20% of fALS cases. Over 110 predominantly missense SOD mutations lead to fALS by an unknown mechanism; however, it is thought that mutant SOD acquires a toxic gain of function. Mice as well as human post mortem studies have identified mutant SOD-rich aggregates in affected neurons, leading to the hypothesis that mutations in SOD increase the tendency of the protein to form toxic aggregates. SOD has a complex maturation process whereby the protein is synthesized in an apo or demetalated state, followed by formation of an intramolecular disulfide bond and binding of Zn2+ and Cu2+. Each of these post-translational modifications increases the stability of the protein. SOD has been shown to aggregate more readily from destabilized immature states, including the apo state both with and without the disulfide bond, highlighting the importance of these states. Thermal unfolding monitored by differential scanning calorimetry (DSC) and chemical denaturation monitored by optical spectroscopy were used to elucidate the folding mechanism and stability of both the apo SOD disulfide-intact and disulfide-reduced states. Chemically and structurally diverse fALS-associated mutants were investigated to gain insights into why mutant SODs may be more prone to misfold and ultimately aggregate. The mutations were introduced into a pseudo wild-type (PWT) background lacking free cysteines, resulting in highly reversible unfolding amenable to accurate thermodynamic analysis. Similarly to what was previously described for fully metallated (holo) SODs, chemical denaturation of the apo disulfide-intact SODs is well described by a 3-state dimer mechanism with native dimer, monomeric intermediate and unfolded monomer populated at equilibrium. Although removal of metals has a relatively small effect on the stability of the dimer interface, the stability of the monomer intermediate is dramatically reduced. Thermal unfolding of some disulfide-intact apo SOD mutants as well as PWT is well described by a 2-state dimer mechanism, while others unfold via a 3-state mechanism similar to chemical denaturation. All but one of the studied disulfide-intact apo mutations are destabilizing as evidenced by reductions in ΔG of unfolding. Additionally, several mutants show an increased tendency to aggregate in thermal unfolding studies through increased ratios of van’t Hoff to calorimetric enthalpy (HvH/ Hcal ). The effects of the mutations on dimer interface stability in the apo disulfide-intact form were further investigated by isothermal titration calorimetry (ITC) which provided a quantitative measure of the dissociation constant of the dimer (Kd). ITC results revealed that disulfide-intact apo SOD mutants generally have increased Kd values and hence favor dimer dissociation to the less stable monomer which has been proposed to be a precursor to toxic aggregate formation. Reduction of the disulfide bond in apo SOD leads to marked destabilization of the dimer interface, and both thermal unfolding and chemical denaturation of PWT and mutants are well described by a 2-state monomer unfolding mechanism. Most mutations destabilize the disulfide-reduced apo SOD to such an extent that the population of unfolded monomer under physiological conditions exceeds 50%. The disulfide-reduced apo mutants show increased tendency to aggregate relative to PWT in DSC experiments through increased HvH /Hcal, low or negative change in heat capacity of unfolding and/or decreased unfolding reversibility. Further evidence of enhanced aggregation tendency of disulfide-reduced apo mutants was derived from analytical ultracentrifugation sedimentation equilibrium experiments that revealed the presence of weakly associated aggregates. Overall, the results presented here provide novel insights into SOD maturation and the possible impact of stability on aggregation.

Chemistry

The folding kinetics of ribonuclease Sa and a charge-reversal variant

Trefethen, Jared M.

