• As the old saying goes, mother knows best. Many scientists, however, would argue that Mother Nature knows best. 
    Increasingly, researchers are turning to nature for inspiration and innovative solutions to human problems. From “green” cement to sustainable architecture to self-cleaning paint products, scientists and inventors are tapping into the power of this new field—biomimicry—to help them design more effective products. 
    Although there are many ways in which nature has inspired innovation, a hot topic among scientists studying biomimicry is bioluminescence, or the production of light by living organisms. Studying species ranging from deep-ocean dwellers—including fish, bacteria, and jellies—to fireflies, researchers are examining bioluminescent properties with an eye toward their potential human uses. While researchers are confident they understand the science of bioluminescence in nature, taking that property out of its biological environment and repurposing it for the human world has proven tricky. 
    “Evolution does a very good job of designing things to do what it wants them to do,” says Theo Sanderson, a geneticist at the Wellcome Trust Sanger Institute in the United Kingdom. 
    The difficulty is in adapting these properties for new uses. “We have a light-emitting system that is very good at functioning in the context of a bacterium and to emit the amount of light a bacterium needs to emit. When you transfer that over to other systems, there will be quite different biochemistry.”
    Sanderson’s experience with bioluminescence and biomimicry dates to 2010, when he and his colleagues at Cambridge University entered the International Genetically Engineered Machine (iGEM) competition.
    "We imagined that perhaps in the future, rather than erecting streetlights, people might be able to plant glowing trees," he says.
    To explore this idea, the team did some genetic modification. They took part of the DNA sequence of Aliivibrio fischeri, a bioluminescent bacterium that lives in symbiosis with squid, and inserted it into Escherichia coli, allowing E.coli to give off light. The project was cleverly dubbed “E. glowli.”
    Though the Cambridge team ultimately wasn’t able to produce bioluminescent trees, the “BioBrick” they did produce was later used by researchers at Peking University as part of the 2011 iGEM. The Peking researchers used the BioBrick to allow bacteria in different flasks to communicate by sending light signals. 
    Other researchers are exploring different potential applications for bioluminescence. Mathew Maye, a chemist at Syracuse University, works with an interdisciplinary team to explore bioluminescent properties at the nanoscale. Simply put, Maye’s team wants to “use biology for non-biological purposes.”
    Maye and his team use luciferase—an enzyme first identified in fireflies—to carry out their experiments. When luciferase interacts with luciferin, a related compound, the chemical reaction produces light. 
    Maye’s team is exploring applications that include identifying the presence of certain toxins within a system and lighting extremely small spaces. Currently, the team is trying to “completely understand the process and to judge the complete brightness of the system.”
    Recyclable Luminescence
    One issue that both Maye and Sanderson have confronted is how to make the light system self-sustaining. As Sanderson says, “We don’t know how to make the fuel that the luciferase runs on [luciferin], and that means that it’s expensive to work with because you have to add that fuel.” 
    Until researchers find a way to make the system “recyclable,” we may not see bioluminescent technology used to light our streets. 
    Serious breakthroughs, however, may be around the corner. 
    “We’re continually finding new, interesting scientific discoveries . . . that will help us to design the next generation,” says Maye. ". . . I would say that there will be some type of bioluminescent lighting within the next five to ten years. Especially if you can make it somehow replenishable or recyclable.”
    The iGEM competition, which launched Sanderson into the field of biomimicry, is held annually and supported by partners like the Federal Bureau of Investigation and software giant Autodesk. Maye’s research is funded in part by the Air Force and the Department of Defense. With the wide variety of potential applications for this technology, it’s no wonder both public and private industry are lining up to find out how they can take advantage of this emerging knowledge.
    Beyond the many practical applications of bioluminescent technology, biomimicry has captured researchers’ attention based on something far more fundamental: human curiosity. 
    As Sanderson says, “When you see what nature can achieve and the amazing diversity of things it can do—emitting light, producing incredibly strong substances—if you imagine what mankind could do if it could harness that power, it’s an exciting area to work in.”
    Everlasting Light
    Happiness is a warm germ? Scientists bask in the glow of genetically altered E.coli.
    Bioluminescent Camouflage
    The bioluminescent Aliivibrio fischeri bacterium lives in a symbiotic relationship with the bobtail squid. The bacteria live in organs inside the squid’s body and emit a soft blue light that prevents the squid from casting a shadow. This helps to camouflage it from predators. 
    Sustainable Christmas Trees?
    "We imagined that perhaps in the future, rather than erecting streetlights, people might be able to plant glowing trees."
    —Theo Sanderson, geneticist
  • Term Part of Speech Definition Encyclopedic Entry
    architecture Noun

    style and design of buildings or open spaces.

    bacteria Plural Noun

    (singular: bacterium) single-celled organisms found in every ecosystem on Earth.

    biochemistry Noun

    study of the chemicals and chemical processes found in living organisms.

    bioluminescence Noun

    light emitted by living things through chemical reactions in their bodies.

    Encyclopedic Entry: bioluminescence
    biomimicry Noun

    process of using models, systems, and elements of nature as a guide for developing new technology.

    E. coli Noun

    (Escherichia coli) common bacteria found in the digestive system of many animals. Some strains of E. coli are dangerous to people.

    emit Verb

    to give off or send out.

    enzyme Noun

    proteins produced in living cells that act as catalysts to accelerate the vital processes of an organism.

    geneticist Noun

    scientist who studies the chemistry, behavior, and purposes of DNA, genes, and chromosomes.

    genetic modification Noun

    process of altering the genes of an organism.

    innovative Adjective

    new, advanced, or original.

    inspiration Noun

    something that influences the development of an idea.

    interdisciplinary Adjective

    having to do with more than one academic subject, or discipline.

    luciferase Noun

    enzyme (catalyst) that reacts with a substrate (luciferin) in a chemical reaction that results in bioluminescence.

    luciferin Noun

    organic substances that upon oxidation produce a virtually heatless light (bioluminescence).

    nanoscale Noun

    length scale whose relevant unit of measurement is the nanometer (nm), or a billionth of a meter. Also called the nanoscopic scale.

    potential Noun


    private industry Noun

    business not funded by the government.

    public Adjective

    available to an entire community, not limited to paying members.

    sustainable Adjective

    able to be continued at the same rate for a long period of time.

    symbiosis Noun

    two or more distinct organisms living together for the benefit of one or both.

    technology Noun

    the science of using tools and complex machines to make human life easier or more profitable.

    toxin Noun

    poisonous substance, usually one produced by a living organism.


National Science Foundation

This material is based in part upon work supported by the National Science Foundation under Grant No. DRL-1114251. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author and do not necessarily reflect the views of the National Science Foundation.