Single-molecule studies of nucleic acid folding and nucleic acid-protein interactions

Pérez González, Daniel Cibrán

January 2017

Nucleic acids and proteins, some of the building blocks of life, are not static structures but highly dynamic entities that need to interact with one another to meet cellular demands. The work presented in this thesis focuses on the application of highly sensitive fluorescence methods, both at ensemble and single-molecule level, to determine the dynamics and structure of specific biomolecular interactions with nanometer resolution and in temporal scales from nanoseconds to minutes, which includes most biologically relevant processes. The main aims of my PhD can be classified in three areas: i) exploring new fluorescent sensors with increased specificity for certain nucleic acid structures; ii) understanding how some of these nucleic acids sense the presence of small molecules in the cellular environment and trigger gene regulation by altering their structure; and iii) understanding how certain molecular machines, such as helicase proteins, are able to unwind the DNA double helix by using chemical energy in the form of ATP hydrolysis.

Contrôle Optogénétique de la Polarité Cellulaire / Optogenetic Control of Cell Polarity

Valon, Léo

22 September 2014

Dans cette thèse, nous avons concentré notre étude sur les mécanismes qui génèrent la polarité cellulaire, en particulier dans le cas de la migration cellulaire. Malgré les derniers développements concernant l’observation de l’activité des RhoGTPases, les principes qui dictent la capacité des cellules à coordonner plusieurs modules de signalisation en parallèle ne sont toujours pas compris. L’optogénétique est un outil d’intérêt pour disséquer ces réseaux de signalisation à partir de la création d’une perturbation dont les caractéristiques spatiotemporelles sont contrôlées. Tout d’abord, à partir de la caractérisation des différents processus biophysiques en jeu, nous avons établi les relations quantitatives entre l’illumination et les gradients moléculaires que l’on induit. Nous avons déterminé qu’il est possible de créer des gradients subcellulaires avec une résolution spatiale de l’ordre de 5 μm et temporelle d’environ 3 minutes Ensuite, nous avons utilisé cette approche optogénétique pour contrôler l’activité de Cdc42, Rac1 et RhoA. Nous avons caractérisé les effets subcellulaires de l’activation de ces RhoGTPases en utilisant l’activité de membrane, les changements de forme cellulaire et leurs déplacements comme rapporteurs de la polarisation et de la migration. Nous avons ainsi montré qu’une activation locale de RhoGTPase permet la réorganisation interne des cellules jusqu’à générer un phénotype de migration.Enfin, nous avons caractérisé les effets d’une activation locale de RhoA sur différents acteurs moléculaires comme les points focaux d’adhésion, l’actine et les moteurs moléculaires myosines. Nous avons mesuré alors la dynamique de l’intégration des points focaux dans le cytosquelette et analysé la réponse du réseau d’acto-myosine au cours d’évènements de rétraction.Notre approche optogénétique couple le contrôle d’une perturbation à la mesure de la réponse cellulaire simultanément de manière directe et reproductible. Elle apporte une méthode pour contrôler la polarité cellulaire et une manière de disséquer des réseaux de signalisation à l’échelle subcellulaire. / In this thesis we focus on the mechanisms that establish cell polarization, particularly during cell migration. Despite latest developments that enable visualization of RhoGTPases activity, the underlying principles dictating the cell’s ability to coordinates multiple signaling modules is still unclear. Optogenetic methods have been recognized as promising tools to dissect these intracellular signaling networks by allowing perturbations to be spatially and temporally controlled. We established the quantitative relationship between illumination patterns and the corresponding gradients of induced signaling activity through the characterization of the biophysical properties of CRY2/CIBN. We determined that it is possible to create subcellular gradients of recruited proteins of different shapes of choice up to spatial resolutions of 5μm and temporal ones of ca. 3 minutes.We applied the aforementioned optogenetic approach as a means to perturb the activity of cdc42, Rac1 and RhoA. We characterized the effects of subcellular activation of those RhoGTPases using membrane activity, cell shape changes and cell displacement as reporters of cell polarization and migration. We show that localized activation of RhoGTPases can trigger cellular organization and drive the cell into a migrating state.We also characterized the effects of local activation of RhoA on different cellular effectors as focal adhesion complexes, actin filaments and myosin molecular motors. We measured the dynamics of the newly formed focal adhesion complexes and the acto-myosin complex during retraction events.Altogether, our optogenetic methodology enables simultaneous measurement of the imposed perturbation and the cell response in a straightforward and reproducible way. It provides a quantitative way to control cell polarity and a step forward in the dissection of subcellular signaling networks.

