I don’t like spiders and snakes. . .
Warning to arachnophobes and the faint of heart: This is the stuff of nightmares, so you might want to proceed with caution.
A University of Michigan-led team of biologists has documented 15 rare and disturbing predator-prey interactions in the Amazon rainforest including keep-you-up-at-night images of a dinner plate-size tarantula dragging a young opossum across the forest floor.
It’s hideous; we’re not going to lie
Something “pretty special”
The photos are part of a new journal article titled “Ecological interactions between arthropods and small vertebrates in a lowland Amazon rainforest.” Arthropods are invertebrate animals with segmented bodies and jointed appendages that include insects, arachnids (spiders, scorpions, mites, and ticks), and crustaceans.
The article, published online Feb. 28 in Amphibian & Reptile Conservation, details instances of arthropod predators — mostly large spiders along with a few centipedes and a giant water bug — preying on vertebrates such as frogs and tadpoles, lizards, snakes, and even a small opossum.
“This is an underappreciated source of mortality among vertebrates,” says evolutionary biologist Daniel Rabosky. “A surprising amount of death of small vertebrates in the Amazon is likely due to arthropods such as big spiders and centipedes.”
Once or twice a year, Rabosky leads a team of U-M researchers (faculty members, postdocs, graduate students, and undergraduates) and international collaborators on a month-long expedition to the Los Amigos Biological Station in the remote Madre de Dios region of southeastern Peru.
“We were pretty ecstatic and shocked, and we couldn’t really believe what we were seeing, we knew we were witnessing something pretty special, but we weren’t aware that it was the first observation until after the fact.”
The study site, in lowland Amazon rainforest near the Andes foothills, is in the heart of one of the most diverse ecosystems on the planet. The team’s main research focus is the ecology of reptiles and amphibians. But over the years, the scientists have witnessed and documented numerous interactions between arthropod predators and vertebrate prey.
“We kept recording these events, and at some point we realized that we had enough observations to put them together in a paper,” says Rabosky. He also is an associate professor in the Department of Ecology and Evolutionary Biology and an associate curator at the U-M Museum of Zoology.Spiders are among the most diverse arthropod predators in the tropics, and previous reports of spider predation in the Amazon include prey from all major vertebrate taxonomic groups: fish, amphibians, reptiles, birds, and mammals.
But knowledge of these interactions remains limited, especially given the diversity of vertebrate prey and potential arthropod predators in species-rich tropical communities. The new paper includes observations from 2008, 2012, 2016, and 2017.
“These events offer a snapshot of the many connections that shape food webs, and they provide insights into an important source of vertebrate mortality that appears to be less common outside the tropics,” says the study’s first author, Rudolf von May, a postdoctoral researcher in Rabosky’s lab.
“Where we do this research there are about 85 species of amphibians — mostly frogs and toads — and about 90 species of reptiles,” von May says. “And considering that there are hundreds of invertebrates that potentially prey upon vertebrates, the number of possible interactions between species is huge, and we are highlighting that fact in this paper.”
Size does matter
In addition to the Los Amigos Biological Station, researchers observed sites at the Villa Carmen Biological Station, also in Peru’s Madre de Dios region, and at the Madre Selva Research Station in the Loreto region of northern Peru.
Nearly all of the sightings were made at night, when the arthropod predators are most active. During their night surveys, team members walked slowly through the forest with flashlights and headlamps, in single file, scanning the forest and listening intently.
During one of those night surveys, U-M doctoral candidate Michael Grundler and two other students “heard some scrabbling in the leaf litter.”
“We looked over and we saw a large tarantula on top of an opossum,” says Grundler, a co-author of the paper. “The opossum had already been grasped by the tarantula and was still struggling weakly at that point, but after about 30 seconds it stopped kicking.”
The tarantula was the size of a dinner plate, and the young mouse opossum was about the size of a softball. Grundler’s sister Maggie pulled out her cell phone and shot photos and some video.
Later, an opossum expert at the American Museum of Natural History confirmed they had captured the first documentation of a large mygalomorph spider preying on an opossum. The infraorder Mygalomorphae is a group of mostly heavy-bodied, stout-legged spiders that includes tarantulas.
Such a tangled web
Most predaceous arthropods rely on specialized body parts and venom to capture and paralyze vertebrate prey. These adaptations include modified jaws, enlarged beaks, and massive fangs. Some groups have evolved dozens of venom proteins that are injected during prey capture.
Other predator-prey interactions documented in the Amphibian & Reptile Conservation paper include:
- Several examples of large spiders of the family Ctenidae preying on frogs and also a lizard. Most of the predation events documented in the paper involve spiders, and most of those were ctenids, which are commonly known as wandering spiders. Ctenid spiders are sit-and-wait predators that hunt at night and use specialized hairs on their legs to detect air vibrations and the direction of prey. Their principal eyes are responsible for object discrimination, and secondary eyes detect motion.
- A large scolopendrid centipede consuming a live Catesby’s snail-eater snake, and another centipede eating a dead coral snake that it had decapitated. “Coral snakes are very dangerous and can kill humans,” says U-M doctoral candidate and study co-author Joanna Larson. “To see one taken down by an arthropod was very surprising. Those centipedes are terrifying animals, actually.”
In addition to predation events, the researchers also report on lethal parasite infections in lowland Amazonian frogs and commensal relationships between spiders and frogs. A commensal relationship is one in which one organism benefits and the other is not harmed.
“One of the coolest things about working in Peru is the sheer number of species that you encounter every day simply by walking in the forest,” says Larson, who studies the evolution of diet in frogs. “Every day you see something new and exciting.”
“One offshoot of the work that we’ve been doing is this collection of odd natural history events we’ve witnessed involving arthropod predators and vertebrates,” she says. “I have not reached the level of being grossed out by any of it yet. We’ll see what else Peru has to offer.”
The other authors of the paper, in addition to Rabosky, von May, Grundler and Larson, are Emanuele Biggi of the International League of Conservation Photographers; Heidy Cárdenas and Roy Santa-Cruz of the Museo de Historia Natural de la Universidad Nacional de San Agustín, Peru; M. Isabel Diaz of the Universidad Nacional de San Antonio Abad del Cusco and the Museo de Biodiversidad del Perú, both in Peru; Consuelo Alarcón of John Carroll University and the Museo de Biodiversidad del Perú; Valia Herrera of the Universidad Nacional Mayor de San Marcos, Peru; Francesco Tomasinelli of Milan, Italy; Erin P. Westeen and Maggie Grundler of the University of California, Berkeley; Ciara Sánchez-Paredes of the Universidad Peruana Cayetano Heredia, Peru; and Pascal Title and Alison Davis Rabosky of the U-M Museum of Zoology and the Department of Ecology and Evolutionary Biology.
The field research was supported by a fellowship from the David and Lucile Packard Foundation to Daniel Rabosky, as well as the Amazon Conservation Association, the Wildlife Conservation Society, the Rosemary Grant Award, the Edwin C. Hinsdale UMMZ Scholarship, and the University of Michigan.
The paper is available online at: Amphibian & Reptile Conservation