Your search keyword '"Salim, Angela A."' showing total 4 results

1. Chemical cues that attract cannibalistic cane toad (Rhinella marina) larvae to vulnerable embryos.

Author

Crossland MR, Salim AA, Capon RJ, and Shine R

Subjects

Animals, Larva drug effects, Larva physiology, Bufanolides chemistry, Bufo marinus physiology, Cannibalism, Toxins, Biological chemistry

Abstract

Chemical cues produced by late-stage embryos of the cane toad (Rhinella marina) attract older conspecific larvae, which are highly cannibalistic and can consume an entire clutch. To clarify the molecular basis of this attraction response, we presented captive tadpoles with components present in toad eggs. As previously reported, attractivity arises from the distinctive toxins (bufadienolides) produced by cane toads, with some toxins (e.g., bufagenins) much stronger attractants than others (e.g., bufotoxins). Extracts of frozen toad parotoid glands (rich in bufagenins) were more attractive than were fresh MeOH extracts of the parotoid secretion (rich in bufotoxins), and purified marinobufagin was more effective than marinobufotoxin. Cardenolide aglycones (e.g., digitoxigenin) were active attractors, whereas C-3 glycosides (e.g., digoxin, oubain) were far less effective. A structure-activity relationship study revealed that tadpole attractant potency strongly correlated with Na + /K + ATPase inhibitory activity, suggesting that tadpoles monitor and rapidly react to perturbations to Na + /K + ATPase activity.

Published

2021

2. The Effects of Conspecific Alarm Cues on Larval Cane Toads (Rhinella marina).

Author

Crossland MR, Salim AA, Capon RJ, and Shine R

Subjects

Animals, Body Size drug effects, Bufo marinus growth & development, Larva growth & development, Larva physiology, Metamorphosis, Biological drug effects, Oligopeptides chemistry, Arginine pharmacology, Avoidance Learning drug effects, Bufo marinus physiology, Caprylates pharmacology, Dicarboxylic Acids pharmacology, Oligopeptides pharmacology

Abstract

Many aquatic organisms detect and avoid damage-released cues from conspecifics, but the chemical basis of such responses, and the effects of prolonged exposure to such cues, remain poorly understood. Injured tadpoles of the cane toad (Rhinella marina) produce chemical cues that induce avoidance by conspecific tadpoles; and chronic exposure to those cues decreases rates of tadpole survival and growth, and reduces body size at metamorphosis. Such effects suggest that we might be able to use the cane toads' alarm cue for biocontrol of invasive populations in Australia. In the present study, we examined behavioral and ecological effects of compounds that are present in cane toad tadpoles and thus, might trigger avoidance of crushed conspecifics. Four chemicals (L-Arg, L-Leu-L-Leu-OH, L-Leu-L-Ile-OH and suberic acid) induced behavioral avoidance in toad tadpoles at some (but not all) dosage levels, so we then exposed toad larvae to these chemicals over the entire period of larval development. Larval survival and size at metamorphosis were decreased by chronic exposure to crushed conspecifics (consistent with earlier studies), but not by exposure to any of the four chemicals. Indeed, L-Arg increased body size at metamorphosis. We conclude that the behavioral response to crushed conspecifics by cane toad tadpoles can be elicited by a variety of chemical cues, but that consistent exposure to these individual chemical cues does not affect tadpole viability or developmental trajectory. The optimal behavioral tactic of a tadpole may be to flee if it encounters even a single chemical cue likely to have come from an injured conspecific (indicative of predation risk), whereas the continuing presence of that single chemical (but no others) provides a less reliable signal of predation risk. Our data are consistent with results from studies on fish, that suggest a role for multiple chemicals in initiating alarm responses to damage-released cues.

Published

2019

3. Microbiome-Mediated Biotransformation of Cane Toad Bufagenins.

Author

Kamalakkannan V, Salim AA, and Capon RJ

Subjects

Animals, Bacillus metabolism, Biotransformation, Bufanolides chemistry, Larva physiology, Molecular Structure, Nuclear Magnetic Resonance, Biomolecular, Bufanolides metabolism, Bufo marinus, Introduced Species, Microbiota physiology, Toxins, Biological physiology

Abstract

Cane toads are an invasive pest species in which all life stages employ cardiotoxic bufagenins as a chemical defense against predators. Curiously, the bufagenin profiles of eggs and tadpoles are more complex than those of parotoid secretion, the principle mechanism of toxin delivery in adult toads. In an effort to understand this complexity, we determined that selected strains of adult toad parotoid-gland-associated Gram-positive bacteria, Bacillus spp., were capable of biotransforming secreted bufagenins, marinobufagenin (1), telocinobufagenin (2), bufalin (3), and resibufagenin (4), to hydroxylated scaffolds commonly encountered in cane toad eggs and tadpoles. Scaled-up cultivation, preparative chromatography, and detailed spectroscopic analysis identified Bacillus sp. CMB-TD29 biotransformation products of 1, as 11α-hydroxymarinobufagenin (6), 12β-hydroxymarinobufagenin (7), and 17α-hydroxymarinobufagenin (8). Comparative bufagenin profiles across the cane toad life cycle suggest that bacterial biotransformation mediates the oxidative adaptation of adult toad bufagenins to hydroxylated bufagenins encountered in eggs and tadpoles. We speculate that knowledge of a relationship between the cane toad microbiome and bufagenin chemical defenses could inspire the development of a natural, nontoxic, environmentally sustainable bacterial biocontrol for this toxic invasive species.

Published

2017

4. Exploiting intraspecific competitive mechanisms to control invasive cane toads (Rhinella marina).

Author

Crossland MR, Haramura T, Salim AA, Capon RJ, and Shine R

Subjects

Animal Communication, Animals, Anura metabolism, Bufanolides analysis, Chromatography, Gas, Chromatography, High Pressure Liquid, Fresh Water, Introduced Species, Northern Territory, Pheromones analysis, Bufanolides pharmacology, Bufo marinus metabolism, Larva drug effects, Ovum chemistry, Pest Control, Biological methods, Pheromones pharmacology

Abstract

If invasive species use chemical weapons to suppress the viability of conspecifics, we may be able to exploit those species-specific chemical cues for selective control of the invader. Cane toads (Rhinella marina) are spreading through tropical Australia, with negative effects on native species. The tadpoles of cane toads eliminate intraspecific competitors by locating and consuming newly laid eggs. Our laboratory trials show that tadpoles find those eggs by searching for the powerful bufadienolide toxins (especially, bufogenins) that toads use to deter predators. Using those toxins as bait, funnel-traps placed in natural waterbodies achieved near-complete eradication of cane toad tadpoles with minimal collateral damage (because most native (non-target) species are repelled by the toads' toxins). More generally, communication systems that have evolved for intraspecific conflict provide novel opportunities for invasive-species control.

Published

2012