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Pigment Cell & Melanoma Research Jul 2022The skin acts as a barrier to environmental insults and provides many vital functions. One of these is to shield DNA from harmful ultraviolet radiation, which is...
The skin acts as a barrier to environmental insults and provides many vital functions. One of these is to shield DNA from harmful ultraviolet radiation, which is achieved by skin pigmentation arising as melanin is produced and dispersed within the epidermal layer. This is a crucial defence against DNA damage, photo-ageing and skin cancer. The mechanisms and regulation of melanogenesis and melanin transfer involve extensive crosstalk between melanocytes and keratinocytes in the epidermis, as well as fibroblasts in the dermal layer. Although the predominant mechanism of melanin transfer continues to be debated and several plausible models have been proposed, we and others previously provided evidence for a coupled exo/phagocytosis model. Herein, we performed histology and immunohistochemistry analyses and demonstrated that a newly developed full-thickness three-dimensional reconstructed human pigmented skin model and an epidermis-only model exhibit dispersed pigment throughout keratinocytes in the epidermis. Transmission electron microscopy revealed melanocores between melanocytes and keratinocytes, suggesting that melanin is transferred through coupled exocytosis/phagocytosis of the melanosome core, or melanocore, similar to our previous observations in human skin biopsies. We, therefore, present evidence that our in vitro models of pigmented human skin show epidermal pigmentation comparable to human skin. These findings have a high value for studies of skin pigmentation mechanisms and pigmentary disorders, whilst reducing the reliance on animal models and human skin biopsies.
Topics: Animals; Epidermis; Humans; Keratinocytes; Melanins; Melanocytes; Melanosomes; Pigmentation; Skin; Skin Pigmentation; Ultraviolet Rays
PubMed: 35325505
DOI: 10.1111/pcmr.13039 -
Science (New York, N.Y.) Aug 2017Coloration mediates the relationship between an organism and its environment in important ways, including social signaling, antipredator defenses, parasitic... (Review)
Review
Coloration mediates the relationship between an organism and its environment in important ways, including social signaling, antipredator defenses, parasitic exploitation, thermoregulation, and protection from ultraviolet light, microbes, and abrasion. Methodological breakthroughs are accelerating knowledge of the processes underlying both the production of animal coloration and its perception, experiments are advancing understanding of mechanism and function, and measurements of color collected noninvasively and at a global scale are opening windows to evolutionary dynamics more generally. Here we provide a roadmap of these advances and identify hitherto unrecognized challenges for this multi- and interdisciplinary field.
Topics: Animals; Biological Evolution; Color Perception; Color Vision; Photoreceptor Cells; Pigmentation; Pigments, Biological; Reproduction
PubMed: 28774901
DOI: 10.1126/science.aan0221 -
Nature May 1948
Topics: Color Vision; Humans; Pigmentation; Pigments, Biological; Racial Groups
PubMed: 18858297
DOI: 10.1038/161687a0 -
Advances in Marine Biology 2002Coral reef communities face unprecedented pressures on local, regional and global scales as a consequence of climate change and anthropogenic disturbance. Optical remote... (Review)
Review
Coral reef communities face unprecedented pressures on local, regional and global scales as a consequence of climate change and anthropogenic disturbance. Optical remote sensing, from satellites or aircraft, is possibly the only means of measuring the effects of such stresses at appropriately large spatial scales (many thousands of square kilometres). To map key variables such as coral community structure, percentages of living coral or percentages of dead coral, a remote sensing instrument must be able to distinguish the reflectance spectra (i.e. "spectral signature", reflected light as a function of wavelength) of each category. For biotic classes, reflectance is a complex function of pigmentation, structure and morphology. Studies of coral "colour" fall into two disparate but potentially complementary types. Firstly, biological studies tend to investigate the structure and significance of pigmentation in reef organisms. These studies often lack details that would be useful from a remote sensing perspective such as intraspecific variation in pigment concentration or the contribution of fluorescence to reflectance. Secondly, remote sensing studies take empirical measurements of spectra and seek wavelengths that discriminate benthic categories. Benthic categories used in remote sensing sometimes consist of species groupings that are biologically or spectrally inappropriate (e.g. merging of algal phyla with distinct pigments). Here, we attempt to bridge the gap between biological and remote sensing perspectives of pigmentation in reef taxa. The aim is to assess