In the weeds: Amaranth genomes reveal secrets of success

University of Illinois College of Agricultural, Consumer and Environmental Sciences

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New chromosome-level genomes have been published for three troublesome Amaranthus weed species: Palmer amaranth and redroot and smooth pigweed. The advancement represents a major leap in scientists’ understanding of the weeds’ biology, including their ability to detoxify common herbicides. They are also among the first genomes published by the International Weed Genomics Consortium.

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Credit: Lauren Quinn, University of Illinois Urbana-Champaign

URBANA, Ill. — Weeds like Palmer amaranth make farming harder and less profitable, and available herbicides are becoming less effective. For scientists to find solutions, they first need to know their enemy. A new study from the University of Illinois Urbana-Champaign and collaborating institutions reveals complete chromosome-level genomes for Palmer and two other Amaranthus species, smooth and redroot pigweed. The advancement represents a major leap in scientists’ understanding of the weeds’ biology, including their ability to detoxify common herbicides.

“Having these reference genomes greatly speeds our ability to investigate weeds with multiple herbicide resistance and gets us closer to novel control strategies,” said study co-author Pat Tranel, professor in the Department of Crop Sciences, part of the College of Agricultural, Consumer and Environmental Sciences at Illinois.

Along with making the genomes available, the study digs into important gene families, such as cytochrome P450s. Because these weeds have hundreds of similar P450 genes, it has been difficult to understand which ones play an important role in non-target-site resistance by detoxifying herbicides before they can cause damage. Tranel says non-target-site resistance has long been seen as a black box, but the new genomes are starting to reveal what’s inside.

“Now that we have a catalog of the P450 genes, we can systematically figure out which ones confer resistance to which herbicides,” he said. “That way we can determine which herbicides are detoxified by the same non-target-site resistance mechanism and avoid tank-mixing those products.”

The study focused extra attention on Palmer amaranth, arguably the most troublesome of the three species. To start, the research team characterized Palmer’s glyphosate resistance gene, which occurs in a large circular segment of DNA that exists outside of any chromosome. Although glyphosate resistance had been linked to this odd structure previously, the study provided new insights into how it originated. 

“The evolutionary story is that this gene got inserted into a circle at one time and then that circle expanded across the globe. That one evolutionary event is responsible for all the resistance we're finding in Palmer across nearly every continent,” said study co-author Jake Montgomery, now a postdoctoral researcher at the University of Chicago after earning graduate degrees at Illinois and Colorado State University. “Our study supports this conclusion, by using the reference genome and new sequence from Palmer amaranth populations from North and South America to show the nearly complete conservation of the sequence of the circle.”

Next, the researchers honed in on genes related to sex determination in Palmer, a line of inquiry Tranel’s group has been working on for some time. His goal is to develop modified male plants containing a gene drive, a segment of DNA coding for maleness, which would be passed on to its offspring, and on through all future generations. Ultimately, all plants in a given population would become male, reproduction would cease, and populations would crash. 

“In the current study, we identified two genes that appear to control maleness on chromosome 3 in Palmer,” said lead study author Damilola Alex Raiyemo, who completed his doctoral work with Tranel. “We still need to validate these genes, but this is an important step forward.” 

Notably, the study also represents the first genomes published by the International Weed Genomics Consortium, an organization comprised of academic institutions and industry partners that generates reference genomes of weed species to facilitate research. The IWGC makes those reference genomes freely available, removing barriers and speeding up the pace of discovery about important weeds.

“Before the IWGC, researchers would apply to grant agencies with ideas about mapping important traits, like new types of herbicide resistance. To do that, you first need a reference genome,” said study co-author Todd Gaines, professor at Colorado State University and executive committee member at IWGC. “But there aren’t that many weed genomicists and few who can do that kind of work within the timeframe of a typical grant cycle. So those grants would go nowhere. With these resources, researchers can jump on their ideas almost immediately.”

As an example, Tranel’s group recently used the reference genome of another troublesome amaranth — waterhemp — to identify regions associated with resistance to the herbicides 2,4-D and dicamba. 

