Friday, February 09, 2024

Foul fumes pose pollinator problems

UNIVERSITY OF WASHINGTON

Pale Evening Primrose in field — IMAGE:
IMAGE OF A FIELD SITE IN EASTERN WASHINGTON SHOWING PALE EVENING PRIMROSE FLOWERS.
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CREDIT: JEREMY CHAN/UNIVERSITY OF WASHINGTON

Link to Google Drive folder containing images and videos with caption and credit information: https://drive.google.com/drive/folders/1KMo7RucC9LCg90iQH3obxutfmA79jNQv?usp=sharing

Post-embargo link to release: https://www.washington.edu/news/2024/02/08/pollinator-pollution/

FROM: James Urton

University of Washington

206-543-2580

jurton@uw.edu

(Note: researcher contact information at the end)

Embargoed by Science

For public release at 2 p.m. U.S. Eastern Time (11 a.m. U.S. Pacific Time) on Thursday, Feb. 8, 2024

Foul fumes pose pollinator problems

A team led by researchers at the University of Washington has discovered a major cause for a drop in nighttime pollinator activity — and people are largely to blame.

The researchers found that nitrate radicals (NO3) in the air degrade the scent chemicals released by a common wildflower, drastically reducing the scent-based cues that nighttime pollinators rely on to locate the flower. In the atmosphere, NO3 is produced by chemical reactions among other nitrogen oxides, which are themselves released by the combustion of gas and coal from cars, power plants and other sources. The findings, published Feb. 9 in the journal Science, are the first to show how nighttime pollution creates a chain of chemical reactions that degrades scent cues, leaving flowers undetectable by smell. The researchers also determined that pollution likely has worldwide impacts on pollination.

The team — co-led by Jeff Riffell, a UW professor of biology, and Joel Thornton, a UW professor of atmospheric sciences — studied the pale evening primrose (Oenothera pallida). This wildflower grows in arid environments across the western U.S. They chose this species because its white flowers emit a scent that attracts a diverse group of pollinators, including nocturnal moths, which are one of its most important pollinators.

At field sites in eastern Washington, the researchers collected scent samples from pale evening primrose flowers. Back in the laboratory, they used chemical analysis techniques to identify the dozens of individual chemicals that make up the wildflower’s scent.

“When you smell a rose, you’re smelling a diverse bouquet composed of different types of chemicals,” said Riffell. “The same is true for almost any flower. Each has its own scent made up of a specific chemical recipe.”

Once they had identified the individual chemicals that make up the wildflower’s scent, the team used a more advanced technique called mass spectrometry to observe how each chemical within the scent reacted to NO3. They found that reacting with NO3 nearly eliminated certain scent chemicals. In particular, the pollutant decimated levels of monoterpene scent compounds, which in separate experiments moths found most attractive.

Moths, which smell through their antennae, have a scent-detection ability that is roughly equivalent to dogs — and several thousand times more sensitive than the human sense of smell. Research suggests that several moth species can detect scents from miles away, according to Riffell.

Using a wind tunnel and computer-controlled odor-stimulus system, the team investigated how well two moth species — the white-lined sphinx (Hyles lineata) and the tobacco hawkmoth (Manduca sexta) — could locate and fly toward scents. When the researchers introduced the pale evening primrose’s normal scent, both species would readily fly toward the scent source. But when the researchers introduced the scent and NO3 at levels typical for a nighttime urban setting, Manduca’s accuracy dropped by 50% and Hyles — one of the chief nocturnal pollinators of this flower — could not locate the source at all.

Experiments in a natural setting backed up these findings. In field experiments, the team showed that moths visited a fake flower emitting unaltered scent as often as they visited a real one. But, if they treated the scent first with NO3, moth visitation levels dropped by as much as 70%.

“The NO3 is really reducing a flower’s ‘reach’ — how far its scent can travel and attract a pollinator before it gets broken down and is undetectable,” said Riffell.

The team also compared how daytime and nighttime pollution conditions impacted the wildflower’s scent chemicals. Nighttime pollution had a much more destructive effect on the scent’s chemical makeup than daytime pollution. The researchers believe this is largely due to sunlight degrading NO3.

The team used a computer model that simulates both global weather patterns and atmospheric chemistry to locate areas most likely to have significant problems with plant-pollinator communication. The areas identified include western North America, much of Europe, the Middle East, Central and South Asia, and southern Africa.

“Outside of human activity, some regions accumulate more NO3 because of natural sources, geography and atmospheric circulation,” said Thornton, who added that natural sources of NO3 include wildfires and lightning. “But human activity is producing more NO3 everywhere. We wanted to understand how those two sources — natural and human — combine and where levels could be so high that they could interfere with the ability of pollinators to find flowers.”