the extent to which spectral discrimination can be given a biological foundation, to reduce the ad hoc nature of discriminatory criteria, and to understand the fundamental (biological) limitations in the spectral separability of biotic classes. Sources of pigmentation in reef biota are reviewed together with remote sensing studies where spectral discrimination has been effectively demonstrated between benthic categories. The basis of reflectance is considered as the sum of pigmented components, such as zooxanthellae, host tissues and skeletons of corals. Problems in the empirical in situ measurement of reflectance are identified, such as the differing types of reflectance which can be measured, the interaction of the light field with morphology, and depth-dependent variability of measured reflectance due to fluorescence. The latter is estimated in some cases to introduce an error of up to 20% when depth differs by 8 m. Spectral features useful in discriminating reef benthos are identified and related to pigmentation. The slope in the reflectance spectra between 650 and 690 nm is dependent on chlorophyll-a concentration and can be used to discriminate bare sand with no algal component from chlorophyll-a containing benthos (algae, corals). The slope in reflectance at various locations between 500 and 560 nm can be useful in discriminating bleached and unbleached corals, possibly due to reduced peridinin concentration. Rhodophyta may be discernible by the presence of a dip in reflectance at 570 nm, due to a phycoerythrin absorption peak. However, the utility of some discriminatory criteria in deeper waters is mitigated by the relatively poor transmission of light through water at longer wavelengths (especially > 600 nm). Contrary to suggested categorizations of fluorescent pigments in coral host tissues, it is shown that these pigments form an almost continuous distribution with respect to their excitation and emission peaks. Remote sensing by induced fluorescence is a promising approach, but further details about the variation and distribution of these pigments are required. It is hoped that this review will promote cross-disciplinary collaboration between pigment biologists and the reef remote sensing community. Where possible, the discriminative criteria adopted in remote sensing should be related to biological phenomena, thus lending an intuitive, process-orientated basis for interpreting spectral data. Similarly, remote sensing may provide a novel scaling perspective to biological studies of pigmentation in reef organisms.
Topics: Animals; Anthozoa; Chlorophyll; Color; Ecosystem; Environmental Monitoring; Eukaryota; Fluorescence; Image Processing, Computer-Assisted; Light; Oceanography; Oceans and Seas; Pigmentation; Pigments, Biological
PubMed: 12154614
DOI: 10.1016/s0065-2881(02)43006-4 -
Current Biology : CB Aug 2018Pigmentation is a fundamental characteristic of living organisms that is used to absorb radiation energy and to regulate temperature. Since darker pigments absorb more...
Pigmentation is a fundamental characteristic of living organisms that is used to absorb radiation energy and to regulate temperature. Since darker pigments absorb more radiation than lighter ones, they stream more heat, which can provide an adaptive advantage at higher latitudes and a disadvantage near the Tropics, because of the risk of overheating. This intuitive process of color-mediated thermoregulation, also known as the theory of thermal melanism (TTM), has been only tested in ectothermic animal models [1-8]. Here, we report an association between yeast pigmentation and their latitude of isolation, with dark-pigmented isolates being more frequent away from the Tropics. To measure the impact of microbial pigmentation in energy capture from radiation, we generated 20 pigmented variants of Cryptococcus neoformans and Candida spp. Infrared thermography revealed that dark-pigmented yeasts heated up faster and reached higher temperatures (up to 2-fold) than lighter ones following irradiation. Melanin-pigmented C. neoformans exhibited a growth advantage relative to non-melanized yeasts when incubated under the light at 4°C but increased thermal susceptibility at 25°C ambient temperatures. Our results extend the TTM to microbiology and suggest pigmentation as an ancient adaptation mechanism for gaining thermal energy from radiation. The contribution of microbial pigmentation in heat absorption is relevant to microbial ecology and for estimating global temperatures. The color variations available in yeasts provide new opportunities in chromatology to quantify radiative heat transfer and validate biophysical models of heat flow [9] that are not possible with plants or animals.
Topics: Acclimatization; Body Temperature Regulation; Candida; Cryptococcus neoformans; Hot Temperature; Pigmentation
PubMed: 30078567
DOI: 10.1016/j.cub.2018.06.034 -
Photochemistry and Photobiology Jan 2021Optical properties of plant leaves are relevant to evaluate their physiological state and stress effect. The main objective of this work was to study how variegation,...