“Waterhemp is an economically impactful agronomic weed in the Midwest that has evolved resistance to herbicides from seven sites of action,” said that study’s lead author, Isabel Werle, doctoral student in crop sciences at Illinois. “We were able to identify eight genomic regions associated with resistance to 2,4-D and dicamba, different products with the same mode of action. Surprisingly, we found very little overlap among the eight regions controlling resistance to the two products, suggesting waterhemp is using multiple strategies to avoid damage.”

As more scientists access these genomic resources, Tranel and his colleagues believe the pace of discovery — and actionable solutions in the hands of farmers — can only increase. 

The genome paper, “Chromosome-level assemblies of Amaranthus palmeri, Amaranthus retroflexus, and Amaranthus hybridus allow for genomic comparisons and identification of a sex-determining region,” is published in The Plant Journal [DOI:10.1111/tpj.70027]. This work was supported by the International Weed Genomics Consortium with funding from the Foundation for Food & Agriculture Research, Bayer AG, Corteva Agriscience, Syngenta Ltd, BASF SE, and CropLife International (Global Herbicide Resistance Action Committee). Funding was also provided by the USDA National Institute of Food and Agriculture. 

The waterhemp paper, “Different nontarget-site mechanisms underlie resistance to dicamba and 2,4-D in an Amaranthus tuberculatus population,” is published in Pest Management Science [DOI: 10.1002/ps.8712]. This work was partially supported by the USDA National Institute of Food and Agriculture.

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Journal

The Plant Journal

DOI

10.1111/tpj.70027 

 

From scraps to sips: Everyday biomass produces drinking water from thin air

University of Texas at Austin

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A sorbent created using biomass that can pull drinkable water out of thin air. 

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Credit: The University of Texas at Austin

Discarded food scraps, stray branches, seashells and many other natural materials are key ingredients in a new system that can pull drinkable water out of thin air developed by researchers from The University of Texas at Austin.

This new “molecularly functionalized biomass hydrogels” system can convert a wide range of natural products into sorbents, materials that absorb liquids. By combining these sorbents with mild heat, the researchers can harvest gallons of drinkable water out of the atmosphere, even in dry conditions.

“With this breakthrough, we’ve created a universal molecular engineering strategy that allows diverse natural materials to be transformed into high-efficiency sorbents,” said Guihua Yu, a professor of materials science and mechanical engineering and Texas Materials Institute at UT Austin. “This opens up an entirely new way to think about sustainable water collection, marking a big step towards practical water harvesting systems for households and small community scale.”

In field tests, the researchers generated 14.19 liters (3.75 gallons) of clean water per kilogram of sorbent daily. Most sorbents can generate between 1 and 5 liters per kilogram per day.

The new research was published in Advanced Materials.

This system represents a new way of designing sorbents, the researchers say. Instead of the traditional "select-and-combine" approach, which requires picking specific materials for specific functions, this general molecular strategy makes it possible to turn almost any biomass into an efficient water harvester.

Unlike existing synthetic sorbents, which use petrochemicals and generally require high energy inputs, the UT Austin team’s biomass-based hydrogel is biodegradable, scalable, and requires minimal energy to release water. The secret lies in a two-step molecular engineering process that imparts hygroscopic properties and thermoresponsive behavior to any biomass-based polysaccharide, such as cellulose, starch, or chitosan.

“At the end of the day, clean water access should be simple, sustainable, and scalable,” said Weixin Guan, a senior doctoral student and the study's lead researcher. “This material gives us a way to tap into nature’s most abundant resources and make water from air—anytime, anywhere.”

The latest innovation is part of Yu’s years-long quest to develop solutions for people lacking access to clean drinking water. He’s developed water-generating hydrogels throughout his career, adapting them for the driest conditions. He recently created an injectable water filtration system, and he has applied his hydrogel technology to farming.

The research team is now working on scaling production and designing real-world device systems for commercialization, including portable water harvesters, self-sustaining irrigation systems, and emergency drinking water devices. Since the beginning, the researchers have focused on scalability and the ability to translate this research into solutions that can help people around the world.

