Genetically Encoded Fluorescent Probe for Detection of Heme-Induced Conformational Changes in Cytochrome c.

Cytochrome c (Cytc) is a key redox protein for energy metabolism and apoptosis in cells. The activation of Cytc is composed of several steps, including its transfer to the mitochondrial membrane, binding to cytochrome c heme lyase (CCHL) and covalent attachment to heme. The spectroscopic methods are often applied to study the structural changes of Cytc. However, they require the isolation of Cytc from cells and have limited availability under physiological conditions. Despite recent studies to elucidate the tightly regulated folding mechanism of Cytc, the role of these events and their association with different conformational states remain elusive. Here, we provide a genetically encoded fluorescence method that allows monitoring of the conformational changes of Cytc upon binding to heme and CCHL. Cerulean and Venus fluorescent proteins attached at the N and C terminals of Cytc can be used to determine its unfolded, intermediate, and native states by measuring FRET amplitude. We found that the noncovalent interaction of heme in the absence of CCHL induced a shift in the FRET signal, indicating the formation of a partially folded state. The higher concentration of heme and coexpression of CCHL gave rise to the recovery of Cytc native structure. We also found that Cytc was weakly associated with CCHL in the absence of heme. As a result, a FRET-based fluorescence approach was demonstrated to elucidate the mechanism of heme-induced Cytc conformational changes with spatiotemporal resolution and can be applied to study its interaction with small molecules and other protein partners in living cells.

Adaptive tracking algorithm for trajectory analysis of cells and layer-by-layer assessment of motility dynamics.

Tracking biological objects such as cells or subcellular components imaged with time-lapse microscopy enables us to understand the molecular principles about the dynamics of cell behaviors. However, automatic object detection, segmentation and extracting trajectories remain as a rate-limiting step due to intrinsic challenges of video processing. This paper presents an adaptive tracking algorithm (Adtari) that automatically finds the optimum search radius and cell linkages to determine trajectories in consecutive frames. A critical assumption in most tracking studies is that displacement remains unchanged throughout the movie and cells in a few frames are usually analyzed to determine its magnitude. Tracking errors and inaccurate association of cells may occur if the user does not correctly evaluate the value or prior knowledge is not present on cell movement. The key novelty of our method is that minimum intercellular distance and maximum displacement of cells between frames are dynamically computed and used to determine the threshold distance. Since the space between cells is highly variable in a given frame, our software recursively alters the magnitude to determine all plausible matches in the trajectory analysis. Our method therefore eliminates a major preprocessing step where a constant distance was used to determine the neighbor cells in tracking methods. Cells having multiple overlaps and splitting events were further evaluated by using the shape attributes including perimeter, area, ellipticity and distance. The features were applied to determine the closest matches by minimizing the difference in their magnitudes. Finally, reporting section of our software were used to generate instant maps by overlaying cell features and trajectories. Adtari was validated by using videos with variable signal-to-noise, contrast ratio and cell density. We compared the adaptive tracking with constant distance and other methods to evaluate performance and its efficiency. Our algorithm yields reduced mismatch ratio, increased ratio of whole cell track, higher frame tracking efficiency and allows layer-by-layer assessment of motility to characterize single-cells. Adaptive tracking provides a reliable, accurate, time efficient and user-friendly open source software that is well suited for analysis of 2D fluorescence microscopy video datasets.

Alteration of cell motility dynamics through collagen fiber density in photopolymerized polyethylene glycol hydrogels.

Polyethylene glycol (PEG) hydrogels that have natural fibers mimicking extracellular matrix can be used as a model to understand the role of substrate properties on cell growth and migration. Due to the dependence of cell movement to adhesion, characterization of motility is needed to prepare biocompatible substrates. We demonstrated a method to encapsulate collagen into PEG hydrogel crosslinked via photopolymerization and studied the effect of fiber density on motility dynamics. Porous hydrogel immersed into collagen solution was coated with fibers after neutralizing solution. We provided a detailed study of cell instantaneous/average speed, total displacement, persistence and angular displacement. We found that cells demonstrated a biphasic motility where a maximum speed of 17.4 µm/h with a total distance of 215 µm and persistence of 0.43 were obtained at 1.2 mg/ml collagen. High occurrence of low angular displacement observed at intermediate fiber density suggests that cells tend to move forward along hydrogels. Increased anisotropy at low density was an indication of forward and backward movement. Finally, matrix deformation was determined in the absence of fluorescent beads by tracking fiber displacement at subpixel resolution. Our findings establish a method for preparation of collagen coated hydrogels and provide an insight into cell motility dynamics.

A detailed investigation of the effect of calcium crosslinking and glycerol plasticizing on the physical properties of alginate films.

