Evolution of Adaptive Plasticity: Risk‐sensitive Hatching in Neotropical Leaf‐breeding Treefrogs

Gómez-Mestre, Iván; Wiens, John J.; Warkentin, Karen M.

doi:10.1890/07-0529.1

Cited by 87 publications

(125 citation statements)

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“…Particularly at early developmental stages, this is the predominant functional framework for investigations of embryo behavior. Research on adaptive plasticity in hatching has demonstrated that embryo behavior, and appropriate responses to environmental cues, can be also of immediate importance for survival (Warkentin, 2007;Gomez-Mestre et al, 2008;Warkentin and Caldwell, in press). Similarly, behavioral interactions of bird embryos, shortly before hatching, with parents and siblings appear to have immediate functions in care solicitation and hatching synchronization (Brua, 2002).…”

Section: Adaptive Embryo Behaviormentioning

confidence: 99%

“…While solving a physiological problem, hatching earlier may, however, create an ecological one. More mature hatchlings typically have greater sensory development and/or locomotor abilities (Fuiman, 2002), both of which can reduce mortality from predation (Sih and Moore, 1993;Warkentin, 1999a;Gomez-Mestre et al, 2008). If predators or other factors in the post-hatching environment impose selection for later hatching, then mechanisms to extend embryonic development will be favored (Warkentin, 2007).…”

Section: Introductionmentioning

confidence: 99%

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External gills and adaptive embryo behavior facilitate synchronous development and hatching plasticity under respiratory constraint

Rogge

Warkentin

2008

Journal of Experimental Biology

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SUMMARYPlasticity in hatching timing allows embryos to balance egg-and larval-stage risks, and depends on the ability of hatchingcompetent embryos to continue developing in the egg. Hypoxia can slow development, kill embryos and induce premature hatching. For terrestrial eggs of red-eyed treefrogs, the embryonic period can extend ~50% longer than development to hatching competence, and development is synchronous across perivitelline oxygen levels (P O 2) ranging from 0.5-16.5 kPa. Embryos maintain large external gills until hatching, then gills regress rapidly. We assessed the respiratory value of external gills using gill manipulations and closed-system respirometry. Embryos without external gills were oxygen limited in air and hatched at an external P O 2 of 17 kPa, whereas embryos with gills regulated their metabolism and remained in the egg at substantially lower P O 2. By contrast, tadpoles gained no respiratory benefit from external gills. We videotaped behavior and manipulated embryos to test if they position gills near the air-exposed portion of the egg surface, where P O 2 is highest. Active embryos remained stationary for minutes in gills-at-surface positions. After manipulations and spontaneous movements that positioned gills in the O 2 -poor region of the egg, however, they returned their gills to the air-exposed surface within seconds. Even neural tube stage embryos, capable only of ciliary rotation, positioned their developing head in the region of highest P O 2. Such behavior may be critical both to delay hatching after hatching competence and to obtain sufficient oxygen for normal, synchronous development at earlier stages.

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Section: Adaptive Embryo Behaviormentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

External gills and adaptive embryo behavior facilitate synchronous development and hatching plasticity under respiratory constraint

Rogge

Warkentin

2008

Journal of Experimental Biology

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“…Agalychnis callidryas eggs are laid in masses of, on average, 40 eggs (Gomez-Mestre et al, 2008b) that are attached to a substrate by a layer of jelly. Egg masses on leaves were collected from Ocelot Pond (9°6′8.62″N, 79°40′56.96″W), Bridge Pond (9°6′50.26″N, 79°41′48.13″W) and Experimental Pond (9°7′14.77″N, 79°42′ 12.03″W) near and in Gamboa, Panamá, under permits from the Panamanian Autoridad Nacional del Ambiente (SE/A-41-08, SE/A-13-11, SC/A-19-11 and SC/A-16-12).…”