Optogénétique

Migration cellulaire

RhoGTPases

Perturbation spatiotemporelle

Microscopie TIRF

Réaction diffusion

Optogenetics

Cell migration

RhoGTPases

Spatiotemporal perturbation

TIRF microscopy

Diffusion reaction

530

Regulace mikrotubulární dynamiky studovaná pomocí IRM a TIRF mikroskopie s rozlišením na úrovni jedné molekuly / Regulation of microtubule dynamics revealed by single-molecule TIRF and IRM microscopy

Zhernov, Ilia

January 2020

The microtubular cytoskeleton is a ubiquitous and highly diverse biopolymer network present in all eukaryotic cells. Microtubules stochastically alternate between phases of growth and shrinkage. Cells take advantage of this dynamicity to generate forces for essential processes, such as cell division, motility or morphogenesis. Regulating the microtubule dynamics enables cells to adaptively respond to a wide range of tasks and conditions. Molecular mechanisms underpinning the regulation are not fully understood. Using a bottom-up approach and the combination of single molecule total internal reflection fluorescence (TIRF) microscopy and interference reflection microscopy (IRM), we here reconstituted and explored two dynamic cytoskeletal systems. (i) Microtubule doublets, comprising incomplete B-microtubule on the surface of a complete A- microtubule, provide an essential structural scaffold for flagella. Despite the fundamental role of microtubule doublets, the molecular mechanism governing their formation is unknown. We here demonstrate an inhibitory role of tubulin C-terminus in microtubule doublet assembly. By partial enzymatic digestion of polymerized microtubules followed by the addition of free tubulin in the presence of a stabilizing agent, we assembled microtubule doublets and revealed the B-...

The role of 1D diffusion for directional long-range communication on DNA

Schwarz, Friedrich

07 November 2012

Many genetic processes require enzymes or enzyme complexes that interact simultaneously with distant sites along the genome. Such long-range DNA-enzyme interactions are important for example in gene regulation, DNA replication, repair and recombination. In addition many restriction enzymes depend on interactions between two recognition sites and form therefore a model system for studying long-range communications on DNA. Topic of the present work are Type III restriction enzymes. For these enzymes the communication mechanism between their distant target sites has not been resolved and conflicting models including 3D diffusion, 1D translocation and 1D diffusion have been proposed. Also the role of ATP hydrolysis by their superfamily 2 helicase domains which catalyse functions of many enzyme systems is still poorly understood. To cleave DNA, Type III restriction enzymes sense the relative orientation of their distant target sites and cleave DNA only if at least two of them are situated in an inverted repeat. This process strictly depends on ATP hydrolysis. The aim of this PhD thesis was to elucidate this long-range communication. For this a new single molecule assay was developed using a setup combining magnetic tweezers and objective-type total internal reflection fluorescence microscopy. In addition of being able to mechanically manipulate individual DNA molecules, this assay allows to directly visualize the binding and movement of fluorescently labelled enzymes along DNA. Applying this assay to quantum dot labelled Type III restriction enzymes, a 1D diffusion of the enzymes after binding at their target sites could be demonstrated. Furthermore, it was found that the diffusion depends on the nucleotide that is bound to the ATPase domains of these enzymes. This suggested that ATP hydrolysis acts as a switch to license diffusion from the target site which leads to cleavage. In addition to the direct visualization of the enzyme-DNA interaction, the cleavage site selection, the DNA end influence (open or blocked) and the DNA binding kinetics were measured in bulk solution assays (not part of this thesis). The experimental results were compared to Monte Carlo simulations of a diffusion-collision-model which is proposed as long-range communication in this thesis.