Optical properties of plant leaves are relevant to evaluate their physiological state and stress effect. The main objective of this work was to study how variegation, pigment composition or reflective features modifies leaves' photophysical behavior. For this purpose, green leaves (Ficus benjamina), purple leaves (Tradescantia pallida), green leaves covered by white trichomes (Cineraria maritima) and variegated leaves (Codiaeum aucubifolium) were analyzed. Firstly, foliar surface morphology was evaluated by scanning electron microscopy. UV-vis and near-IR reflectance and transmittance spectra were obtained to calculate absorption (k) and scattering (s) coefficients. The theoretical approaches of Pile of Plates and Kubelka-Munk's theory resulted still valid for nonstandard leaves with differing surface conditions. However, frequently used spectral indices were not reliable for predicting water content, when leaves differed from conventional ones. The proportionality between the absorption factor and chromophore/pigment concentration was also lost for hairy leaves. A simplified model to describe these facts was presented here. Fluorescence spectra were recorded and corrected, due to light re-absorption. Water-optical parameter connection and pigment-optical parameter connection were thoroughly discussed. Leaf surface morphology and pigmentation have not only influenced the optical features of leaves but also played a role in the effect that particulate matter could cause on leaf photosynthesis.
Topics: Fluorescence; Light; Particulate Matter; Pigmentation; Plant Leaves; Plants; Species Specificity; Surface Properties
PubMed: 32297341
DOI: 10.1111/php.13273 -
Biological Reviews of the Cambridge... May 2017The phylum Mollusca is highly speciose, and is the largest phylum in the marine realm. The great majority of molluscs are shelled, including nearly all bivalves, most... (Review)
Review
The phylum Mollusca is highly speciose, and is the largest phylum in the marine realm. The great majority of molluscs are shelled, including nearly all bivalves, most gastropods and some cephalopods. The fabulous and diverse colours and patterns of molluscan shells are widely recognised and have been appreciated for hundreds of years by collectors and scientists alike. They serve taxonomists as characters that can be used to recognise and distinguish species, however their function for the animal is sometimes less clear and has been the focus of many ecological and evolutionary studies. Despite these studies, almost nothing is known about the evolution of colour in molluscan shells. This review summarises for the first time major findings of disparate studies relevant to the evolution of shell colour in Mollusca and discusses the importance of colour, including the effects of visual and non-visual selection, diet and abiotic factors. I also summarise the evidence for the heritability of shell colour in some taxa and recent efforts to understand the molecular mechanisms underpinning synthesis of shell colours. I describe some of the main shell pigments found in Mollusca (carotenoids, melanin and tetrapyrroles, including porphyrins and bile pigments), and their durability in the fossil record. Finally I suggest that pigments appear to be distributed in a phylogenetically relevant manner and that the synthesis of colour is likely to be energetically costly.
Topics: Animal Shells; Animals; Color; Ecology; Fossils; Mollusca; Pigmentation
PubMed: 27005683
DOI: 10.1111/brv.12268 -
The Journal of Pharmacology and... Apr 1976The experiments were designed to study the well-known pigment-dependent mydriatic effect of atropine in the eye. In vitro, relative to the accumulation of 3H-atropine by...
The experiments were designed to study the well-known pigment-dependent mydriatic effect of atropine in the eye. In vitro, relative to the accumulation of 3H-atropine by the nonpigmented rabbit iris, the pigmented iris accumulated high amounts of the drug. A nonpigmented tissue, stomch fundus strip, obtained from either albino or nonalbino animals, accumulated relatively low amounts of 3H-atropine. On repeated washings, the accumulated drug from the nonpigmented tissues was rapidly lost, T 1/2 of 14 minutes, while that accumulated by the pigmented iris was retained much longer. Although in vitro aqueous humor from serum-atropinesterase positive rabbits rapidly degraded atropine, extracts from irides of the same type of rabbit gave a single peak radioactivity, with Rf identical to the authentic atropine sulfate. The accumulation of 3H-atropine by pigmented human iris or pigment epithelium was similar to that observed for the pigmented rabbit iris. pA2 values of atropine from nonpigmented iris and from fundus strips varied between 8.58 and 8.88 with slope values close to 1. The pA2 value of atropine in pigmented iris was 8.82; at higher concentrations, atropine was less effective compared to the nonpigmented iris. In the pigmented iris, the lesser effectiveness of the drug at high concentration could be explained on the basis of accumulation of the drug by the pigment cell and its constituents. Thus, the free concentration of the drug in the vicinity of the muscarinic receptor will fall. The lesser concentration will give weaker muscarinic blockade in the pigmented iris. On repeated washing, the atropine blockade of the nonpigmented iris could be easily washed out while that in the pigmented iris was retained. In vivo, the relative T 1/2 for the duration of atropine mydriasis in rabbits were: albino atropinesterase-positive, 3.8 hours; nonalbino atropinesterase-positive, 12.4 hours; albino atropinesterase-negative is greater than or equal to 96 hours. Only the latter T 1/2 for the duration of atropine mydriasis is quite clear. The small magnitude of the mydriatic effect in humans is explained by the loss of free drug to the pigment cells and their constituents. The longer duration of mydriatic effect in the heavily pigmented eye is explained on the basis of slow release of the accumulated drug onto the muscarinic receptor.
