Single-Crystal Rutile TiO2 Nanocylinders are Highly Effective Transducers of Optical Force and Torque.

Optical trapping of (sub)micron-sized particles is broadly employed in nanoscience and engineering. The materials commonly employed for these particles, however, have physical properties that limit the transfer of linear or angular momentum (or both). This reduces the magnitude of forces and torques, and the spatiotemporal resolution, achievable in linear and angular traps. Here, we overcome these limitations through the use of single-crystal rutile TiO2, which has an exceptionally large optical birefringence, a high index of refraction, good chemical stability, and is amenable to geometric control at the nanoscale. We show that rutile TiO2 nanocylinders form powerful joint force and torque transducers in aqueous environments by using only moderate laser powers to apply nN·nm torques at kHz rotational frequencies to tightly trapped particles. In doing so, we demonstrate how rutile TiO2 nanocylinders outperform other materials and offer unprecedented opportunities to expand the control of optical force and torque at the nanoscale.

Understanding the sub-cellular dynamics of silicon transportation and synthesis in diatoms using population-level data and computational optimization.

Controlled synthesis of silicon is a major challenge in nanotechnology and material science. Diatoms, the unicellular algae, are an inspiring example of silica biosynthesis, producing complex and delicate nano-structures. This happens in several cell compartments, including cytoplasm and silica deposition vesicle (SDV). Considering the low concentration of silicic acid in oceans, cells have developed silicon transporter proteins (SIT). Moreover, cells change the level of active SITs during one cell cycle, likely as a response to the level of external nutrients and internal deposition rates. Despite this topic being of fundamental interest, the intracellular dynamics of nutrients and cell regulation strategies remain poorly understood. One reason is the difficulties in measurements and manipulation of these mechanisms at such small scales, and even when possible, data often contain large errors. Therefore, using computational techniques seems inevitable. We have constructed a mathematical model for silicon dynamics in the diatom Thalassiosira pseudonana in four compartments: external environment, cytoplasm, SDV and deposited silica. The model builds on mass conservation and Michaelis-Menten kinetics as mass transport equations. In order to find the free parameters of the model from sparse, noisy experimental data, an optimization technique (global and local search), together with enzyme related penalty terms, has been applied. We have connected population-level data to individual-cell-level quantities including the effect of early division of non-synchronized cells. Our model is robust, proven by sensitivity and perturbation analysis, and predicts dynamics of intracellular nutrients and enzymes in different compartments. The model produces different uptake regimes, previously recognized as surge, externally-controlled and internally-controlled uptakes. Finally, we imposed a flux of SITs to the model and compared it with previous classical kinetics. The model introduced can be generalized in order to analyze different biomineralizing organisms and to test different chemical pathways only by switching the system of mass transport equations.

Reconstituting functional microtubule-barrier interactions.

Local interactions between the tips of microtubules and the cell cortex, or other cellular components such as kinetochores, play an important role in essential cellular processes like establishing cell polarity, distribution of organelles, and microtubule aster and chromosome positioning. Here we present two in vitro assays that specifically mimic microtubule-cortex interactions by employing selectively functionalized microfabricated barriers that allow for the immobilization of proteins with a range of affinities. We describe the microfabrication process to create gold or glass barriers and the subsequent functionalization of these barriers using self-assembled thiol monolayers or polylysine-poly(ethylene glycol), respectively. Near-permanent attachment of proteins is obtained using biotinylated surfaces combined with streptavidin and biotinylated proteins. Lower affinity interactions, further tunable with the addition of imidazole, are obtained using nickel-nitrilotriacetic acid (Ni(II)-NTA) functionalization combined with his-tagged proteins. Both mono-NTA and tris-NTA compounds are used. We show an assay to reconstitute the "end-on" interaction between dynamic microtubule tips and barrier-attached dynein, mimicking the cellular situation at the cortex and at kinetochores. In a second assay, we reconstitute microtubule-based delivery of end-tracking proteins to functionalized barriers, mimicking the transport of cell-end markers to the cell poles in interphase fission yeast cells.