Friday, August 09, 2024

 

Social rank may determine if animals live fast, die young


Dartmouth study of macaques suggests leaders put immediate survival above longevity.

Peer-Reviewed Publication

Dartmouth College

Macaque washing 

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Macaques on Thailand’s Koram Island may engage in food-washing based on their social rank. The researchers set trays of sliced cucumber mixed with varying amounts of sand on the beach to observe how thoroughly the animals cleaned their food before eating it. They found that lower-ranked animals (pictured) first washed their cucumber slices in the ocean, often well past the point it was clean.

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Credit: Amanda Tan




Anyone who has picnicked on the beach has experienced the unpleasant crunch of a sandwich with a surprise helping of sand. But for primates, the tolerance for sand may depend on whether their energy is better spent reproducing and fighting rivals or on protecting their teeth from a mouthful of grit, according to a new Dartmouth study.

Social rank may determine whether animals prioritize immediate energy consumption over long-term health, or vice versa, the researchers report in the journal eLife. They observed the eating habits of long-tailed macaques on Thailand's Koram Island and found that the dominant and lowest-ranked animals briefly rubbed sand-covered food on their fur or between their paws before devouring it, along with most of the sand, and moving on to the next morsel.

Middle-ranked monkeys, however, having more time on their paws, carried their food to the water's edge and washed it in the sea to remove the sand. These animals often expended time and energy scrubbing their snacks past the point when they were clean and would even amble down the beach on their hind legs with their front paws full of food.

Nathaniel Dominy, the study's corresponding author and the Charles Hansen Professor of Anthropology at Dartmouth, says the findings provide insight into how animals—even those in hierarchical groups—choose survival strategies based on individual needs. The study supports the disposable soma hypothesis, which proposes that animals sometimes prioritize immediate survival and reproduction over longevity, Dominy says, adding, "Delayed gratification has its limits."

That may be the case for monkeys at the top and the bottom of the social ladder, for whom life is short and hard, Dominy says. As a result, these animals consume and conserve energy whenever they can. Existing research shows that sand causes significant damage to macaque tooth enamel. But for dominant males especially, that may not be important in a life fraught with challengers.

"High-ranking males are constantly lunging at or chasing other males, behaviors that maximize their siring of offspring. So, they need to eat rapidly to make up for that energy expenditure and that's exactly what we saw them doing," Dominy says. "They just stuff food into their mouths—sand be damned—because they don't have time to walk to the water. It's the urgency of now that matters, not their teeth. To humans, it seems like a shrewd calculation."

The monkeys that wash their food might instead be playing a long game, says Amanda Tan, the study's co-corresponding author and an assistant professor of anthropology at Durham University. Tan worked on the project as a postdoctoral scholar in Dominy's research group at Dartmouth.

"We think these animals invest a lot more time in washing their food because they cannot afford to damage their teeth and compromise their longevity," Tan says. "This strategy could allow them to maximize their potential reproductive success by living longer and producing more offspring over their lifetime."

The findings also could shed light on how the wear and pitting observed in the fossilized teeth of early humans relate to social structure and access to water, Dominy says.

"What if tooth wear is telling us about rank, not food properties," Dominy asks. "If we find more variable wear on a male hominin tooth, the classic interpretation is that it's the result of a varied diet. We ought to consider the possibility that he was eating quickly and couldn't be bothered to clean his food. Or maybe he lived in an area that was historically arid. We have cause to be more open-minded about variable tooth wear."

To observe the macaques' eating habits, Tan and the study's first author, Jessica Rosien '21, arranged plastic trays on the beach that contained cucumber slices. The slices were either on their own, placed on top of sand, or buried in sand. Rosien and Tan recorded the animals every day for six weeks as they foraged for cucumbers in the trays, capturing nearly 1,300 instances of food-handling by 42 individual macaques.

The monkeys that washed their food devoted an average of five seconds to over a minute to each cucumber slice—often washing multiple slices—while the average amount of time spent just brushing sand off a slice was effectively zero, the researchers report. That time makes a difference. In lab trials with sand-coated cucumbers, the researchers found that washing removed 93% of sand and brushing removed only 75%.

