Visible light alters yeast metabolic rhythms by inhibiting respiration

Robertson, J. Brian; Davis, Chris; Johnson, Carl Hirschie

doi:10.1073/pnas.1313369110

Cited by 75 publications

(75 citation statements)

References 45 publications

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“…Alternatively, the Cry2 and Cib1 proteins from plants dimerize in the presence of blue light, which can in turn be used to activate a modified bacterial lexA promoter (28,34). And although we have previously shown that intense visible light perturbs the yeast oscillation, we have also shown that intensities less than 100 E/m 2 /s have little effect on the oscillation (9). A lightinducible promoter system offers the advantages of a heterologous gene control system that can be rapidly activated or inactivated without adding chemicals to the culture or disturbing the oscillation.…”

Section: Figmentioning

confidence: 71%

“…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)(8)(9)(10), all of which may make certain phases of the oscillation better for rhythmic protein production than others.…”

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confidence: 99%

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Dual-Color Monitoring Overcomes the Limitations of Single Bioluminescent Reporters in Fast-Growing Microbes and Reveals Phase-Dependent Protein Productivity during the Metabolic Rhythms of Saccharomyces cerevisiae

Krishnamoorthy

Robertson

2015

Appl Environ Microbiol

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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...

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Section: Figmentioning

confidence: 71%

mentioning

confidence: 99%

Dual-Color Monitoring Overcomes the Limitations of Single Bioluminescent Reporters in Fast-Growing Microbes and Reveals Phase-Dependent Protein Productivity during the Metabolic Rhythms of Saccharomyces cerevisiae

Krishnamoorthy

Robertson

2015

Appl Environ Microbiol

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“…The growth of yeast strains that are null for the yeast activator protein-1 gene that regulates oxidative stress genes is exquisitely sensitive to visible light. This reveals that light can both modulate respiration and induce oxidative stress [7].…”

Section: Plants and Animalsmentioning

confidence: 94%

Chronobiology and circadian rhythms establish a connection to diagnosis

Nydegger

Escobar

Risch³

et al. 2014

Diagnosis

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Circadian rhythms are synchronized by the light/dark (L/D) cycle over the 24-h day. A suprachiasmatic nucleus in the hypothalamus governs time keeping based on melanopsin messages from the retina in the eyes and transduces regulatory signals to tissues through an array of hormonal, metabolic and neural outputs. Currently, vague impressions on circadian regulation in health and disease are replaced by scientific facts: in addition to L/D cyling, oscillation is maintained by genetic (Clock, Bmal1, Csnk1, CHRONO, Cry, Per) programs, autonomous feedback loops, including melatonin activities, aerobic glycolysis intensity and lipid signalling, among others. Such a multifaceted influential system on circadian rhythm is bound to be fragile and genomic clock acitvities can become disrupted by epigenetic modifications or such environmental factors as mistimed sleep and feeding schedules albeit leaving the centrally driven melatonindependent pacemakter more or less unaffected.

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“…Some researchers have proposed that high-frequency metabolic feedback loops—under selective pressure from the daily environment—were recruited to coalescence of an approximately daily period (16). Another model for the evolution of circadian timing—the so-called escape-from light hypothesis (7, 143, 144)—posits that light can damage cellular metabolism (e.g., DNA damage caused by UV light), which could have been a selective force for the evolution of circadian pacemakers. Briefly, the escape-from-light hypothesis proposes that light during the sunlit portion of the daily cycle had profound and mostly deleterious effects on early life; therefore, phasing cellular processes that are hypersensitive to light so that they occur in the dark nighttime may have driven the early evolution of circadian timers.…”

Section: Evolution Of Circadian Systems: Did Metabolic Cycles Play a mentioning

confidence: 99%

“…The authors of this paper suggested that most organisms that survived the transition to an aerobic environment 2.5 billion years ago were those that respired and/or evolved oxygen. Electron-transport chains involving oxygen inevitably produce ROS by-products, and due to daily cycles of photosynthesis and metabolism driven by daily LD and temperature changes, these ROS were produced rhythmically over the span of the daily cycle (113, 144). Therefore, a system to anticipate and manage the concomitant daily generation of intracellular ROS was adaptive.…”

Section: Evolution Of Circadian Systems: Did Metabolic Cycles Play a mentioning

confidence: 99%

Metabolic Compensation and Circadian Resilience in Prokaryotic Cyanobacteria

Johnson

Egli

2014

Annu. Rev. Biochem.

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For a biological oscillator to function as a circadian pacemaker that confers a fitness advantage, its timing functions must be stable in response to environmental and metabolic fluctuations. One such stability enhancer, temperature compensation, has long been a defining characteristic of these timekeepers. However, an accurate biological timekeeper must also resist changes in metabolism, and this review suggests that temperature compensation is actually a subset of a larger phenomenon, namely metabolic compensation, which maintains the frequency of circadian oscillators in response to a host of factors that impinge on metabolism and would otherwise destabilize these clocks. The circadian system of prokaryotic cyanobacteria is an illustrative model because it is composed of transcriptional and nontranscriptional oscillators that are coupled to promote resilience. Moreover, the cyanobacterial circadian program regulates gene activity and metabolic pathways, and it can be manipulated to improve the expression of bioproducts that have practical value.

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Visible light alters yeast metabolic rhythms by inhibiting respiration

Cited by 75 publications

References 45 publications

Dual-Color Monitoring Overcomes the Limitations of Single Bioluminescent Reporters in Fast-Growing Microbes and Reveals Phase-Dependent Protein Productivity during the Metabolic Rhythms of Saccharomyces cerevisiae

Dual-Color Monitoring Overcomes the Limitations of Single Bioluminescent Reporters in Fast-Growing Microbes and Reveals Phase-Dependent Protein Productivity during the Metabolic Rhythms of Saccharomyces cerevisiae

Chronobiology and circadian rhythms establish a connection to diagnosis

Metabolic Compensation and Circadian Resilience in Prokaryotic Cyanobacteria

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