6,517 research outputs found
Charter School Funding: Inequity in New York City
Charter schools have been a part of the educational landscape in New York City since the first New York charter school opened in Harlem in 1999. We define a charter school as any school that (1) operates based on a formal charter in place of direct school district management and (2) reports its finances independently from the school district. We define all other public schools as district schools. According to the New York State Department of Education (NYSDoE), New York City was home to 1,575 district and 183 charter schools in Fiscal Year 2014 (FY2014). Seven percent of all public school students in New York City attended charter schools that year
Effect of 2-H and 18-O water isotopes in kinesin-1 gliding assay
We show here the effects of heavy-hydrogen water (^2^H~2~O) and heavy-oxygen water (H~2~^18^O) on the gliding speed of microtubules on kinesin-1 coated surfaces. Increased fractions of isotopic waters used in the motility solution decreased the gliding speed of microtubules by a maximum of 21% for heavy-hydrogen and 5% for heavy-oxygen water. We discuss possible interpretations of these results and the importance for future studies of water effects on kinesin and microtubules. We also discuss the implication for biomolecular devices incorporating molecular motors
Electromigration early resistance increase measurements
An early resistance change measurement set-up, using an AC bridge technique, has been developed, and measurements have been performed. Large sample-to-sample variations occur. The characteristic time for the resistance change curve is shorter for resistance increase (under current stress) than for resistance decay (during recovery)
Speed effects in gliding motility assays due to surface passivation, water isotope, and osmotic stress.
The molecular motor kinesin-1, an ATPase, and the substrate it walks along, microtubules, are vital components of eukaryotic cells. Kinesin converts chemical energy to linear motion as its two motor domains step along microtubules in a process similar to how we walk. Cells create systems of microtubules that direct the motion of kinesin. This directed motion allows kinesin to transport various cargos inside cells.

During the stepping process, the kinesin motor domains bind and unbind from their binding sites on the microtubules. Binding and unbinding rates of biomolecules are highly dependent on hydration and exclusion of water from the binding interface. Osmotic stress will likely strongly affect the binding and unbinding rates for kinesin and thus offers a tool to specifically probe those steps. We will report the effects of different osmolytes on microtubule speed and other observables in the gliding motility assay.

Kinesin’s kinetic core cycle hydrolyzes ATP with the help of a water molecule. Any modification to the water molecules the kinesin is in will change how ATP hydrolyzes and will ultimately affect how kinesin moves along microtubules. We will report preliminary results showing how kinesin is affected when the solvent it is in is changed from light water to heavy water.
 
When used in a surface assay or in devices, the kinesin and microtubule system is also dependent on substrate passivation. Kinesin motor domains do not transport microtubules in the gliding motility assay if kinesin is added to a glass microscope slide that has not been functionalized. Functionalization of the glass slides and slips is typically performed with bovine milk proteins called caseins. Bovine casein is a globular protein that can be broken up into four constituents: αs1, αs2, β, and κ. Each casein constituent affects how kinesin adheres to the glass and ultimately the speed at which microtubules are observed to glide at. Building on the work of Verma et.al., we have found that each constituent individually produces different outcomes in gliding assays. We will present these findings and discuss implications they have for use of gliding assays to study kinesin and use of kinesin-microtubule system in microdevices. 

[1] Chaen, S, N Yamamoto, I Shirakawa, and H Sugi. 2001. Effect of deuterium oxide on actomyosin motility in vitro. _Biochimica et biophysica acta_ 1506, no. 3: 218-23. 
[2] Vivek Verma, William O Hancock, Jeffrey M Catchmark, "The role of casein in supporting the operation of surface bound kinesin," _J. Biol. Eng._ 2008; 2: 14.

Acknowledgements: This work was supported by the DTRA CB Basic Research Program under Grant No. HDTRA1-09-1-008.

Subextensive Scaling in the Athermal, Quasistatic Limit of Amorphous Matter in Plastic Shear Flow
We present the results of numerical simulations of an atomistic system
undergoing plastic shear flow in the athermal, quasistatic limit. The system is
shown to undergo cascades of local rearrangements, associated with quadrupolar
energy fluctuations, which induce system-spanning events organized into lines
of slip oriented along the Bravais axes of the simulation cell. A finite size
scaling analysis reveals subextensive scaling of the energy drops and
participation numbers, linear in the length of the simulation cell, in good
agreement with the observed real-space structure of the plastic events.Comment: 4 pages, 6 figure
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