Reflectin

Last updated December 03, 2023

Leucophore layer composition

Reflectins are a family of intrinsically disordered proteins evolved by a certain number of cephalopods including Euprymna scolopes and Doryteuthis opalescens to produce iridescent camouflage and signaling. The recently identified protein family is enriched in aromatic and sulfur-containing amino acids, and is utilized by certain cephalopods to refract incident light in their environment.^[1] The reflectin protein is responsible for dynamic pigmentation and iridescence in organisms. This process is “dynamic” due to its reversible properties, allowing reflectin to change an organism's appearance in response to external factors such as needing to camouflage or send warning signals.

Origin

Reflectin is presumed to have originated from a type of transposon (nicknamed jumping genes), which is a DNA sequence that can change positions within genetic material by encoding an enzyme. The encoded enzyme detaches transposon from one location in a genome and ligates (binds) it to another. "Jumps" of transposon can create or reverse mutations that alter a cell's genetic identity which can result in new characteristics. This process can be thought of as a “cut and paste” mechanism. Transposons’ ability to adapt in a genome and quickly shift its identity is a property that closely resemble the behavior of reflectin.

An additional ancestor could be symbiotic Vibrio fischeri (also called Aliivibrio fischeri) which is a bioluminescent (produces and emits light) bacterium often found in symbiotic relationships. As reflectin and Vibrio fischeri share similar functions such as producing an iridescent appearance in organisms, it is also thought that, just like Vibrio fischeri, Reflectin is symbiotic and is used by cephalopods to interact with their environment.^[4]^[5]

Structure

Reflectin is a disordered protein made up of conserved amino acid sequences. Each sequence includes a combination of standard and sulphur-containing amino acids. Although the basic structure can be deduced, the exact molecular structure is yet to be determined. Light interacting properties of reflectin can be attributed to its ordered hierarchical structure and hydrogen bonding.^[6]^[7]^[8]

Reflectin in membranes

Reflectin make up the majority of Bragg reflectors which are formed by invaginations of the cell membrane. Bragg reflectors are responsible for reflecting color in a type of skin cell called iridocyte. Reflectors are composed of periodically stacked lamellae which are thin layers of tissue bound to a membrane. The color and brightness of light reflected by many species is determined by the thickness, spacing, and refractive index (how fast light can travel through the membrane) of the Bragg lamellae.^[9] A change in membrane thickness triggers an outflow of water from the Bragg lamellae, essentially dehydrating it, increasing their refractive index and decreasing thickness and spacing. This results in an increase in reflectance from the Bragg lamellae, and a change in color of the reflected light. This change additionally allows initially transparent cells to increase in brightness ^[8]

Mechanisms

Reflectin is able to receive information from signals for a continuous process to fine-tune the osmotic pressure of sub-cellular structures of cephlapods. This ongoing process is used to regulate photonic behavior, or in other words, control how an organism changes color. The components of reflectin carry a very strong positive charge. Nerve signals are sent to iridophore cells (also called chromatophores) which are pigment-containing cells that add a negative charge to reflectin. With the charges balanced, the protein folds up to expose a sticky surface, causing reflecting molecules to clump together. This process repeats until enough reflectin proteins have accumulated to change the fluid pressure of the membrane of the cell walls. The thickness of the membrane reduces as water escapes, a process that changes the wavelength of light reflected.^[2] By adapting an organism's membrane to reflect different wavelengths, reflection allows cephlapods to shift from different colors of red, yellow, green, and blue as well as adjust the brightness of the projected color.^[10]^[11]^[12]^[13]