Topics: Animals; Atropine; Epithelium; Esterases; Eye; Female; Humans; In Vitro Techniques; Iris; Male; Mydriatics; Pigmentation; Rabbits
PubMed: 1263134
DOI: No ID Found -
Insect Biochemistry and Molecular... Feb 2020In many arthropod species including insects, the cuticle tanning pathway for both pigmentation and sclerotization begins with tyrosine and is responsible for production...
In many arthropod species including insects, the cuticle tanning pathway for both pigmentation and sclerotization begins with tyrosine and is responsible for production of both melanin- and quinoid-type pigments, some of which are major pigments for body coloration. In this study we identified and cloned cDNAs of the yellow mealworm, Tenebrio molitor, encoding seven key enzymes involved in this pathway including tyrosine hydroxylase (TmTH), DOPA decarboxylase (TmDDC), laccase 2 (TmLac2), Yellow-y (TmY-y), arylalkylamine N-acetyltransferase (TmAANAT1), aspartate 1-decarboxylase (TmADC) and N-β-alanyldopamine synthase (Tmebony). Expression profiles of these genes during development were analyzed by real-time PCR, revealing development-specific patterns of expression. Loss of function mediated by RNAi of either 1) TmTH or TmLac2, 2) TmDDC or TmY-y, and 3) TmAANAT1, TmADC or Tmebony resulted in pale/white, light yellow/brown and dark/black adult body coloration, respectively. In addition, there are three distinct layer/regional pigmentation differences in rigid types of adult cuticle, a brownish outer exocuticle (EX), a dark pigmented middle mesocuticle (ME) and a transparent inner endocuticle (EN). Decreases in pigmentation of the EX and/or ME layers were observed after RNAi of TmDDC or TmY-y. In TmADC- or Tmebony-deficient adults, a darker pigmented EX layer was observed. In TmAANAT1-deficient adults, trabeculae formed between the dorsal and ventral elytral cuticles as well as the transparent EN layer became highly pigmented. These results demonstrate that knocking down the level of gene expression of specific enzymes of this tyrosine metabolic pathway leads to abnormal pigmentation in individual layers and substructure of the rigid adult exoskeleton of T. molitor.
Topics: Animal Shells; Animals; Insect Proteins; Pigmentation; Tenebrio; Wings, Animal
PubMed: 31812474
DOI: 10.1016/j.ibmb.2019.103291 -
The Journal of Experimental Biology Sep 2018Optical imaging of gene expression by fluorescence hybridisation (FISH) in insects is often impeded by their pigmented cuticle. As most chemical bleaching agents are...
Optical imaging of gene expression by fluorescence hybridisation (FISH) in insects is often impeded by their pigmented cuticle. As most chemical bleaching agents are incompatible with FISH, we developed an RNA interference (RNAi)-based method for clearing cuticular pigmentation which enables the use of whole-mount body appendages for RNA FISH (termed RNA-i-FISH). Silencing or in two leaf beetles species ( and ) cleared their pigmented cuticle and decreased light absorbance. Subsequently, intact appendages (palps, antennae, legs) from RNAi-cleared individuals were used to image the expression and spatial distribution of antisense mRNA of two chemosensory genes encoding gustatory receptor and odorant-binding protein. Imaging did not work for RNAi controls because the pigmentation was retained, or for FISH controls (sense mRNA). Several bleaching agents were incompatible with FISH, because of degradation of RNA, lack of clearing efficacy or long incubation times. Overall, silencing pigmentation genes is a significant improvement over bleaching agents, enabling FISH in intact insect appendages.
Topics: Animals; Coleoptera; Extremities; Gene Silencing; In Situ Hybridization, Fluorescence; Pigmentation; Pigments, Biological; RNA Interference
PubMed: 30026238
DOI: 10.1242/jeb.185710