“The biggest challenge in sustainable water harvesting is developing a solution that scales up efficiently and remains practical outside the lab,” said Yaxuan Zhao, a graduate researcher in Yu’s lab. “Since this hydrogel can be fabricated from widely available biomass and operates with minimal energy input, it has strong potential for large-scale production and deployment in off-grid communities, emergency relief efforts, and decentralized water systems.”

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Journal

Advanced Materials

DOI

10.1002/adma.202420319 

Article Title

Molecularly Functionalized Biomass Hydrogels for Sustainable Atmospheric Water Harvesting

Article Publication Date

24-Feb-2025

 

Scientists design novel battery that runs on atomic waste

Strong nuclear radiation boosts device efficiency, study finds

Ohio State University

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COLUMBUS, Ohio – Researchers have developed a battery that can convert nuclear energy into electricity via light emission, a new study suggests. 

Nuclear power plants, which generate about 20% of all electricity produced in the United States, produce almost no greenhouse gas emissions. However, these systems do create radioactive waste, which can be dangerous to human health and the environment. Safely disposing of this waste can be challenging. 

Using a combination of scintillator crystals, high-density materials that emit light when they absorb radiation, and solar cells, the team, led by researchers from The Ohio State University,  demonstrated that ambient gamma radiation could be harvested to produce a strong enough electric output to power microelectronics, like microchips. 

To test this battery, which is a prototype about 4 cubic centimeters small, researchers used two different radioactive sources, cesium-137, and cobalt-60, some of the most significant fission products that come from spent nuclear fuel. The battery was tested at Ohio State’s Nuclear Reactor Laboratory. The NRL supports student and faculty research, student education, and service to industry – it does not produce electrical power.

Their results showed that when cesium-137 was used, the battery generated 288 nanowatts. Yet with the much stronger isotope cobalt-60, the battery produced 1.5 microwatts of power, about enough to switch on a tiny sensor. 

Although most power outputs for homes and electronics are measured in kilowatts, this suggests that with the right power source, such devices could be scaled up to target applications at or beyond the watts level, said Raymond Cao, lead author of the study and a professor in mechanical and aerospace engineering at Ohio State.

The study was recently published in the journal Optical Materials: X.

The researchers said these batteries would be used near where the nuclear waste is produced, such as in nuclear waste storage pools or nuclear systems for space and deep sea exploration – they aren’t designed for public use. Fortunately, although the gamma radiation utilized in this work is about a hundred times more penetrating than a normal X-ray or CT scan, the battery itself does not incorporate radioactive materials, meaning it is still safe to touch. 

“We're harvesting something considered as waste and by nature, trying to turn it into treasure,” said Cao, who also serves as the director of Ohio State’s Nuclear Reactor Lab. 

According to the study, the team’s battery may also have experienced an increase in power due to the makeup of the prototype scintillator crystal the team opted to use. They found that even the shape and size of the crystals can impact the final electrical output, as a larger volume allows it to absorb more radiation and convert that extra energy into more light. A larger surface area also helps the solar cell generate power.

“These are breakthrough results in terms of power output,” said Ibrahim Oksuz, co-author of the study and a research associate in mechanical and aerospace engineering at Ohio State. “This two-step process is still in its preliminary stages, but the next step involves generating greater watts with scale-up constructs.” 

Since batteries of this type would most likely end up in environments where high levels of radiation already exist and aren't easily accessible to the public, these long-lasting devices wouldn’t pollute their surroundings. Even more significantly, they could also operate without the need for routine maintenance.

Scaling this technology up would be costly unless these batteries could be reliably manufactured, said Cao. Further research is needed to assess the batteries’ usefulness and limitations, including how long they might last once safely implemented, said Oksuz.

“The nuclear battery concept is very promising,” he said. “There's still lots of room for improvement, but I believe in the future, this approach will carve an important space for itself in both the energy production and sensors industry.”

This work was supported by the U.S. Department of Energy’s National Nuclear Security Administration and the U.S. Department of Energy’s Office of Energy Efficiency and Renewable Energy. Other co-authors include Sabin Neupane and Yanfa Yan from The University of Toledo.

