Bioluminescent Deep-Sea Fish Harness Crystal Prisms to Recycle Their Own Glow

Marine biologists have made a groundbreaking discovery while studying the light-emitting organs of bioluminescent fish species. They identified needle-shaped guanine crystals that scatter and redirect light, providing potential inspiration for developing more efficient biomedical and optical devices.



Sigmapus gracilis. Image credit: Wu Quancheng / Taiwan Agriculture Commission Fisheries Research Institute.

Approximately 75% of marine organisms exhibit bioluminescence, featuring specialized light-emitting organs known as photophores.

These luminous organisms utilize emitted light for various purposes, including mate attraction, prey luring, and predator evasion.

Notably, bioluminescent fish possess unique crystal structures called guanine platelets that significantly contribute to their light emission.

While all bioluminescent fish have luminescent vacuoles and platelets, the quantity, placement, and shape of these biological structures differ across species.

In a recent study led by researchers from Hiroshima University, including Masakazu Iwasaka, the light control mechanisms within the luminescent vesicles of the deep-sea fish Sigmapus gracilis were investigated.

The team found that localized layers of guanine platelets not only reflect light but also scatter it in intricate patterns.

“During our deep-sea fish studies aboard a research vessel, we realized traditional lab materials might not yield the insights we needed,” Dr. Iwasaka noted.

“This epiphany led me to explore biomimetics, inspired by the unique phenomena observed in the field.”

“Both my own observations and prior research indicate that guanine crystals can form surface layers on luminescent vacuoles in select fish species.”

“Our findings confirmed significant anisotropic reflection, meaning the reflected light varies considerably based on the incident angle.”

“This suggests that guanine crystals have a previously unrecognized role in light directionality control.”

Guanine platelets in Sigmapus gracilis exhibit needle-like structures that cluster around the light organ.

Upon light interaction, the unique shape of the guanine crystals results in scattering effects.

“In previous research, I demonstrated that guanine crystals in goldfish function as tiny mirrors, where their slightly tilted orientation causes anisotropic reflections,” Dr. Iwasaka explained.

“Conversely, the elongated crystals in this study act more like prisms, redirecting light instead of merely reflecting it.”

“Their layered configuration exhibits qualities reminiscent of photonic crystals.”

The layered crystalline structures of guanine platelets reveal insights for highly efficient biomimetic designs aimed at maximizing and reusing leaked light rather than allowing mere reflection.

The researchers tested various orientations of the guanine crystals with an electromagnet and analyzed the scattering patterns generated by an external light source at different angles.

Given that these small structures operate underwater, the findings could significantly enhance the design of implantable biomedical devices.

Professor Iwasaka remarked, “While deep-sea fish are challenging to obtain for research, their value is immeasurable.”

“Examining guanine in diverse fish species will yield valuable knowledge in biomimetics.”

The results are published in this week’s issue of Biointerphases here.

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Masakazu Iwasaka et al. 2026. Biomimetic illumination enhancement inspired by guanine platelets on luminophoric surfaces of deep-sea bristle mice Sigmapus gracilis. Biointerphases 21, 031003;doi: 10.1116/6.0005382

Source: www.sci.news

New discovery: Bioluminescent bacterial species Mycena crocata

Misena Crocata is a long-known bacterial species that has been frequently reported from Europe and Japan, but until now it was thought that it did not emit light.

heintzelman others. report evidence of bioluminescence in Misena Crocata And we show that the genome of this species is fully populated with genes related to fungal bioluminescence. Image credit: Heintzelman others., doi: 10.47371/mycosci.2024.03.001.

Misena Crocata It is a species of fungus Misena It is known in Europe, North Africa, Asia, and North America.

It occurs primarily in fallen beech leaves and woody debris, but occasionally in other hardwoods such as oak, ash, alder, and birch.

Misena CrocataThe fruiting bodies of this plant appear from summer to autumn, so they can be easily identified.

It reaches a height of 5-15 cm, has a narrow stalk and exhibits a characteristic color gradation from bright orange at the base to red and pale yellow or cream at the top.

In addition, yellow-red or orange-red stains may be present on the whitish gills.

But most impressively, Misena Crocata When cut, it oozes a distinctive saffron red sap. This is reflected in the common name Saffron Drop Bonnet Mushroom and the Latin epithet of the species. Kurokata It means saffron color.

evidence of bioluminescence Misena Crocata It was discovered by Zurich-based artists Heidi Bagenstos and Andreas Rudolph.

“We wanted to show that bioluminescent mushrooms exist in Swiss forests and that you don't have to travel far to find them,” Bagenstos said.

“One evening, as I was walking through the Albisrieden forest near Zurich, I saw a green light shining through my camera.”

“The bioluminescence of fungi can be so weak that it cannot be seen with the naked eye.”

Bagenstos, Rudolf and Dr. Renate Heintzelmann from the Swiss Federal Institute for Forestry, Snow and Landscape Research further investigated the large collection. Misena Crocata.

They investigated the bioluminescent properties of its fruiting bodies and mycelium using digital imaging and photomultiplier tubes.

Furthermore, they captured the bioluminescence spectrum emitted by the species and confirmed the presence of bioluminescence-related genes in its genome.

“Light measurements show that the fruiting bodies Misena CrocataThe mycelium showed the most bioluminescence, except for the base of the stalk, which was non-luminescent,” the researchers explained.

“As a result, the rotten trees Misena Crocata The mature wood also emits a green glow when split, which lasts up to 4 hours before the wood dries. ”

“When we grew pure mycelial cultures under optimal conditions, they remained bioluminescent for up to 164 days.”

According to the authors, the ecological role of bioluminescence in fungi remains a mystery.

“For some fungal species with intensely luminescent fruiting bodies, bioluminescence may attract arthropods at night, which may facilitate spore dispersal,” the researchers said.

“The spores of Misena Seeds are usually dispersed by wind and in species that do not have luminescent fruiting bodies. Misena CrocataBioluminescence probably plays another, but as yet unknown, role. ”

“As a result of our research, we conclude that it is very likely that there are others that may be more familiar. Misena It is a species whose bioluminescent properties are yet to be discovered,” they added.

“As a result, existing studies of fungal bioluminescence may underestimate the frequency of bioluminescence in mysenoid lineages.”

“In the absence of clear evidence for the absence of bioluminescence, further studies on the evolution of luminescence within the mysenoid lineage are recommended to validate the luminescent properties of putative non-luminescent species.”

a paper The survey results were published in a magazine mycoscience.

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Renate Heintzelman others. 2024. Many bioluminescent Misena An overlooked species? – Case study from M. crocata In Switzerland. mycoscience 65 (4): 173-179;doi: 10.47371/mycosci.2024.03.001

Source: www.sci.news