17 February 2005

The primary objective was to study the kinetics of folding of RNase Sa. Wild-type RNase Sa does not contain tryptophan. A tryptophan was substituted at residue 81 (WT*) to allow fluorescence spectroscopy to be used to monitor folding. This tryptophan mutation did not change the stability. An analysis of the folding kinetics of RNase Sa showed two folding phases, indicating the presence of an intermediate and consistent with the following mechanism: D ↔ I ↔ N. Both refolding limbs of the chevron plot (abcissa = final conc. of denaturant and ordinate = kinetic rate) had non-zero slopes suggesting that proline isomerization was not rate-limiting. The conformational stability of a charge-reversed variant, WT*(D17R), of a surface exposed residue on RNase Sa has been studied by equilibrium techniques. This mutant with a single amino acid charge reversal of a surface exposed residue resulted in decreased stability. Calculations using Coulomb’s Law suggested that favorable electrostatic interactions in the denatured state were the cause for the decreased stability for the charge-reversed variant. Folding and unfolding kinetic studies were designed and conducted to study the charge-reversal effect. Unfolding kinetics showed a 10-fold increase in the unfolding rate constant for WT*(D17R) over WT* and no difference in the rate of refolding. Kinetics experiments were also conducted at pH 3 where protonation of Asp17 (charge reversal site) would be expected to negate the observed kinetic effect. At pH 3 the kinetics of unfolding of WT* RNase Sa and the WT*(D17R) mutant were more similar. These kinetic results indicate that a single-site charge reversal lowered the free energy of the denatured state as suspected. Additionally, the results showed that the transition state was stabilized as well. These results show that a specific Coulombic interaction lowered the free energy in the denatured and transition state of the charge-reversal mutant, more than in WT*. To our knowledge, this is the first demonstration that a favorable electrostatic interaction in the denatured state ensemble has been shown to influence the unfolding kinetics of a protein.

protein folding

protein folding kinetics

protein stability

charge-reversal

denatured state

An energy landscaping approach to the protein folding problem

Sapsaman, Temsiri

16 November 2009

The function of a protein is largely dictated by its natural shape called the "native conformation." Since the native conformation and the global minimum energy configuration highly correlate, predicting this conformation is a global optimization known as the "protein folding problem." It is computationally intensive due to the high-dimensional and complex energy landscape. Typical conformation algorithms combine a probabilistic search with analytical optimization. The analytical portion typically takes longer than the probabilistic part since more function evaluations are required, which are algorithm bottlenecks. To reduce the computational cost, this research studies the effects of exponential energy landscaping (XEL) on three analytical optimization algorithms: Newton's method, a quasi-Newton algorithm (QNA), and the Broyden-Fletcher-Goldfarb-Shanno (BFGS) algorithm. The XEL changes the heights and the depths of the extrema but keeps their location the same, which eliminates the troublesome process of remapping minima onto the original landscape. The Newton-XEL is found to have a similar convergence property as Newton's method by showing that their error residues are of the same order. Found by observation, stability and convergence are improved when the error residue is bounded. While XEL is found to have no effect on the similarity of resulting configurations to the native conformation, results show that the XEL can improve the speed in terms of average iterations in the QNA by 47% and in the BFGS by 41%. In terms of the average score improvement, which indicates how the energy of the resulting configuration is compared to that of the initial configuration, the XEL can improve the quality of resulting configurations in the QNA by 12% and in the BFGS by 10%. Since both results were not achieved simultaneously, the adaptive exponential energy landscaping (AXEL) is developed. The results lead to the conclusion that a trade-off between quality and speed must be considered when XEL is implemented. To improve speed by 15% to 47% and efficiency by 13% to 75%, XEL with n within 2⁻⁹-2⁻⁵ should be used and to improve quality by 4% to 7%, AXEL with Scheme E that keeps the error residue bounded should be used.

Energy landscaping

Protein folding

Optimization

Protein folding

Mathematical optimization

Proteins Conformation

Computational studies of the folding patterns of small and medium-size polypeptides