Current Research

Research teams of ICB (Institute for Collaborative Biotechnologies) discovered that reflectin assembly can be electrically fine-tuned, suggesting a new approach of controlling protein machines similar to reflectin^[14] Biotic-abiotic manipulating by electrically fine-tuning reflectin assembly
Researchers at the University of California in Santa Barbara (UCSB) may have implications for molecular engineering based on the mechanisms similar to transformations controlled by reflectin. Discoveries about reflectin may even point the way towards treatments for Alzheimer's disease. Processes used by reflectin are similar to those seen when proteins assemble in the brain during the progress of protein-related diseases like Alzheimer's and Parkinson's. Understanding how brain-damaging pathology might be reversed.
Researchers think that reversible mechanisms used by reflectin protein may be replicated to develop dynamic living human cells and tissues. These findings could be applied to the development of biophotonic tools used in material science and bioengineering^[15] Optical engineering of human cells
Based on reflectin's function to camouflage cephalopods, researchers believe it is possible to create a material used for the growth of human neural and progenitor cells.^[16] Using reflectin as a material for neural stem cell growth

Use in bioengineering

Engineered human cells with tunable optical properties

Reflectins have been heterologously expressed in mammalian cells to change their refractive index.^[17]

Related Research Articles

Camouflage is the use of any combination of materials, coloration, or illumination for concealment, either by making animals or objects hard to see, or by disguising them as something else. Examples include the leopard's spotted coat, the battledress of a modern soldier, and the leaf-mimic katydid's wings. A third approach, motion dazzle, confuses the observer with a conspicuous pattern, making the object visible but momentarily harder to locate, as well as making general aiming easier. The majority of camouflage methods aim for crypsis, often through a general resemblance to the background, high contrast disruptive coloration, eliminating shadow, and countershading. In the open ocean, where there is no background, the principal methods of camouflage are transparency, silvering, and countershading, while the ability to produce light is among other things used for counter-illumination on the undersides of cephalopods such as squid. Some animals, such as chameleons and octopuses, are capable of actively changing their skin pattern and colours, whether for camouflage or for signalling. It is possible that some plants use camouflage to evade being eaten by herbivores.

A squid is a mollusc with an elongated soft body, large eyes, eight arms, and two tentacles in the superorder Decapodiformes, though many other molluscs within the broader Neocoleoidea are also called squid despite not strictly fitting these criteria. Like all other cephalopods, squid have a distinct head, bilateral symmetry, and a mantle. They are mainly soft-bodied, like octopuses, but have a small internal skeleton in the form of a rod-like gladius or pen, made of chitin.

A cephalopod is any member of the molluscan class Cephalopoda such as a squid, octopus, cuttlefish, or nautilus. These exclusively marine animals are characterized by bilateral body symmetry, a prominent head, and a set of arms or tentacles modified from the primitive molluscan foot. Fishers sometimes call cephalopods "inkfish", referring to their common ability to squirt ink. The study of cephalopods is a branch of malacology known as teuthology.

<span class="mw-page-title-main">Eye</span> Organ that detects light and converts it into electro-chemical impulses in neurons

Eyes are organs of the visual system. They provide living organisms with vision, the ability to receive and process visual detail, as well as enabling several photo response functions that are independent of vision. Eyes detect light and convert it into electro-chemical impulses in neurons (neurones). In higher organisms, the eye is a complex optical system which collects light from the surrounding environment, regulates its intensity through a diaphragm, focuses it through an adjustable assembly of lenses to form an image, converts this image into a set of electrical signals, and transmits these signals to the brain through complex neural pathways that connect the eye via the optic nerve to the visual cortex and other areas of the brain. Eyes with resolving power have come in ten fundamentally different forms, and 96% of animal species possess a complex optical system. Image-resolving eyes are present in molluscs, chordates and arthropods.

A photophore is a glandular organ that appears as luminous spots on various marine animals, including fish and cephalopods. The organ can be simple, or as complex as the human eye; equipped with lenses, shutters, color filters and reflectors, however unlike an eye it is optimized to produce light, not absorb it. The bioluminescence can variously be produced from compounds during the digestion of prey, from specialized mitochondrial cells in the organism called photocytes, or, similarly, associated with symbiotic bacteria in the organism that are cultured.