info:eu-repo/classification/ddc/570

ddc:570

Temperature-dependence of microtubule dynamics across Xenopus species

de Gaulejac, Ella

17 May 2023

Eukaryontische Zellen besitzen ein Zytoskelett, ein zelluläres Netzwerk aus Biopolymeren. Unter diesen Biopolymeren sind die Mikrotubuli weitgehend konserviert. Diese aus Tubulin aufgebauten Filamente sind dynamisch und wechseln zwischen Phasen des Wachstums und der Schrumpfung. Die genauen Mechanismen, die die dynamische Instabilität der Mikrotubuli bestimmen, werden noch erforscht. Die Allgegenwart von Mikrotubuli wirft die Frage auf, wie sie in verschiedenen thermischen Umgebungen konservierte Funktionen ausführen können. Um dieser Fragestellung nachzugehen, habe ich verwandte Froscharten mit unterschiedlich temperierten Lebensräumen untersucht: Xenopus laevis (16-22 °C), Xenopus borealis (19-23 °C) und Xenopus tropicalis (22-30 °C). Um zu untersuchen, ob sich die biochemischen Eigenschaften von Tubulin und die Dynamik der Mikrotubuli bei den drei Arten an die Temperatur angepasst hat, habe ich die Methoden der Tubulin-Affinitätsreinigung und die temperaturgesteuerte TIRF-Mikroskopie zur Rekonstitution der Mikrotubuli-Dynamik kombiniert. Dabei habe ich festgestellt, dass bei einer Temperatur von 25°C die Wachstumsgeschwindigkeit der Mikrotubuli im Bezug zur thermischen Nische der einzelnen Arten negativ korreliert. Die Verwendung der Arrhenius-Gleichung zum Vergleich der Aktivierungsenergie der Mikrotubuli-Polymerisation für jede Spezies ergab, dass die freie Energie des Tubulins umso höher ist, je kälter die thermische Nische der Spezies ist. Die Mikrotubuli von X. laevis und X. borealis zeigten eine längere Lebensdauer und wurden häufiger zerstört als die von X. tropicalis. Die Tubuline von X. laevis und X. borealis sind phosphoryliert, im Gegensatz zu X. tropicalis. Die Ergebnisse zeigen, dass sich Xenopus Tubulin und die Dynamik der Mikrotubuli an die Temperatur angepasst haben. Kalt lebende Arten kommen mit der niedrigeren Energie des Milieus zurecht, durch verbessertes Wachstum und Stabilität. / Eukaryotic cells hold a cytoskeleton, a cellular network of biopolymers. Among the filaments of the cytoskeleton, microtubules are widely conserved. Built from tubulin, those filaments are dynamic, alternating between phases of growth and shrinkage. The biochemical properties of tubulin shape the dynamic behavior of microtubules, which is crucial for many cellular processes. The precise mechanisms determining microtubule dynamic instability are still under investigation. The ubiquity of microtubules raises the question of how they can perform conserved functions within various thermal environments. To address this, I turned to closely related frog species living at different temperatures, Xenopus laevis (niche: 16-22°C), Xenopus borealis (19-23°C) and Xenopus tropicalis (22-30°C). To probe whether the biochemical properties of tubulin and microtubule dynamics adapted to temperature across those three species, I combined tubulin affinity purification and temperature-controlled TIRF microscopy of in vitro reconstitution of microtubule dynamics. I found that at 25°C, the microtubule growth velocity inversely correlates with the thermal niche of each species. Adjusting temperature to each species’ endogenous condition modulates the growth rate differences across species. Using the Arrhenius equation to compare the activation energy of microtubule polymerization for each species suggested that the colder the thermal niche of the species, the higher the free energy of its tubulin. Microtubules from the cold-adapted species X. laevis and X. borealis have longer lifetimes and rescue more often than those of X. tropicalis, both at 25°C and at each species’ endogenous condition. X. laevis and X. borealis tubulins are phosphorylated, contrary to X. tropicalis. My results show that Xenopus tubulin and microtubule dynamics have adapted to temperature. Cold-living species cope with the lower energy of the milieu by facilitating growth and stability.

Tubulin

Thermische Adaptation

Xenopus

TIRF Mikroskopie

Tubulin

Thermal adaptation

Xenopus

TIRF microscopy

Microtubules

Dynamic instability

in vitro assay

572 Biochemie

ddc:572

Sur quelques problèmes de reconstruction en imagerie MA-TIRF et en optimisation parcimonieuse par relaxation continue exacte de critères pénalisés en norme-l0 / On some reconstruction problems in MA-TIRF imaging and in sparse optimization using continuous exact relaxation of l0-penalized criteria

