Dissecting The Coordinated Transport Of Molecular Motors A Single Molecule Approach Towards Studying Bidirectional Motion PDF Download
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| Author | : Abdullah Chaudhary |
| Publisher | : |
| Total Pages | : |
| Release | : 2020 |
| Genre | : |
| ISBN | : |
Download Dissecting the Coordinated Transport of Molecular Motors a Single Molecule Approach Towards Studying Bidirectional Motion Book in PDF, ePub and Kindle
"Many cellular processes are driven by the collective action of motors working in teams. One such example of this type of phenomenon is intracellular transport -- the transport of cargoes carried out by teams of similar or opposite polarity motors (kinesin and dynein). In most cells, long-range transport occurs along microtubules that are oriented with their plus ends towards the cell periphery, and minus ends towards the cell body. Despite the presence of opposite polarity motors, the mechanism by which cargoes are directed to specific locations in the cell is not well understood. A set of microtubule-associated proteins (MAPs) and scaffolding molecules have been shown to have some effect on motility and cargo directionality, but the mechanism by which these molecules tune motor specific processivity is not well understood. Defects in intracellular trafficking can result in severe developmental and neurodegenerative diseases. One prominent example is Huntington’s disease (HD), which is an autosomal dominant neurodegenerative disorder caused by an extension of the CAG repeat region in the N-terminus of the huntingtin gene. Though it is clear that wild-type huntingtin plays a role in intracellular trafficking by interacting with motor and motor-associated proteins, it is unclear how post-translational modifications (PTMs) modulate the activity of motor proteins and the specific biophysical mechanism behind this activity. In HD, mutated huntingtin aggregates in neurons, disrupting cargo transport. Disruption in vesicle transport results in abnormal cell signaling and impaired clearance of damaged proteins and organelles. This suggests a mechanism where defects in transport are due to misregulation of motor protein activity by vesicle-bound huntingtin.In addition to scaffolding molecules like huntingtin, transport is also regulated by microtubule-associated proteins (MAPs) that bind along the microtubule surface. Tau is a neuronal MAP that stabilizes axonal microtubules by crosslinking them into bundles. It also indirectly modulates cargo motility by serving as a roadblock to motors. Misregulation of tau leads to a range of neurodegenerative diseases known as tauopathies, including Alzheimer’s disease (AD). In AD, tau hyperphosphorylation leads to the development of fibrillary bodies that aggregate to form neurofibrillary tangles (NFTs). Varying concentration of tau inhibits single motor and multiple motor activity. Yet, despite the presence of tau in healthy neurons, teams of motors are still able to navigate efficiently over long distances in the axon without being inhibited. Similar to tau, MAP7 (ensconsin) also binds along microtubules and stabilizes them. It organizes the microtubule cytoskeleton in mitosis and neuronal branching. MAP7 not only promotes the interaction of kinesin-1 to microtubules but also competes with tau for binding along microtubules to regulate kinesin transport. Since bidirectional motility is a hallmark of intracellular transport, understanding how MAPs regulate teams of kinesin and dynein motors will provide insight into how transport is regulated"--
| Author | : Athena Ierokomos |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2022 |
| Genre | : |
| ISBN | : |
Download Dissecting Structure-function Relationships in Molecular Motors Using Protein Engineering and Single-molecule Methods Book in PDF, ePub and Kindle
Biological cells can harness the free energy of ATP hydrolysis to perform mechanical tasks using molecular motor proteins. These nanoscale machines are able to generate directional motion through mechanochemical cycles which rely on allosteric communication and large rearrangements of protein domains. In studies of molecular motors, protein engineering allows us to test our understanding of relationships between structure and function, while single-molecule methods allow us to directly observe motor dynamics. Here we consider two systems which undergo large conformational changes: cytoplasmic dynein and DNA gyrase. We use protein engineering to investigate structural features that contribute to dynein velocity and processivity. Building on our initial findings, we are able to design dynein motors that change speed in response to light. The speed and controllability of future designs may be improved with further engineering, in order to generate light-activatable, dynein-based tools which can be used to study transport functions in vivo. In the second half of this dissertation, we consider a single-molecule technique for multimodal measurements of mechanics and fluorescence in DNA and DNA:protein complexes. Mechanical measurements based on magnetic tweezers are combined with simultaneous fluorescence imaging that can report on macromolecular binding and local conformational changes. We outline how this method can be applied to study the mechanism of DNA gyrase, a motor which introduces negative supercoils by coordinating protein domain motions and ATP hydrolysis with DNA cleavage and religation. We observe binding coincident with mechanics and report on challenges in using FRET-labeled enzymes to correlate domain motions with mechanical substeps. We anticipate that correlative multimodal measurements will be valuable tools for characterizing the dynamics of DNA gyrase and other large nucleoprotein machines.