Bobtail squid are a group of cephalopods closely related to cuttlefish. Bobtail squid tend to have a rounder mantle than cuttlefish and have no cuttlebone. They have eight suckered arms and two tentacles and are generally quite small.

Aliivibrio 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 animals, such as the Hawaiian bobtail squid. It is heterotrophic, oxidase-positive, and motile by means of a single polar flagella. Free-living A. fischeri cells survive on decaying organic matter. The bacterium is a key research organism for examination of microbial bioluminescence, quorum sensing, and bacterial-animal symbiosis. It is named after Bernhard Fischer, a German microbiologist.

<span class="mw-page-title-main">Distributed Bragg reflector</span> Structure used in waveguides

A distributed Bragg reflector (DBR) is a reflector used in waveguides, such as optical fibers. It is a structure formed from multiple layers of alternating materials with different refractive index, or by periodic variation of some characteristic of a dielectric waveguide, resulting in periodic variation in the effective refractive index in the guide. Each layer boundary causes a partial reflection and refraction of an optical wave. For waves whose vacuum wavelength is close to four times the optical thickness of the layers, the interaction between these beams generates constructive interference, and the layers act as a high-quality reflector. The range of wavelengths that are reflected is called the photonic stopband. Within this range of wavelengths, light is "forbidden" to propagate in the structure.

Aposymbiosis occurs when symbiotic organisms live apart from one another. Studies have shown that the lifecycles of both the host and the symbiont are affected in some way, usually negative, and that for obligate symbiosis the effects can be drastic. Aposymbiosis is distinct from exsymbiosis, which occurs when organisms are recently separated from a symbiotic association. Because symbionts can be vertically transmitted from parent to offspring or horizontally transmitted from the environment, the presence of an aposymbiotic state suggests that transmission of the symbiont is horizontal. A classical example of a symbiotic relationship with an aposymbiotic state is the Hawaiian bobtail squid Euprymna scolopes and the bioluminescent bacteria Vibrio fischeri. While the nocturnal squid hunts, the bacteria emit light of similar intensity of the moon which camouflages the squid from predators. Juveniles are colonized within hours of hatching and Vibrio must outcompete other bacteria in the seawater through a system of recognition and infection.

The firefly squid, also commonly known as the sparkling enope squid or hotaru-ika in Japan, is a species of squid in the family Enoploteuthidae. W. scintillans is the sole species in the monotypic genus Watasenia.

Many scientists have found the evolution of the eye attractive to study because the eye distinctively exemplifies an analogous organ found in many animal forms. Simple light detection is found in bacteria, single-celled organisms, plants and animals. Complex, image-forming eyes have evolved independently several times.

Biological pigments, also known simply as pigments or biochromes, are substances produced by living organisms that have a color resulting from selective color absorption. Biological pigments include plant pigments and flower pigments. Many biological structures, such as skin, eyes, feathers, fur and hair contain pigments such as melanin in specialized cells called chromatophores. In some species, pigments accrue over very long periods during an individual's lifespan.

Euprymna scolopes, also known as the Hawaiian bobtail squid, is a species of bobtail squid in the family Sepiolidae native to the central Pacific Ocean, where it occurs in shallow coastal waters off the Hawaiian Islands and Midway Island. The type specimen was collected off the Hawaiian Islands and is located at the National Museum of Natural History in Washington, D.C.

Cuttlefish, or cuttles, are marine molluscs of the order Sepiida. They belong to the class Cephalopoda which also includes squid, octopuses, and nautiluses. Cuttlefish have a unique internal shell, the cuttlebone, which is used for control of buoyancy.

Underwater camouflage is the set of methods of achieving crypsis—avoidance of observation—that allows otherwise visible aquatic organisms to remain unnoticed by other organisms such as predators or prey.

Counter-illumination is a method of active camouflage seen in marine animals such as firefly squid and midshipman fish, and in military prototypes, producing light to match their backgrounds in both brightness and wavelength.