Soubies, Emmanuel

14 October 2016

Cette thèse s'intéresse à deux problèmes rencontrés en traitement du signal et des images. Le premierconcerne la reconstruction 3D de structures biologiques à partir d'acquisitions multi-angles enmicroscopie par réflexion totale interne (MA-TIRF). Dans ce contexte, nous proposons de résoudre leproblème inverse avec une approche variationnelle et étudions l'effet de la régularisation. Une batteried'expériences, simples à mettre en oeuvre, sont ensuite proposées pour étalonner le système et valider lemodèle utilisé. La méthode proposée s'est montrée être en mesure de reconstruire avec précision unéchantillon phantom de géométrie connue sur une épaisseur de 400 nm, de co-localiser deux moléculesfluorescentes marquant les mêmes structures biologiques et d'observer des phénomènes biologiquesconnus, le tout avec une résolution axiale de l'ordre de 20 nm. La deuxième partie de cette thèseconsidère plus précisément la régularisation l0 et la minimisation du critère moindres carrés pénalisé (l2-l0) dans le contexte des relaxations continues exactes de cette fonctionnelle. Nous proposons dans unpremier temps la pénalité CEL0 (Continuous Exact l0) résultant en une relaxation de la fonctionnelle l2-l0 préservant ses minimiseurs globaux et pour laquelle de tout minimiseur local on peut définir unminimiseur local de l2-l0 par un simple seuillage. Par ailleurs, nous montrons que cette relaxation éliminedes minimiseurs locaux de la fonctionnelle initiale. La minimisation de cette fonctionnelle avec desalgorithmes d'optimisation non-convexe est ensuite utilisée pour différentes applications montrantl'intérêt de la minimisation de la relaxation par rapport à une minimisation directe du critère l2-l0. Enfin,une vue unifiée des pénalités continues de la littérature est proposée dans ce contexte de reformulationexacte du problème / This thesis is devoted to two problems encountered in signal and image processing. The first oneconcerns the 3D reconstruction of biological structures from multi-angle total interval reflectionfluorescence microscopy (MA-TIRF). Within this context, we propose to tackle the inverse problem byusing a variational approach and we analyze the effect of the regularization. A set of simple experimentsis then proposed to both calibrate the system and validate the used model. The proposed method hasbeen shown to be able to reconstruct precisely a phantom sample of known geometry on a 400 nmdepth layer, to co-localize two fluorescent molecules used to mark the same biological structures andalso to observe known biological phenomena, everything with an axial resolution of 20 nm. The secondpart of this thesis considers more precisely the l0 regularization and the minimization of the penalizedleast squares criteria (l2-l0) within the context of exact continuous relaxations of this functional. Firstly,we propose the Continuous Exact l0 (CEL0) penalty leading to a relaxation of the l2-l0 functional whichpreserves its global minimizers and for which from each local minimizer we can define a local minimizerof l2-l0 by a simple thresholding. Moreover, we show that this relaxed functional eliminates some localminimizers of the initial functional. The minimization of this functional with nonsmooth nonconvexalgorithms is then used on various applications showing the interest of minimizing the relaxation incontrast to a direct minimization of the l2-l0 criteria. Finally we propose a unified view of continuouspenalties of the literature within this exact problem reformulation framework

Problèmes inverses

Microscopie MA-TIRF

Reconstruction 3D

Étalonnage microscope

Optimisation parcimonieuse

Norme-l0

Relaxations continues exactes

Équivalence des minimiseurs

Inverse problems

MA-TIRF microscopy

3D reconstruction

Microscope calibration

Sparse optimization

L0-norm

Exact continuous relaxations

Minimizers equivalence

Biophysical Characterization of Cell-Penetrating Peptides for Cargo Delivery or Lipid-Sensing

Vinay K. Menon (15295864)

13 June 2023

<p>Peptides, specifically cell-penetrating peptides (CPP), have become wonderful research tools due to their enhanced stability, solubility, and ease of synthesis. They have been used for a wide range of biomedical applications, from insecticides to biosensors and drug-delivery scaffolds. The work presented in this dissertation characterizes the biophysical properties of two different CPPs. The first is the cationic amphiphilic polyproline helix (CAPH) peptide, P14LRR. In addition to cell penetration, this CPP has demonstrated broad spectrum antibacterial properties. Fluorescence polarization (FP) and SEC-MALS were conducted to understand the dissociation constant (KD) and oligomerization effects of P14LRR with respect to its putative molecular target in Staphylococcus aureus (S. aureus). A biotinylated derivative of this peptide was also used as a drug-delivery scaffold to transport fluorescently conjugated streptavidin into mammalian cells. A second CPP, DAN13, was also developed as a biosensor for phosphoinositide lipids, specifically PI(4,5)P2. This was effected through careful calibration using stacked supported lipid bilayers (SSLB) in combination with total internal reflection fluorescence (TIRF) microscopy. This was then used to determine the absolute densities and spatial distribution of PIP2 in live KRas mutant cells.</p>