| Author | : Sara Tafoya |
| Publisher | : |
| Total Pages | : 123 |
| Release | : 2017 |
| Genre | : |
| ISBN | : |
Download A Single-molecule Approach to Study Multimeric Molecular Motors and Optimal Thermodynamic Length Book in PDF, ePub and Kindle
Single molecule techniques are uniquely informative for kinetic processes. As a result, in recent years they have become the methods of choice to interrogate many complex biomolecular systems (Bustamante & Tafoya 2017). During my PhD, I used optical tweezers, a technique for single-molecule manipulation, to study various biological processes. First, I revisited the high internal pressure built inside the viral capsid of the bacteriophage phi29 during genome encapsidation (Liu et al. 2014b). During assembly of double-stranded DNA bacteriophages, the viral genome is encapsidated by a DNA packaging motor. High internal pressure builds up inside the viral capsid as a result of entropic and electrostatic repulsive forces resulting from DNA confinement. Previous single-molecule studies have determined the value of the internal pressure to be as high as 110 pN towards the end of DNA packaging. However, this value seemed overly high based on theoretical calculations. Using higher resolution data than in previous studies, my colleagues and I showed that the internal pressure reaches ~ 20 +/- 7 pN at 100% capsid filling, which is in better agreement with previous theoretical models. Second, I determined the molecular mechanism for inter-subunit coordination in a viral ring ATPase. Subunits in multimeric ring motors must coordinate their enzymatic activity to perform their function (Tafoya et al. 2017). The bacteriophage phi29 DNA packaging motor is a pentameric ring ATPase whose subunits have been shown to operate in a highly coordinated manner. Therefore, this system is ideal to investigate how global subunit coordination can arise from stochastic processes and local molecular interactions. Using single-molecule optical tweezers and targeted mutagenesis, I showed that coordination arises from inter-subunit enzymatic regulation.The subunits use their arginine finger to promote nucleotide exchange and to activate ATP hydrolysis in their neighbors. These regulatory processes display similar features to those observed in small GTPases. Third, in light of what I learned about the phi29 DNA packaging motor's operation, I reviewed various mechanisms of small GTPase-like regulation in different motor proteins (Tafoya & Bustamante 2017). In particular, I highlighted the fact that all these mechanisms share a general feature: the motor's function is controlled by stimulation or repression of its ATPase activity, which is regulated allosterically by different factors. Finally, I tested a prediction from fluctuation theorems to minimize the thermodynamic length in a process out of equilibrium (Tafoya et al. 2017b). Genome encapsidation by the phi29 DNA packaging motor is only an example of the multiple non-equilibrium processes occurring in the cell. In fact, to maintain their organization, biological systems must operate far from equilibrium, continuously utilizing and dissipating energy. Non-equilibrium theory is underdeveloped, but recent work has approximated the excess work in processes out of equilibrium. I tested this theory's predictions performing pulling experiments on a DNA hairpin. I found that the predicted minimum-dissipation protocols indeed require significantly less work than naive ones across a wide span of driving velocities.
