Bioluminescent bacteria are light-producing

bacteria Bacteria (; singular: bacterium) are ubiquitous, mostly free-living organisms often consisting of one biological cell. They constitute a large domain of prokaryotic microorganisms. Typically a few micrometres in length, bacteria were among ...

that are predominantly present in sea water, marine sediments, the surface of decomposing fish and in the gut of marine animals. While not as common, bacterial bioluminescence is also found in terrestrial and freshwater bacteria. These bacteria may be free living (such as ''

Vibrio harveyi ''Vibrio harveyi'' is a Gram-negative, bioluminescent, marine bacterium in the genus ''Vibrio''. ''V. harveyi'' is rod-shaped, motile (via polar flagella), facultatively anaerobic, halophilic, and competent for both fermentative and respiratory ...

'') or in symbiosis with animals such as the Hawaiian Bobtail squid (''

Aliivibrio fischeri ''Aliivibrio fischeri'' (also called ''Vibrio fischeri'') is a Gram-negative, rod-shaped bacterium found globally in marine environments. This species has bioluminescent properties, and is found predominantly in symbiosis with various marine an ...

'') or terrestrial

nematode The nematodes ( or grc-gre, Νηματώδη; la, Nematoda) or roundworms constitute the phylum Nematoda (also called Nemathelminthes), with plant-Parasitism, parasitic nematodes also known as eelworms. They are a diverse animal phylum inhab ...

s (''

Photorhabdus luminescens ''Photorhabdus luminescens'' (previously called ''Xenorhabdus luminescens'') is a Gammaproteobacterium of the family Morganellaceae, and is a lethal pathogen of insects. It lives in the gut of an entomopathogenic nematode of the family Heteror ...

''). The host organisms provide these bacteria a safe home and sufficient nutrition. In exchange, the hosts use the light produced by the bacteria for camouflage, prey and/or mate attraction. Bioluminescent bacteria have evolved symbiotic relationships with other organisms in which both participants benefit close to equally. Another possible reason bacteria use luminescence reaction is for

quorum sensing In biology, quorum sensing or quorum signalling (QS) is the ability to detect and respond to cell population density by gene regulation. As one example, QS enables bacteria to restrict the expression of specific genes to the high cell densities at ...

, an ability to regulate gene expression in response to bacterial cell density.

History

Records of bioluminescent bacteria existed for thousands of years. They appear in the folklore of many regions, including Scandinavia and the Indian subcontinent. Both

Aristotle Aristotle (; grc-gre, Ἀριστοτέλης ''Aristotélēs'', ; 384–322 BC) was a Greek philosopher and polymath during the Classical period in Ancient Greece. Taught by Plato, he was the founder of the Peripatetic school of phil ...

and

Charles Darwin Charles Robert Darwin ( ; 12 February 1809 – 19 April 1882) was an English naturalist, geologist, and biologist, widely known for his contributions to evolutionary biology. His proposition that all species of life have descended fr ...

have described the phenomenon of the oceans glowing. Since its discovery less than 30 years ago, the enzyme

luciferase Luciferase is a generic term for the class of oxidative enzymes that produce bioluminescence, and is usually distinguished from a photoprotein. The name was first used by Raphaël Dubois who invented the words ''luciferin'' and ''luciferase'', ...

and its regulatory gene, ''lux'', have led to major advances in molecular biology, through use as a reporter gene.

Luciferase Luciferase is a generic term for the class of oxidative enzymes that produce bioluminescence, and is usually distinguished from a photoprotein. The name was first used by Raphaël Dubois who invented the words ''luciferin'' and ''luciferase'', ...

was first purified by McElroy and Green in 1955. It was later discovered that there were two subunits to luciferase, called subunits α and β. The genes encoding these enzymes, ''luxA'' and ''luxB,'' respectively, were first isolated in the ''lux'' operon of ''Aliivibrio fisheri''''.''

Purpose of bio-luminescence

The wide-ranged biological purposes of bio-luminescence include but are not limited to attraction of mates, defense against predators, and warning signals. In the case of bioluminescent bacteria, bio-luminescence mainly serves as a form of dispersal. It has been hypothesized that enteric bacteria (bacteria that survive in the guts of other organisms) - especially those prevalent in the depths of the ocean - employ bio-luminescence as an effective form of distribution. After making their way into the digestive tracts of fish and other marine organisms and being excreted in fecal pellets, bioluminescent bacteria are able to utilize their bio-luminescent capabilities to lure in other organisms and prompt ingestion of these bacterial-containing fecal pellets. The bio-luminescence of bacteria thereby ensures their survival, persistence, and dispersal as they are able to enter and inhabit other organisms.