Receptors and membrane biology

Proteins and peptides

Cell-penetrating peptides (CPPs)

Antimicrobial peptides (AMPs)

PI(4,5)P2

supported lipid bilayer (SLB)

KRas4B

Biophysical characterizations

A novel parabolic prism-type TIR microscope to study gold nanoparticle-loaded kinesin-1 motors with nanometer precision

Schneider, René

06 June 2013

Movement of motor proteins along cytoskeletal filaments is fundamental for various cellular processes ranging from muscle contraction over cell division and flagellar movement to intracellular transport. Not surprisingly, the impairment of motility was shown to cause severe diseases. For example, a link between impaired intracellular transport and neurodegenerative diseases, such as Alzheimer’s, has been established. There, the movement of kinesin-1, a neuronal motor protein transporting vesicles along microtubules toward the axonal terminal, is thought to be strongly affected by roadblocks leading to malfunction and death of the nerve cell. Detailed information on how the motility of kinesin-1 deteriorates in the presence of roadblocks and whether the motor has a mechanism to circumvent such obstructions is scarce. In this thesis, kinesin-1 motility was studied in vitro in the presence of rigor kinesin-1 mutants, which served as permanent roadblocks, under controlled single-molecule conditions. The 25 nm wide microtubule track, consisting of 13 individual protofilaments, resembles a multi-lane environment for transport by processive kinesin-1 motors. The existence of multiple traffic-lanes, allows kinesin-1 to utilize different paths for cargo transport and potentially also for the circumvention of roadblocks. However, direct observation of motor encounters with roadblocks has been intricate in the past, mainly due to limitations in both, spatial and temporal resolution. These limitations, intrinsic to fluorescent probes commonly utilized to report on the motor positions, originate from a low rate of photon generation (low brightness) and a limited photostability (short observation time). Thus, studying kinesin-1 encounters with microtubule-associated roadblocks requires alternative labels, which explicitly avoid the shortcomings of fluorescence and consequently allow for a higher localization precision. Promising candidates for replacing fluorescent dyes are gold nanoparticles (AuNPs), which offer an enormous scattering cross-section due to plasmon resonance in the visible part of the optical spectrum. Problematic, however, is their incorporation into conventionally used (fluorescence) microscopes, because illumination and scattered light have the same wavelength and cannot be separated spectrally. Therefore, an approach based on total internal reflection (TIR) utilizing a novel parabolically shaped quartz prism for illumination was developed within this thesis. This approach provided homogenous and spatially invariant illumination profiles in combination with a convenient control over a wide range of illumination angles. Moreover, single-molecule fluorescence as well as single-particle scattering were detectable with high signal-to-noise ratios. Importantly, AuNPs with a diameter of 40 nm provided sub-nanometer localization accuracies within millisecond integration times and reliably reported on the characteristic 8 nm stepping of individual kinesin-1 motors moving along microtubules. These results highlight the potential of AuNPs to replace fluorescent probes in future single-molecule experiments. The newly developed parabolic prism-type TIR microscope is expected to strongly facilitate such approaches in the future. To study how the motility of kinesin-1 is affected by permanent roadblocks on the microtubule lattice, first, conventional objective-type TIRF microscopy was applied to GFP-labeled motors. An increasing density of roadblocks caused the mean velocity, run length, and dwell time to decrease exponentially. This is explained by (i) the kinesin-1 motors showing extended pausing phases when confronted with a roadblock and (ii) the roadblocks causing a reduction in the free path of the motors. Furthermore, kinesin-1 was found to be highly sensitive to the crowdedness of microtubules as a roadblock decoration as low as 1 % sufficed to significantly reduce the landing rate. To study events, where kinesin-1 molecules continued their runs after having paused in front of a roadblock, AuNPs were loaded onto the tails of the motors. When observing the kinesin-1 motors with nanometer-precision, it was interestingly found that about 60 % of the runs continued by movements to the side, with the left and right direction being equally likely. This finding suggests that kinesin-1 is able to reach to a neighboring protofilament in order to ensure ongoing transportation. In the absence of roadblocks, individual kinesin-1 motors stepped sideward with a much lower, but non-vanishing probability (0.2 % per step). These findings suggest that processive motor proteins may possess an intrinsic side stepping mechanism, potentially optimized by evolution for their specific intracellular tasks.

