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The Marine Toad, Bufo marinus (recently re-classified as Rhinella marina) in Nature and Captivity – Part I, Natural History

Overview
Recently I wrote about those tiny jewels of the frog world, Latin America’s poison frogs (Article Part I and II).  Today I’ll introduce you to a behemoth that is largely their direct opposite, the massive Marine Toad – at once one of the world’s most interesting and troublesome of amphibians (actually, the people who have transported it around the globe are troublesome, not the toads!).

Physical Description
This largest of the world’s toads may reach 10 inches in length.  Generally brown to tan in color, some individuals show a yellow or reddish tint.  One that I received from a friend working on Guam was clad in several shades of yellow and quite beautiful. Enormous paratoid (poison) glands extend from behind the eyes to the sides of the body.  The body is squat and rounded in profile.

There seems to be a great deal of variation in size among different Marine Toad populations, with the true giants that came out of Colombia and Suriname in the 1960’s and early 70’s being rarely seen in the trade today.  I examined a great many in working in Venezuela, and most were in the 4-6 inch range (this comports with locally published accounts).  Florida’s introduced animals are relatively small in size (but large as toads go), as are those in south Texas.

Me with Large Marine ToadThe photo accompanying this article shows me holding a large female that was collected, I believe, in Colombia.  She has inflated her lungs with air to prevent my swallowing her (fat chance!) – the stick is to discourage the two 18 foot long anacondas that share her exhibit from attempting to swallow me!

Range and Habitat
People are sometimes surprised to learn that the Marine Toad is a US native, but those living in southern Texas are indeed part of a naturally occurring group.  Florida and Hawaii’s large populations are introduced.

From Texas, this toad range south from southern Sonora, Mexico through Central America to central Brazil, Amazonian Peru and Bolivia.  Marine Toads have been widely introduced and are well established in Florida, Hawaii, Taiwan, Japan, New Guinea, Australia, and throughout the islands of the Caribbean (i.e. Puerto Rico, Antilles, St. Lucia) and the South Pacific (i.e. Fiji, Guam).

Marine toads dwell in a wide variety of habitats, including open forest, overgrown scrub, grasslands, fields and marshes.  They adjust well to disturbed sites and are common in agricultural areas, suburbs and urban parks (i.e. within Miami, Fla.).  Several I observed on Tortuguero, Costa Rica, crossed a 30 foot stretch of mowed lawn each evening to feed near my bedroom’s outdoor light.

Status in the Wild
Generally common within natural range and usually very common, to the point of being a harmful invasive, where introduced.

Diet
Marine Toads consume nearly any creature that fits within their cavernous mouths – centipedes, roaches, beetles, millipedes, earthworms, land crabs, spiders and other invertebrates, frogs, lizards and snakes.  Mice, birds and similar creatures are taken when encountered, but stomach analysis of toads in the Venezuelan llanos (grasslands) showed this to be a rare occurrence in that habitat.

This is one of only a very few frog species to consume non-living food items (African Clawed Frogs, Xenopus spp. will take carrion and, amazingly, Izecksohn’s Treefrog of Brazil eats berries).  While in Costa Rica, I regularly observed a large toad eating dog food (after pushing open a screen door to get at it!), and those kept by co-workers at the Bronx Zoo ate salad set out for tortoises.  Field reports from New Guinea indicate that Marine Toads there rely upon vegetation as food during the dry season.  Stomach analysis of wild individuals indicates that they also will take carrion (chicken and fish) and the eggs of other Marine Toads.

In addition to hunting by sight, these toads apparently utilize olfaction (rare for a terrestrial frog) as well.

Reproduction
Marine ToadAn extremely flexible reproductive biology accounts for this animal’s success as an invasive species.  Unlike most amphibians, it can reproduce throughout the year in favorable habitats, in brackish (saline) water and in waters containing high fish populations.

Large females may lay as many as 36,000 eggs, attached in strings to aquatic vegetation.  In contrast to most frogs, both eggs and tadpoles are protected by virulent toxins.  The tadpoles take 10 days to 6 months to transform, depending upon temperature and diet, and can survive 10 hours without water.  They consume algae, dead plants, carrion and each other, and generally out-compete or eat the tadpoles of other species.  Newly transformed toads disperse widely and often establish new limits to existing ranges.

Miscellaneous
Marine toads are likely the world’s most widely introduced amphibian (American Bullfrogs and Greenhouse Frogs are close competitors for this title).  They are generally transported to agricultural areas to control insect pests, a strategy that rarely works.  In Australia, for example, the toads seldom catch cane beetles, their intended prey – the beetles dwell high above the ground and the toads do not climb.

Introduced populations expand rapidly, consume native animals and out-compete others.  On Oahu, Hawaii, 148 introduced toads multiplied to over 100,000 in a 2 year period.

The Marine Toad’s toxins are powerful and complex.  Threatened toads will lower their heads and attempt to bring the poison-containing paratoid glands in contact with the attacker.  In Australia, 3 species of quoll (a medium-sized mammal) and 8 species of monitor lizards prey upon the toads and are declining due to deaths caused by the toad’s skin toxins.  Dingoes, snakes, foxes, dogs and other animals have also expired after eating Marine Toads.