| Author | : Anatoly B. Kolomeisky |
| Publisher | : CRC Press |
| Total Pages | : 221 |
| Release | : 2015-05-21 |
| Genre | : Medical |
| ISBN | : 1482224763 |
Download Motor Proteins and Molecular Motors Book in PDF, ePub and Kindle
A Unified Microscopic Approach to Analyzing Complex Processes in Molecular MotorsMotor Proteins and Molecular Motors explores the mechanisms of cellular functioning associated with several specific enzymatic molecules called motor proteins. Motor proteins, also known as molecular motors, play important roles in living systems by supporting cellular
| Author | : Comert Kural |
| Publisher | : ProQuest |
| Total Pages | : 100 |
| Release | : 2007 |
| Genre | : |
| ISBN | : 9780549340621 |
Download Studying Processive Molecular Motors Inside Live Cells Book in PDF, ePub and Kindle
Processive molecular motors are the proteins that transport various kinds of cargos within a cell. All processive motors have two motor domains that let the protein proceed by taking steps. These motor proteins can carry their cargos for microns by taking hundreds of steps before detaching form the cytoskeletal tracks they walk on. In year 2003 it has been reported that the position of a single fluorescent dye attached to a molecular motor can be located within ∼ 1 nm (with half-a-second temporal resolution) in vitro. This new localization technique is named Fluorescence Imaging with One Nanometer Accuracy (FIONA). Yildiz et al. has shown that FIONA is precise enough to resolve the hand-over-hand steps of the processive molecular motors myosin V, kinesin and myosin VI, in the order. In our study we have searched for the possibilities of working on the same motor proteins in vivo, in other words, inside live cells. In order to overcome the complications of imaging in live organisms we have tracked the cargos (organelles carried by motors) instead of single molecule markers bound to the motors. Fluorescently labeled peroxisomes and dark pigment carrying melanosomes can be tracked in vivo with high spatial (∼1.5 nm) and temporal (∼1 msec) resolution by the derivatives of FIONA. This has enabled us to resolve the stepwise motion of motor proteins conventional kinesin, cytoplasmic dynein, kinesin II and myosin V.
| Author | : Marco Tjioe |
| Publisher | : |
| Total Pages | : |
| Release | : 2017 |
| Genre | : |
| ISBN | : |
Download Noise in Noise Out - Single Molecule Studies of Molecular Motors Book in PDF, ePub and Kindle
| Author | : Ann O. Sperry |
| Publisher | : Humana |
| Total Pages | : 0 |
| Release | : 2010-11-19 |
| Genre | : Science |
| ISBN | : 9781617377068 |
Download Molecular Motors Book in PDF, ePub and Kindle
Molecular motor proteins produce force for movement in an incredibly wide variety of cellular processes. This volume explores the extreme functional and structural diversity of molecular motors and presents methods relevant to each motor family. In addition, it describes techniques directed at motors that fall outside of the three characterized families: dynamin and F1ATPase.
| Author | : Swathi Ayloo |
| Publisher | : |
| Total Pages | : 300 |
| Release | : 2016 |
| Genre | : |
| ISBN | : |
Download Molecular and Cellular Approaches Toward Understanding Dynein-driven Motility Book in PDF, ePub and Kindle
Active transport is integral to organelle localization and their distribution within the cell. Kinesins, myosins and dynein are the molecular motors that drive this long range transport on the actin and microtubule cytoskeleton. Although several families of kinesins and myosins have evolved, there is only one form of cytoplasmic dynein driving active retrograde transport in cells. While dynactin is an essential co-factor for most cellular functions of dynein, the mechanistic basis for this evolutionarily well conserved interaction remains unclear. Here, I use single molecule approaches with purified dynein to reconstitute processes in vitro, and implement an optogenetic tool in neurons to further dissect regulatory mechanisms of dynein-driven transport in cells. I demonstrate for the first time, at the single molecule level, that dynactin functions as a tether to enhance the initial recruitment of dynein onto microtubules but also acts as a brake to slow the motor. I then extend this work in neurons to understand regulation of the dynein motor at the cellular level. Neurons are particulary dependent on long-range transport as organelles and macromolecules must be efficiently moved over the extended length of the axon and further, have mechanisms in place for the compartment-specific regulation of trafficking in axons and dendrites. I use a light-inducible dimerization tool to recruit motor proteins or motor adaptors to organelles in real time to examine downstream effects of organelle motility and compartment-specific regulation of motors. I find that while dynein works efficiently in both axons and dendrites, kinesins are differentially regulated in a compartment-specific manner. I further demonstrate that dynein-driven motility in neurons is largely governed by microtubule orientation and requires microtubule dynamics for efficient navigation in axons and dendrites. Together, this work sheds light on the molecular and cellular mechanisms of dynein function both in vitro and in vivo using a combination of approaches. My findings converge to a model wherein dynactin enhances the recruitment of dynein onto microtubule plus ends, leading to efficient minus-end directed motility of dynein. This becomes especially critical in neuronal growth cones and dendrites owing to the large number of highly dynamic microtubules in these compartments.