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Journal

Optical Materials X

DOI

10.1016/j.omx.2025.100401 

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Scintillator based nuclear photovoltaic batteries for power generation at microwatts level

 

Bubbles That Break the Rules: The Fluid Discovery That Defies Logic

University of North Carolina at Chapel Hill

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A team led by researchers at UNC-Chapel Hill have made an extraordinary discovery that is reshaping our understanding of bubbles and their movement. Picture tiny air bubbles inside a container filled with liquid. When the container is shaken up and down, these bubbles engage in an unexpected, rhythmic ‘galloping’ motion—bouncing like playful horses and moving horizontally, even though the shaking occurs vertically. This counterintuitive phenomenon, revealed in a new study, has significant implications for technology, from cleaning surfaces to improving heat transfer in microchips and even advancing space applications.  

These galloping bubbles are already garnering significant attention: their impact in the field of fluid dynamics has been recognized with an award for their video entry at the most recent Gallery of Fluid Motion, organized by the American Physical Society. 

“Our research not only answers a fundamental scientific question but also inspires curiosity and exploration of the fascinating, unseen world of fluid motion,” said Pedro Sáenz, principal investigator and professor of applied mathematics at UNC-Chapel Hill. “After all, the smallest things can sometimes lead to the biggest changes.” 

A Simple Question, A Revolutionary Answer 

In collaboration with a colleague at Princeton University, the research team sought to answer a seemingly simple question: Could shaking bubbles up and down make them move continuously in one direction? 

To their surprise, not only did the bubbles move—but they did so perpendicularly to the direction of shaking. This means that vertical vibrations were spontaneously transformed into persistent horizontal motion, something that defies common intuition in physics. Moreover, by adjusting the shaking frequency and amplitude, the researchers discovered that bubbles could transition between different movement patterns: straight-line motion, circular paths, and chaotic zigzagging reminiscent of bacterial search strategies. 

“This discovery transforms our understanding of bubble dynamics, which is usually unpredictable, into a controlled and versatile phenomenon with far-reaching applications in heat transfer, microfluidics, and other technologies,” explained Connor Magoon, joint first author and graduate student in mathematics at UNC-Chapel Hill. 

Future Innovations and Real-World Applications 

Bubbles play a key role in a vast range of everyday processes, from the fizz in soft drinks to climate regulation and industrial applications such as cooling systems, water treatment, and chemical production. 

Controlling bubble movement has long been a challenge across multiple fields, but this study introduces an entirely new method: leveraging a fluid instability to direct bubbles in precise ways. 

One immediate application is in cooling systems for microchips. On Earth, buoyancy naturally removes bubbles from heated surfaces, preventing overheating. However, in microgravity environments such as space, there is no buoyancy, making bubble removal a major issue. This newly discovered method allows bubbles to be actively removed without relying on gravity, which can enable improved heat transfer in satellites and space-based electronics.   

Another breakthrough is in surface cleaning. Proof-of-concept experiments show that ‘galloping bubbles’ can clean dusty surfaces by bouncing and zigzagging across them, like a tiny Roomba. The ability to manipulate bubble motion in this way could lead to innovations in industrial cleaning and biomedical applications such as targeted drug delivery. 

“The newly discovered self-propulsion mechanism allows bubbles to travel distances and gives them an unprecedented capacity to navigate intricate fluid networks,” said Saiful Tamim, joint first author and postdoctoral research assistant at UNC-Chapel Hill. “This could offer solutions to long-standing challenges in heat transfer, surface cleaning, and even inspire new soft robotic systems.” 

A Leap Forward in Bubble Research 

Bubbles have fascinated scientists for centuries. Leonardo da Vinci was among the first to document their erratic paths, describing how they spiral unpredictably rather than rising straight up. Until now, controlling bubble motion has remained a challenge, with available approaches being few and lacking versatility. This new research changes that perspective, demonstrating that bubbles can be guided along predictable paths using carefully tuned vibrations. 

“It’s fascinating to see something as simple as a bubble reveal such complex and surprising behavior,” said Jian Hui Guan, joint first author and postdoctoral research assistant at UNC-Chapel Hill. “By harnessing a new method to move bubbles, we’ve unlocked possibilities for innovation in fields ranging from microfluidics to heat transfer.” 