Mokoena, Paul

January 2010

Submitted in partial fulfilment for the Degree of Doctor of Technology: Biotechnology, Durban University of Technology, 2010. / This study involved a series of molecular dynamics (MD) simulations applied to case studies of small and medium-size polypeptides to assess the thermodynamics of their folding characteristics. Peptide folding is a complex and vital phenomenon taking place in all living systems. Bioactive conformational structures of folded peptides need to be well characterized before using them in computer-aided drug design. The computational procedure was validated on the 10-residue long chignolin-like synthetic mini-protein (CLN025). For this peptide, replica exchange molecular dynamics (REMD) calculations were carried out in explicit and implicit solvents using the generalized Born (GB)/surface area (SA) approximation with different sets of force field parameters. Following this validation procedure, case studies of the folding conformations of peptides of different lengths including the 5-residue met-enkephalin, the 27-residue pituitary adenylate-activating polypeptide 27(PACAP27) and the 28-residue vasoactive intestinal peptide (VIP) were undertaken. The latter two peptides are multifunctional hormones that mediate diverse biological functions, such as the cell cycle, cardiac muscle relaxation, immune response, septic shock, bone metabolism, and endocrine function. Results obtained indicate that when explicit water, methanol and DMSO solvents were used, it appeared that methanol (MeOH) and dimethylsulphoxide (DMSO) afforded met-enkephalin the ability to form more intra-hydrogen bonds than water, producing type I and type III β-turn structures; thus enhancing the helical conformation of the peptide. MD trajectories of longer polypeptides (VIP and PACAP27) were also populated with type I and type III β-turns, which occurred consecutively; with α- and 310-helices occurring from the middle of each peptide towards the C-terminal. Characterization of implicit solvent results, reveal that these simulations have been able to reproduce the same type of conformers obtained by experimental NMR studies published in literature, which structurally resemble the native conformation of the bioactive peptides. These conformational structures will be applied as lead agents in computer-aided drug design. One of the major achievements of this study is the ability to optimize and validate the force field parameter sets to describe the thermodynamic properties of peptide systems in an unbiased manner, a non-trivial task for even the smallest of peptides. These findings re-affirm the notion that computational methods have matured enough to model dynamic biological phenomena such as peptide folding, a feat previously thought to be impossible.

Biotechnology

Peptides--Computer simulation

Peptides--Conformation

Polypeptides

Protein folding

ER-stress signaling and chondrocyte differentiation in mice

Lo, Ling-kit, Rebecca., 羅令潔.

January 2006

published_or_final_version / abstract / Biochemistry / Master / Master of Philosophy

Protein folding.

Endoplasmic reticulum.

Cartilage cells.

Cell differentiation.

Transgenic mice.

NMR Studies of SH3 Domain Structure and Function

Bezsonova, Irina

19 January 2009

SH3 domains are excellent models for probing folding and protein interactions. This thesis describes NMR studies of several SH3 domains, including the N-terminal SH3 domain of the Drosophila adaptor protein Drk (drkN SH3 domain), the SH3 domain of the proto-oncogene tyrosine-kinase Fyn, and the SH3 domains of the human adaptor protein CIN85, involved in Cbl-mediated downregulation of epidermal growth factor receptor (EGFR) and other receptor tyrosine kinases (RTKs). The drkN SH3 domain is an ideal system for studying disordered states. The unique quality of this isolated domain is that it exists in an approximately 50/50 equilibrium between its folded and unfolded states under non-denaturating buffer conditions. Interestingly, the single T22G mutation dramatically stabilizes the domain. Here the NMR structures of the drkN SH3 domain and its T22G mutant are determined and compared in order to illuminate the causes of the marginal stability of the domain. Solvent exposure of the folded and the unfolded drkN SH3 domains are probed and compared with a novel NMR technique using molecular oxygen dissolved in solution as a paramagnetic probe. The changes in partial molar volume along the folding trajectories of the drkN SH3 and Fyn SH3 domains are also studied and analyzed here in terms of changes in protein hydration and packing accompanying folding. Finally, the interactions between the SH3 domains of CIN85 and ubiquitin are discussed. All three are shown to bind ubiquitin. The structure of the SH3-C domain in complex with ubiquitin is presented and the effect of disruption of ubiquitin binding on ubiquitination of CIN85 and EGFR in vivo is discussed. SH3 domains are easily amendable to a wide range of NMR approaches and provide a good system for development and testing of novel methods. Through the use of these approaches significant insights into details of SH3 domain structure, stability, mechanisms of folding and cellular function have been gained.

