Toshiteru Enomoto

cDNA Cloning and Characterization of a Secreted Luciferase from the Luminous Japanese Ostracod, Cypridina noctiluca

A secreted luciferase from the marine ostracod, Vargula hilgendorfii, is a useful tool for gene expression assays in living mammalian cells. We have cloned the cDNA of a new secreted luciferase from the ostracod Cypridina noctiluca, which inhabits the coast of Japan. C. noctiluca luciferase consists of 553 amino acid residues with a molecular mass of 61,415 Da, as deduced from the nucleotide sequence. The homologies of nucleotide and amino acid sequences with V. hilgendorfii luciferase are 79.2% and 83.1%, respectively. C. noctiluca luciferase can expressed in and secreted from cultured mammalian cells. The characteristic properties of expressed C. noctiluca luciferase are similar to those of V. hilgendorfii luciferase. However, the activity of C. noctiluca luciferase in culture medium is much higher than that of V. hilgendorfii luciferase, suggesting that C. noctiluca luciferase is a highly potent reporter enzyme for real-time and continuous monitoring of gene expression in living cells.

Multicolor luciferase assay system: one-step monitoring of multiple gene expressions with a single substrate

Reporter assays that use luciferase are widely employed for monitoring cellular events associated with gene expression. In general, firefly luciferase and Renilla luciferase are used for monitoring single gene expression. However, the expression of more than one gene cannot be monitored simultaneously by this system because one of the two reporting luciferases must be used as an internal control. We have developed a novel reporter assay system in which three luciferases that emit green, orange, and red light with a single substrate are used as reporter genes. The activities of the luciferases can be measured simultaneously and quantitatively with optical filters. This system enables us to simply and rapidly monitor multiple gene expressions in a one-step reaction.

Development of a Quantitative Bio/Chemiluminescence Spectrometer Determining Quantum Yields: Re-examination of the Aqueous Luminol Chemiluminescence Standard

We have developed a bio/chemiluminescence spectrometer with a cooled charge‐coupled‐device (CCD) detector to obtain a quantitative luminescence spectrum as the absolute number of all emitted photons at each wavelength. The integrated area of the spectrum divided by the number of reacted substrate molecules gives the quantum yield. Calibration of the absolute sensitivity of the CCD‐spectrometer system was performed by using lasers and a tungsten lamp with calibrated powers as primary light standards, and calibration of the light‐collection efficiency of the spectrometer with several kinds of cells for liquid samples was achieved by introducing a simple reference double‐plate cell. The reference cell is not convenient for final bio/chemiluminescence measurements but is useful for the calibration because it has well‐defined angular dependence of light emission, allowing accurate calculation of the light‐collection efficiency. Using this CCD‐spectrometer system, we re‐examined the quantum yield of aqueous luminol chemiluminescence with H2O2 catalyzed by horseradish peroxidase. The quantum yield was constant for a wide range of luminol concentrations, whereas it changed and had an optimum against H2O2 concentrations. The optimum quantum yield was 1.23(±0.20)%, which is in good agreement with previously reported values.

Bioluminescence imaging of dual gene expression at the single-cell level

Bioluminescence imaging reveals the long-term dynamics of individual gene expression in a single cell. However, methods for simultaneously imaging multiple gene expression patterns have been unknown to date. Here, we constructed a dual-path optical luminescence imaging system using a two-color reporter system and could simultaneously track two gene expression patterns for several days in a single cell.

Multichannel perfusion culture bioluminescence reporter system for long-term detection in living cells

We constructed a multichannel perfusion culture system. Using this device, we developed a perfusion device to detect six samples at the same time and demonstrated the response to dexamethasone of the circadian-related promoter activity in Rat1 fibroblast cells. We could detect the sequential phase shifts of the circadian peaks that are dependent on the timing of the drug treatments. We also demonstrate a temporal dual reporter assay using two kinds of secreted luciferase in the perfusion culture. The combination of secreted luciferase and multiple perfusion culture assay system reveals the effects of transient drug treatment for the pharmacological assay.

Absolute bioluminescence imaging at the single-cell level with a light signal at the Attowatt level

Bioluminescence imaging (BLI) demonstrates cellular events as a light signal at the single-cell level using a highly sensitive, cooled CCD camera. However, BLI signals are relative values and thus, images taken on different days or using different equipment cannot be compared directly. We established a reference LED light source that was characteristic of the total flux and light distribution and calibrated the BLI system as an absolute light signal. This calibrated BLI system revealed that the average light signal of beetle luciferase was at an attowatt level per sec at the single cell level.