| Author | : Stefan Niekamp |
| Publisher | : |
| Total Pages | : |
| Release | : 2020 |
| Genre | : |
| ISBN | : |
Download Mechanisms of Dynein Motility: Insights from Single-Molecule Studies Book in PDF, ePub and Kindle
Transport of cargos not only plays a critical role on the meter scale in our daily life when we travel from A to B but also plays an essential role for cellular processes on the nanometer scale without which we would not exist. This cellular transport is carried out by motor proteins which walk on cellular highways and are responsible for almost all directed transport in cells. Moreover, these motor proteins play key roles in other cellular processes including mitosis and cilia motility. One of these motor proteins is the microtubule-based motor dynein. Dynein is a complex, flexible, and large machine that has to coordinate it's two engines and feet in order to achieve directed and continuous motility. Recent structural and biochemical studies uncovered key molecular mechanisms contributing to dynein motility. However, a comprehensive understanding of how dynein steps along its microtubule track, and how its different domains are coordinated to achieve this movement were lacking in the field. Therefore, I first set out to determine how dynein's ATPase activity and mechanics are coupled among the motor domain of dynein and showed that the ~15 nm long coiled-coil linking the catalytic AAA ring and its microtubule-binding domain is indispensable in regulating motor activity. Moreover, I found that the length rather than the sequence of this coiled-coil is remarkably well conserved and that the length conservation is paramount for directional motility. Integrating these observations allowed us to generate an updated model for the internal regulation of dynein.Our understanding of how the different domains of dynein move relative to each other has been limited by insufficient high spatiotemporal resolution. To overcome this, I first created a method that enables three-color image registration and distance measurements with one nanometer accuracy and second, I developed DNA FluoroCubes that enabled me to track the position of multiple domains of dynein for a prolonged time with nanometer precision. Combining both of these methods enabled me to gain insights into the conformational changes of dynein's domains while moving along microtubules. I found that the motor domain of dynein is very flexible and that this flexibility is important for dynein motility and enables dynein to adopt a large variety of conformations. Together, these findings revealed a new model for dynein stepping that defines the minimal requirements to facilitate directed and continuous motility.
| Author | : Veronika Bierbaum |
| Publisher | : |
| Total Pages | : 126 |
| Release | : 2011 |
| Genre | : |
| ISBN | : |
Download Chemomechanical Coupling and Motor Cycles of the Molecular Motor Myosin V Book in PDF, ePub and Kindle
In the living cell, the organization of the complex internal structure relies to a large extent on molecular motors. Molecular motors are proteins that are able to convert chemical energy from the hydrolysis of adenosine triphosphate (ATP) into mechanical work. Being about 10 to 100 nanometers in size, the molecules act on a length scale, for which thermal collisions have a considerable impact onto their motion. In this way, they constitute paradigmatic examples of thermodynamic machines out of equilibrium. This study develops a theoretical description for the energy conversion by the molecular motor myosin V, using many different aspects of theoretical physics. Myosin V has been studied extensively in both bulk and single molecule experiments. Its stepping velocity has been characterized as a function of external control parameters such as nucleotide concentration and applied forces. In addition, numerous kinetic rates involved in the enzymatic reaction of the molecule have been determined. For forces that exceed the stall force of the motor, myosin V exhibits a 'ratcheting' behaviour: For loads in the direction of forward stepping, the velocity depends on the concentration of ATP, while for backward loads there is no such influence. Based on the chemical states of the motor, we construct a general network theory that incorporates experimental observations about the stepping behaviour of myosin V. The motor's motion is captured through the network description supplemented by a Markov process to describe the motor dynamics. This approach has the advantage of directly addressing the chemical kinetics of the molecule, and treating the mechanical and chemical processes on equal grounds. We utilize constraints arising from nonequilibrium thermodynamics to determine motor parameters and demonstrate that the motor behaviour is governed by several chemomechanical motor cycles. In addition, we investigate the functional dependence of stepping rates on force by deducing the motor's response to external loads via an appropriate Fokker-Planck equation. For substall forces, the dominant pathway of the motor network is profoundly different from the one for superstall forces, which leads to a stepping behaviour that is in agreement with the experimental observations. The extension of our analysis to Markov processes with absorbing boundaries allows for the calculation of the motor's dwell time distributions. These reveal aspects of the coordination of the motor's heads and contain direct information about the backsteps of the motor. Our theory provides a unified description for the myosin V motor as studied in single motor experiments.
