The export of cytochrome c from mitochondria to the cytoplasm has been detected during apoptosis. Addition of cytochrome c to cytosolic extracts can activate the caspases, suggesting that this export could be an important intracellular signal for initiating the apoptotic programme. We have investigated the mechanism of caspase activation by cytochrome c. Mitochondrial cytochrome c normally shuttles electrons between complexes III and IV of the electron transport chain. Interaction with these complexes is dependent on electrostatic interactions via a polylysine binding pocket. Cytosolic caspase activation was only observed with intact holocytochrome c, and increasing the ionic composition of the extracts prevented activation, suggesting that stringent allosteric interactions between cytochrome c and other cytoplasmic factors are necessary. Cytochrome c was fully reduced within 5 min of addition to the cytosolic extracts. Potassium ferricyanide could maintain cytochrome c in an oxidized state, but care was taken to use ferricyanide at concentrations where its polyanion effect did not cause interference. The oxidized form of cytochrome c was able to activate the caspases. We conclude that reduced cytochrome c will function in the cytoplasm; however, its reduction is not a critical step, and electron transfer from cytochrome c to its cytoplasmic-binding partner(s) is not necessary in the pathway leading to apoptosis.
Filopodia are 5–10 μm long processes that elongate by actin polymerization, and promote axon growth and guidance by exerting mechanical tension and by molecular signaling. Although axons elongate in response to mechanical tension, the structural and functional effects of tension specifically applied to growth cone filopodia are unknown. Here we developed a strategy to apply tension specifically to retinal ganglion cell (RGC) growth cone filopodia through surface-functionalized, membrane-targeted superparamagnetic iron oxide nanoparticles (SPIONs). When magnetic fields were applied to surface-bound SPIONs, RGC filopodia elongated directionally, contained polymerized actin filaments, and generated retrograde forces, behaving as bona fide filopodia. Data presented here support the premise that mechanical tension induces filopodia growth but counter the hypothesis that filopodial tension directly promotes growth cone advance. Future applications of these approaches may be used to induce sustained forces on multiple filopodia or other subcellular microstructures to study filopodial on axon growth or cell migration.
Clinical risk factors for diabetic retinopathy (DR), such as duration of disease and degree of glucose control, do not adequately predict disease progression in individual patients, suggesting the presence of a genetic component. Multiple smaller studies have investigated genotype–phenotype correlations in genes encoding vascular endothelial growth factor, aldose reductase, the receptor for advanced glycation end products, and many others. In general, reported results have been conflicting, due to factors including small sample sizes, variations in study design, differences in clinical end points, and underlying genetic differences between study groups. At this time, there is no confirmed association with any risk allele reported. As we continue to collect data from additional studies, the role of genetics in DR may become more apparent.
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