The researchers hope their study is just the first of many to help uncover the full scope of pollinator failure.

“Our approach could serve as a roadmap for others to investigate how pollutants impact plant-pollinator interactions, and to really get at the underlying mechanisms,” said Thornton. “You need this kind of holistic approach, especially if you want to understand how widespread the breakdown in plant-pollinator interactions is and what the consequences will be.”

The study highlights the dangers of human-fueled pollution and its implications for all pollinators as well as the future of agriculture.

“Pollution from human activity is altering the chemical composition of critical scent cues, and altering it to such an extent that the pollinators can no longer recognize it and respond to it,” said Riffell.

Approximately three-quarters of the more than 240,000 species of flowering plants rely on pollinators, Riffell said. And more than 70 species of pollinators are endangered or threatened.

Lead author on the paper is Jeremy Chan, a postdoctoral researcher at the University of Copenhagen who conducted this study as a UW doctoral student in biology. Co-authors are Sriram Parasurama in the UW Department of Biology; Rachel Atlas, a postdoctoral researcher at the Pierre Simon Laplace Institute in France who participated in this study as a UW doctoral student in atmospheric sciences; Ursula Jongebloed, a UW doctoral students in atmospheric sciences; Ruochong Xu, a doctoral student at Tsinghua University in China; Becky Alexander, a UW professor of atmospheric sciences; and Joseph Langenhan, a professor of chemistry at Seattle University. The research was funded by the Air Force Office of Scientific Research, the National Science Foundation, the National Institutes of Health, the Human Frontiers in Science Program, and the University of Washington.

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For more information, contact Riffell at 206-348-0789 or jriffell@uw.edu and Thornton at 206-543-4010 or joelt@uw.edu.

Reference: Chan JK, Parasurama S, Atlas R, Xu R, Jongeblood UA, Alexander B, Langenhan JM, Thornton JA, Riffell JA. “Olfaction in the Anthropocene: NO3 negatively affects floral scent and nocturnal pollination.” Science 2024. DOI: 10.1126/science.adi0858

A note from Science for journalists: “Advance copies of embargoed papers may be obtained by registered reporters from our press package, SciPak, at https://www.eurekalert.org/press/scipak/. For reporters having difficulties accessing the paper from the press package, please have them contact scipak@aaas.org.”

Grant numbers:

Air Force Office of Scientific Research: FA9550-21-1-0101 and FA9550-20-1-0422
National Science Foundation: 2121935
National Institutes of Health: R01AI148300
Human Frontiers in Science Program: RGP0044/2021

Name pronunciation guide:

Jeff Riffell: Jef RIF-el
Joel Thornton: Jol THORN-tun

Link to Google Drive folder containing images and videos with caption and credit information: https://drive.google.com/drive/folders/1KMo7RucC9LCg90iQH3obxutfmA79jNQv?usp=sharing

JOURNAL

Science

DOI

10.1126/science.adi0858

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

Olfaction in the Anthropocene: NO3 negatively affects floral scent and nocturnal pollination

ARTICLE PUBLICATION DATE

8-Feb-2024

Image showing a white-lined sphinx pollinating a pale evening primrose flower.

Moth visiting flower in field [VIDEO] |

CREDIT

Ron Wolf/University of Washington

An innovative approach to shield against foodborne illness

The project, led by University of Missouri researchers, is supported by a $5 million grant from the National Science Foundation’s Convergence Accelerator Program.

Grant and Award Announcement

UNIVERSITY OF MISSOURI-COLUMBIA

COLUMBIA, Mo. — Like a silent saboteur, foodborne pathogens can sneak up and ruin your next meal. One of the biggest culprits is salmonella, a type of bacteria found in many foods that causes more than 1.3 million cases of foodborne illnesses annually according to the Centers for Disease Control and Prevention.

Despite nationwide efforts, salmonella’s infection rates have remained nearly unchanged for the past 30 years. Now, MU is part of an interdisciplinary effort determined to change that after recently receiving a three-year, $5 million grant from the National Science Foundation’s Convergence Accelerator program.

The 19-member team of investigators — with expertise in engineering, poultry and food science, public health and supply chain management — is developing new technology to rapidly detect and mitigate salmonella and other foodborne pathogens throughout the entire poultry supply chain.

Rapid results

One in every 25 packages of chicken found on store shelves is contaminated with salmonella, according to the U.S. Food and Drug Administration. Because chicken is a major source of illnesses from salmonella, the researchers decided to begin their efforts by focusing on helping the poultry industry.

The team’s goal is to significantly reduce the risk of foodborne illness in people, said Mahmoud Almasri, lead principal investigator (PI) and an associate professor of electrical engineering and computer science in the MU College of Engineering.

