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The Relationship of Force on Myosin Subfragment 2 Region to the Coiled-Coiled Region of the Myosin DimerHall, Nakiuda M. 12 1900 (has links)
The stability of myosin subfragment 2 was analyzed using gravitational force spectroscopy. The region was found to destabilize under physiological force loads, indicating the possibility that subfragment 2 may uncoil to facilitate actin binding during muscle contraction. As a control, synthetic cofilaments were produced to discover if the observations in the single molecule assay were due to the lack of the stability provided by the thick filament. Statistically, there was no difference between the single molecule assay data and the synthetic cofilament assay data. Thus, the instability of the region is due to intrinsic properties within subfragment 2.
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Identification of the Sea Urchin Egg Myosin Binding Protein GeneShea, Laura R. January 1999 (has links)
No description available.
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Smooth muscle contraction by small GTPase RhoKawano, Yoji, Yoshimura, Takeshi, Kaibuchi, Kozo 05 1900 (has links)
No description available.
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Stability of Myosin Subfragment-2 Modulates the Force Produced by Acto-Myosin Interaction of Striated MuscleSingh, Rohit Rajendraprasad 12 1900 (has links)
Myosin subfragment-2 (S2) is a coiled coil linker between myosin subfragment-1 and light meromyosin (LMM). This dissertation examines whether the myosin S2 coiled coil could regulate the amount of myosin S1 heads available to bind actin thin filaments by modulating the stability of its coiled coil. A stable myosin S2 coiled coil would have less active myosin S1 heads compared to a more flexible myosin S2 coiled coil, thus causing increased force production through acto-myosin interaction. The stability of the myosin S2 coiled coil was modulated by the binding of a natural myosin S2 binding protein, myosin binding protein C (MyBPC), and synthetic myosin S2 binding proteins, stabilizer and destabilizer peptide, to myosin S2. Competitive enzyme linked immunosorbent assay (cELISA) experiments revealed the cross specificity and high binding affinity of the synthetic peptides to the myosin S2 of human cardiac and rabbit skeletal origins. Gravitational force spectroscopy (GFS) was performed to test the stability of myosin S2 coiled coil in the presence of these myosin S2 binding proteins. GFS experiments demonstrated the stabilization of the myosin S2 coiled coil by the binding of MyBPC and stabilizer peptide to myosin S2, while the binding of destabilizer peptide to the same resulted in a flexible myosin S2 coiled coil. The binding of MyBPC and stabilizer peptide respectively, resulted in 3.35 and 1.5 times increase in force required to uncoil the myosin S2, while the binding of destabilizer peptide resulted in 1.6 times decrease in force required to uncoil the myosin S2. The myofibrillar contractility assay was performed to test the effect of synthetic myosin S2 binding proteins on the sarcomere shortening in myofibrils. The stabilizer peptide resulted in decreased sarcomere shortening of myofibrils as a result of decreased acto-myosin interaction, on the other hand, the binding of destabilizer peptide caused an increase in sarcomere shortening. The in vitro motility assay was performed to test the effect of altered stability of myosin S2 by binding of these myosin S2 binding proteins on the motility of actin filaments sliding over myosin. The motility of actin filaments was hindered by treating myosin thick filaments with whole length skeletal MyBPC or by treating heavy meromyosin with stabilizer peptide, while the motility of actin filaments was enhanced when heavy meromyosin was treated with destabilizer peptide. This study demonstrates that the myosin S2 coiled coil stability influences the force produced by acto-myosin interaction in striated skeletal muscle. The myosin S2 coiled coil when stabilized by MyBPC and stabilizer peptide resulted in decreased force production by reduced acto-myosin interaction. While the binding of destabilizer resulted in a flexible myosin S2 coiled coil and increased force production by enhanced acto-myosin interaction. The potentially cooperative response of contractility to the instability of the S2 coiled coil promises that this biological mechanism may be the target of drugs to modulate muscle performance.
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Scanning force microscopy of striated muscle proteinsHallett, Peter C. January 1996 (has links)
No description available.
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A study of the cell biology of motility in Eimeria tenella sporozoitesBruce, David Robert January 2001 (has links)
No description available.
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Kinetic investigation of the mechanism underlying muscle contraction in myofibrils using T.I.R.F. microscopyBurns, Ronald Ian Scott January 1999 (has links)
No description available.
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STRUCTURAL INSIGHTS INTO DICTYOSTELIUM DISCOIDEUM MYOSIN LIGHT CHAIN SPECIFICITYLiburd, JANINE 29 January 2013 (has links)
Myosins are molecular motor proteins involved in cell movement, vesicle and organelle transport by moving along the cytoskeletal actin filaments. They include a myosin heavy chain and at least one myosin light chain (LC). The latter are typically bilobal proteins like calmodulin, where each lobe comprises a pair of EF-hand Ca2+-binding motifs. The LCs bind to ~25-residue IQ motifs that loosely conform to an IQXXXRGXXXR consensus sequence, and impart rigidity that is crucial for myosin function.
