An investigation of the reaction kinetics of luciferase and the effect of ionizing radiation on the reaction rate.

The bioluminescence produced by luciferase, a firefly enzyme, requires three substrates: luciferin, ATP and oxygen. We find that ionizing radiation, in the form of a proton beam from a cyclotron, will eliminate dissolved oxygen prior to any damage to other substrates or to the protein. The dose constant for removal of oxygen is 70 +/- 20 Gy, a much smaller dose than required to cause damage to protein. Removal of oxygen, which is initially in excess, leads to a sigmoidal response of bioluminescence to radiation dose, consistent with a Michaelis-Menten relationship to substrate concentration. When excess oxygen is exhausted, the response becomes exponential. Following the irradiation, bioluminescence recovers due to a slow leak of oxygen into the solution. This may also explain previous observations on the response of bioluminescent bacteria to radiation. We have studied the dependence of the reaction rate on enzyme and substrate concentration and propose a model for the reaction pathway consistent with this data. The light output from unirradiated samples decreases significantly with time due to product inhibition. We observe that this inhibition rate changes dramatically immediately after a sample is exposed to the beam. This sudden change of the inhibition rate is unexplained but shows that enzyme regulatory function responds to ionizing radiation at a dose level less than 0.6 Gy.

Single-cell imaging of c-fos expression in rat primary hippocampal cells using a luminescence microscope.

Methods to study gene expression in live cells over time have been limited. One known method is the luciferase assay, which measures the luminescence of luciferase by coupling its expression to the promoter of a gene under study. This luminescence in cells can be measured over time by a luminometer. One major drawback of the luminometer, however, is that it can only measure the luminescence of a group of cells, and cannot follow the differences that may exist among individual cells. A novel luminescence microscope allows the visualization of individual luminescent cells over time through CCD photography. In this study, live single cells of the rat hippocampus were observed under the microscope for luciferase expression driven by the c-fos promoter. We showed that the cell body and neurite areas within a single neuron exhibited differences in luminescence. Because this microscope could detect differences among subcellular regions of single-cell, it may be a promising novel tool to study polarized cells like neurons, and to elucidate proteins involved in neuronal processes such as dendritic/axonal targeting and synaptogenesis.

The kinetics of radiation damage to the protein luciferase and recovery of enzyme activity after irradiation.

Experimental observations are reported which follow the bioluminescence intensity of luciferase during irradiation by a 5 MeV proton beam. Bioluminescence is a measure of the protein enzyme activity and provides an assay of the enzyme rate of reaction in real time. Transient responses after a pulse of protons show recovery of the reaction rate with two time constants of 0.3 s(-1) and 0.01 s(-1). Changes in the reaction rate are due to radiation damage to the active form of the protein luciferase. Quantitative analysis of the radiation damage and recovery of the protein shows that products of the radiolysis of water play major part in the process of enzyme damage at room temperature. A few minutes after the pulse of protons, most of the enzyme activity has recovered. We attribute the fast recovery to the removal of charged ions, while the slow recovery involves refolding of denatured protein.

A critical analysis of the use of radiation inactivation to measure the mass of protein.

Measurements are presented of the radiation inactivation of four enzymes exposed to a 6 MeV proton beam. It has long been thought that the measurement of the susceptibility of an enzyme to ionizing radiation can be used to determine its molecular mass. Results are frequently interpreted using the empirical analysis of Kempner and Macey (Biochim. Biophys. Acta 163, 188-203, 1963). We examine this analysis and discuss the validity and limitations of the assumptions on which it is based. Our results indicate that the specific biochemical properties of each enzyme make a significant contribution to its radiation sensitivity.