“Real-time data collected from multiple portable sensors will be added to a transformative sensor-enabled decision support system (SENS-D), allowing us to produce results in one hour or less,” Almasri said. “Our rapid results will enable both the supply chain and health partners to make data-driven decisions to enhance food safety, equity and security by providing evidence-based solutions.”

While the current gold standard of testing for foodborne pathogens takes at least 24 hours to produce results, the researchers’ forward-thinking approach could one day revolutionize the poultry industry and influence policy, said Kate Trout, co-PI and an assistant professor of health sciences in the MU College of Health Sciences.

“These pathogens grow very quicky, so a lot can happen to a food product in just 24 hours,” Trout said. “We think our sensors, combined with our decision support system, could change the way that the entire poultry industry and health stakeholders make decisions to ensure a safer food supply for everyone.”

For instance, this research is vital for helping ensure food safety between the packing plant and a store shelf.

“Our project could help increase the understanding of the impact of time and temperature during distribution and transit,” said Tim Safranski, co-PI and a professor of animal sciences in the MU College of Agriculture, Food and Natural Resources and a state swine extension specialist with MU Extension.

The team will also use advanced statistical and machine learning techniques to improve risk mitigation.

“One strength of our project is using advanced analytics and artificial intelligence (AI) to develop innovative descriptive, predictive and prescriptive capabilities for a safe, efficient, equitable and resilient food supply chain,” said Haitao Li, co-PI and a professor and chair of supply chain and analytics department at the University of Missouri-St. Louis.

While the sensors are currently in protype development, the team is already exploring how the new technology might work for detecting other foodborne pathogens besides salmonella.

"We hope our technology can go beyond poultry and be adapted to detect and reduce the risk of other foodborne pathogens to benefit society as a whole,” said Amit Morey, co-PI and an associate professor of poultry science at Auburn University.

When the technology is ready for real-world use, the team will work with MU Extension to help industry partners in Missouri and beyond understand how to use the new tools through various workforce education and training initiatives.

“We know that just developing a new technology and putting it out in the world doesn’t make a large impact unless we teach people in the industry how to use these new AI and detection technologies,” Trout said. “We’re fortunate to have such a strong state extension program to be able to implement that component of the program.”

The team also includes researchers at University of Notre Dame and Lincoln University.

Read more from the National Science Foundation.

Cleaned surfaces may be germ-free, but they’re not bare

Peer-Reviewed Publication

AMERICAN CHEMICAL SOCIETY

Since the outbreak of COVID-19, surfaces in public spaces are cleaned more often. While disinfectant solutions eliminate germs, they don’t leave behind a truly bare surface. They deposit a thin film that doesn’t get wiped up, even after giving the surface a good polish. Researchers reporting in ACS ES&T Air show that residues left by commercial cleaning products contain a wider range of compounds that could impact indoor air quality than previously thought.

Residues on indoor surfaces — like those deposited during cooking or cleaning — may contain compounds that are potentially harmful if absorbed through the skin or if they become airborne and are inhaled. To investigate the impact on indoor air quality, scientists study the gunk that builds up with laboratory models of surfaces. In the models, researchers start with the assumption that a thin film exists on any “clean” surface, but the source and actual makeup of these films is unknown. Because the chemical compositions of commercial cleaning products are different from the products used to prep surfaces in the lab, Rachel O’Brien and colleagues hypothesized that commercial sanitizers could be a missing source for the films. So, they decided to characterize films left behind on recently cleaned surfaces.

Using a surface-indoor solvent extractor, the researchers directly collected films from cleaned surfaces in a controlled lab setting and on regularly washed surfaces in university buildings. This method allowed them to pick up and measure a wide array of compounds, including substances that barely evaporate. In contrast, only semivolatile organic compounds (SVOCs) are picked up by wiping a surface film with a solvent-damp cloth, the typical method used to analyze films. The team’s analyses of the residue samples by mass spectrometry found that:

Films from commercial cleaning products were different on the model lab surfaces and university building surfaces and more complex than previously thought.
While the composition of the films was different, they all contained SVOCs that can become airborne and impact indoor air quality.
This method confirmed the presence of lower volatility surfactants, the primary components of soaps, in residues thought to be from the cleaning solutions. However, surfactants’ effects on surface films have not yet been defined.

As a result of these findings, the researchers say that more compounds could be deposited on cleaned surfaces than had previously been identified. They add that future indoor film studies should use surfaces prepared with commercial cleaning products to more accurately identify how the residues impact indoor air quality. And given the extent and regularity of cleaning done in public spaces and people’s homes, more research is needed to determine the effects of lower volatility compounds on film growth and behavior.

The authors acknowledge funding from the Alfred P. Sloan Foundation.

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