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DNA Nanomachines

We successfully construct and study two types of DNA-motors.

Autonomous motor: We constructed a bipedal autonomous DNA-motor with a coordinate activity between the two motor legs and monitored its activity using SMF techniques. The measurements are done in-situ which enables monitoring the motor’s progress and structural dynamics without disturbing its activity. Our kinetic measurements of the motor’s assembly and activity indicate that it takes dozens of seconds to complete reactions, rather than hours, if components are properly designed. However, we monitor side reactions that significantly reduce the yield of the reaction and resulting in defected motors. We are now working on implementing new strategies for motors’ preparation which will prevent side reactions, altogether, resulting in much higher yield. On the methodological side, we have measured the motor’s dynamics and its interaction with its energy source, a DNA-fuel, in equilibrium and non-equilibrium conditions. Our work demonstrates that by using SMF, one can construct a DNA-machine and monitor its activity in ways not possible with conventional methods. We demonstrate that our methods enable simultaneous in-situ monitoring of the motors efficiency, integrity and activity.

Non-autonomous motor:  We constructed a two-leg motor which walks on a DNA-origami track and use energy in the form of fuel/anti-fuel ss-DNAs. The motor successfully completes more than 15 steps and we are now working on increasing the stepping efficiency, speed and walking range. Kinetic measurements indicate that it is possible to significantly improve this kind of motors, such that they will have far higher efficiency and speed.  The motor will be capable of maneuvering molecules of interest, e.g. nanoparticles, to a specific location and orientation. Later on, we will use these motors in a device which will maneuver nano-particles in respect to each other in electro-optic device, and a device that exert force on foreign molecules.



 
Autonomous Motors

Three steps detected for Autonomous motor using single-molecule FRET-ALEX







Non-Autonomous Motors


DNA Dynamics
It is now understood that to enable rational design of nanodevice it is necessary to have a good insight of the intrinsic DNA dynamics. For that reason we implement SMF techniques to study the fundamental physical rules that govern the behavior of DNA, especially of ss-DNA hairpin dynamics. The structural dynamics of hairpins containing various loop and stamp sequences are studied when they freely-diffusing and when immobilized to a surface. Together, these two complementary methods enable measuring hairpin dynamics with a typical time spanning over several orders of magnitude (dozens of microsecond to many minutes). For the first time, the hairpins opening and closing rates are accurately and directly measured. We are now drawing general conclusions regarding ss-DNA dynamics which will enable rational design of the DNA machines’ moving parts and of fuels.

DNA Dynamics
Freely diffusing approach applied to DNA hairpin


TIRF
Immobilized approach using TIRF applied to DNA hairpin



DNA-Nanoparticles 3D Electronic Devices

We are using the specificity and orthogonality of DNA molecules and DNA-origami to assemble nanoparticles of versions types in a particular position and orientation in respect to each other in ways not possible with any other method. As a first step, we successfully position gold nanoparticles in a specific location on a DNA-origami. We are now working on simultaneously positioning several gold nanoparticles and nanoroads on a single DNA-origami at specific sites. In collaboration with Taleb Mokari’s group, we are planning to position semi-conducting nanoparticles in various configurations and study how the nanoparticles relative configurations influence the device’s electro-optical properties. Especially we are interested in Plasmon fluoresces enhancement, a promising strategy for efficient light harvesting.


DNA_AuNP

Nucleosome Core Particles (NCP)

Nucleosome Core Particles (NCP) are responsible for tightly packing chromosomal DNA and they form an obstacle for regulatory proteins, polymerases, repair and remodeling proteins, all of which require access to DNA for their functionality. The local mechanical properties of DNA, believed to be sequence dependent, are known to play a significant role in formation of a stable NCP. Thus, a good understanding of DNA-related processes and their regulatory functions must include the understanding of affinities between the various nucleosome components, NCP association/dissociation mechanisms and NCP dynamics, and DNA interaction with DNA-binding-proteins, all of the above, in relation to DNA sequence.

Due to NCP heterogeneous, complexity and dynamic nature it is adequate to be studied by single-molecule fluorescence techniques, which enable carful in-situ structural-dynamics and interaction investigation of DNA and proteins.

NCP

Methodological Development
Our group specializes in developing SMF spectroscopical techniques. We are currently working on several methodological developments which will significantly improve the SMF resolution, accuracy and stability.

Photons distribution analysis: In a single-molecule fluorescence measurement of freely diffusing samples, photons belonging to a single-molecule (‘burst’) are analyzed in terms of their number and not distribution. As a result, static and dynamic heterogeneity are not distinguishable, and often, data is wrongly interpreted. We developed a mathematical algorithm that analyzes the photon distribution inside the burst, indicating whether a single-molecule event undergoes dynamics or it is purely static. Using our method, it is now possible to analyze complicated dynamical behavior in ways not possible with the conventional method. We believe our straightforward, robust and informative approach will be adapted and widely used for analyzing SMF data.

Kinetic measurements: We develop several methods to measure reaction kinetic profiles at the single-molecule level and successfully implement them to monitor DNA-motors assembly and activity reactions (Fig. 2 and Fig 4). Analysis of the kinetic profiles reveals the underlying mechanisms that operate in the motors’ assembling process and in their reaction to fuel and anti-fuel during regular activity. As far as we know, this is a new type of measurements, never done before at single-molecule level and for DNA-motors.

Methodological_Development