Strawberry poison dart frog

Appearance

The strawberry poison frog is perhaps most famous for its widespread variation in coloration, comprising approximately 15–30 color morphs, most of which are presumed to be true-breeding. "O. pumilio", while not the most poisonous of the dendrobatids, is the most toxic member of its genus.

Behavior

"Oophaga pumilio" is diurnal and primarily terrestrial, and can often be found in leaf litter in both forested and disturbed areas. Though brightly colored and toxic, these frogs are relatively small, growing to approximately 17.5–22 mm in standard length. Males are extremely territorial, guarding small territories; females and juveniles are far more sociable.

Reproduction

"Oophaga pumilio" is an external breeder, and other species of the genus "Oophaga" are notable in the amphibian world for exhibiting a high degree of parental care. The strawberry poison frog has dual parental care. The males defend and water the nests, and the females feed the oophagous tadpoles their unfertilized eggs. Although both male and female contribute to parental care, females invest more heavily in terms of energy expenditure, time investment, and loss of potential reproduction. Females provide energetically costly eggs to the tadpoles for 6–8 weeks, remain sexually inactive during tadpole rearing, and care for only one clutch of four to 6 tadpoles at a time. The males, though, contribute the relatively "cheap" act of watering and protecting the eggs for a relatively short period, and can care for multiple nests at one time. The extreme maternal investment in their offspring is believed to be the result of high egg mortality. Only 5–12% of the clutch develops into tadpoles, so the female's fitness may be best increased by making sure those few eggs that form tadpoles survive.

After mating, the female lays three to five eggs on a leaf or bromeliad axil. The male then ensures the eggs are kept hydrated by transporting water in his cloaca. After about 10 days, the eggs hatch and the female transports the tadpoles on her back to some water-filled location. In captivity, on rare occasions, the male is observed transporting the tadpoles, though whether this is intentional, or the tadpoles simply hitch a ride, is unknown. Bromeliad axils are frequently used tadpole deposition sites, but anything suitable can be used, such as knots in trees, small puddles, or human trash such as aluminum cans.

Tadpoles are deposited singly at each location. Once this has been done, the female will come to each tadpole every few days and deposit several unfertilized food eggs. In captivity, tadpoles have been raised on a variety of diets, ranging from algae to the eggs of other dart frogs, but with minimal success. "O. pumilio" tadpoles are considered obligate egg feeders, as they are unable to accept any other form of nutrition.

After about a month, the tadpole will metamorphose into a small froglet. Generally, it stays near its water source for a few days for protection as it absorbs the rest of its tail.

Food

The diet of "O. pumilio" causes the skin of the amphibian to become toxic in nature when certain subspecies of mites and ants are ingested. Alkaloid toxins are organic in nature and contain nitrogenous bases that react with carbon and hydrogen groups....hieroglyph snipped... Pumiliotoxin 251D is the specialized toxin that is sequestered by this species of frog. This toxin has a negative stimulating effect on cardiac function and is a severe disruptor of the sodium potassium ion channels within cells. Upon ingestion of Pumiliotoxin 251D, organisms preying on "O. pumilio" experience convulsions, paralysis, and death.

Oribatida mites belonging to the glandulate suborder Brachypylina are an important origin of pumiliotoxins in "O. pumilio". Hexane-extraction techniques indicate presence of alkaloid toxins in Brachypylina. Toxins appear to be biosynthesized in adult mites, as nymph and larval stages of the arachnid do not carry the toxins. Experimental analysis of this species of mite show alkaloid toxins are found almost exclusively in the opisthonotal glands of mites of the Scheloribatidae. Oil glands of the mite contain the toxins and are then released internally as the amphibian digests the arthropod.

"O. pumilio" can also attribute its cutaneous toxicity to its rich diet of formicine ants. Species of the formicine genus "Brachymyrmex" contain pumiliotoxins which the frogs incorporate and accumulate poison from. There is a variability of alkaloid profiles among populations and individuals of "O. pumilio", which is indicative of varying levels of available prey within their intraspecific habitats. Research and physical analysis reveal that maternally derived alkaloids exist in young tadpoles. During tadpole-rearing, mother frogs feed their young an unfertilized egg from their ovaries after dropping each individual tadpole into a repository of water usually found in a bromeliad. Tadpoles lacking the obligate nutritive egg diet do not contain the alkaloid. This step is crucial for the tadpoles to sequester the alkaloid from their mother; without such, young tadpoles become susceptible to predation by arthropods and other frogs.

Evolution

Strawberry poison frog, "Oophaga pumilio", shows extreme variation in color and pattern between populations that have been geographically isolated for more than 10,000 years. When populations are separated by geographic distances and landscape barriers, they frequently experience restricted gene flow, which can enable phenotypic divergence between populations through selection or drift. Their variety in warning coloration is used for their visibility, toxicity and resistance to predators. When divergent phenotypes are mostly restricted to separate islands, the biogeography of color polymorphism suggests a major role for neutral process. However, Summers et al. provide evidences that neutral divergence alone is unlikely to have caused the variation in color patterns. As shown by Lande, rapid evolution in sexually selecting species is led by the interaction of random genetic drift with natural and sexual selection such as random genetic drift in female mating preferences. Color is known to play a role in male–female signaling, mate attraction, and male–male signaling in anurans. Based on Tazzyman and Iwasa’s study that involved collections of samples from main islands in the Bocas del Toro archipelago, its results proved that female preference on male calls led to call divergence and therefore divergence was driven by sexual selection. Mate choice plays a critical role in generating and maintaining biodiversity. Furthermore, spatial variation in predators or habitat features could exert divergent natural selection on coloration in response to its subjection to predator selection. It is still unclear to what extent sexual selection has driven the evolution of color morphs rather than reinforcing the reproductive isolation of morphs. In an aposematic organism such as "Oophaga pumilio", we cannot attribute a phylogenetic signal of selection to female mate choice alone but is quite possible that genetic drift would interact with female color preferences to trigger divergence