Glass frogs living near roaring waterfalls wave hello to attract mates

UC Berkeley conservationist discovers the first evidence of visual communication among tropical glass frogs

UNIVERSITY OF CALIFORNIA - BERKELEY

Research News

 

Berkeley -- Most frogs emit a characteristic croak to attract the attention of a potential mate. But a few frog species that call near loud streams -- where the noise may obscure those crucial love songs -- add to their calls by visually showing off with the flap of a hand, a wave of a foot or a bob of the head. Frogs who "dance" near rushing streams have been documented in the rainforests of India, Borneo, Brazil and, now, Ecuador.

Conservation ecologist Rebecca Brunner, a Ph.D. candidate at the University of California, Berkeley, has discovered that the glass frog Sachatamia orejuela can be added to the list of species that make use of visual cues in response to their acoustic environments. This is the first time a member of the glass frog family (Centrolenidae) has been observed using visual communication in this manner.

"A handful of other frog species around the world use visual signaling, in addition to high-pitched calls, to communicate in really loud environments," Brunner said. "What's interesting is that these species are not closely related to each other, which means that these behaviors likely evolved independently, but in response to similar environments -- a concept called convergent evolution."

Sachatamia orejuela glass frogs are native to the rainforests of Ecuador and Colombia. They are especially unique because they are almost exclusively found on rocks and boulders within the spray zones of waterfalls, where rushing water and slippery surfaces offer some protection against predators, and their green-gray color and semi-transparent skin make them nearly impossible to spot. As a result, little is known about this species' mating and breeding behavior.

Brunner, who studies the bioacoustics of different ecological environments, was chest-deep in an Ecuadorean rainforest stream recording the call of a Sachatamia orejuela when she first observed this visual signaling behavior. As soon as she saw the frog repeatedly raising its front and back legs, Brunner climbed a slippery rock face and balanced on one foot to get video footage of the behavior.

"I was already over the moon because I had finally found a calling male after months of searching. Before our publication, there was no official record of this species' call, and basic information like that is really important for conservation," Brunner said. "But then I saw it start doing these little waves, and I knew that I was observing something even more special."

While she filmed, the frog continued to wave its hands and feet and bob its head. She also observed another male Sachatamia orejuela glassfrog a few meters away performing the same actions.

"This is a really exhilarating discovery because it's a perfect example of how an environment's soundscape can influence the species that live there. We've found that Sachatamia orejuela has an extremely high-pitched call, which helps it communicate above the lower-pitched white noise of waterfalls. And then to discover that it also waves its hands and feet to increase its chances of being noticed -- that's a behavior I've always loved reading about in textbooks, so it is beyond thrilling to be able to share another amazing example with the world," said Brunner.

Though the COVID-19 pandemic has put a pause on Brunner's fieldwork, she hopes to return to Ecuador soon to continue her research, which links bioacoustics and conservation.

"One of the best things about fieldwork is that nature is always full of surprises -- you never know what discoveries you may happen upon," Brunner said. "I hope our findings can serve as a reminder that we share this planet with incredible biodiversity. Conserving ecosystems that support species like Sachatamia orejuela is important not only for our well-being, but also for our sense of wonder."

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Juan M. Guayasamin, professor of biology at Universidad San Francisco de Quito, is a co-author of this research, which appears in the journal Behaviour. Brunner's fieldwork was supported by a National Geographic Explorer Grant (EC-57058R-19) and a National Science Foundation Graduate Research Fellowship.

Youtube video: https://www.youtube.com/watch?v=U6prmVIyxXI&feature=emb_title

Large mammals make soil more fertile in tropical forests

A study conducted by scientists at São Paulo State University demonstrates that animals like peccaries and tapirs boost soil levels of nitrogen, an essential element to plant growth.