Regulation of bio-luminescence

The regulation of bio-luminescence in bacteria is achieved through the regulation of the oxidative enzyme called

. It is important that bio-luminescent bacteria decrease production rates of luciferase when the population is sparse in number in order to conserve energy. Thus, bacterial bioluminescence is regulated by means of chemical communication referred to as

. Essentially, certain signaling molecules named

autoinducer Autoinducers are signaling molecules that are produced in response to changes in cell-population density. As the density of quorum sensing bacterial cells increases so does the concentration of the autoinducer. Detection of signal molecules by ba ...

s with specific bacterial receptors become activated when the population density of bacteria is high enough. The activation of these receptors leads to a coordinated induction of luciferase production that ultimately yields visible

luminescence Luminescence is spontaneous emission of light by a substance not resulting from heat; or "cold light". It is thus a form of cold-body radiation. It can be caused by chemical reactions, electrical energy, subatomic motions or stress on a cryst ...

Biochemistry of bio-luminescence

The chemical reaction that is responsible for bio-luminescence is catalyzed by the enzyme

. In the presence of oxygen, luciferase catalyzes the oxidation of an organic molecule called

luciferin Luciferin (from the Latin ''lucifer'', "light-bearer") is a generic term for the light-emitting compound found in organisms that generate bioluminescence. Luciferins typically undergo an enzyme-catalyzed reaction with molecular oxygen. The result ...

. Though bio-luminescence across a diverse range of organisms such as bacteria, insects, and dinoflagellates function in this general manner (utilizing luciferase and luciferin), there are different types of luciferin-luciferase systems. For bacterial bio-luminescence specifically, the biochemical reaction involves the oxidation of an

aliphatic In organic chemistry, hydrocarbons ( compounds composed solely of carbon and hydrogen) are divided into two classes: aromatic compounds and aliphatic compounds (; G. ''aleiphar'', fat, oil). Aliphatic compounds can be saturated, like hexane, or ...

aldehyde In organic chemistry, an aldehyde () is an organic compound containing a functional group with the structure . The functional group itself (without the "R" side chain) can be referred to as an aldehyde but can also be classified as a formyl grou ...

by a reduced

flavin mononucleotide Flavin mononucleotide (FMN), or riboflavin-5′-phosphate, is a biomolecule produced from riboflavin (vitamin B2) by the enzyme riboflavin kinase and functions as the prosthetic group of various oxidoreductases, including NADH dehydrogenase, as ...

. The products of this oxidation reaction include an oxidized flavin mononucleotide, a fatty acid chain, and energy in the form of a blue-green visible light. Reaction: FMNH₂ + O₂ + RCHO → FMN + RCOOH + H₂O + light

Evolution of bio-luminescence

Of all light emitters in the ocean, bio-luminescent bacteria is the most abundant and diverse. However, the distribution of bio-luminescent bacteria is uneven, which suggests evolutionary adaptations. The bacterial species in terrestrial genera such as

Photorhabdus ''Photorhabdus'' is a genus of bioluminescent, gram-negative bacilli which lives symbiotically within entomopathogenic nematodes, hence the name ''photo'' (which means light producing) and ''rhabdus'' (rod shape). ''Photorhabdus'' is known to be ...

are bio-luminescent. On the other hand, marine genera with bio-luminescent species such as

Vibrio ''Vibrio'' is a genus of Gram-negative bacteria, possessing a curved-rod (comma) shape, several species of which can cause foodborne infection, usually associated with eating undercooked seafood. Being highly salt tolerant and unable to survive ...

and

Shewanella oneidensis ''Shewanella oneidensis'' is a bacterium notable for its ability to reduce metal ions and live in environments with or without oxygen. This proteobacterium was first isolated from Lake Oneida, NY in 1988, hence its name. ''S. oneidensis'' is a ...

have different closely related species that are not light emitters. Nevertheless, all bio-luminescent bacteria share a common gene sequence: the enzymatic oxidation of

Aldehyde In organic chemistry, an aldehyde () is an organic compound containing a functional group with the structure . The functional group itself (without the "R" side chain) can be referred to as an aldehyde but can also be classified as a formyl grou ...

and reduced

Flavin mononucleotide Flavin mononucleotide (FMN), or riboflavin-5′-phosphate, is a biomolecule produced from riboflavin (vitamin B2) by the enzyme riboflavin kinase and functions as the prosthetic group of various oxidoreductases, including NADH dehydrogenase, as ...

which are contained in the lux operon. Bacteria from distinct ecological niches contain this gene sequence; therefore, the identical gene sequence evidently suggests that bio-luminescence bacteria result from evolutionary adaptations.

