Isolated Torrey pine populations yield insights into genetic diversity

Researchers find a few genes that allowed trees from insular populations to adapt to local conditions may inhibit their adjustment long term to a new location

Penn State

LinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

Study co-first author Alayna Mead, postdoctoral scholar in the Department of Ecosystem Science and Management, stands among Torrey pine trees in southern California. 

view more 

Credit: Penn State

UNIVERSITY PARK, Pa. — Entire regions of trees are disappearing because of invasive pests, disease and a changing climate. The key to their ability to adapt to varied growing conditions and, ultimately, their survival, may reside in the complex genetic makeup of replacement trees, according to forest geneticists tasked with reintroducing tree species. A study of one of the rarest pine trees in the world, Torrey pine, conducted by a team including Penn State scientists, has yielded what the researchers called valuable insight into the value of genetic diversity and the importance of ensuring locally adapted diversity is maintained for restoration.

They published their findings in Evolutionary Applications. 

“To conserve species with extremely low genetic diversity, introducing new genetic variation from one population to another can be beneficial, providing a ‘rescue’ to facilitate evolution and species adaptation,” said team leader and senior author Jill Hamilton, Penn State associate professor in ecosystem science and management and director of the university’s Schatz Center for Tree Molecular Genetics. “But we show that in some cases where populations have evolved in isolation, like Torrey pine, caution may be warranted when considering the introduction of new variation.”  

Critically endangered Torrey pine persists naturally across only one island and one coastal mainland population in southern California. Using a common garden experiment established in 2007 by the U.S.­ Forest Service Pacific Southwest Research Station that contains trees from both populations and hybrids from interbreeding, the researchers compared fitness between the island population of Torrey pines, the mainland population and hybrids of the two. They identified genetic variants within the two populations that may indicate reproductive barriers have evolved between the island and mainland populations.

To evaluate the genomic and fitness consequences of interpopulation gene flow or “rescue,” the researchers extracted DNA from the pine needles of all three groups and sequenced it, identifying regions where the DNA sequence varied among individuals. They evaluated whether some of these genetic regions were responsible for differences in growth and cone production among the island and mainland population and their hybrids.

Hamilton’s research group in the College of Agricultural Sciences has studied the plight of Torrey pine over the last decade and how it may yield lessons that could guide efforts to save tree species in peril in the Eastern U.S. such as ash and American chestnut.

Study co-first author Alayna Mead, postdoctoral scholar working in Hamilton’s lab, noted that the unique history of the Torrey pine makes it an ideal system to study conservation genetics. Its two limited populations have been separated for a long time, and they’re adapted to their local climates, she explained. So, if populations have evolved barriers to reproduction n, interpopulation rescue via hybridization could negatively impact the fertility and health of hybrid offspring.

“Around 1.2 million years ago, on the coast of California, Torrey pine colonized an island, and since then, this pine species has persisted through multiple glacial periods and, eventually, warming and drying of California's climate,” Mead said. “Now, only two populations remain, one mainland and one island, both with very low genetic diversity, which could restrict their ability to adapt to a rapidly warming climate.”

Hybrids between the island and mainland population grow faster than their parents, suggesting increased genetic rescue could be beneficial, Mead noted. However, the two populations may have adapted differently to the island and mainland climates, so hybrids planted in nature may carry genes that are adapted to the wrong climate. 

“To test whether hybridization could impact the fitness of future generations, we looked for genes with low levels of mixing between island and mainland variants, which could indicate that island and mainland variants are incompatible and prevent pollination or cause young trees to die,” she said. “For one of these genetic variants, having a mainland-type variant was associated with higher growth and cone production when trees were planted in a mainland garden.”

Hamilton suggested that the findings of the Torrey pines study could inform efforts by Penn State’s Schatz Center and others to rescue trees species in the East decimated by invasive disease and pests.

“For example, in Pennsylvania, forest geneticists are working to manage our forests under climate change,” she said. “Unlike Torrey pine, populations are not separated by the ocean, but habitat fragmentation and ‘sky islands’ — where tree species have retreated to deal with warmer climatic conditions — on mountain peaks have caused more recent barriers. Genetics will be important to determining when and where introducing new genetic diversity could be beneficial to restoration efforts.”

Co-first author on the study, Lionel Di Santo, who was a member of Hamilton’s research group at North Dakota State University before Hamilton came to Penn State, is now a postdoctoral scholar at the University of Basel, Switzerland. Jessica Wright, research geneticist for the Pacific Southwest Research Station, U.S. Department of Agriculture­ Forest Service, Placerville, California, contributed to the research.