The researchers determined social rank using established methods of observing how the animals interact. But the social order was not subtle, Rosien says. She recalls a low-ranking male that, rejected by his peers, spent his time sitting next to her on the beach. A high-ranked female would fearlessly challenge other macaques for their cucumbers and steal anything Rosien left unattended, including her backpack of supplies. "I loved getting to know the different monkeys' personalities over time and I definitely got a sense of the impact of social rank," she says.

Before the study, Tan worked on Koram Island for years observing how the macaques developed skills using tools through social learning. She knew that some animals washed their food while others did not. It was Dominy who wondered if there was a rank-based trade-off between getting calories quickly versus preventing tooth wear, Tan says. "To our knowledge, no one had tested the hypothesis that food-washing served as an adaptive function for removing grit," she says.

Food-washing among primates is not common, Dominy says. The Koram Island macaques were first observed doing so after the 2004 Indian Ocean earthquake and tsunami. Their habit became a draw for tourists, who, before authorities put a stop to it, would throw fruit on the beach from boats to watch the animals wash it in the surf.

The other known instance is among the Japanese macaques on Japan's Kōjima Island. In the 1950s, researchers studying the animals lured them toward the beach with wheat and sweet potatoes to observe them more clearly.

In 1953, a young female named Imo first picked up a sandy sweet potato and washed it in a stream. Five years later, the other animals had taken up the practice, washing their food in the sea. Today, 92% of the Kōjima Island macaques wash their food.

"I love the story of Imo," Rosien says. "It shows how an individual can cause a shift in a whole population. To see such a significant advance in real time makes it easier to understand how small changes can lead to big changes."

The spread of a similar habit in two independent populations separated by 50 years and 5,000 miles speaks to the value of culture, Dominy says.

"You have to be experimental and entrepreneurial to invent a new behavior out of whole cloth, but it has to be clear enough that other individuals will understand its purpose and copy it," he says. "And they have to be smart enough to recognize when another animal has figured out something valuable. That's what culture is—seeing the value of a new behavior and adopting it."

The value for the macaques of washing their food was considered so obvious, no one had studied it before, the researchers write in their paper. "Even if something seems intuitive, it’s still important to be curious, ask questions, and test assumptions," Tan says.

"In this case," she continues, "our study provides a fuller picture of the various trade-offs that animals may juggle relative to their place in a social structure and gives us a better understanding of how that leads individuals to behave distinctly."


First author Jessica Rosien '21 recorded nearly 1,300 instances of food-handling by 42 individual macaques over six weeks. Monkeys that washed their food devoted an average of five seconds to over a minute to each cucumber slice—often washing multiple slices—while the average amount of time spent just brushing sand off a slice was effectively zero, the researchers report. The researchers determined social rank using established methods of observing how the animals interact.

Credit

Amanda Tan



Video of macaques washing and [VIDEO] | 


Video of macaques washing and brushing. (VIDEO)

Dartmouth College


Caption

Dominant macaques briefly brushed cucumber slices from the experimental setup on their fur before eating them, along with a mouthful of tooth-degrading sand. Lower-ranked macaques carried their slices to the ocean and washed them obsessively before eating. The macaques picked up their habit of washing food after the 2004 tsunami. Afterward, tourists would throw fruit from boats to watch the animals food-wash, but the government put a stop to the practice.


Credit

Jessica Rosien

 

Cutting-edge 3D-printed microneedle technology revolutionizes remote healthcare




Terasaki Institute for Biomedical Innovation




Los Angeles, California – August 6, 2024 - In a significant leap forward for healthcare equity and accessibility, researchers at the University of Victoria and the Terasaki Institute for Biomedical Innovation (TIBI) have developed a revolutionary system that combines remote health monitoring and drug delivery using 3D-printed hollow microneedles. This innovative approach, detailed in a recent study published in Advanced Healthcare Materials, promises to transform healthcare delivery, particularly for those in underserved or remote regions.