SH3 domain

NMR

drk

fyn

CIN85

ubiquitination

protein folding

0487

Towards a Mechanistic Understanding of the Molecular Chaperone Hsp104

Lum, Ronnie

18 February 2011

The AAA+ chaperone Hsp104 mediates the reactivation of aggregated proteins in Saccharomyces cerevisiae and is crucial for cell survival after exposure to stress. Protein disaggregation depends on cooperation between Hsp104 and a cognate Hsp70 chaperone system. Hsp104 forms a hexameric ring with a narrow axial channel penetrating the centre of the complex. In Chapter 2, I show that conserved loops in each AAA+ module that line this channel are required for disaggregation and that the position of these loops is likely determined by the nucleotide bound state of Hsp104. This evidence supports a common protein remodeling mechanism among Hsp100 members in which proteins are unfolded and threaded along the axial channel. In Chapter 3, I use a peptide-based substrate mimetic to reveal other novel features of Hsp104’s disaggregation mechanism. An Hsp104-binding peptide selected from solid phase arrays recapitulated several properties of an authentic Hsp104 substrate. Inactivation of the pore loops in either AAA+ module prevented stable peptide or protein binding. However, when the loop in the first AAA+ was inactivated, stimulation of ATPase turnover in the second AAA+ module of this mutant was abolished. Drawing on these data, I propose a detailed mechanistic model of protein unfolding by Hsp104 in which an initial unstable interaction involving the loop in the first AAA+ module simultaneously promotes penetration of the substrate into the second axial channel binding site and activates ATP turnover in the second AAA+ module. In Chapter 4, I explore the recognition elements within a model Hsp104-binding peptide that are required for rapid binding to Hsp104. Removal of bulky hydrophobic residues and lysines abrogated the ability of this peptide to function as a peptide-based substrate mimetic for Hsp104. Furthermore, rapid binding of a model unfolded protein to Hsp104 required an intact N-terminal domain and ATP binding at the first AAA+ module. Taken together, I have defined numerous structural features within Hsp104 and its model substrates that are crucial for substrate binding and processing by Hsp104. This work provides a theoretical framework that will encourage research in other protein remodeling AAA+ ATPases.

molecular chaperone

thermotolerance

Hsp104

yeast

disaggregation

protein folding

0487

Investigations of peptide structural stability in vacuo

Kalapothakis, Jason Michael Drosos

January 2010

Gas-phase analytical techniques provide very valuable tools for tackling the structural complexity of macromolecular structures such as those encountered in biological systems. Conformational dynamics of polypeptides and polypeptide assemblies underlie most biological functionalities, yet great difficulties arise when investigating such phenomena with the well-established techniques of X-ray crystallography and NMR. In areas such as these ion mobility interfaced with mass spectrometry (IMMS) and molecular modelling can make a significant contribution. During an IMMS experiment analyte ions drift in a chamber filled with an inert gas; measurement of the transport properties of analyte ions under the influence of a weak electric field can lead to determination of the orientationally-averaged collision cross-section of all resolved ionic species. A comparison with cross-sections estimated for model molecular geometries can lead to structural assignments. Thus IMMS can be used effectively to separate gas-phase ions based on their conformation. The drift tube employed in the experiments described herein is thermally regulated, which also enables the determination of collision cross-sections over a range of temperatures, and can provide a view of temperature-dependent conformational dynamics over the experimental (low microsecond) timescale. Studies described herein employ IMMS and a gamut of other MS-based techniques, solution spectroscopy and – importantly – molecular mechanics simulations to assess a) conformational stability of isolated peptide ions, with a focus on small model peptides and proteins, especially the Trp cage miniprotein; and b) structural characteristics of oligomeric aggregates of an amyloidogenic peptide. The results obtained serve to clarify the factors which dominate the intrinsic stability of non-covalent structure in isolated peptides and peptide assemblies. Strong electrostatic interactions are found to play a pivotal role in determining the conformations of isolated proteins. Secondary structures held together by hydrogen bonding, such as helices, are stable in the absence of solvent, however gas-phase protein structures display loss of their hydrophobic cores. The absence of a polar solvent, “self-solvation” is by far the most potent force influencing the gas-phase configuration of these systems. Geometries that are more compact than the folded state observed in solution are routinely detected, indicating the existence of intrinsically stable compact non-native states in globular proteins, illuminating the nature of proteins’ ‘unfolded’ states.

571.4