FUNDAÇÃO DE AMPARO À PESQUISA DO ESTADO DE SÃO PAULO

Research News

 

IMAGE: ANIMALS LIKE PECCARIES AND TAPIRS BOOST SOIL LEVELS OF NITROGEN, AN ESSENTIAL ELEMENT TO PLANT GROWTH view more 

CREDIT: JOÃO PAULO KRAJEWSKI

The White-lipped peccary Tayassu pecari is a boar-like hoofed mammal found throughout Central and South America. These animals roam the forest in bands of 50 to 100 individuals, eating a wide variety of foods. In Brazil's Atlantic Rainforest, they prefer the fruit of the jussara palm Euterpe edulis.

The jussara is very abundant in this biome, probably thanks to vast amounts of dung, urine, and soil trampling by peccaries as well as tapirs (Tapirus terrestris) and other fruit-eating animals, or frugivores. This behavior releases forms of nitrogen, a key element in plant growth.

A study supported by São Paulo Research Foundation - FAPESP and published in the journal Functional Ecology showed that in areas free of these frugivores the level of ammonium, a form of nitrogen in soil, was up to 95% lower. The findings evidence for the first time the importance of these animals to the nitrogen cycle and serve as yet another warning of the ecosystem losses caused when large mammals disappear from tropical forests.

"Any farmer knows how crucial the nitrogen cycle is to achieve high crop yields. Studies in other environments have already shown that the presence of ruminants stimulates the growth of grasses thanks to the effect of their excretions on the nitrogen cycle, including optimization of microorganism activity. Our latest study has now shown that large fruit-eating mammals provide the same service in tropical forests," said Nacho Villar, first author of the article. Villar is a researcher affiliated with São Paulo State University's Institute of Biosciences (IB-UNESP) in Rio Claro, Brazil. Currently he is a postdoctoral fellow at the Netherlands Institute of Ecology (NIOO-KNAW).

The study also shows that these animals redistribute nitrogen, fertilizing areas that would otherwise be nutrient-poor, and hence sustain plant growth. According to the researchers' estimates, such areas receive four times more ammonium and 50 times more nitrate than areas without frugivores.

The study was part of the Thematic Project "Ecological consequences of defaunation in the Atlantic Rainforest", for which the principal investigator was Mauro Galetti, a professor at IB-UNESP, and was conducted under the auspices of FAPESP's Research Program on Biodiversity Characterization, Conservation, Restoration and Sustainable Use (BIOTA-FAPESP)).

The researchers used South America's leading herbivore exclosure experiment, comprising 86 forest plots measuring 15 square meters in Serra do Mar State Park (São Paulo State), Brazil's largest continuous Atlantic Rainforest reserve. Half the plots have been fenced since 2010 to prevent the entry of large mammals. All animals can roam freely into and out of the other plots.

Camera traps on fenced and open plots demonstrated the presence or absence of White-lipped peccaries, Collared peccaries (Pecari tajacu) and tapirs, among other frugivores.

Microorganisms, ammonium and nitrate

In this study, the researchers analyzed soil samples from eight exclusion plots and their paired open controls, collected in the wet and dry seasons. Jussara palm abundance varied across the different plots.

In soil from open plots, ammonium levels were 95% higher, and rates of nitrification (conversion of ammonium to nitrate) were also higher owing to the frugivore-driven abundance of microorganisms in the soil. Although plants absorb ammonium, their metabolism can immediately use nitrate, which is therefore considered more valuable in terms of plant growth.

"Peccaries account for 80% to 90% of the total mammal biomass in the Atlantic Rainforest. Large groups of these animals roam extensive territories, fertilizing the forest," Villar said. "Tapir density is lower, so their contribution to the nitrogen cycle isn't as great, but the amount excreted by each individual is considerable, as is each animal's range as it disperses seeds." Another study by the same group had already shown how peccaries and tapirs contribute to plant species diversity and abundance (read more at: https://agencia.fapesp.br/31840).

This large frugivore biomass is attracted by the vast amount of fruit from jussara palms, whose abundance is due to fertilization of the soil by the animals' excretions (which also probably increase the palms' fruit-bearing capacity). The outcome is a virtuous cycle for animals, plants and soil microorganisms (also stimulated by the excretions), leading the researchers to propose the term "fruiting lawns" as a description of such areas. The term is considered analogous to the concept of grazing lawns, which refers to the positive feedback between ruminant food consumption and food availability in African savannas and other grassland landscapes.