The integrated theranostic microneedle array (MNA) system significantly advances personalized medicine. These 3D-printed hollow microneedles provide painless and minimally invasive access to interstitial fluid, revolutionizing drug delivery and diagnostics.

It features an array of colorimetric sensors that quantitatively measure key health indicators such as pH, glucose, and lactate levels. Simultaneously, the system incorporates a remotely-triggered mechanism for on-demand drug delivery.

One of the most notable features of this technology is its use of an ultrasonic atomizer, which streamlines the drug delivery process. This innovation enables rapid, pumpless, and point-of-care drug administration, significantly enhancing the system's portability and reducing complexity.

The system's capabilities are impressive, with a demonstrated ability to detect pH levels ranging from 3 to 8, glucose concentrations up to 16 mm, and lactate levels up to 1.6 mm. These measurements provide crucial data for monitoring various health conditions.

A vital component of this technology is its accompanying smartphone application, which serves as an interface for both the sensing and drug delivery functions. This user-friendly approach ensures that patients and healthcare providers can easily access and interpret the data and control the drug delivery process.

The implications of this technology are far-reaching. By enabling remote health monitoring and treatment, it has the potential to bridge geographical and socioeconomic disparities in healthcare access. This democratization of healthcare could lead to more timely interventions, continuous monitoring, and truly personalized care, regardless of a patient's location or economic status. The system's potential impact on managing chronic diseases that require long-term treatment is particularly promising. The ability to deliver medications on-demand and monitor health indicators non-invasively could significantly improve patient outcomes and quality of life. As healthcare systems worldwide grapple with issues of equity and access, this technology offers a glimpse into a future where quality healthcare is not limited by geography or socioeconomic factors. This system combines remote monitoring, on-demand drug delivery, and user-friendly interfaces. It represents a significant step towards a more equitable distribution of health resources and outcomes.

Dr. Ali Khademhosseini, CEO of the Terasaki Institute for Biomedical Innovation and a renowned expert in bioengineering, commented, "This innovative approach confronts drug delivery challenges, particularly in managing chronic diseases requiring long-term treatment, while also offering avenues for non-invasive health monitoring through microneedle-based sensors."

The researchers behind this groundbreaking work have addressed current drug delivery and health monitoring challenges and paved the way for future innovations in personalized, accessible healthcare for all.

###

For more information, please contact:

Stewart Han

Email: shan@terasaki.org 

 

Alireza Hassani, Ph.D. 

Email: hassania@terasaki.org 

 

Grant Information: This study received backing from the Natural Sciences and Engineering Research Council of Canada (NSERC), the International Collaboration on Repair Discoveries (ICORD), the Canadian Institutes for Health Research (CIHR), and the Canadian Foundation for Innovation (CFI).

About Terasaki Institute for Biomedical Innovation (TIBI):

The Terasaki Institute for Biomedical Innovation is a non-profit research organization dedicated to leveraging cutting-edge technology to address global health challenges. By fostering interdisciplinary collaborations and pushing the boundaries of innovation, TIBI aims to transform healthcare and improve lives worldwide.

DESANTISLAND

South Florida estuaries warming faster than Gulf of Mexico, global ocean, USF research shows



Possible causes include evaporation, water capacity and residence time (the amount of time water spends in an estuary). No single factor has been identified as dominant



Peer-Reviewed Publication

University of South Florida

Chuanmin Hu, University of South Florida 

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Chuanmin Hu, University of South Florida

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Credit: USF




TAMPA. (Aug. 7, 2024) – Sea surface temperatures are on the rise around the world, but the problem is pronounced in South Florida, according to a series of studies published by researchers at the University of South Florida College of Marine Science.

Estuaries in South Florida have experienced rapid warming over the past two decades, including a record-breaking marine heat wave in 2023.

Using satellite data, the researchers found that sea surface temperatures in four estuaries in South Florida have risen faster than sea surface temperatures globally and in the Gulf of Mexico. The findings, published in Environmental Research Letters and Estuaries and Coasts, paint a troubling picture for the marine life that calls Florida home.

