Lipid composition and molecular interactions change with depth in the avian stratum corneum to regulate cutaneous water loss

Champagne, Alex M.; Allen, Heather C.; Williams, Joseph B.

doi:10.1242/jeb.125310

Cited by 13 publications

(6 citation statements)

References 59 publications

(86 reference statements)

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“…Muñ oz-Garcia et al [5] suggested that, at low and moderate temperatures, polar cerebrosides form ordered structures with the ceramides and they might sequester water molecules in their sugar moieties, decreasing the diffusion of water vapour through the skin. However, at higher temperatures, molecular motion causes cerebrosides to release water molecules bound to their sugar moieties and thus water vapour diffusion through the SC increases [28]. We propose that the presence of cerebrosides in the SC of bats may play a role in maintaining skin flexibility and elasticity by allowing increased hydration, a property that is important for animals using flight Table 2.…”

Section: Discussionmentioning

confidence: 98%

The cutaneous lipid composition of bat wing and tail membranes: a case of convergent evolution with birds

et al. 2016

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ResearchCite this article: Ben-Hamo M, Muñoz-Garcia A, Larrain P, Pinshow B, Korine C, Williams JB. 2016 The cutaneous lipid composition of bat wing and tail membranes: a case of convergent evolution with birds. The water vapour permeability barrier of mammals and birds resides in the stratum corneum (SC), the outermost layer of the epidermis. The molar ratio and molecular arrangement of lipid classes in the SC determine the integrity of this barrier. Increased chain length and polarity of ceramides, the most abundant lipid class in mammalian SC, contribute to tighter packing and thus to reduced cutaneous evaporative water loss (CEWL). However, tighter lipid packing also causes low SC hydration, making it brittle, whereas high hydration softens the skin at the cost of increasing CEWL. Cerebrosides are not present in the mammalian SC; their pathological accumulation occurs in Gaucher's disease, which leads to a dramatic increase in CEWL. However, cerebrosides occur normally in the SC of birds. We tested the hypothesis that cerebrosides are also present in the SC of bats, because they are probably necessary to confer pliability to the skin, a quality needed for flight. We examined the SC lipid composition of four sympatric bat species and found that, as in birds, their SC has substantial cerebroside contents, not associated with a pathological state, indicating convergent evolution between bats and birds.

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Section: Discussionmentioning

confidence: 98%

The cutaneous lipid composition of bat wing and tail membranes: a case of convergent evolution with birds

et al. 2016

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“…Salamanders limit water loss through perfusion and vascular regression, which would also reduce the amount of blood delivered to the skin for gas exchange (Brown 1972;Burggren and Moallf 1984;Riddell et al 2019). In previous studies that examined gene expression in this experiment, salamanders without physiological flexibility constitutively express higher levels of ALOXE3 (Riddell et al 2019), a gene underlying the production of a lipid barrier to reduce water loss rates across the skin (Champagne et al 2015). Salamanders have the capacity to reduce desiccation risk by increasing the dermal barrier to water loss, but these responses likely constrain respiration over longer periods of time.…”

Section: Discussionmentioning

confidence: 99%

Terrestrial Salamanders Maintain Habitat Suitability under Climate Change despite Trade-Offs between Water Loss and Gas Exchange

Riddell

Sears

2020

Physiological and Biochemical Zoology

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Physiological acclimation has the potential to improve survival during climate change by reducing sensitivity to warming. However, acclimation can produce trade-offs due to links between related physiological traits. Water loss and gas exchange are intrinsically linked by the need for respiratory surfaces to remain moist. As climates warm and dry, organisms may attempt to lower desiccation risk by limiting water loss but at a cost of inhibiting their ability to breathe. Here we used laboratory experiments to evaluate the trade-off between water loss and gas exchange in a fully terrestrial, lungless salamander (Plethodon metcalfi). We measured acclimation of resistance to water loss and metabolic rates in response to long-term exposure to temperature and humidity treatments. We then integrated the trade-off into a simulationbased species distribution model to determine the consequences of ignoring physiological trade-offs on energy balance and aerobic scope under climate change. In the laboratory, we found a close association between acclimation of resistance to water loss and metabolic rates indicative of a trade-off. After incorporating the trade-off into our simulations, we found that energy balance and aerobic scope were reduced by 49.7% and 34.3%, respectively, under contemporary climates across their geographic range. Under future warming scenarios, incorporating the trade-off lowered the number of sites predicted to experience local extirpation by 52.2% relative to simulations without the trade-off; however, the number of sites capable of supporting the energetic requirements for reproduction declined from 44.6% to 32.6% across the species' geographic range. These experiments and simulations suggest that salamanders can maintain positive energy balance across their geographic range under climate change despite the costs associated with trade-offs between water loss and gas exchange.

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“…Our study revealed a negative association with plasticity in r i and expression of the ALOXE3 , a gene associated with production of ceramides, a type of essential fatty acid in epidermal tissue 55 . Loss of function mutations in this family of genes results in pathological disorders associated with high transepidermal water loss 55 , and many mammals and birds rely on ceramides or related fatty acids to limit transepidermal water loss 52 . With lower production of ceramides, salamanders might then rely on vascular regression to regulate water loss.…”

Section: Discussionmentioning

confidence: 99%

Thermal cues drive plasticity of desiccation resistance in montane salamanders with implications for climate change

Riddell,

Roback,

Wells

et al. 2019

Nat Commun

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Organisms rely upon external cues to avoid detrimental conditions during environmental change. Rapid water loss, or desiccation, is a universal threat for terrestrial plants and animals, especially under climate change, but the cues that facilitate plastic responses to avoid desiccation are unclear. We integrate acclimation experiments with gene expression analyses to identify the cues that regulate resistance to water loss at the physiological and regulatory level in a montane salamander (Plethodon metcalfi). Here we show that temperature is an important cue for developing a desiccation-resistant phenotype and might act as a reliable cue for organisms across the globe. Gene expression analyses consistently identify regulation of stem cell differentiation and embryonic development of vasculature. The temperature-sensitive blood vessel development suggests that salamanders regulate water loss through the regression and regeneration of capillary beds in the skin, indicating that tissue regeneration may be used for physiological purposes beyond replacing lost limbs.

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Lipid composition and molecular interactions change with depth in the avian stratum corneum to regulate cutaneous water loss

Cited by 13 publications

References 59 publications

The cutaneous lipid composition of bat wing and tail membranes: a case of convergent evolution with birds

The cutaneous lipid composition of bat wing and tail membranes: a case of convergent evolution with birds

Terrestrial Salamanders Maintain Habitat Suitability under Climate Change despite Trade-Offs between Water Loss and Gas Exchange

Thermal cues drive plasticity of desiccation resistance in montane salamanders with implications for climate change

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