Snail genome duplication offers look at evolution in transition

University of Iowa

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University of Iowa biologists discovered that a New Zealand freshwater snail duplicated its entire genome, capturing a rare evolutionary transitory state. The finding shows how large-scale genetic events can generate the raw material needed to fuel significant new adaptations and innovations in animals.

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Credit: Christian Böck, Research Institute for Limnology, Mondsee, Austria

A tiny freshwater snail from New Zealand may be further revealing what scientists know about how animals evolve. 

University of Iowa biologists have traced the snail’s evolutionary history through its genome and discovered that the species recently duplicated all of its genetic material — a finding that could further reveal how major evolutionary shifts in animals occur.

The Iowa team chose to study this snail species because individuals can reproduce either sexually or asexually (meaning females can produce offspring without males). While piecing together the snail’s genome, the biologists discovered duplicated genes and doubled regions of DNA, evidence that the organism once carried more than two complete sets of chromosomes, a condition known as polyploidy.

Most animals, including humans, are diploids, meaning they have only two copies of their genome — the full set of instructions needed to make every cell, tissue, and organ in the body.

Asexual reproduction is often associated with polyploidy, as females may more easily manage extra chromosomes by cloning offspring. Biologists have long wondered whether these extra chromosomes help or hinder species over time.

To investigate, the Iowa biologists assembled the snail’s genome by reconstructing some 20,000 genes from 30 individuals in the same lineage, much like completing a master puzzle despite the challenge of sorting through multiple pieces from several nearly identical puzzles. Their reconstruction revealed that the snail had copied all its genetic materials, a process known as whole-genome duplication, within the past 1 million to 2 million years.

“Having more than two genome copies is something that's breaking the rule, but it seems to be a rule that when it's broken, it's corrected over time,” says Kyle McElroy, co-corresponding author on the study, who earned a doctorate from Iowa in 2019 and is now a postdoctoral research associate at Iowa State University. “And we don't know why being diploid is the rule.” 

They also found that the snail was still fairly early in its evolutionary return to a diploid state, the two-copy genome standard common in sexual animals, including humans.

“What we’re looking at today is a mosaic,” says Joseph Jalinsky, visiting assistant professor in the Department of Biology, who earned a doctorate from Iowa in 2022. “Some genes have two copies, some have three, some have four. So, the simplest explanation for how you have so many genes with more than two copies is a whole-genome duplication event.”

“It is this discovery that is perhaps the most exciting,” adds Maurine Neiman, professor in the Department of Biology and the study’s senior author. “We hardly ever see organisms, and especially animals, in this transitory state.”

The discovery raises new questions about how and why whole-genome duplication occurs and what role it plays in the emergence of new traits. Neiman notes that such events may mark evolutionary turning points by creating the raw genetic material for “evolutionary innovations.”

“This could include advanced animal cognition or flowers developing seeds — basically almost any interesting traits might have been enabled by whole-genome duplications,” Neiman says.

The study, “Whole-genome sequence of Potamopyrgus antipodarum — a model system for the maintenance of sexual reproduction — reveals a recent whole-genome duplication,” was published online Nov. 5 in the journal Genome Biology and Evolution.

Contributing authors from Iowa include John Logsdon Jr., Laura Bankers, Joel Sharbrough, Chelsea Higgins, and Cynthia Toll. Other contributing authors are Peter Fields, from the University of Basel, in Switzerland; and Jeffrey Boore, from the University of California-Berkeley.

The U.S. National Science Foundation, the Carver Biomedical Trust at Iowa, the Iowa Office for Undergraduate Research Funding, and the Iowa Science Foundation funded the research.

Neiman is the principal investigator, and Boore and Logsdon are co-principal investigators on the original grant funding the research.

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Why it matters

By uncovering that a New Zealand snail recently copied its entire genome, University of Iowa biologists have revealed a living example of how massive genetic changes can reshape reproduction and may hold clues to the rare moments when evolution takes its biggest leaps.

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Journal

Genome Biology and Evolution

DOI

10.1093/gbe/evaf192 

Method of Research

Data/statistical analysis

Subject of Research

Animals

Article Title

Whole-Genome Sequence of Potamopyrgus antipodarum—A Model System for the Maintenance of Sexual Reproduction—Reveals a Recent Whole-Genome Duplication

Article Publication Date

5-Nov-2025

First graphene-based solar cells used to power temperature sensors

Tests confirm graphene-based energy harvesters can use ambient energy to run ultra-low power sensors — the first hurdle in developing autonomous sensor systems

University of Arkansas

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Testing a graphene-based sensor.