“The temperatures in South Florida estuaries are not only rising faster than the global average, but also faster than temperatures in the open Gulf of Mexico,” said Chuanmin Hu, professor of physical oceanography at the University of South Florida and co-author of the recent papers. “We even saw more of a response within the estuaries to last year’s marine heat wave.”

Over the past two decades, sea surface temperatures in Florida Bay, Tampa Bay, St. Lucie Estuary and Caloosahatchee River Estuary rose around 70 percent faster than the Gulf of Mexico and 500 percent faster than the global oceans, according to the authors. The temperatures are expected to take a toll on marine life.

Estuaries are nurseries where many marine animals begin their lives. South Florida’s estuaries are home to critical habitats such as seagrass meadows, and adjacent waters in the Florida Keys are home to world-renowned coral reefs. These may be impacted by rising water temperatures.

“Algae, seagrass and coral are all sensitive to temperature changes,” Hu said. “Algae prefer warm water, which can increase the size and frequency of blooms. Meanwhile, seagrass and coral undergo stress if the water gets too warm.”

The researchers hope to partner with colleagues at the Florida Fish and Wildlife Conservation Commission and the National Oceanic and Atmospheric Administration to explore the potential impacts of water temperatures on seagrass and coral populations in South Florida.

The researchers speculated on possible causes for the high rate of warming in South Florida’s estuaries, including evaporation, water capacity and residence time (the amount of time water spends in an estuary). No single factor has been revealed as dominant.

Ongoing research by Hu and Jing Shi, a doctoral student in Hu’s lab and first author of the papers, will investigate another peculiar observation: the accelerated warming seen in South Florida’s estuaries has not been detected in other estuaries across the region.

“Not every estuary around the Gulf of Mexico is behaving this way,” Hu said. “These temperature changes appear unique to the estuaries of South Florida.”

The next question, Hu said, is how long this faster warming in South Florida will be sustained.

“We expect the rate of warming to eventually balance with the open Gulf of Mexico,” he said. “We just don’t know when that will happen.”

This research was supported by a grant from the NASA Water Resources Program and a USF presidential fellowship.


This high-resolution image from the ECOSTRESS dataset depicts sea surface temperatures around the Florida Keys in response to the 2023 marine heat wave. Courtesy of Jing Shi.

About the University of South Florida

The University of South Florida, a high-impact research university dedicated to student success and committed to community engagement, generates an annual economic impact of more than $6 billion. With campuses in Tampa, St. Petersburg and Sarasota-Manatee, USF serves approximately 50,000 students who represent nearly 150 different countries. U.S. News & World Report has ranked USF as one of the nation’s top 50 public universities for five consecutive years, and this year USF earned its highest ranking ever among all universities public or private. In 2023, USF became the first public university in Florida in nearly 40 years to be invited to join the Association of American Universities, a prestigious group of the leading universities in the United States and Canada. Through hundreds of millions of dollars in research activity each year and as one of the top universities in the world for securing new patents, USF is a leader in solving global problems and improving lives. USF is a member of the American Athletic Conference. Learn more at www.usf.edu. 

 

Bacterial gut diversity improves the athletic performance of racehorses




University of Surrey





The composition of gut bacteria of Thoroughbred racehorses at one-month-old can predict their future athletic performance, according to a new study from the University of Surrey. Foals with lower bacterial diversity at 28 days old also had a significantly increased risk of respiratory disease later in life. 

Researchers from Surrey's School of Veterinary Medicine and School of Bioscience, led by Professor Chris Proudman, investigated the composition of gut bacteria in Thoroughbred foals bred for flat racing and its impact on their long-term health and athletic performance.  

To investigate this, 438 faecal samples from 52 foals were analysed and respiratory, gastrointestinal, orthopaedic and soft-tissue health issues were tracked from birth to age three. In addition, the team analysed information regarding finishing position, official rating, and total prize money earnings as measures of athletic performance.  

Professor Chris Proudman, Professor of Veterinary Clinical Science at the School of Veterinary Medicine at the University of Surrey, said:  

"Minimising the risk of disease and injury is important for the welfare of racehorses, and maximising their athletic potential is important for their owners. We have found that gut health, in particular the health of gut bacterial communities very early in life, exerts a profound and enduring impact on racehorse health and performance." 