The U.S. Department of Agriculture Forest Service Health Protection Gene Conservation Program and Western Wildlands Environmental Threat Assessment Center funded this research.

One of the two isolated populations of Torrey pines is on Santa Rosa Island (shown here), off the coast of southern California.

The researchers suggest that the findings of the Torrey pines study could inform efforts by Penn State’s Schatz Center and others to rescue trees species in the East decimated by invasive disease and pests. 

Credit

Penn State

---

Journal

Evolutionary Applications

DOI

10.1111/eva.70094 

Method of Research

Observational study

Subject of Research

Not applicable

Article Title

Genetic Basis of Reproductive Isolation in Torrey Pine (Pinus torreyana Parry): Insights From Hybridization and Adaptation

 

Some dog breeds are more likely to get diarrhea

One in every 12 dogs in the U.K. is diagnosed with diarrhea each year, though 80% resolve with just a single vet visit

PLOS

Facebook

XLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

Cavapoo.

view more 

Credit: Royal Veterinary College, CC-BY 4.0 (https://creativecommons.org/licenses/by/4.0/)

Approximately one in every 12 dogs in the U.K. will be diagnosed with diarrhea each year, with some breeds more susceptible than others, according to a study published June 11, 2025 in the open-access journal PLOS One by Dan O’Neill from the Royal Veterinary College, U.K., and colleagues.

For this new study, researchers analyzed the health records of more than two million dogs brought to the vet in the U.K. in 2019. They estimated that 8.18% of them, or about 1-in-12, were diagnosed with diarrhea at some point during the year.

But six breeds — Maltese, Miniature Poodle, Cavapoo, German Shepherd, Yorkshire Terrier, and Cockapoo — were significantly more likely to be diagnosed with diarrhea than generic crossbreeds. Just two breeds, Jack Russell Terrier and Chihuahua, were less likely to be diagnosed with diarrhea. It’s possible that these breeds have higher and lower predispositions to diarrhea. Alternatively, the authors of the new study speculate, different breeds could also have different diets and exercise habits, or even owners with different likelihoods of taking their dog to the vet in the first place.

Dogs which were three years old and younger, as well as dogs aged nine and over, were more likely to be diagnosed with diarrhea than dogs four to five years old. Young dogs may be more likely to eat things they shouldn’t, giving them digestive issues, and older dogs may suffer diarrhea from the complications of aging, the authors suggest. In addition, many of the dogs with diarrhea were diagnosed with other conditions at the same time. About 44% had vomiting, 28% had a reduced appetite, and 24% were lethargic — and approximately 29% of all cases were classified as hemorrhagic, or bloody, diarrhea.

Most dogs appeared to recover quickly from their diarrhea, with more than 80% needing just one visit to the vet. Despite this, the study found that around 38% of all diarrhea cases were treated with antibiotics, even as experts recommend against antibiotic use in dogs with mild or moderate diarrhea.

Dr. Dan O’Neill, Associate Professor of Companion Animal Epidemiology at the RVC and co-author of the paper, adds: “Experiencing the dreaded “poonami” with your dog is one of those events any dog owner fears. This new study shows that diarrhea events are very common in dogs but that owners should not panic – no matter how bad the deluge, most dogs will recover in a few days after veterinary treatment.” 

 

 

In your coverage, please use this URL to provide access to the freely available article in PLOS One: https://plos.io/3Fe2GYJ

Citation: O’Neill DG, Prisk LJ, Brodbelt DC, Church DB, Allerton F (2025) Epidemiology and clinical management of acute diarrhoea in dogs under primary veterinary care in the UK. PLoS One 20(6): e0324203. https://doi.org/10.1371/journal.pone.0324203

Author countries: U.K.

Funding: This study was supported at the RVC by an award from the Kennel Club Charitable Trust and Agria Pet Insurance. Neither the Kennel Club Charitable Trust, Agria Pet Insurance nor the Kennel Club had any input in the design of the study, the collection, analysis and interpretation of data or in writing the manuscript.