The highly motile amoeba Dictyostelium discoideum expresses seven class I myosins, two of which (MyoD and MyoB) recruit the specific LCs MlcD and MlcB, with MlcB being the first observed single-lobe LC. However, the LCs for the remaining D. discoideum class I myosins are unknown. Identifying and characterizing these LCs is one focus of this thesis, with an overall goal of understanding their role in myosin function and regulation.
Nuclear magnetic resonance spectroscopy, site-directed mutagenesis, and computational modeling were used to determine the solution structure of apo-MlcB and identify the MyoB IQ motif-binding site. Apo-MlcB differs from the typical closed conformation of an EF-hand Ca2+-binding protein in the apo-state as helix 1 in its structure is splayed from the remaining helices. The MyoB IQ motif-binding surface is not altered by Ca2+, involves residues from helices 1 and 4, and from residues in the N-terminal canonical EF-hand Ca2+-binding loop, and represents a unique mode of IQ recognition by a myosin LC.
Calmodulin was identified as the LC for MyoA and MyoE while another single-lobe LC, MlcC, bound to two of three IQ motifs in MyoC. The solution structure of MlcC was more similar to the C-terminal lobe of apo-calmodulin than to apo-MlcB. Chemical shift perturbation studies suggest that like apo-CaM, MlcC undergoes a global MyoC IQ motif-induced conformational change. Computational modeling of the MlcC-MyoC IQ complex indicates that this is a feasible mode of IQ recognition. The structures of MlcB and MlcC, with their different modes of IQ motif binding, provide novel insights into IQ motif binding specificity and begin to illustrate their role in myosin function and regulation. / Thesis (Ph.D, Biochemistry) -- Queen's University, 2013-01-29 11:42:03.428
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Fluorescence labeling and computational analysis of the strut of myosin's 50 kDa cleft.Gawalapu, Ravi Kumar 08 1900 (has links)
In order to understand the structural changes in myosin S1, fluorescence polarization and computational dynamics simulations were used. Dynamics simulations on the S1 motor domain indicated that significant flexibility was present throughout the molecular model. The constrained opening versus closing of the 50 kDa cleft appeared to induce opposite directions of movement in the lever arm. A sequence called the "strut" which traverses the 50 kDa cleft and may play an important role in positioning the actomyosin binding interface during actin binding is thought to be intimately linked to distant structural changes in the myosin's nucleotide cleft and neck regions. To study the dynamics of the strut region, a method of fluorescent labeling of the strut was discovered using the dye CY3. CY3 served as a hydrophobic tag for purification by hydrophobic interaction chromatography which enabled the separation of labeled and unlabeled species of S1 including a fraction labeled specifically at the strut sequence. The high specificity of labeling was verified by proteolytic digestions, gel electrophoresis, and mass spectroscopy. Analysis of the labeled S1 by collisional quenching, fluorescence polarization, and actin-activated ATPase activity were consistent with predictions from structural models of the probe's location. Although the fluorescent intensity of the CY3 was insensitive to actin binding, its fluorescence polarization was notably affected. Intriguingly, the mobility of the probe increases upon S1 binding to actin suggesting that the CY3 becomes displaced from interactions with the surface of S1 and is consistent with a structural change in the strut due to cleft motions. Labeling the strut reduced the affinity of S1 for actin but did not prevent actin-activated ATPase activity which makes it a potentially useful probe of the actomyosin interface. The different conformations of myosin S1 indicated that the strut is not as flexible as several other key regions of myosin as determined by the application of force constraints to elastic portions of the myosin structure.
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Investigations in Early Polarity in the Sea Urchin EmbryoMoorhouse, Kathleen January 2014 (has links)
Thesis advisor: David R. Burgess / Establishment and maintenance of cell polarity has become an increasingly interesting biological question in a diversity of cell types and has been found to play a role in a variety of biological functions. Previously, it was thought that the echinoderm embryo remained relatively unpolarized until the first asymmetric division at the 16 cell stage of development. However, there is mounting evidence to suggest that polarity is established much earlier. I analyzed roles of the cell polarity regulators, the PAR complex proteins, and how their disruption in early development affects later developmental milestones such as blastula formation. I found that PAR6 along with aPKC and CDC42 localize to the apical cortex (free surface) as early as the 2 cell stage of development and this localization is retained through the gastrula stage. Interestingly, PAR1 also colocalizes with these apical markers through the gastrula stage, despite the formation of a polarized epithelium and a series of asymmetric divisions. Additionally, PAR1 was found to be in complex with aPKC, but not PAR6, during these developmental stages. PAR6, aPKC, and CDC42 are anchored in the cortex by assembled myosin; however, a clear role for myosin assembly in PAR1 localization could not be determined. Furthermore, myosin assembly was found to be necessary to maintain proper PAR6 localization through subsequent cleavage divisions. Interference with myosin assembly prevented the embryos from reaching the blastula stage, while transient disruptions of either actin or microtubules did not have this effect. Similarly, inhibition of aPKC activity during early cleavage stages impeded blastula formation; however, aPKC is not involved in the regulation of the first asymmetric division at the 16 cell stage in sea urchin embryos. These observations suggest that disruptions of the polarity complex in the early embryo can have a significant impact on the ability of the embryo to reach later critical stages in development. / Thesis (PhD) — Boston College, 2014. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.
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