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Credit: Russell Cothren

Researchers at the University of Arkansas and the University of Michigan have reported the first use of ultra-low power temperature sensors using graphene-based solar cells. The test is the first hurdle in developing autonomous sensor systems that draw power from multiple sources in the environment — solar, thermal, acoustic, kinetic, nonlinear and ambient radiation.

The end goal is development of multi-modal sensors (incorporating more than one of the above power sources) using the energy-harvesting capability of graphene that can last decades and helps realize the "Internet of Things," in which smart technology is woven into the fabric of daily life.

Ashaduzzaman, a Ph.D. candidate in physics, is first author on the U of A-led paper, but graphene energy harvesters are the brainchild of physics professor Paul Thibado, who began studying graphene's unique properties more than a decade ago and is the corresponding author.

Success depended on overcoming two challenges:

1. Reducing sensor power demand to nanowatts, a billionth of a watt, as opposed to the current standard, which is measured in microwatts (a millionth of a watt) and
2. Powering the sensor using energy harvested from the local environment.

Notably, this system and those expected to follow do not include batteries, which have a limited lifespan, allowing graphene-based energy harvesters to achieve long operational lifetimes — potentially decades.

"Power has to be drawn from the local environment," Thibado explained, "so it's self-powered and autonomous, and it has to have an extremely long operational lifetime to dramatically reduce the total cost of ownership. So set it and forget it."

The U of A team was largely responsible for completing the second challenge above, while the University of Michigan team, led by David Blaauw, a professor of electrical engineering and computer science, was largely responsible for the first. Blaauw is an expert in low-power wireless sensors and embedded systems. He has even designed tiny sensors that can be planted in the wings of a butterfly.

The paper confirms it's possible to create an ultra-low power temperature sensor using graphene-based solar energy.

"We thought if we could remove the power management unit, maybe this sensor system would take an even smaller amount of power," Ashaduzzaman explained. "So that is what we did. Then we connected three sets of solar cells to power the temperature systems directly with three storage capacitors."

Thibado added that "We anticipate building devices that harvest multiple sources of energy within that device."

By making them "multi-modal," intermittent shortages in solar power can be augmented with additional thermal or non-linear power, whatever the case may be.

Thibado foresees the sensors being used in areas and fields where sensors would be useful, but the need to replace batteries would make them labor and cost prohibitive. This could include use in things like agricultural climate monitoring, tracking livestock, wearable fitness monitoring, building alarm systems, predictive maintenance and a wide range of other applications.

OVERVIEW OF WORK

The abstract of the paper describes the work in plain language, stating that the researchers "built dozens of graphene-based solar cells, wire bonded them into standard packages and characterized the current-voltage characteristics of each under illumination. Next, solar cells were connected in series to increase the output voltage. Three different sets of solar cells were used to charge three storage capacitors to the voltage levels required by [the] temperature sensor.

"The storage capacitors require only a few minutes to charge, yet power the sensor system for more than 24 hours without recharging. Using storage capacitors also eliminates the need for a typical power management chip and the commonly used rechargeable battery. As a result, one can lower the overall power consumed by the sensor system and significantly extend its useful life."

The paper was published in the Journal of Vacuum Science and Technology B. Co-authors from the U of A also included Syed M. Rahman, Md R. Kabir and James M. Magnum, all doctoral students. Co-authors from the University of Michigan included Hung Do and Gordon Carichner, in addition to Blaauw.

Ashaduzzaman said he has been working on the temperature sensor about a year and a half. He said the next step is to perfect a kinetic energy harvester that harvests energy from the unique vibrational qualities of graphene. This capability will then be joined with the solar sensor, creating a multi-modal sensor. At least, that is the plan.

This innovative work was supported by a $900,000 grant from the WoodNext Foundation.

OTHER COLLABORATORS

NTS Innovations, a company specializing in nanotechnology, owns the exclusive license to develop graphene energy harvesters into commercial products. The company has provided funding for patenting, creating business plans, finding business partners and customer discovery.

NTS Innovations' role over the course of the grant is to engage with customers on acceptance criteria, such as the minimum power levels needed for inclusion in products. Currently, more than 60 parties have expressed interest in testing the technology and working with Thibado and his colleagues to integrate it into their applications.

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About the WoodNext Foundation: The WoodNext Foundation manages the philanthropy of tech innovator and Roku CEO/founder, Anthony Wood, and his wife Susan. Their philanthropic efforts are guided by their overall mission to advance human progress and remove obstacles to a fulfilling life. The WoodNext Foundation makes grants and investments in a variety of areas, including scientific and biomedical research, mental health, homelessness, education, nature conservation, disaster recovery, and economic opportunity, with a focus on addressing root causes.