Use as laboratory tool

After the discovery of the lux operon, the use of bioluminescent bacteria as a laboratory tool is claimed to have revolutionized the area of environmental microbiology. The applications of bioluminescent bacteria include biosensors for detection of contaminants, measurement of pollutant toxicity and monitoring of genetically engineered bacteria released into the environment. Biosensors, created by placing a ''lux'' gene construct under the control of an inducible promoter, can be used to determine the concentration of specific pollutants. Biosensors are also able to distinguish between pollutants that are bioavailable and those that are inert and unavailable. For example, ''Pseudomonas fluorescens'' has been genetically engineered to be capable of degrading salicylate and naphthalene, and is used as a biosensor to assess the bioavailability of salicylate and naphthalene. Biosensors can also be used as an indicator of cellular metabolic activity and to detect the presence of pathogens.

Evolution

The light-producing chemistry behind bioluminescence varies across the lineages of bioluminescent organisms. Based on this observation, bioluminescence is believed to have evolved independently at least 40 times. In bioluminescent bacteria, the reclassification of the members of''Vibrio fischeri'' species group as a new genus, ''Aliivibrio,'' has led to increased interest in the evolutionary origins of bioluminescence''.'' Among bacteria, the distribution of bioluminescent species is polyphyletic. For instance, while all species in the terrestrial genus ''Photorhabdus'' are luminescent, the genera ''Aliivibrio, Photobacterium, Shewanella'' and ''Vibrio'' contain both luminous and non-luminous species. Despite

bioluminescence Bioluminescence is the production and emission of light by living organisms. It is a form of chemiluminescence. Bioluminescence occurs widely in marine vertebrates and invertebrates, as well as in some fungi, microorganisms including some b ...

in bacteria not sharing a common origin, they all share a gene sequence in common. The appearance of the highly conserved lux operon in bacteria from very different ecological niches suggests a strong selective advantage despite the high energetic costs of producing light. DNA repair is thought to be the initial selective advantage for light production in bacteria. Consequently, the lux operon may have been lost in bacteria that evolved more efficient DNA repair systems but retained in those where visible light became a selective advantage. The evolution of quorum sensing is believed to have afforded further selective advantage for light production.

Quorum sensing In biology, quorum sensing or quorum signalling (QS) is the ability to detect and respond to cell population density by gene regulation. As one example, QS enables bacteria to restrict the expression of specific genes to the high cell densities at ...

allows bacteria to conserve energy by ensuring that they do not synthesize light-producing chemicals unless a sufficient concentration are present to be visible.

Bacterial groups that exhibit bioluminescence

All bacterial species that have been reported to possess bioluminescence belong within the families ''

Vibrionaceae The Vibrionaceae are a family of Pseudomonadota given their own order, Vibrionales. Inhabitants of fresh or salt water, several species are pathogenic, including the type species ''Vibrio cholerae'', which is the agent responsible for cholera. ...

'', ''

Shewanellaceae ''Shewanella'' is the sole genus included in the marine bacteria family Shewanellaceae. Some species within it were formerly classed as ''Alteromonas''. ''Shewanella'' consists of facultatively anaerobic Gram-negative rods, most of which are fou ...

'', or ''

Enterobacteriaceae Enterobacteriaceae is a large family (biology), family of Gram-negative bacteria. It was first proposed by Rahn in 1936, and now includes over 30 genera and more than 100 species. Its classification above the level of family is still a subject ...

'', all of which are assigned to the class

Gammaproteobacteria Gammaproteobacteria is a class of bacteria in the phylum Pseudomonadota (synonym Proteobacteria). It contains about 250 genera, which makes it the most genera-rich taxon of the Prokaryotes. Several medically, ecologically, and scientifically imp ...

. (List from Dunlap and Henryk (2013), "Luminous Bacteria", ''The Prokaryotes'' )

Distribution

Bioluminescent bacteria are most abundant in marine environments during spring blooms when there are high nutrient concentrations. These light-emitting organisms are found mainly in coastal waters near the outflow of rivers, such as the northern Adriatic Sea, Gulf of Trieste, northwestern part of the Caspian Sea, coast of Africa and many more. These are known as milky seas. Bioluminescent bacteria are also found in freshwater and terrestrial environments but are less wide spread than in seawater environments. They are found globally, as free-living, symbiotic or parasitic forms and possibly as

opportunistic pathogens An opportunistic infection is an infection caused by pathogens (bacteria, fungi, parasites or viruses) that take advantage of an opportunity not normally available. These opportunities can stem from a variety of sources, such as a weakened immune ...

