Conceptual design and mechanisms for foldable pyramidal plated structures

Khayyat, Hassan A.

January 2008

In spite of the presence of much research in the field of foldable structures whose applications have covered most of the requirements of academic and practical aspects of life, there is still a wide domain in which to undertake further studies. One of the required studies is to invest in foldable structures for the process of temporary accommodation. This study endeavours to find solutions for folding pyramidal shapes constructed from stiff panels that can be used as an upper part of temporary accommodation units, e.g., roofs. Several attempts have been made to find a mechanism that realises the folding of a three-dimensional pyramid. These attempts led to suggest a design that represents an initial solution for folding the pyramid. It was taken into consideration in this design that the structure should deploy strain free when the thickness of its panels is not considered. Trigonometry was used to find mathematical equations that can be used to identify the lengths and angles of the proposed design plates. These equations theoretically proved the validity of the proposed mechanism. The proposed design was applied to construct an actual model formed with thick panels. Considering the panel thickness of the model plates led to amendments and improvements to the proposed design. Two actual models were experimentally tested to make sure that they achieve the design concepts in the processes of full folding and deployment. The models were also tested in the laboratory to make sure of the integrity of the panel hinges and resistance of the elements to external loading. The model was constructed in a simulation program in order to verify the foldability of the design, folding efficiency and absence of strain or collisions during the process of folding and deployment at all stages.

624.1

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

Design obytného přívěsu. / Design of caravan.

Novák, Jakub

January 2010

Theme of this diploma thesis is the design of caravan meaning travel trailer. Concept is adapted to the technical and ergonomic requirements and the main goal of this concept is to provide original design with a view to the future. The complex concept meets the operational, technical and ergonomic demands of such trailers. The project is focused on the design concept of the implemented folding mechanism. Design of the travel trailer is due to todays modern technological methods and the construction ready for production and everyday operating usage.

Deformačně-napěťová analýza sklápěcího mechanismu předního sedadla / Stress-strain analysis of front seat folding mechanism

Gergeľ, Erik

January 2014

This master thesis deals with creation of computational model for stress - strain analysis of front car seat folding mechanism. The calculation has been done using FEM for static and dynamic load case. The results displayed the critical area of mechanism and determined the value of force when the safety of mechanism is not guaranteed and the force when the mechanism failure occurs. According to results from both load cases was made a statement that is necessary to model the dynamic load cases respecting the load time course.

Influence of Cooperativity on the Protein Folding Mechanism

Qi, Xianghong

21 August 2008

No description available.

Biophysics

Physics

protein folding mechanism

TSE

folding rates

barrier heights

topology

critical folding nucleus

folding pattern

packing fraction

stability

Détection, caractérisation et visualisation des structures transitoires de protéines par sondage au tryptophane

Vallée-Bélisle, Alexis

January 2008

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal.

Protéines

Proteins

Mécanisme de repliement

Folding mechanism

Ubiquitine

Ubiquitin

Structure d'intermédiaires transitoires

Transient intermediates state

Spectroscopie de fluoresence

Fluorescence spectroscopy

Mutagenèse dirigée

Mutagenesis

Sondage par tryptophane

Tryptophan scanning

Analyse par valeur-w

w-value analysis

Biotechnologies

Biotechnology

Détection, caractérisation et visualisation des structures transitoires de protéines par sondage au tryptophane

Vallée-Bélisle, Alexis

January 2008

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal

Protéines

Proteins

Mécanisme de repliement

Folding mechanism

Ubiquitine

Ubiquitin

Structure d'intermédiaires transitoires

Transient intermediates state

Spectroscopie de fluoresence

Fluorescence spectroscopy

Mutagenèse dirigée

Mutagenesis

Sondage par tryptophane

Tryptophan scanning

Analyse par valeur-w

w-value analysis

Biotechnologies

Biotechnology