Diverse set of Turing nanopatterns coat corneae across insect lineages

Blagodatski, Artem; Sergeev, Anton; Kryuchkov, Mikhail; Lopatina, Yuliya; Katanaev, Vladimir L.

doi:10.1073/pnas.1505748112

Cited by 67 publications

(124 citation statements)

References 37 publications

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“…Another interesting attribute of Turing patterns is that they can be obtained on a wide variety of scales ranging from the nanoscale to the macroscopic scale. Patterns can be observed in leaves of plants and nano-Turing patterns were recently observed in the corneas of different arthropods (Blagodatski, et al, 2015), Figure 3a; microscopic analysis of corneas from different insect families showed that there is a certain correlation between families with similar evolutionary origins and the morphology of the observed pattern, enabling entomology to consider a new taxonomic criterion.…”

Section: Pattern Formation At All Scales: Main Featuresmentioning

confidence: 87%

“…Thus, the presence of patterns in living beings can be indicators of their evolutionary history and their adaptability, as suggested by some recent studies (Blagodatski, et al, 2015). Regarding inert systems, pattern formation results in the design of efficient bio-inspired technologies, in particular the design of structured-surface solids with appropriate patterns for specific applications (Bensemann, et al, 2005) and the design of chemical processes that emulate organic systems of living beings, such as the respiratory and circulatory systems (Coppens, 2012) …”

Section: What Advantages Do Static Patterns Bring To the System?mentioning

confidence: 96%

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Patrones en la naturaleza: más que un diseño inspirador

Serna

2017

Rev. Acad. Colomb. Cienc. Ex. Fis. Nat.

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At all scales and both in animate and inanimate systems, nature displays a wide variety of colors, rhythms, and forms. For decades, these natural patterns and rhythms have been studied and used as a source of inspiration for the technological development and well-being of human beings. Today we understand that the design of these patterns responds to principles of functionality and efficiency. This article focuses on physicochemical aspects to show how the study of spatiotemporal patterns became such an important area of interest and research for natural sciences. In particular, we address some systems in which the formation of patterns is explained by the coupling between chemical and transport processes, such as chemical gardens, periodic precipitation and Turing patterns. © 2017. Acad. Colomb. Cienc. Ex. Fis. Nat. Key words: Turing patterns; Morphogenesis; Periodic precipitation; Energy Economy; Bio-inspired processes. Patrones en la naturaleza: más que un diseño inspirador ResumenEn la naturaleza observamos una amplia variedad de colores, ritmos y formas, a toda escala y en sistemas animados e inanimados. Desde hace décadas los patrones y ritmos de la naturaleza han sido objeto de estudio y fuente de inspiración en el desarrollo tecnológico y en el bienestar del ser humano. Hoy entendemos que el diseño de los patrones de la naturaleza obedece a principios de funcionalidad y de eficiencia. En este artículo nos enfocamos en aspectos fisicoquímicos para mostrar cómo el estudio de los patrones espacio-temporales se convirtió en un área de gran interés e investigación en ciencias naturales. En particular, abordamos algunos sistemas donde la formación de patrones se explica mediante el acople entre procesos químicos y de transporte, tales como los jardines químicos, la precipitación periódica y los patrones de Turing.

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Section: Pattern Formation At All Scales: Main Featuresmentioning

confidence: 87%

Section: What Advantages Do Static Patterns Bring To the System?mentioning

confidence: 96%

Patrones en la naturaleza: más que un diseño inspirador

Serna

2017

Rev. Acad. Colomb. Cienc. Ex. Fis. Nat.

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“…This is particularly true for insects living in low-light conditions, such as moths and other nocturnal insects, which feature similar nanopillars covering their facet lenses ( Figure 15C,D). [342][343][344][345] These so-called corneal nipple arrays optimize light flux into the eye and photon detection by the photoreceptors. As a positive side effect, the surface reflection of the eyes is minimized during daytime, suppressing a detectable reflection of the inactive insects by predators.…”

Section: Transparencymentioning

confidence: 99%

“…[332] Copyright 2014, Matteo Burresi. nanostructures ( Figure 15E) whose developmental pathway is unknown but is hypothesized to be based on a Turing-like patterning of the outermost corneal layer during development. [344] …”

Section: Transparencymentioning

confidence: 99%

It's Not a Bug, It's a Feature: Functional Materials in Insects

2018

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Over the course of their wildly successful proliferation across the earth, the insects as a taxon have evolved enviable adaptations to their diverse habitats, which include adhesives, locomotor systems, hydrophobic surfaces, and sensors and actuators that transduce mechanical, acoustic, optical, thermal, and chemical signals. Insect‐inspired designs currently appear in a range of contexts, including antireflective coatings, optical displays, and computing algorithms. However, as over one million distinct and highly specialized species of insects have colonized nearly all habitable regions on the planet, they still provide a largely untapped pool of unique problem‐solving strategies. With the intent of providing materials scientists and engineers with a muse for the next generation of bioinspired materials, here, a selection of some of the most spectacular adaptations that insects have evolved is assembled and organized by function. The insects presented display dazzling optical properties as a result of natural photonic crystals, precise hierarchical patterns that span length scales from nanometers to millimeters, and formidable defense mechanisms that deploy an arsenal of chemical weaponry. Successful mimicry of these adaptations may facilitate technological solutions to as wide a range of problems as they solve in the insects that originated them.

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“…1C). Turing systems are thought to underlie many different examples of developmental patterning, including mesendodermal and left-right organization (Müller et al, 2012), mammalian palatal rugal ridge formation (Economou et al, 2012), hair follicle spacing (Sick et al, 2006), finger formation (Raspopovic et al, 2014) and nano-features of insect cornea (Blagodatskia et al, 2015).…”

Section: Box 1 Glossarymentioning

confidence: 99%

Using synthetic biology to explore principles of development

Davies

2017

Development

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Developmental biology is mainly analytical: researchers study embryos, suggest hypotheses and test them through experimental perturbation. From the results of many experiments, the community distils the principles thought to underlie embryogenesis. Verifying these principles, however, is a challenge. One promising approach is to use synthetic biology techniques to engineer simple genetic or cellular systems that follow these principles and to see whether they perform as expected. As I review here, this approach has already been used to test ideas of patterning, differentiation and morphogenesis. It is also being applied to evo-devo studies to explore alternative mechanisms of development and 'roads not taken' by natural evolution.

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Diverse set of Turing nanopatterns coat corneae across insect lineages

Cited by 67 publications

References 37 publications

Patrones en la naturaleza: más que un diseño inspirador

Patrones en la naturaleza: más que un diseño inspirador

It's Not a Bug, It's a Feature: Functional Materials in Insects

Using synthetic biology to explore principles of development

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