The discovery of galloping bubbles represents a significant leap forward in our understanding of bubble dynamics, with implications stretching across industries. As researchers continue to explore and refine this phenomenon, the world may soon see new technologies that harness the power of these tiny, acrobatic bubbles. 

The research paper is available online in the journal Nature Communications at: Galloping Bubbles | Nature Communications 

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Journal

Nature

DOI

10.1038/s41467-025-56611-5 

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Galloping Bubbles

Article Publication Date

22-Feb-2025

Mimicking shark skin to create clean cutting boards

Laser-textured metal inspired by shark skin and cicada wings creates antibacterial surfaces

American Institute of Physics

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Inspired by the naturally antimicrobial textures of cicada wings and shark skin, micro- and nanoscale textures at the scale of bacterial cells make it difficult for bacteria to attach. They also change the water-repellent properties of the surface, a key factor for bacterial growth.

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Credit: Sebastiampillai Raymond

WASHINGTON, Feb. 25, 2025 – Keeping work surfaces clean during meat processing is a challenge. Bacteria from meat can attach, grow, and build up to create a biofilm that is difficult to remove, even on stainless steel surfaces used in industrial facilities. It can also aggregate, clumping together into an invisible mass that is stronger than individual cells, making it harder to kill using food-grade antibacterial surface cleaners.

In a paper published this week in Journal of Laser Applications, from AIP Publishing and the Laser Institute of America, researchers from the Hopkirk Research Institute, New Zealand Food Safety Science and Research Centre, and Applied Technologies Group in New Zealand deliver key insights into a solution that could replace the current practice altogether: Instead of constantly battling to prevent bacteria buildup, they created surfaces that stop bacteria from attaching in the first place.

“Antimicrobial interventions currently approved and used commercially have a limited capacity to reduce well-established bacterial biofilms and spores, and complete decontamination is rarely achieved,” author Sebastiampillai Raymond said.

Using lasers to etch and alter the surface of the metal, Raymond and his colleagues were able to create micro- or nanoscale textures that make it difficult for microbial cells to attach to the surface. The technique, known as laser-induced surface texturing, also alters the metal’s water-repellent properties, a key factor impacting bacterial growth.

“Laser-textured surfaces possess antibacterial properties, because they physically disrupt bacterial adhesion, growth, and proliferation,” Raymond said. “These nanoscale and microscale surface textures mimic natural antimicrobial surfaces, such as those found on cicada wings and shark skin.”

The researchers discovered the laser-texturing technique is highly effective for carefully controlling and tuning textures on metal. Different bacteria can be targeted using specific textures designed around the shape of the bacterial cells, making it particularly difficult for those cells to attach to the surface. They are also working on developing machine learning models that could help manufacturers optimize and automate laser surface texturing.

“Compared to some conventional approaches, laser surface texturing does not introduce non-native materials or require chemical etchants or sensitizers on treated surfaces,” Raymond said. “This could lower barriers to introducing new technology into a regulated environment and eliminates any risk of potential chemical contamination from the coating.”

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The article “Antibacterial effectiveness of laser surface textured metal on meat-borne bacteria” is authored by Aswathi Soni, Amanda Gardner, Gale Brightwell, Lan Le-Ngoc, and Sebastiampillai Raymond. It will appear in Journal of Laser Applications on Feb. 25, 2025 (DOI: 10.2351/7.0001535). After that date, it can be accessed at https://doi.org/10.2351/7.0001535.

ABOUT THE JOURNAL

The Journal of Laser Applications (JLA) is the scientific platform of the Laser Institute of America and is co-published in partnership with AIP Publishing. The journal covers a broad range of research from fundamental and applied research and development to industrial applications. JLA presents the latest breakthroughs in laser applications related to photonic production, sensing and measurement, as well as laser safety. See https://pubs.aip.org/lia/jla.

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Journal

Journal of Laser Applications

DOI

10.2351/7.0001535 

Article Title

Antibacterial effectiveness of laser surface textured metal on meat-borne bacteria

Article Publication Date

25-Feb-2025