. Factors that affect the distribution of bioluminescent bacteria include temperature, salinity, nutrient concentration, pH level and solar radiation. For example, ''Aliivibrio'' ''fischeri'' grows favourably in environments that have temperatures between 5 and 30 °C and a pH that is less than 6.8; whereas, ''

Photobacterium phosphoreum ''Photobacterium phosphoreum'' or ''Vibrio phosphoreum'' is a Gram-negative bioluminescence, bioluminescent bacterium living in symbiosis with marine organisms, such as anglerfish. It can emit bluish-green light (490 nm) due to a chemical r ...

'' thrives in conditions that have temperatures between 5 and 25 °C and a pH that is less than 7.0.

Genetic diversity

All bioluminescent bacteria share a common gene sequence: the ''lux'' operon characterized by the ''luxCDABE'' gene organization. ''LuxAB'' codes for luciferase while ''luxCDE'' codes for a fatty-acid reductase complex that is responsible for synthesizing aldehydes for the bioluminescent reaction. Despite this common gene organization, variations, such as the presence of other lux genes, can be observed among species. Based on similarities in gene content and organization, the ''lux'' operon can be organized into the following four distinct types: the ''Aliivibrio''/''Shewanella'' type, the ''Photobacterium'' type, the''Vibrio''/''Candidatus'' Photodesmus type, and the ''Photorhabdus'' type. While this organization follows the genera classification level for members of ''

'' (''

Aliivibrio ''Aliivibrio'' is a genus in the phylum Pseudomonadota (Bacteria). Etymology The name ''Aliivibrio'' derives from: Latin ', other, another, different; New Latin ''Vibrio'', a bacterial genus name, to give ''Aliivibrio'', the other ''Vibrio''. S ...

'', ''

Photobacterium ''Photobacterium'' is a genus of gram-negative, oxidase positive and catalase positive bacteria in the family ''Vibrionaceae''. Members of the genus are bioluminescent, that is they have the ability to emit light. Many species, including '' Pho ...

'', and ''

''), its evolutionary history is not known. With the exception of the ''Photorhabdus'' operon type, all variants of the ''lux'' operon contain the flavin reductase-encoding ''luxG'' gene. Most of the ''Aliivibrio''/''Shewanella'' type operons contain additional ''luxI/luxR'' regulatory genes that are used for autoinduction during

. The ''Photobacterum'' operon type is characterized by the presence of ''rib'' genes that code for riboflavin, and forms the ''lux-rib'' operon''.'' The''Vibrio''/''Candidatus'' Photodesmus operon type differs from both the ''Aliivibrio''/''Shewanella'' and the ''Photobacterium'' operon types in that the operon has no regulatory genes directly associated with it.

Mechanism

All bacterial luciferases are approximately 80 KDa heterodimers containing two subunits: α and β. The α subunit is responsible for light emission. The ''luxA'' and ''luxB'' genes encode for the α and β subunits, respectively. In most bioluminescent bacteria, the ''luxA'' and ''luxB'' genes are flanked upstream by ''luxC'' and ''luxD'' and downstream by ''luxE''. The bioluminescent reaction is as follows: FMNH₂ + O₂ + R-CHO -> FMN + H₂O + R-COOH + Light (~ 495 nm) Molecular oxygen reacts with FMNH₂ (reduced flavin mononucleotide) and a long-chain aldehyde to produce FMN (flavin mononucleotide), water and a corresponding fatty acid. The blue-green light emission of bioluminescence, such as that produced by ''

'' and '' Vibro harveyi'', results from this reaction. Because light emission involves expending six ATP molecules for each photon, it is an energetically expensive process. For this reason, light emission is not constitutively expressed in bioluminescent bacteria; it is expressed only when physiologically necessary.

Quorum sensing

Bioluminescence in bacteria can be regulated through a phenomenon known as autoinduction or

. Quorum sensing is a form of cell-to-cell communication that alters gene expression in response to cell density. Autoinducer is a diffusible pheromone produced constitutively by bioluminescent bacteria and serves as an extracellular signalling molecule. When the concentration of autoinducer secreted by bioluminescent cells in the environment reaches a threshold (above 10⁷ cells per mL), it induces the expression of luciferase and other enzymes involved in bioluminescence. Bacteria are able to estimate their density by sensing the level of autoinducer in the environment and regulate their bioluminescence such that it is expressed only when there is a sufficiently high cell population. A sufficiently high cell population ensures that the bioluminescence produced by the cells will be visible in the environment. A well known example of quorum sensing is that which occurs between ''