Section: Materials and Methods Egg Collection And Carementioning

confidence: 99%

“…Other phyllomedusines can also hatch rapidly from their terrestrial eggs (e.g. Agalychnis annae, A. moreletti, Pachymedusa dacnicolor, Cruziohyla calcarifer; Gomez-Mestre et al, 2008b) and may share the rapid hatching mechanism of A. callidryas. Clades that have independently evolved terrestrial eggs and rapid escape-hatching [e.g.…”

Section: Hg Distribution and Functionmentioning

confidence: 99%

“…However, rapid, predatorinduced hatching is not unique to A. callidryas. Two other Agalychnis species and the closely related Pachymedusa dacnicolor also have high escape success in snake attacks, and a more distantly related phyllomedusine, Cruziohyla calcarifer, hatches rapidly in response to mechanically simulated attack, suggesting that this ability may be ancestral or common in the group (Gomez-Mestre et al, 2008b). The glassfrogs, Centrolenidae, evolved terrestrial eggs independently of phyllomedusines (Gomez-Mestre et al, 2012), and some species can also hatch rapidly, to escape from predators, with no prior degradation of the membrane (J.…”

Section: Introductionmentioning

confidence: 99%

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How embryos escape from danger: the mechanism of rapid, plastic hatching in red-eyed treefrogs

Cohen

Seid

Warkentin

2016

Journal of Experimental Biology

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Environmentally cued hatching allows embryos to escape dangers and exploit new opportunities. Such adaptive responses require a flexibly regulated hatching mechanism sufficiently fast to meet relevant challenges. Anurans show widespread, diverse cued hatching responses, but their described hatching mechanisms are slow, and regulation of timing is unknown. Arboreal embryos of redeyed treefrogs, Agalychnis callidryas, escape from snake attacks and other threats by very rapid premature hatching. We used videography, manipulation of hatching embryos and electron microscopy to investigate their hatching mechanism. High-speed video revealed three stages of the hatching process: pre-rupture shaking and gaping, vitelline membrane rupture near the snout, and muscular thrashing to exit through the hole. Hatching took 6.5-49 s. We hypothesized membrane rupture to be enzymatic, with hatching enzyme released from the snout during shaking. To test this, we displaced hatching embryos to move their snout from its location during shaking. The membrane ruptured at the original snout position and embryos became trapped in collapsed capsules; they either moved repeatedly to relocate the hole or shook again and made a second hole to exit. Electron microscopy revealed that hatching glands are densely concentrated on the snout and absent elsewhere. They are full of vesicles in embryos and release most of their contents rapidly at hatching. Agalychnis callidryas' hatching mechanism contrasts with the slow process described in anurans to date and exemplifies one way in which embryos can achieve rapid, flexibly timed hatching to escape from acute threats. Other amphibians with cued hatching may also have novel hatching mechanisms.

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Phyllomedusa Azurea : Reproduction and Development

Candioti

2021

Microscopic Anatomy of Animals

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The life cycle of Phyllomedusa azurea shows astonishing anatomical and biological aspects. The embryonic morphology shares most features with other phyllomedusines (e.g. overdeveloped external gills and body ciliation), but some traits (adhesive and hatching glands) appear to be exclusive of the Phyllomedusa hypochondrialis group and likely evolved in parallel in Agalychnis callidryas . Tadpoles are similar to other Phyllomedusa , with the main differences concerning oral aspects (e.g. length of tooth rows, shape of labial teeth, and papillation). Cranial musculoskeletal anatomy is conserved, and at least three larval characters are proposed as synapomorphies of the subfamily.

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Evolution of Adaptive Plasticity: Risk‐sensitive Hatching in Neotropical Leaf‐breeding Treefrogs

Cited by 87 publications

References 124 publications

External gills and adaptive embryo behavior facilitate synchronous development and hatching plasticity under respiratory constraint

External gills and adaptive embryo behavior facilitate synchronous development and hatching plasticity under respiratory constraint

How embryos escape from danger: the mechanism of rapid, plastic hatching in red-eyed treefrogs

Phyllomedusa Azurea : Reproduction and Development

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