---

Journal

PLOS One

DOI

10.1371/journal.pone.0324203 

Method of Research

Observational study

Subject of Research

Animals

Article Title

Epidemiology and clinical management of acute diarrhoea in dogs under primary veterinary care in the UK

Article Publication Date

11-Jun-2025

 

Mapping patient satisfaction across U.S. hospitals reveals the Midwest as the leading region

Data from more than 3,200 hospitals indicates clear geographic differences, and shows South Dakota ranking on top while New York performs poorly

PLOS

LinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

Heatmap of Overall Hospital Rating Star Rating Across States.

view more 

Credit: Hung et al., 2025, PLOS One, CC-BY 4.0 (https://creativecommons.org/licenses/by/4.0/)

A new study analyzing more than 3,200 hospitals across the United States (U.S.) has revealed stark differences in how patients rate their hospital experiences depending on where they receive care. The research was published June 11, 2025 in the open-access journal PLOS One and led by Man Hung of the University of Utah, U.S., and colleagues.

Patient satisfaction in the United States is known to vary regionally, likely due to cultural, socioeconomic, and infrastructure differences. In the new study, researchers analyzed data from the Hospital Consumer Assessment of Healthcare Providers and Systems (HCAHPS) survey from 3,286 U.S. hospitals from July 1, 2021 through June 30, 2022. In the HCAHPS survey, patients rated ten specific aspects of their hospital stay, from communication with nurses and doctors to the cleanliness and quietness of hospital rooms.

Across regions, the Midwest emerged as the clear leader in reported patient satisfaction, scoring highest in nearly every category, including staff communication, hospital cleanliness, and overall ratings. Meanwhile, the “Other” region, which included places like Puerto Rico and the District of Columbia, consistently received the lowest scores—especially in critical areas like staff responsiveness and discharge information. Within individual states, New York and South Carolina performed especially poorly, while South Dakota ranked on top in nearly every category.

Across all regions, communication about medications and discharge instructions were consistently among the lowest-rated aspects of care. These are essential elements of care transitions, and poor communication in these areas can lead to complications or hospital readmissions.

The healthcare landscape may well have changed since the 2021-2022 survey was conducted, in the middle of the COVID-19 pandemic. However, the authors conclude that studying high-performing regions and states could help guide policymakers in enhancing national healthcare quality, reducing quality gaps, and ensuring equitable access to high-quality healthcare across the U.S.

The authors add: “While one might expect no significant differences in patient satisfaction among hospitalized patients across the U.S., our findings revealed small but statistically significant regional variations. Encouragingly, overall satisfaction and willingness to recommend the hospital were consistently rated moderately high across all regions.”

“Disparities in patient satisfaction between states may indicate a need for policy reform or increased investment, such as funding for hospital improvements or staff training initiatives. These variations could also reflect unequal access to healthcare or differences in care quality among diverse populations.”

“Notably, patient satisfaction with the overall hospital experience and willingness to recommend remained moderately high across U.S. regions. However, we were surprised to find that satisfaction scores were lowest for communication about medications and discharge information.”

 

 

In your coverage, please use this URL to provide access to the freely available article in PLOS One: https://plos.io/43gYYGO

Citation:  Hung M, Vu S, Hon ES, Reese L, Gardner J, Lipsky MS (2025) Unveiling the drivers of patient satisfaction in the United States hospitals: Assessing quality indicators across regions. PLoS One 20(6): e0324737. https://doi.org/10.1371/journal.pone.0324737

Author countries: U.S.

Funding: The author(s) received no specific funding for this work.

---

Journal

PLOS One

DOI

10.1371/journal.pone.0324737 

Method of Research

Survey

Subject of Research

Not applicable

Article Title

Unveiling the drivers of patient satisfaction in the United States hospitals: Assessing quality indicators across regions

Article Publication Date

11-Jun-2025

 

Single-material electronic skin gives robots the human touch

University of Cambridge

Facebook

XLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

Scientists have developed a low-cost, durable, highly-sensitive robotic ‘skin’ that can be added to robotic hands like a glove, enabling robots to detect information about their surroundings in a way that’s similar to humans.

view more 

Credit: University of Cambridge

Scientists have developed a low-cost, durable, highly-sensitive robotic ‘skin’ that can be added to robotic hands like a glove, enabling robots to detect information about their surroundings in a way that’s similar to humans.

The researchers, from the University of Cambridge and University College London (UCL), developed the flexible, conductive skin, which is easy to fabricate and can be melted down and formed into a wide range of complex shapes. The technology senses and processes a range of physical inputs, allowing robots to interact with the physical world in a more meaningful way.

Unlike other solutions for robotic touch, which typically work via sensors embedded in small areas and require different sensors to detect different types of touch, the entirety of the electronic skin developed by the Cambridge and UCL researchers is a sensor, bringing it closer to our own sensor system: our skin.  