'' and its host. This process is regulated by LuxI and LuxR, encoded by ''luxI'' and ''luxR'' respectively. LuxI is autoinducer synthase that produces autoinducer (AI) while LuxR functions as both a receptor and transcription factor for the lux operon. When LuxR binds AI, LuxR-AI complex activates transcription of the lux operon and induces the expression of

. Using this system, '' A. fischeri'' has shown that

is expressed only when the bacteria are host-associated and have reached sufficient cell densities. Another example of quorum sensing by bioluminescent bacteria is by ''

'', which are known to be free-living. Unlike ''

,'' '' V. harveyi'' do not possess the ''luxI/luxR'' regulatory genes and therefore have a different mechanism of quorum sensing regulation. Instead, they use the system known as three-channel quorum sensing system.

Role

The uses of

and its biological and ecological significance for animals, including host organisms for bacteria symbiosis, have been widely studied. The biological role and evolutionary history for specifically bioluminescent bacteria still remains quite mysterious and unclear. However, there are continually new studies being done to determine the impacts that bacterial bioluminescence can have on our constantly changing environment and society. Aside from the many scientific and medical uses, scientists have also recently begun to come together with artists and designers to explore new ways of incorporating bioluminescent bacteria, as well as bioluminescent plants, into urban light sources to reduce the need for electricity. They have also begun to use bioluminescent bacteria as a form of art and urban design for the wonder and enjoyment of human society. One explanation for the role of bacterial bioluminescence is from the biochemical aspect. Several studies have shown the biochemical roles of the luminescence pathway. It can function as an alternate pathway for electron flow under low oxygen concentration, which can be advantageous when no fermentable substrate is available. In this process, light emission is a side product of the metabolism. Evidence also suggests that bacterial luciferase contributes to the resistance of oxidative stress. In laboratory culture, ''luxA'' and ''luxB'' mutants of ''

'', which lacked luciferase activity, showed impairment of growth under high oxidative stress compared to wild type. The ''luxD'' mutants, which had an unaffected luciferase but were unable to produce luminescence, showed little or no difference. This suggests that luciferase mediates the detoxification of reactive oxygen. Bacterial bioluminescence has also been proposed to be a source of internal light in photoreactivation, a DNA repair process carried out by photolyase. Experiments have shown that non-luminescent '' V. harveyi'' mutants are more sensitive to UV irradiation, suggesting the existence of a bioluminescent-mediated DNA repair system. Another hypothesis, called the “bait hypothesis”, is that bacterial bioluminescence attracts predators who will assist in their dispersal. They are either directly ingested by fish or indirectly ingested by zooplankton that will eventually be consumed by higher trophic levels. Ultimately, this may allow passage into the fish gut, a nutrient-rich environment where the bacteria can divide, be excreted, and continue their cycle. Experiments using luminescent '' Photobacterium leiognathi'' and non-luminescent mutants have shown that luminescence attracts zooplankton and fish, thus supporting this hypothesis.

Symbiosis with other organisms

The symbiotic relationship between the Hawaiian bobtail squid ''Euprymna scolopes'' and the marine gram-negative bacterium ''

'' has been well studied. The two organisms exhibit a mutualistic relationship in which bioluminescence produced by '' A. fischeri'' helps to attract pray to the squid host, which provides nutrient-rich tissues and a protected environment for'' A. fischeri''. Bioluminescence provided by '' A. fischeri'' also aids in the defense of the squid '' E. scolopes'' by providing camouflage during its nighttime foraging activity. Following bacterial colonization, the specialized organs of the squid undergo developmental changes and a relationship becomes established. The squid expels 90% of the bacterial population each morning, because it no longer needs to produce bioluminescence in the daylight. This expulsion benefits the bacteria by aiding in their dissemination. A single expulsion by one bobtail squid produces enough bacterial symbionts to fill 10,000m³ of seawater at a concentration that is comparable to what is found in coastal waters. Thus, in at least some habitats, the symbiotic relationship between '' ''A. fischeri'''' and '' ''E. scolopes'''' plays a key role in determining the abundance and distribution of '' ''E. scolopes''.'' There is a higher abundance of '' ''A. fischeri'''' in the vicinity of a population of ''E. scolopes'' and this abundance markedly decreases with increasing distance from the host's habitat. Bioluminescent ''

'' species also engage in mutually beneficial associations with fish and squid. Dense populations of ''P. kishitanii, P. leiogathi,'' and ''P. mandapamensis'' can live in the light organs of marine fish and squid, and are provided with nutrients and oxygen for reproduction in return for providing bioluminescence to their hosts, which can aid in sex-specific signaling, predator avoidance, locating or attracting prey, and schooling.