Luciferase is a useful, noninvasive reporter of gene regulation that can be continuously monitored over long periods of time; however, its use is problematic in fast-growing microbes like bacteria and yeast because rapidly changing cell numbers and metabolic states also influence bioluminescence, thereby confounding the reporter's signal. Here we show that these problems can be overcome in the budding yeast Saccharomyces cerevisiae by simultaneously monitoring bioluminescence from two different colors of beetle luciferase, where one color (green) reports activity of a gene of interest, while a second color (red) is stably expressed and used to continuously normalize green bioluminescence for fluctuations in signal intensity that are unrelated to gene regulation. We use this dual-luciferase strategy in conjunction with a light-inducible promoter system to test whether different phases of yeast respiratory oscillations are more suitable for heterologous protein production than others. By using pulses of light to activate production of a green luciferase while normalizing signal variation to a red luciferase, we show that the early reductive phase of the yeast metabolic cycle produces more luciferase than other phases.
Genetic tractability, rapid growth, and simple nutritional requirements have made the budding yeast Saccharomyces cerevisiae an attractive eukaryotic microbe for producing industrially important heterologous proteins like insulin, hydrocortisone, growth hormones, and vaccines (1-4); however, production efficiency is always a chief concern when a microbe and growth strategy for producing protein are being chosen. Rhythmic production of proteins from oscillating cultures can be more efficient than steady-state production, especially for unstable proteins and those strongly affected by cell cycle-dependent proteases (5, 6). A respiratory oscillation manifests in yeast under specific conditions of continuous culture and exhibits 1-to 6-h rhythms of oxygen consumption, cell division, metabolite production, and gene expression (7-10), all of which may make certain phases of the oscillation better for rhythmic protein production than others.Monitoring production of heterologous proteins can be laborintensive; however, by producing a gene product that is easy to detect, the use of heterologous reporter genes can provide a noninvasive, automated way of measuring gene regulation and protein production in real time with high temporal fidelity. When a regulatory element(s) from a gene of interest is used to control expression of a reporter gene, the resulting reporter gene product provides an easily quantifiable surrogate that reflects gene regulation (and protein production) for the gene of interest. Luciferases from bacteria (11, 12), fireflies (8, 13), click beetles (14), and marine organisms like Renilla reniformis (15, 16) and Gaussia princeps (17) have been extensively used as reporter genes in a host of organisms ranging from microbes to animals and plants owing largely to luciferase's bioluminescent reac...
