Light pollution: the possible consequences of excessive illumination on retina.

Light is the visible part of the electromagnetic radiation within a range of 380-780 nm; (400-700 on primates retina). In vertebrates, the retina is adapted to capturing light photons and transmitting this information to other structures in the central nervous system. In mammals, light acts directly on the retina to fulfill two important roles: (1) the visual function through rod and cone photoreceptor cells and (2) non-image forming tasks, such as the synchronization of circadian rhythms to a 24 h solar cycle, pineal melatonin suppression and pupil light reflexes. However, the excess of illumination may cause retinal degeneration or accelerate genetic retinal diseases. In the last century human society has increased its exposure to artificial illumination, producing changes in the Light/Dark cycle, as well as in light wavelengths and intensities. Although, the consequences of unnatural illumination or light pollution have been underestimated by modern society in its way of life, light pollution may have a strong impact on people's health. The effects of artificial light sources could have direct consequences on retinal health. Constant exposure to different wavelengths and intensities of light promoted by light pollution may produce retinal degeneration as a consequence of photoreceptor or retinal pigment epithelium cells death. In this review we summarize the different mechanisms of retinal damage related to the light exposure, which generates light pollution.

Tubulin carboxypeptidase/microtubules association can be detected in the distal region of neural processes.

The association of tubulin carboxypeptidase with microtubules has been demonstrated in crude brain extracts and in living non-nervous cells. Here, we studied this phenomenon in cultured brain cells. To determine the association of the enzyme with neural microtubules we isolated the cytoskeletons (detergent-extraction under microtubule-stabilizing conditions) and measured the content of Tyr, Glu, and delta2 tubulin as a function of the in vitro incubation time of the cytoskeletons. The carboxypeptidase was found associated with microtubules in 2 days-cultured cells but not in 7 days-cultured cells. Quantitative analysis of digitized images after immunofluorescent staining revealed that detyrosination during the incubation of the cytoskeletons occurred preferentially in the distal regions of the neural processes. Prolonged taxol-treatment of the cells promoted higher detyrosination but Tyr tubulin was not depleted suggesting the existence of a subset of microtubules that has not associated carboxypeptidase and therefore cannot be detyrosinated even after prolonged taxol-treatment. This hypothesis was supported, although not conclusively, by additional experiments.

Association of tubulin carboxypeptidase with microtubules in living cells.

Tubulin carboxypeptidase is the enzyme that releases the C-terminal tyrosine from alpha-tubulin, converting tyrosine-terminated (Tyr) to detyrosinated (Glu) tubulin. The present study demonstrates that this enzyme is associated with microtubules in living cells. We extracted cultured cells (COS-7) with Triton X-100 under microtubule-stabilizing conditions and found tubulin carboxypeptidase activity in the cytoskeleton fraction. We ruled out, by using several control experiments, the possibility that this result was due to contamination of the isolated cytoskeletons by non-associated proteins contained in the detergent fraction or to an artifact in vitro during the extraction procedure. The associated carboxypeptidase activity showed characteristics similar to those of brain tubulin carboxypeptidase and different from those of pancreatic carboxypeptidase A. In comparison with cultures at confluence, those at low cell density contained small (if any) amounts of carboxypeptidase activity associated with microtubules. In addition, the enzyme was shown to be associated only with cold-labile microtubules. The tubulin carboxypeptidase/microtubule association was also demonstrated in Chinese hamster ovary, NIH 3T3 and PC12 cells. Interestingly, this association was not observed in cultured embryonic brain cells. Our results demonstrate that tubulin carboxypeptidase is indeed associated with microtubules in living cells. Furthermore, the findings that this association occurs with a subset of microtubules and that its magnitude depends on the degree of confluence of the cell culture indicate that it could be part of the mechanism that regulates the tyrosination state of microtubules.