Alginates attract growing interest due to their biocompatible and biodegradable nature. Here, a wide spectrum of glycerol added alginate films (from 0 to 30% w/w, glycerol/alginate) were prepared and crosslinked by four different concentrations of calcium chloride solutions (0.5, 1, 1.5, 2%, w/w). This is the first investigation involving variation of both the plasticizer and crosslinker concentrations in twenty different compositions. It is shown that glycerol and calcium have a synergic effect on the mechanical properties and the behavior of crosslinked and plasticized alginate films cannot be predicted by studies, which vary only one of these, keeping the other constant. Without glycerol, crosslinking had a negligible effect on tensile behavior, but with glycerol addition, the effect of crosslinking became evident in mechanical properties. Calcium and glycerol concentrations exhibited a combined effect, displaying optimum combinations with good strength and fracture strain properties. Crosslinking increased the thermal resistance of all films. Low crosslinked high swelling films and highly crosslinked low swelling films were prepared. Water vapor permeability of films decreased regularly with increasing calcium concentration. The films exhibited high transmittance in the visible region. The results showed that alginate films have an appreciable potential in wound dressing and food packaging applications.

Identification of SERPINE1 as a Regulator of Glioblastoma Cell Dispersal with Transcriptome Profiling.

High mortality rates of glioblastoma (GBM) patients are partly attributed to the invasive behavior of tumor cells that exhibit extensive infiltration into adjacent brain tissue, leading to rapid, inevitable, and therapy-resistant recurrence. In this study, we analyzed transcriptome of motile (dispersive) and non-motile (core) GBM cells using an in vitro spheroid dispersal model and identified SERPINE1 as a modulator of GBM cell dispersal. Genetic or pharmacological inhibition of SERPINE1 reduced spheroid dispersal and cell adhesion by regulating cell-substrate adhesion. We examined TGFß as a potential upstream regulator of SERPINE1 expression. We also assessed the significance of SERPINE1 in GBM growth and invasion using TCGA glioma datasets and a patient-derived orthotopic GBM model. SERPINE1 expression was associated with poor prognosis and mesenchymal GBM in patients. SERPINE1 knock-down in primary GBM cells suppressed tumor growth and invasiveness in the brain. Together, our results indicate that SERPINE1 is a key player in GBM dispersal and provide insights for future anti-invasive therapy design.

Centrosomal and ciliary targeting of CCDC66 requires cooperative action of centriolar satellites, microtubules and molecular motors.

Mammalian centrosomes and cilia play key roles in many cellular processes and their deregulation is linked to cancer and ciliopathies. Spatiotemporal regulation of their biogenesis and function in response to physiological stimuli requires timely protein targeting. This can occur by different pathways, including microtubule-dependent active transport and via centriolar satellites, which are key regulators of cilia assembly and signaling. How satellites mediate their functions and their relationship with other targeting pathways is currently unclear. To address this, we studied retinal degeneration gene product CCDC66, which localizes to centrosomes, cilia, satellites and microtubules and functions in ciliogenesis. FRAP experiments showed that its centrosomal pool was dynamic and the ciliary pool associated with the ciliary axoneme and was stable. Centrosomal CCDC66 abundance and dynamics required microtubule-dependent active transport and tethering, and was inhibited by sequestration at satellites. Systematic quantitation of satellite dynamics identified only a small fraction to display microtubule-based bimodal motility, consistent with trafficking function. Majority displayed diffusive motility with unimodal persistence, supporting sequestration function. Together, our findings reveal new mechanisms of communication between membrane-less compartments.

Stress relaxation and humidity dependence in sodium alginate-glycerol films.

The control of viscoelastic properties of alginate biopolymer that mimics the matrix properties of biological substrates plays an important role for the success of its biomedical applications. For this purpose stress relaxation behavior of glycerol plasticized sodium alginate films is characterized at room temperature as a function of the glycerol concentration ranging up to 40%. A series of experiments are thus conducted at relative humidity levels of 38 ±â€¯1% and 51 ±â€¯1%. The glycerol content is demonstrated to amplify the effect of humidity on relaxation profiles. In the case of 30% glycerol, normalized stress at the level of 65% is recorded at the end of the first 30 min at the low humidity level, whereas the corresponding value drops to 8% with increased humidity. Alginate films with no glycerol content exhibit much higher normalized stresses of 89% and 73% at low and high humidity levels, respectively. In addition, stress relaxation is observed to continue well beyond the first 30 min, especially for glycerol concentrations lower than 30%, where 9-hour parameters for a stretched exponential Kohlrausch - Williams - Watts function are reported demonstrating the importance of relaxation time for successful modeling.