Researchers found that the athletic performance of the foals was positively associated with higher faecal bacterial diversity at one month old. They identified that a higher abundance of the bacteria Anaeroplasmataceae was associated with a higher official rating (an evaluation of a horse based on its past performances), and increased levels of Bacillaceae at 28 days old were linked to higher race placings.  

The team also investigated the long-term impact of foals receiving antibiotics during the first month of life. It was found that these foals had significantly lower faecal bacterial diversity at 28 days old compared to other foals who did not receive such treatments. Further analysis revealed that these foals won significantly lower prize money earnings (an indicator of athletic performance) in their subsequent racing careers. In addition, foals who received antibiotics during their first 28 days of life had a significantly increased rate of developing a respiratory disease compared to their counterparts. 

Professor Roberto La Ragione, co-investigator from the School of Bioscience at the University of Surrey, said: 

"Antibiotics are vital in treating infections and protecting the long-term health of foals; they do, however, need to be used responsibly. Our study demonstrates that treatment with antibiotics can disrupt the healthy gut microbiome with long-term impacts on health and performance. The next part of our study will examine how we can minimise disruption of gut bacteria when antibiotics have to be used to treat infections." 

Interestingly, researchers also identified that low gut bacterial diversity in early life is associated with an increased risk of soft-tissue and orthopaedic issues developing later in life. Researchers believe that the health impacts of low gut bacterial diversity in early life are likely to be related to immunological priming. The reasons underlying the observed negative impacts on racehorse performance are currently not understood. 

Dr Kirsten Rausing, Chairman of the International Thoroughbred Breeders Federation and, through her ALBORADA Trust, study sponsor, commented  

"This ground-breaking study has identified the importance of gut health in our very young foals. As breeders, if we can get this right, we will produce foals that will be healthier, and that will grow into more successful racehorses." 

Work is currently underway to develop novel probiotics that will enhance the gut health of foals in early life and to investigate how antibiotics can be used whilst preserving gut health. 

This study is published in the journal Scientific Reports (link will go live when paper is published).

Professor Chris Proudman will be speaking further on this research at the Thoroughbred Breeders Association at Newbury on 13 August. If you would like to attend the event, please contact Victoria.Murrell@thetba.co.uk

More information on horse microbiome and research currently underway at the University, please visit here.

Notes to editors 

  • Due to the nature of the study-specific horses, their official race positions or training yards cannot be identified 
  • Foals came from 5 stud farms and were in training at 27 different training yards across the country
  • Professor Chris Proudman is available for interview on request 
  • Pictures of foals are available on request. (Please note these foals were not a part of the study)  

Paper information

Paper title: 'Early-life gut bacterial community structure predicts disease risk and athletic performance in horses bred for racing.'

DOI: 10.1038/s41598-024-64657-6

 

Fishing is causing frightened fish to flee when they should flirt




Lancaster University
Fish 

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Squaretail groupers at a spawning aggregation site

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Credit: Rucha Karkarey




Populations of squaretail grouper face an uncertain future as new research shows fishing that targets their spawning sites is causing males to be repeatedly scared away from their territories during their short mating meet-ups.

By fleeing for safety, individuals are losing valuable time to catch the eye and court female fish.

A study, led by scientists at Lancaster University and published today in Biology Letters, shows that the impacts of fishing that targets squaretail grouper spawning sites goes beyond those fish that are caught, causing widespread behavioural change in those left behind.

These changes impact ability to reproduce. With disrupted mating, fewer offspring might be created, setting up potential long-term consequences for the survival of their population.

Squaretail grouper gather at very specific spawning aggregation sites for a few days only a handful of times a year – during the new and full moons between December and March.

Male groupers arrive at aggregation sites a few days before new or full moons and establish mating territories to attract females, which they would normally defend vigorously from rivals. Females arrive a day before the new moon and fish will attempt to pair and spawn in synchrony with the moon’s cycles before females leave.  