Although the robotic skin is not as sensitive as human skin, it can detect signals from over 860,000 tiny pathways in the material, enabling it to recognise different types of touch and pressure – like the tap of a finger, a hot or cold surface, damage caused by cutting or stabbing, or multiple points being touched at once – in a single material.

The researchers used a combination of physical tests and machine learning techniques to help the robotic skin ‘learn’ which of these pathways matter most, so it can sense different types of contact more efficiently.

In addition to potential future applications for humanoid robots or human prosthetics where a sense of touch is vital, the researchers say the robotic skin could be useful in industries as varied as the automotive sector or disaster relief. The results are reported in the journal Science Robotics.

Electronic skins work by converting physical information – like pressure or temperature – into electronic signals. In most cases, different types of sensors are needed for different types of touch – one type of sensor to detect pressure, another for temperature, and so on – which are then embedded into soft, flexible materials. However, the signals from these different sensors can interfere with each other, and the materials are easily damaged.

“Having different sensors for different types of touch leads to materials that are complex to make,” said lead author Dr David Hardman from Cambridge’s Department of Engineering. “We wanted to develop a solution that can detect multiple types of touch at once, but in a single material.”

“At the same time, we need something that’s cheap and durable, so that it’s suitable for widespread use,” said co-author Dr Thomas George Thuruthel from UCL.

Their solution uses one type of sensor that reacts differently to different types of touch, known as multi-modal sensing. While it’s challenging to separate out the cause of each signal, multi-modal sensing materials are easier to make and more robust.

The researchers melted down a soft, stretchy and electrically conductive gelatine-based hydrogel, and cast it into the shape of a human hand. They tested a range of different electrode configurations to determine which gave them the most useful information about different types of touch. From just 32 electrodes placed at the wrist, they were able to collect over 1.7 million pieces of information over the whole hand, thanks to the tiny pathways in the conductive material.

The skin was then tested on different types of touch: the researchers blasted it with a heat gun, pressed it with their fingers and a robotic arm, gently touched it with their fingers, and even cut it open with a scalpel. The team then used the data gathered during these tests to train a machine learning model so the hand would recognise what the different types of touch meant. 

“We’re able to squeeze a lot of information from these materials – they can take thousands of measurements very quickly,” said Hardman, who is a postdoctoral researcher in the lab of co-author Professor Fumiya Iida. “They’re measuring lots of different things at once, over a large surface area.”

“We’re not quite at the level where the robotic skin is as good as human skin, but we think it’s better than anything else out there at the moment,” said Thuruthel. “Our method is flexible and easier to build than traditional sensors, and we’re able to calibrate it using human touch for a range of tasks.”

In future, the researchers are hoping to improve the durability of the electronic skin, and to carry out further tests on real-world robotic tasks.

The research was supported by Samsung Global Research Outreach Program, the Royal Society, and the Engineering and Physical Sciences Research Council (EPSRC), part of UK Research and Innovation (UKRI). Fumiya Iida is a Fellow of Corpus Christi College, Cambridge.

Scientists have developed a low-cost, durable, highly-sensitive robotic ‘skin’ that can be added to robotic hands like a glove, enabling robots to detect information about their surroundings in a way that’s similar to humans.

Improved electronic skin gives robots the human touch [VIDEO] | 

Scientists have developed a low-cost, durable, highly-sensitive robotic ‘skin’ that can be added to robotic hands like a glove, enabling robots to detect information about their surroundings in a way that’s similar to humans.

Credit

University of Cambridge

Journal

Science Robotics

DOI

10.1126/scirobotics.adq2303 

Article Title

Multimodal Information Structuring with Single-Layer Soft Skins and High-Density Electrical Impedance Tomography

Article Publication Date

11-Jun-2025

Soft robotic gripper injects leaves with precision

Cornell University

Facebook

WhatsAppEmail

 

image: 

The soft robotic leaf gripper injects leaves with sensors that help it detect and communicate with its environment.

view more 

Credit: Savan DeSouza/Cornell University

Tools that offer early and accurate insight into plant health – and allow individual plant interventions – are key to increasing crop yields as environmental pressures increasingly impact horticulture and agriculture.

In response to this challenge, Cornell researchers have developed a soft robotic device that gently grips and injects living plant leaves with sensors that help it detect and communicate with its environment. The robot can also inject genetic material that could be used for bioengineering plants in the future.