Direct conversion of cytochrome c spectral shifts to fluorescence using photochromic FRET.

Photochromic fluorescence resonance energy transfer (pcFRET) was used to monitor the redox activity of non-fluorescent heme protein. Venus fluorescent protein was used as a donor where its emission intensity was reversibly modulated by the absorption change of Cytochrome c.

In vitro and in vivo biolasing of fluorescent proteins suspended in liquid microdroplet cavities.

Fluorescent proteins are indispensable for selective, quantitative visualization of localization, dynamics, and interactions of key molecular constituents of live cells. Incorporation of fluorescent proteins into an optical cavity can lead to a significant increase in fluorescence signal levels due to stimulated emission and light amplification in the cavity, forming a laser with biological gain medium. Utilization of lasing emission from fluorescent biological molecules can then greatly enhance the performance of fluorescence-based biosensors benefiting from the high sensitivity of non-linear lasing processes to small perturbations in the cavity and the gain medium. Here we study optofluidic biolasers that exploit active liquid optical resonators formed by surface-supported aqueous microdroplets containing purified yellow fluorescent protein or a suspension of live E. coli bacterial cells expressing the fluorescent protein. We first demonstrate lasing in fluorescent protein solutions at concentrations as low as 49 µM. Subsequently, we show that a single fluorescent bacterial cell of micrometre size confined in a droplet-based cavity can serve as a laser gain medium. Aqueous droplet microcavities allow the maintenance of the bacterial cells under conditions compatible with unimpeded growth. Therefore, our results also suggest a direct route to microscopic sources of laser light with self-regenerating gain media.

Ultrasensitive measurements of microbial rhodopsin photocycles using photochromic FRET.

Microbial rhodopsins are an important class of light-activated transmembrane proteins whose function is typically studied on bulk samples. Herein, we apply photochromic fluorescence resonance energy transfer to investigate the dynamics of these proteins with sensitivity approaching the single-molecule limit. The brightness of a covalently linked organic fluorophore is modulated by changes in the absorption spectrum of the endogenous retinal chromophore that occur as the molecule undergoes a light-activated photocycle. We studied the photocycles of blue-absorbing proteorhodopsin and sensory rhodopsin II (SRII). Clusters of 2-3 molecules of SRII clearly showed a light-induced photocycle. Single molecules of SRII showed a photocycle upon signal averaging over several illumination cycles.

Intermolecular electron-transfer catalyzed on nanoparticle surfaces.

Surface-functionalized nanoparticles enhance the rate of electron transfer (ET) between Cyt c(Fe(2+)) and Co(phen)(3)(3+) by a factor of 10(5) through simultaneous electrostatic binding of an ET donor and acceptor.

Controlled nanoparticleassembly through protein conformational changes.

Selective surface recognition by proteins provides programmed bottom-up assembly of synthetic nanomaterials. We have investigated the controlled self-assembly of functionalized gold nanoparticles (Au-TAsp) with cytochrome c (Cyt c) and apoCyt c through complementary electrostatic interactions. Au-TAsp formed discrete, water-soluble adducts with native Cyt c, whereas unfolded apoCyt c induced nanocomposite formation at high Cyt c : Au-TAsp ratios. The binding of random-coil apoCyt c to Au-TAsp at low ratios induced α-helix formation in soluble nanocomposites, but at elevated ratios insoluble micron-scale aggregates were formed. The local structure of the assemblies was critically dependent on the Cyt c : Au-TAsp ratio. The dispersibility of apoCyt c-Au-TAsp was pH dependent, providing rapid and reversible control over nanocomposite assembly. The apoCyt c-Au-TAsp aggregates could likewise be disassembled through proteolytic cleavage of apoCyt c, demonstrating the ability to selectively remodel these hybrid materials.

Recognition and modulation of cytochrome c's redox properties using an amphiphilic homopolymer.

An amphiphilic homopolymer scaffold has been used to bind to the protein, cytochrome c. This interaction is analyzed using cyclic voltammetry, native gel electrophoresis, UV-visible absorption, and circular dichroism spectroscopy. The polymer binds to cytochrome c with micromolar affinity and the association of polymer with cytochrome c leads to a structural change of the protein. This conformational change exposes the heme unit of the protein, which affords an opportunity to reversibly modulate its electron-transfer properties. We have also shown that the electrostatic binding of polymer to cytochrome c can be used to disrupt its interaction with its natural partner, cytochrome c peroxidase.

Disruption of protein-protein interactions using nanoparticles: inhibition of cytochrome c peroxidase.

Functionalized gold nanoparticles bind selectively to cytochrome c or cytochrome c peroxidase and inhibit enzyme turnover.