Most predators occurring within the Marine Toad’s natural range leave them strictly alone.  I have, for example, housed them with green anacondas for many years – despite that fact that the snakes will avidly consume other frog species.  However, several snake and possibly bird species have evolved toxin immunities and prey upon them.  In Australia, White-Tailed Water Rats have apparently learned to avoid the skin toxins by flipping the toads and chewing through the belly skin to reach the internal organs.

Marine toads are quite responsive to their surroundings.  Captive animals anticipate food upon seeing their keepers, and those living in developed areas learn to gather under street lights to capture insects.

A field report detailing some of the unusual foods and other items found in the stomachs’ of free-living Marine Toads is posted at:
http://www.jstor.org/pss/1564710

 

Product Review – Nutrafin Cycle

Nutrafin Cycle is used to help establish high populations of nitrifying bacteria (the species that convert ammonia to nitrites and nitrates) in aquariums.  At a recent seminar sponsored by Hagen, the manufacturer, I learned that the product has been modified in several important ways. 

 

Cycle contains 5 strains of bacteria, in correct proportion of lithotrophic to heterotrophic types, and these activate almost immediately upon exposure to salt or fresh water.  This ability results from a unique fermentation process that, by joining the bacteria into naturally occurring units, or “flocs”, prepares them for immediate action.  So Cycle effective is the process that fish can now be added to an aquarium on the day it is set up – the nitrogen cycle is in full swing that quickly!

 

Nitrifying bacteria are also necessary in amphibian aquariums, as aquatic species in particular absorb toxins over an even greater surface area than do fish, and so succumb to ammonia poisoning quickly.  Some years ago I learned that the country’s largest African Clawed Frog laboratory (breeders for research) was suggesting that the bacteria might even be useful in amphibian water bowls, as a safety measure.  While I have no direct evidence of such, I have had very good results using bacteria in this way.

 

The main drawback concerning water bowls is the fact that oxygen levels are low (nitrifying bacteria require a high oxygen environment) and the bacteria used in products other than Cycle take 3-4 days to activate.   Given Cycle’s immediate activation and the fact that the bacteria used have fairly low oxygen requirements, I am recommending the product’s use in amphibian water bowls (and aquariums). 

 

Even a single day’s delay in cleaning a water bowl can result in an amphibian’s death – in fact, such is a common occurrence among otherwise long-lived frogs that produce a large volume of waste, such a Horned and African Bullfrogs.  Cycle should prove a very effective form of insurance (not, of course, a replacement for water changes) and, happily enough, it is not possible to overdose the animal.

 

In amphibian aquariums, Cycle used on a weekly basis will also inhibit, via competition, undesirable species of bacteria.  Furthermore, the bacteria in Cycle utilize phosphates as a food source, thereby eliminating a nutrient required by algae and limiting its growth.

 

Has Anyone Observed This?….. Madagascar and Standing’s Day Geckos (Phelsuma madagascariensis grandis, P. m. madagascariensis, P. standingi) maintain excellent health and reproduce without a UVB source

It is well known that many species of lizard, turtle and crocodilian require ultraviolet light of a specific wavelength (290-310 nanometers) in order to synthesize Vitamin D3.  This vitamin, in turn, allows the reptiles to make use of the calcium in their diets.  Such reptiles (which generally bask in the sun in the wild) develop calcium deficiencies and a host of related problems if denied UVB in captivity.  This occurs despite their being offered a diet high in calcium.

Day geckos of the genus Phelsuma seem to require quite high levels of UVB in captivity.  Several species, and gravid females in particular, develop bulging “chalk sacs” (calcium stores) behind the head, and are quick to succumb to health problems in the absence of UVB.

Some years ago, however, I observed a situation that caused me to question what I knew, or thougMadagascar Giant Day Geckoht I knew, about this subject.  A number of Madagascar, Madagascar Giant and Standing’s Day Geckos were released into a densely-planted indoor “rainforest” in NYC’s Central Park Zoo.  The lizards thrived and reproduced, and, when last I checked, had been doing so for several generations.  Animals that are captured from time to time exhibit excellent bone density and overall good health, despite the fact that they have no access to natural or artificial UVB.

The aviary in which they live supports a wide variety of spiders, beetles, roaches, sow bugs and other invertebrates, as well as nectar and fruit producing plants.  I imagine that the lizards, amid this banquet, have found a source of calcium that is usable in the absence of UVB, or D3 that can be absorbed from the diet.  I will keep you posted as to further developments.

I have since spoken with lizard-keepers who maintain day geckos without UVB.  However, as we know little of the interaction between calcium, phosphorus and Vitamin D3 in these animals, a good deal of experimentation is needed, and the results are spotty.  The lizards at the Central Park Zoo are the most robust I’ve seen, and the population has remained so for 15 years or more at this point.

Red-eared Sliders, Chrysemys picta elegans, also suffer from calcium deficiencies if unable to bask under a UVB source – yet I know of a number of instances in which perfectly formed specimens were raised without such.  Again, I can only guess as to the explanation.

I tend to encourage dietary variety in my nutrition articles, due in part to experiences such as described above.  We really know very little about many common reptiles and amphibians, especially concerning nutrition.  I would greatly appreciate hearing about experiences you may have had – good or bad – regarding UVB light and diet.

The abstract of an article about Zoo Zurich’s “free-ranging” colony of Madagascar Giant Day Geckos is posted at:

http://www3.interscience.wiley.com/journal/112731133/abstract?CRETRY=1&SRETRY=0

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