RESUMEN
Optogenetics is a molecular biological technique involving transfection of cells with photosensitive proteins and the subsequent study of their biological effects. The aim of this study was to evaluate the effect of blue light on the survival of HeLa cells, transfected with channelrhodopsin-2 (ChR2). HeLa wild-type cells were transfected with a plasmid that contained the gene for ChR2. Transfection and channel function were evaluated by real-time polymerase chain reaction (RT-PCR), fluorescence imaging using green fluorescent protein (GFP) and flow cytometry for intracellular calcium changes using a Fura Red probe. We developed a platform for optogenetic stimulation for use within the cell culture incubator. Different stimulation procedures using blue light (467 nm) were applied for up to 24 h. Cell survival was determined by flow cytometry using propidium iodide and rhodamine probes. Change in cell survival showed a statistically significant (p < 0.05) inverse association with the frequency and time of application of the light stimulus. This change seemed to be associated with the ChR2 cis-trans-isomerization cycle. Cell death was associated with high concentrations of calcium in the cytoplasm and stimulation intervals less than the period of isomerization. It is possible to transfect HeLa cells with ChR2 and control their survival under blue light stimulation. We suggest that this practice should be considered in the future development of optogenetic systems in biological or biomedical research.
Asunto(s)
Supervivencia Celular/fisiología , Calcio/metabolismo , Ciclo Celular/fisiología , Channelrhodopsins/genética , Channelrhodopsins/metabolismo , Células HeLa , Humanos , Optogenética , TransfecciónRESUMEN
Hydrogen peroxide (H2O2) is a messenger involved in both damaging neuroinflammatory responses and physiological cell communication. The ventrolateral medulla, which regulates several vital functions including breathing and blood pressure, is highly influenced by hydrogen peroxide, whose extracellular levels could be determined by hypoxia and microglial activity, both of which modulate ventrolateral medulla function. Therefore, in this study we aimed to test whether different patterns of hypoxia and/or putative microglial modulators change extracellular hydrogen peroxide in the ventrolateral medulla by using an enzymatic reactor online sensing procedure specifically designed for this purpose. With this new technique, we detected extracellular levels of hydrogen peroxide in the ventrolateral medulla in vitro, which spontaneously fluctuated. These fluctuations are reduced by minocycline, a putative microglial inhibitor, and by the microglial toxin liposomal clodronate. Suitably, lipopolysaccharide increases extracellular hydrogen peroxide, while minocycline and liposomal clodronate reduce this increase. Application of blue light to slices with microglia expressing channelrhodopsin-2 also increases extracellular hydrogen peroxide. Moreover, long-lasting and intermittent hypoxia (as well as subsequent reoxygenation) increase extracellular hydrogen peroxide to similar levels, which is partially prevented by minocycline. The effect of long-lasting hypoxia was reproduced in vivo. Overall, our data show that changes in oxygen concentration, and possibly microglial function, modulate extracellular H2O2 levels in the ventrolateral medulla, which could influence the function of this neural circuit under normal and pathological conditions related to inflammation and/or hypoxia.