These gatherings at the spawning sites can be the only opportunities for these populations to reproduce. But, fisheries, particular spearfishing, and hook and line fishing, which involve free-diving, have begun targeting and exploiting some of these gatherings intensively to guarantee catches while fish are distracted.

India’s Lakshadweep archipelago, situated north of the Maldives, has restricted access to protect the culture of its people and ecology. However, the opening of new fisheries markets has seen a sharp increase in fishing at some grouper spawning sites around the archipelago over the last five years.

Aggregation densities at the studied fished site has plummeted by 70% in a decade with fisheries targeting groupers all year round.

The marine scientists behind the research had studied some of these sites more than a decade ago and first noticed a change in fish behaviour when attempting to replicate aspects of their earlier study.

“We discovered that we couldn’t film or study the fish as easily at the aggregation sites as we could in the past,” said Dr Rucha Karkarey of Lancaster University and lead author of the research. “We couldn’t get as close to them, they would swim away as though we were predators. It was obvious to us that there was a difference in their behaviour and we realised that the major thing that had changed in the decade since our previous study was the start of fishing at the site.”

The researchers compared male squaretail grouper behaviour at fished and unfished spawning sites, as well as comparing with data gathered from their earlier studies of spawning sites.

They analysed fish fear responses, by simulating a threat. Divers would swim horizontally towards spawning groupers to see how close they could get to a fish before it would flee, as well as the time it spent defending territory and engaged in courtship in the absence of a direct threat.

Although males who had already partnered with females at the fished site took greater risks (from potentially being caught by fishers) during courtship, fleeing later and returning earlier, the study found that single males at fished sites were twice as likely to flee and took two and a half times longer to return to territories than fish at unfished sites.

Fewer than half of the single males returned to their territories at the fished site, while two-thirds of unpaired males at the unfished site returned to their territories.

While escaping early can ensure survival for individuals, escaping too early may mean lost mating opportunities.

Squaretail groupers are a long-lived species, living up to 12 years, so researchers believe the behaviour change may result from fish individuals experiencing fishing.

“Our findings suggest that the stresses caused by fishing are making the fish more nervous and on guard,” said Dr Karkarey. “In turn this is reducing the opportunities for single male groupers to find a mate and reproduce because they are being more vigilant and compromising territorial defence by fleeing. It also means that paired males, that are fitter and more successful at reproducing, are the ones being fished, which can have a consequence for the fitness of this population in the future.

“If a spawning aggregation event only lasts for a short period of time then every hour counts.”

The researchers also found that male groupers at fished sites also spent significantly less time and  energy aggressively defending territories from rivals.

The fish at the fished site traded aggressively defending their territories for fleeing. Males spent nearly ten times longer engaged in aggressive behaviour at the unfished site compared to their counterparts at the unfished site.

Researchers believe this could be due to a number of factors including females becoming less choosy in high risk (from fishing) situations, or bolder fish removed from the population by being caught by fishers, though this was not studied.

“Decreased aggression can hold significant evolutionary implications in mating aggregations, specifically through a relaxation in sexual selection, which could have implications for mate choice, population fitness and long-term resilience,” said co-author Dr Sally Keith of Lancaster University.

Dr Idrees Babu from the Department of Scient and Technology, UT Lakshadweep, said: “This study is  the first of its kind in these atoll reef islands, and the findings can play an important role in fishery resource management in this archipelago.”

The findings are detailed in the paper ‘Do risk-prone behaviours compromise reproduction and increase vulnerability of fish aggregations exposed to fishing?’ which is published in the journal Biology Letters.

The paper’s authors are Dr Rucha Karkarey, Dr Lisa Bostrom Einarsson, Dr Sally Keith and Professor Nicholas Graham or Lancaster University and local field collaborators and associates Ibrahim MK of Mukkrikakuddi House, U.T Lakshadweep; Mohammed Nowshad and Abdul Riyas of the Research and Environmental Education Foundation, U.T Lakshadweep; and Dr Idrees Babu of the Department of Science and Technology U.T Lakshadweep.