Two-photon laser scanning microscopy (TPLSM) of endogenous reduced nicotinamide adenine dinucleotide (NAD(P)H) provides important information regarding the cellular metabolic state. When imaging the punctate mitochondrial fluorescence originating from NAD(P)H in a rat basophilic leukemia (RBL) cell at low laser powers, no morphological changes are evident, and photobleaching is not observed when many images are taken. At higher powers, mitochondrial NAD(P)H fluorescence bleaches rapidly. To assess the limitations of this technique and to quantify the extent of photodamage, we have measured the effect of TPLSM on DNA synthesis. Although previous reports have indicated a threshold power for ''safe'' two-photon imaging, we find the laser power to be an insufficient indicator of photodamage. A more meaningful metric is a two-photon-absorbed dose that is proportional to the number of absorbed photon pairs. A temporary reduction of DNA synthesis in RBL cells occurs whenever a threshold dose of approximately 2 3 10 53 photon 2 cm 24 s 21 is exceeded. This threshold is independent of laser intensity when imaging with average powers ranging from 5 to 17 mW at 740 nm. Beyond this threshold, the extent of the reduction is intensity dependent. DNA synthesis returns to control levels after a recovery period of several hours.
Two-photon laser scanning microscopy (TPLSM) of endogenous reduced nicotinamide adenine dinucleotide (NAD(P)H) provides important information regarding the cellular metabolic state. When imaging the punctate mitochondrial fluorescence originating from NAD(P)H in a rat basophilic leukemia (RBL) cell at low laser powers, no morphological changes are evident, and photobleaching is not observed when many images are taken. At higher powers, mitochondrial NAD(P)H fluorescence bleaches rapidly. To assess the limitations of this technique and to quantify the extent of photodamage, we have measured the effect of TPLSM on DNA synthesis. Although previous reports have indicated a threshold power for "safe" two-photon imaging, we find the laser power to be an insufficient indicator of photodamage. A more meaningful metric is a two-photon-absorbed dose that is proportional to the number of absorbed photon pairs. A temporary reduction of DNA synthesis in RBL cells occurs whenever a threshold dose of approximately 2 x 10(53) photon2 cm-4 s-1 is exceeded. This threshold is independent of laser intensity when imaging with average powers ranging from 5 to 17 mW at 740 nm. Beyond this threshold, the extent of the reduction is intensity dependent. DNA synthesis returns to control levels after a recovery period of several hours.
Many aspects of cellular function or physiology can be used to indicate the level of damage resulting from the application of potentially deleterious agents such as drugs, solvents or even light. The dose required to reach a specific biological endpoint will necessarily depend on the characteristics of the damage induced by the agent. By using multiple biological probes, it is possible to get a more complete description of the type of damage induced. Photodamage was induced in rat basophilic leukemia cells by either 254-nm UVC light exposure or rose bengal photosensitization. Damage was measured by three quantitative assays employing fluorescent probes: calcein, to measure nonspecific esterase activity, propidium iodide (PI), to measure loss of plasma membrane integrity, rhodamine 123 (R123) to measure mitochondrial depolarization, and the incorporation of 5'-bromodeoxyuridine (BrdU), to measure the progress of cell replication. BrdU incorporation was found to be the most sensitive indicator for both forms of photodamage. For UVC photodamage, the BrdU assay was 330 times more sensitive than the other two assays. For rose bengal photosensitization, the BrdU assay was 48 or 62 times more sensitive than either the R123 or calcein/PI assays, respectively.
Two-photon laser scanning microscopy (TPLSM) of endogenous reduced nicotinamide adenine dinucleotide (NAD(P)H) provides important information regarding the cellular metabolic state, When imaging the punctate mitochondria1 fluorescence originating from NAD(P)H in a rat basophilic leukemia (RBL) cell at low laser powers, no morphological changes are evident, and photobleaching is not observed when many images are taken. At higher powers, mitochondrial NAD(P)H fluorescence bleaches rapidly. To assess the limitations of this technique and to quantify the extent of photodamage, we have measured the effect of TPLSM on DNA synthesis. Although previous reports have indicated a threshold power for "safe" two-photon imaging, we find the laser power to be an insufficient indicator of photodamage. A more meaningful metric is a two-photon-absorbed dose that is proportional to the number of absorbed photon pairs. A temporary reduction of DNA synthesis in RBL cells occurs whenever a threshold dose of approximately 2 X photon' cm-4 s-' is exceeded. This threshold is independent of laser intensity when imaging with average powers ranging from 5 to 17 mW at 740 nm. Beyond this threshold, the extent of the reduction is intensity dependent. DNA synthesis returns to control levels after a recovery period of several hours.YPosted on the website
Many aspects of cellular function or physiology can be used to indicate the level of damage resulting from the application of potentially deleterious agents such as drugs, solvents or even light. The dose required to reach a specific biological endpoint will necessarily depend on the characteristics of the damage induced by the agent. By using multiple biological probes, it is possible to get a more complete description of the type of damage induced. Photodamage was induced in rat basophilic leukemia cells by either 254‐nm UVC light exposure or rose bengal photosensitization. Damage was measured by three quantitative assays employing fluorescent probes: calcein, to measure nonspecific esterase activity, propidium iodide (PI), to measure loss of plasma membrane integrity, rhodamine 123 (R123) to measure mitochondrial depolarization, and the incorporation of 5′‐bromodeoxyuridine (BrdU), to measure the progress of cell replication. BrdU incorporation was found to be the most sensitive indicator for both forms of photodamage. For UVC photodamage, the BrdU assay was 330 times more sensitive than the other two assays. For rose bengal photosensitization, the BrdU assay was 48 or 62 times more sensitive than either the R123 or calcein/PI assays, respectively.
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