The next steps in the group's research will include investigating whether the increase in nitrogen due to plants' interaction with large mammals boosts their carbon absorption and reduces the release of greenhouse gases from the soil. If so, plant-animal interaction should play a major role in regulating global climate change.

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About São Paulo Research Foundation (FAPESP)

The São Paulo Research Foundation (FAPESP) is a public institution with the mission of supporting scientific research in all fields of knowledge by awarding scholarships, fellowships and grants to investigators linked with higher education and research institutions in the State of São Paulo, Brazil. FAPESP is aware that the very best research can only be done by working with the best researchers internationally. Therefore, it has established partnerships with funding agencies, higher education, private companies, and research organizations in other countries known for the quality of their research and has been encouraging scientists funded by its grants to further develop their international collaboration. You can learn more about FAPESP at http://www.fapesp.br/en and visit FAPESP news agency at http://www.agencia.fapesp.br/en to keep updated with the latest scientific breakthroughs FAPESP helps achieve through its many programs, awards and research centers. You may also subscribe to FAPESP news agency at http://agencia.fapesp.br/subscribe.

Designer cytokine makes paralyzed mice walk again

Paraplegia

RUHR-UNIVERSITY BOCHUM

Research News

 

The researchers published their report in the Journal Nature Communications from 15 January 2021.

When the communication breaks down

Spinal cord injuries caused by sports or traffic accidents often result in permanent disabilities such as paraplegia. This is caused by damage to nerve fibers, so-called axons, which carry information from the brain to the muscles and back from the skin and muscles. If these fibers are damaged due to injury or illness, this communication is interrupted. Since severed axons in the spinal cord can't grow back, the patients suffer from paralysis and numbness for life. To date, there are still no treatment options that could restore the lost functions in affected patients.

Designer protein stimulates regeneration

In their search for potential therapeutic approaches, the Bochum team has been working with the protein hyper-interleukin-6. "This is a so-called designer cytokine, which means it doesn't occur like this in nature and has to be produced using genetic engineering," explains Dietmar Fischer. His research group already demonstrated in a previous study that hIL-6 can efficiently stimulate the regeneration of nerve cells in the visual system.

In their current study, the Bochum team induced nerve cells of the motor-sensory cortex to produce hyper-Interleukin-6 themselves. For this purpose, they used viruses suitable for gene therapy, which they injected into an easily accessible brain area. There, the viruses deliver the blueprint for the production of the protein to specific nerve cells, so-called motoneurons. Since these cells are also linked via axonal side branches to other nerve cells in other brain areas that are important for movement processes such as walking, the hyper-interleukin-6 was also transported directly to these otherwise difficult to access essential nerve cells and released there in a controlled manner.

Applied in one area, effective in several areas

"Thus, gene therapy treatment of only a few nerve cells stimulated the axonal regeneration of various nerve cells in the brain and several motor tracts in the spinal cord simultaneously," points out Dietmar Fischer. "Ultimately, this enabled the previously paralyzed animals that received this treatment to start walking after two to three weeks. This came as a great surprise to us at the beginning, as it had never been shown to be possible before after full paraplegia."

The research team is now investigating to what extent this or similar approaches can be combined with other measures to optimize the administration of hyper-Interleukin-6 further and achieve additional functional improvements. They are also exploring whether hyper-interleukin-6 still has positive effects in mice, even if the injury occurred several weeks previously. "This aspect would be particularly relevant for application in humans," stresses Fischer. "We are now breaking new scientific ground. These further experiments will show, among other things, whether it will be possible to transfer these new approaches to humans in the future."

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Funding

The German Research Foundation funded the study.

Original publication

Marco Leibinger, Charlotte Zeitler, Philipp Gobrecht, Anastasia Andreadaki, Günter Gisselmann, Dietmar Fischer: Transneuronal delivery of hyper-IL-6 enables functional recovery after severe spinal cord injury in mice, in: Nature Communications, 2021, DOI: 10.1038/s41467-020-20112-4,
https://rdcu.be/cdCob

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