The device allows for safe, repeatable delivery of sensors and genetic material in a reliable, plant-safe way – an essential step in precision, data-driven agriculture. The team’s findings were published in Science Robotics.

Funding for the research was provided by the National Science Foundation under a five-year, $25 million grant supporting the Cornell-led Center for Research on Programmable Plant Systems (CROPPS).

“Plants, like people, have different responses to the environment, and precision agriculture is an effort to move closer and closer to single-plant-level intervention – and the soil surrounding it,” said the paper’s senior author, Robert F. Shepherd, professor in the Sibley School of Mechanical and Aerospace Engineering in Cornell Engineering, and a research lead at CROPPS.

Horticulturists, farmers and agriculturalists face rising pressures from environmental impacts, such as drought and fertilizer runoff. By implanting sensors into leaves, researchers can monitor the impact of drought or an overdose of fertilizer on the plant.

To demonstrate, the team used the gripper to deliver two types of probes. The first, AquaDust, is a tiny gel particle that fluoresces in response to water stress, allowing researchers to non-invasively monitor a plant’s hydration levels. The second probe, RUBY, is a gene-encoded biological reporter that causes red pigmentation to appear where genetic transformation occurs within the plant.

“AquaDust allowed us to ‘see’ the water stress inside a leaf, and similarly, by injecting a bacterium that transforms the injection region with RUBY reporter genes, we were able to ‘see’ that this part of the leaf experienced a genetic transformation,” said first author Mehmet Mert Ilman, previously a postdoctoral researcher in the Organic Robotics Lab and now an assistant professor in mechanical engineering at Manisa Celal Bayar University in Turkey.

“It was fascinating to be able to robotically transform the local genetics of the plant leaf and then see it change back,” he said.

The researchers tested the device on sunflower and cotton leaves – plants known for their structural resistance to infiltration. The gripper achieved more than 91% success in delivery while causing significantly less damage than syringe-based methods and expanding the effective infiltration area by more than 12 times.

The soft robotic system works hands-free, delivers materials more evenly and causes little to no damage, even in tough and durable species like cotton. The technique is an improvement over traditional manual methods such as vacuum infiltration, which uses low air pressure to force liquids into plant tissues, or needle injections, which can injure leaves, are labor-intensive and often fail in tough plant types. This is especially important for horticultural crops – soft-skinned plants cultivated for their fruits, vegetables, flowers or ornamental value.

The device applies gentle, uniform pressure through a sponge tip that holds the nanoparticle or genetic probes. The design of the soft material and actuator (the portion of a machine that produces force or torque) were optimized through simulations software and 3D printing, allowing the gripper to function with a variety of leaf types and shapes.

“Its low stiffness allows it to warp the gripper’s shape to adapt to the orientation and surface of the leaf with little health implications to the leaf,” Shepherd said. “The shape of the extending actuator allowed for a large displacement and ability to adjust orientation without bulky or complex motor control.”

The research lays the foundation for real-time, minimally invasive plant monitoring, Shepherd said. 

“Soft grippers to inject physical or biological probes unlock new and incredible capabilities,” he said. “The immediate use of our system would likely be in greenhouses, where a robot would persistently inject and monitor individual plants to infer how much water they need.”

In the long term, similar grippers could be used to deliver or retrieve other diagnostic materials, including sensors for nitrogen uptake, disease presence or even real-time metabolic changes, opening up new possibilities for smart agriculture and plant research.

“New nanoparticles will also eventually be created that will inform us about many other health aspects of the plant,” Shepherd said. “With this information, plants will yield more, and we will waste less.”

The team is now exploring the integration of the gripper onto robotic arms for automated greenhouse systems, with the long-term goal of adapting it for field-deployable platforms.

“Once translated out of greenhouses, the implications will be larger,” Shepherd said. “I am particularly interested in limiting the waste streams into lakes to prevent harmful algal blooms.”

Co-authors include researchers from the Boyce Thompson Institute, the Smith School of Chemical and Biomolecular Engineering and the School of Integrative Plant Science in the College of Agriculture and Life Sciences. 

The work was supported by the National Science Foundation, the USDA National Institute of Food and Agriculture and the Scientific and Technological Research Council of Turkey.

Stephen D’Angelo is communications manager for Cornell Research and Innovation.

---

Journal

Science Robotics

Article Title

In situ foliar augmentation of multiple species for optical phenotyping and bioengineering using soft robotics

Article Publication Date

11-Jun-2025