TIRF Mikroskopie

Goldnanopartikel

Kinesin-1

Motor Protein

Hindernis

Blockade

Nanometer Tracking

Lokalisation

intrazellulärer Transport

in vitro

motility assay

TIRF microscopy

prism-type

gold nanoparticles

kinesin-1

motor protein

roadblock

obstacle

side stepping

nanometer tracking

localization

cargo transport

intracellular transport

side stepping

in vitro

motility assay

ddc:570

rvk:WC 2900

A novel parabolic prism-type TIR microscope to study gold nanoparticle-loaded kinesin-1 motors with nanometer precision

Schneider, René

21 February 2013

Movement of motor proteins along cytoskeletal filaments is fundamental for various cellular processes ranging from muscle contraction over cell division and flagellar movement to intracellular transport. Not surprisingly, the impairment of motility was shown to cause severe diseases. For example, a link between impaired intracellular transport and neurodegenerative diseases, such as Alzheimer’s, has been established. There, the movement of kinesin-1, a neuronal motor protein transporting vesicles along microtubules toward the axonal terminal, is thought to be strongly affected by roadblocks leading to malfunction and death of the nerve cell. Detailed information on how the motility of kinesin-1 deteriorates in the presence of roadblocks and whether the motor has a mechanism to circumvent such obstructions is scarce. In this thesis, kinesin-1 motility was studied in vitro in the presence of rigor kinesin-1 mutants, which served as permanent roadblocks, under controlled single-molecule conditions. The 25 nm wide microtubule track, consisting of 13 individual protofilaments, resembles a multi-lane environment for transport by processive kinesin-1 motors. The existence of multiple traffic-lanes, allows kinesin-1 to utilize different paths for cargo transport and potentially also for the circumvention of roadblocks. However, direct observation of motor encounters with roadblocks has been intricate in the past, mainly due to limitations in both, spatial and temporal resolution. These limitations, intrinsic to fluorescent probes commonly utilized to report on the motor positions, originate from a low rate of photon generation (low brightness) and a limited photostability (short observation time). Thus, studying kinesin-1 encounters with microtubule-associated roadblocks requires alternative labels, which explicitly avoid the shortcomings of fluorescence and consequently allow for a higher localization precision. Promising candidates for replacing fluorescent dyes are gold nanoparticles (AuNPs), which offer an enormous scattering cross-section due to plasmon resonance in the visible part of the optical spectrum. Problematic, however, is their incorporation into conventionally used (fluorescence) microscopes, because illumination and scattered light have the same wavelength and cannot be separated spectrally. Therefore, an approach based on total internal reflection (TIR) utilizing a novel parabolically shaped quartz prism for illumination was developed within this thesis. This approach provided homogenous and spatially invariant illumination profiles in combination with a convenient control over a wide range of illumination angles. Moreover, single-molecule fluorescence as well as single-particle scattering were detectable with high signal-to-noise ratios. Importantly, AuNPs with a diameter of 40 nm provided sub-nanometer localization accuracies within millisecond integration times and reliably reported on the characteristic 8 nm stepping of individual kinesin-1 motors moving along microtubules. These results highlight the potential of AuNPs to replace fluorescent probes in future single-molecule experiments. The newly developed parabolic prism-type TIR microscope is expected to strongly facilitate such approaches in the future. To study how the motility of kinesin-1 is affected by permanent roadblocks on the microtubule lattice, first, conventional objective-type TIRF microscopy was applied to GFP-labeled motors. An increasing density of roadblocks caused the mean velocity, run length, and dwell time to decrease exponentially. This is explained by (i) the kinesin-1 motors showing extended pausing phases when confronted with a roadblock and (ii) the roadblocks causing a reduction in the free path of the motors. Furthermore, kinesin-1 was found to be highly sensitive to the crowdedness of microtubules as a roadblock decoration as low as 1 % sufficed to significantly reduce the landing rate. To study events, where kinesin-1 molecules continued their runs after having paused in front of a roadblock, AuNPs were loaded onto the tails of the motors. When observing the kinesin-1 motors with nanometer-precision, it was interestingly found that about 60 % of the runs continued by movements to the side, with the left and right direction being equally likely. This finding suggests that kinesin-1 is able to reach to a neighboring protofilament in order to ensure ongoing transportation. In the absence of roadblocks, individual kinesin-1 motors stepped sideward with a much lower, but non-vanishing probability (0.2 % per step). These findings suggest that processive motor proteins may possess an intrinsic side stepping mechanism, potentially optimized by evolution for their specific intracellular tasks.

info:eu-repo/classification/ddc/570

ddc:570