Structural coloration in animals, and a few plants, is the production of colour by microscopically structured surfaces fine enough to interfere with visible light instead of pigments, although some structural coloration occurs in combination with pigments. For example, peacock tail feathers are pigmented brown, but their microscopic structure makes them also reflect blue, turquoise, and green light, and they are often iridescent.

<span class="mw-page-title-main">Bioluminescent bacteria</span>

Bioluminescent bacteria are light-producing bacteria 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 or in symbiosis with animals such as the Hawaiian Bobtail squid or terrestrial nematodes. 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, an ability to regulate gene expression in response to bacterial cell density.

Bio-inspired photonics or bio-inspired optical materials are the application of biomimicry to the field of photonics. This differs slightly from biophotonics which is the study and manipulation of light to observe its interactions with biology. One area that inspiration may be drawn from is structural color, which allows color to appear as a result of the detailed material structure. Other inspiration can be drawn from both static and dynamic camouflage in animals like the chameleon or some cephalopods. Scientists have also been looking to recreate the ability to absorb light using molecules from various plants and microorganisms. Pulling from these heavily evolved constructs allows engineers to improve and optimize existing photonic technologies, whilst also solving existing problems within this field.

Margaret McFall-Ngai is an American animal physiologist and biochemist best-known for her work related to the symbiotic relationship between Hawaiian bobtail squid, Euprymna scolopes and bioluminescent bacteria, Vibrio fischeri. Her research helped expand the microbiology field, primarily focused on pathogenicity and decomposition at the time, to include positive microbial associations. She currently is a professor at PBRC’s Kewalo Marine Laboratory and director of the Pacific Biosciences Research Program at the University of Hawaiʻi at Mānoa.