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Journal

Journal of Vacuum Science and Technology

DOI

10.1063/10.0039935 

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Array of mini-graphene-silicon solar cells intermittently recharges storage capacitors powering a temperature sensor

Article Publication Date

10-Nov-2025

 

What can a whale’s breath tell us? According to a new study, a lot about its health

A first of its kind study links drone-collected respiratory microbes with health assessments, offering hope for protecting vulnerable populations

Woods Hole Oceanographic Institution

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Between 2016 and 2024, researchers collected 103 respiratory samples from 85 NorthAtlantic right whales using drones. Drones provide a stable, quiet platform, minimizing stressand disturbance to the animal.

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Credit: NEAq/WHOI, NMFS/NOAA Permit #21371

Woods Hole, Mass. (Nov. 12, 2025) A new study published today in The ISME (International Society for Microbial Ecology) Journal marks the first time scientists have shown a connection between respiratory microbes and the health of a free-ranging whale population.

The study, Respiratory microbiomes reflect whale health opens the door to effective ways to monitor and protect the critically endangered North Atlantic right whale, whose population has dwindled to fewer than 400 individuals.

Between 2016 and 2024, researchers from the Woods Hole Oceanographic Institution (WHOI), University of St Andrews, New England Aquarium, SR³, and Whale and Dolphin Conservation, collected 103 respiratory samples from 85 North Atlantic right whales using drones. The researchers found that the microbial matter whales exhale through their blowholes carry valuable information about their health, including distinct, individual microbial patterns that can be linked to characteristics such as robust versus thin whales, among other health metrics.

As the drone flies over a whale as it exhales, it holds a petri dish in the exhalation to collect a sample of the breath. Using drones provides a stable, quiet platform, minimizing stress and disturbance to the animal, and allows permitted researchers to access areas or animals that are difficult and dangerous to reach. Microbial samples were paired with multiple health indexes, including photogrammetric body condition data, visual health assessments, and estimates from a long-term health and survival model. By combining microbiology, drone-based imaging, and long-term ecological datasets, researchers show how interdisciplinary methods can expand understanding of whale health.

“This is a major step forward in developing new approaches for monitoring wildlife health,” said Carolyn Miller, a large whale biologist at WHOI and a lead author of the study. “By studying the microbes in their breath, we can begin to develop a non-invasive diagnostic tool that tells us how whales are doing without ever having to touch them.”

The study underscores the importance of long-term North Atlantic right whale datasets, including photo-identification catalogs and health assessments as critical baselines for testing new health indicators.

Enrico Pirotta, co-lead author, and statistical ecologist at the Centre for Research into Ecological and Environmental Modelling, University of St Andrews, UK said, “Being able to measure whale health is a critical step towards assessing the effects of multiple stressors on these animals and, ultimately, come up with management solutions that can ensure their conservation.”

“This first of its kind study provides a new window into the biology of some of the ocean’s most endangered species,” said Amy Apprill, co-author, and associate scientist at WHOI. “This technique shows promise as a non-invasive “health checkup” for whales, made possible by drones and microbiome science.”

“As right whales face threats from ship strikes, fishing gear, and ocean changes, having better tools to monitor their health is essential,” added Miller. “Breath samples may hold a key to protecting the species.”

The research was conducted with support from Strategic Environmental Research and Development Program, Office of Naval Research, NOAA, and SR³.

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About Woods Hole Oceanographic Institution
Woods Hole Oceanographic Institution (WHOI) is a private, non-profit organization on Cape Cod, Massachusetts, dedicated to marine research, engineering, and higher education. Founded in 1930, its mission is to understand the ocean, its interactions with the Earth, and its role in a changing global environment. WHOI’s pioneering discoveries arise from a unique blend of science and engineering that has made it one of the world’s most trusted leaders in ocean research and exploration. Known for its multidisciplinary approach, advanced ship operations, and unmatched deep-sea robotics, WHOI also operates the most extensive suite of ocean data-gathering platforms worldwide. More than 800 concurrent projects—driven by top scientists, engineers, and students—push the boundaries of knowledge to inform people and policy for a healthier planet. Behind the scenes, ship captains, mates, craftsmen, marine operations, and other skilled professionals provide essential support that makes this work possible. Learn more at whoi.edu.

  

Researchers found that microbes in whale blowhole spray reveal key health information,including patterns linked to body condition and other traits.

Credit

Photo courtesy NEAq/WHOI,NMFS/NOAA Permit #21371

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DOI

10.1093/ismejo/wraf231 

Method of Research

Observational study

Subject of Research

Animals

Article Title

Respiratory microbiomes reflect whale health

Article Publication Date

12-Nov-2025