References

↑ DeMartini DG, Izumi M, Weaver AT, Pandolfi E, Morse DE (June 2015). "Structures, Organization, and Function of Reflectin Proteins in Dynamically Tunable Reflective Cells". The Journal of Biological Chemistry. 290 (24): 15238–49. doi: 10.1074/jbc.M115.638254 . PMC 4463464 . PMID 25918159.
1 2 Song, Junyi; Levenson, Robert; Santos, Jerome; Velazquez, Lourdes; Zhang, Fan; Fygenson, Deborah; Wu, Wenjian; Morse, Daniel E. (2020-03-17). "Reflectin Proteins Bind and Reorganize Synthetic Phospholipid Vesicles". Langmuir. 36 (10): 2673–2682. doi:10.1021/acs.langmuir.9b03632. ISSN 0743-7463. PMID 32097553. S2CID 211525202.
↑ Kim, Meeri (2017-08-21). "New research on reflectin proteins sheds light on cephalopods' camouflage". Scilight. 2017 (9): 090008. doi:10.1063/1.5000813.
↑ Guan, Zhe; Cai, Tiantian; Liu, Zhongmin; Dou, Yunfeng; Hu, Xuesong; Zhang, Peng; Sun, Xin; Li, Hongwei; Kuang, Yao; Zhai, Qiran; Ruan, Hao (2017-09-25). "Origin of the Reflectin Gene and Hierarchical Assembly of Its Protein". Current Biology. 27 (18): 2833–2842.e6. doi: 10.1016/j.cub.2017.07.061 . ISSN 0960-9822. PMID 28889973.
↑ "Research group discovers the origin of octopuses' instant modulation of body coloration". phys.org. Retrieved 2020-11-16.
↑ "NSF Award Search: Award#1856055 - Molecular basis of tunable iridescence and excellent proton conductance of the reflectin assembly". www.nsf.gov. Retrieved 2020-11-16.
↑ Kramer, Ryan M.; Crookes-Goodson, Wendy J.; Naik, Rajesh R. (July 2007). "The self-organizing properties of squid reflectin protein". Nature Materials. 6 (7): 533–538. Bibcode:2007NatMa...6..533K. doi:10.1038/nmat1930. ISSN 1476-4660. PMID 17546036.
1 2 "Structure of Reflectin Protein Probed by Solid-State Nuclear Magnetic Resonance | Argonne National Laboratory". www.anl.gov. Retrieved 2020-11-16.
↑ Ghoshal, Amitabh; DeMartini, Daniel G.; Eck, Elizabeth; Morse, Daniel E. (2013-08-06). "Optical parameters of the tunable Bragg reflectors in squid". Journal of the Royal Society Interface. 10 (85). doi:10.1098/rsif.2013.0386. ISSN 1742-5689. PMC 4043173 . PMID 23740489.
↑ Phan, Long; Kautz, Rylan; Arulmoli, Janahan; Kim, Iris H.; Le, Dai Trang T.; Shenk, Michael A.; Pathak, Medha M.; Flanagan, Lisa A.; Tombola, Francesco; Gorodetsky, Alon A. (2016-01-13). "Reflectin as a Material for Neural Stem Cell Growth". ACS Applied Materials & Interfaces. 8 (1): 278–284. doi:10.1021/acsami.5b08717. ISSN 1944-8244. PMC 4721522 . PMID 26703760.
↑ Qin, Guokui; Dennis, Patrick B.; Zhang, Yuji; Hu, Xiao; Bressner, Jason E.; Sun, Zhongyuan; Crookes‐Goodson, Wendy J.; Naik, Rajesh R.; Omenetto, Fiorenzo G.; Kaplan, David L. (2013). "Recombinant reflectin-based optical materials". Journal of Polymer Science Part B: Polymer Physics. 51 (4): 254–264. Bibcode:2013JPoSB..51..254Q. doi:10.1002/polb.23204. ISSN 1099-0488.
↑ Naughton, Kyle L.; Phan, Long; Leung, Erica M.; Kautz, Rylan; Lin, Qiyin; Van Dyke, Yegor; Marmiroli, Benedetta; Sartori, Barbara; Arvai, Andy; Li, Sheng; Pique, Michael E. (2016-07-25). "Self-Assembly of the Cephalopod Protein Reflectin". Advanced Materials. 28 (38): 8405–8412. doi:10.1002/adma.201601666. ISSN 0935-9648. PMID 27454809.
↑ Levenson, Robert; Bracken, Colton; Sharma, Cristian; Santos, Jerome; Arata, Claire; Malady, Brandon; Morse, Daniel E. (2019-11-08). "Calibration between trigger and color: Neutralization of a genetically encoded coulombic switch and dynamic arrest precisely tune reflectin assembly". Journal of Biological Chemistry. 294 (45): 16804–16815. doi: 10.1074/jbc.RA119.010339 . ISSN 0021-9258. PMC 6851332 . PMID 31558609.
↑ "Synthetic Biology with Reflectin: Engineering a New Kind of Biomolecular Machine | Institute for Collaborative Biotechnology (ICB) | UCSB, MIT and Caltech". www.icb.ucsb.edu. Retrieved 2020-11-17.
↑ Nathan, Stuart (2019-11-18). "Squid discovery could revolutionise molecular engineering". The Engineer. Retrieved 2020-11-17.
↑ Phan, Long; Kautz, Rylan; Arulmoli, Janahan; Kim, Iris H.; Le, Dai Trang T.; Shenk, Michael A.; Pathak, Medha M.; Flanagan, Lisa A.; Tombola, Francesco; Gorodetsky, Alon A. (2016-01-13). "Reflectin as a Material for Neural Stem Cell Growth". ACS Applied Materials & Interfaces. 8 (1): 278–284. doi:10.1021/acsami.5b08717. ISSN 1944-8244. PMC 4721522 . PMID 26703760.
↑ Chatterjee A, Cerna Sanchez JA, Yamauchi T, Taupin V, Couvrette J, Gorodetsky AA (June 2020). "Cephalopod-inspired optical engineering of human cells". Nature Communications. 11 (1): 2708. Bibcode:2020NatCo..11.2708C. doi:10.1038/s41467-020-16151-6. PMC 7266819 . PMID 32488070.