Tuesday, September 05, 2023

Mixed-use solar and agricultural land is the silver bullet Alberta’s Conservatives have wished for

Story by Joshua M. Pearce, John M. Thompson Chair in Information Technology and Innovation and Professor, Western University •8h
THE CONVERSATION

The Alberta government recently announced a much-maligned seven-month pause on renewable (including solar) energy development in the province. While the exact reasons are up for debate, one specific factor has been the desire to investigate ways to make renewable energy, particularly solar, more integrated within the province over the long term.

Specifically, there is a real concern among some in the party and the general public that industrial solar will displace farming and raise food prices as well as create end-of-life problems with potentially abandoned equipment.

Luckily, we can have our cake and eat it too, with a new concept of agrivoltaics. Agrivoltaics is the simultaneous placement of food crops and solar photovoltaic systems that produce electricity directly from sunlight — while also producing a beneficial micro climate. Covering crops with solar panels may not seem intuitive, however, dozens of studies from all over the world have shown that many crop yields increase when they are partially shaded from solar panels.

This is good news for everyone, but especially for Alberta’s ruling Conservatives, as it provides a seemingly simple solution to a potentially complicated land-use debate between agriculture and energy generation within the province.

Alberta and energy

Alberta’s energy portfolio is changing rapidly. Low-cost solar energy is now growing so fast as to be a “gold rush” in Alberta.

In fact, much to Ontario’s shame, Alberta has taken on the leadership role in solar development in Canada, generating millions of solar dollars and creating thousands of solar jobs for Alberta’s energy workers.

Solar companies have grown so fast precisely because there is profit in offsetting costly fossil-fuel electricity. However, many in Alberta are worried that this new boom will lead to higher food costs, scarred landscapes and a repeat of costs from cleaning up after the oil and gas industry.

This particular land-use conflict between solar and agriculture has been a concern for solar researchers like myself for some time. However, our research in the United States has shown that agrivoltaics provide higher economic productivity, energy and food yields. So much so that the U.S. Department of Energy is now investing millions of dollars to ensure America’s dominance in the field.

Read more: How shading crops with solar panels can improve farming, lower food costs and reduce emissions

One of the studies in the U.S., for example, observed pepper production shoot up by more than 200 per cent while other crops like wheat in Germany were more reserved with a few per cent increase — but they still produced more wheat.

Not surprisingly, agrivoltaics is slated to grow to a $9.3 billion market by 2031.

Agrivoltaics in Canada

Agrivoltaics is happening right here in Canada already (mostly with sheep grazing between panels on marginal land). Last year, we held the first agrivoltaics conference anywhere in North America at the Ivey Business School.

The trade group made up of farmers and solar companies called Agrivoltaics Canada has formed because agrivoltaic farming can help meet Canada’s food and energy needs all the while getting rid of our fossil fuel reliance and greenhouse gas emissions (and the associated emissions liabilities).

Agrivoltaics will allow Alberta’s farmers to keep farming, make more money, drop energy costs, and help protect the environment for all of our children. To take advantage of all the profit that agrivoltaics represents for the province, our team completed a study that showed the changes to Alberta’s regulations would actually need to be relatively modest.

The simple trick is to install solar systems that enable conventional farming, so farmers do not need to change anything. By spacing solar rows out far enough that combines/tractors can drive between them using vertical racks or tracker systems, agrivoltaics are out of the way when the farmer needs to farm. We did a study that looked specifically at Alberta’s agrivoltaic potential, which was second only to Saskatchewan in Canada.
Moving forward together

Agrivoltaics really has broad appeal. Farmers love it as it increases yields and provides steady incomes and so do solar developers and environmentalists. Even most Americans support solar development when agrivoltaics protects farm jobs. It is thus not surprising that agrivoltaics is exploding on the world market.

Eighty-nine per cent of Alberta’s electricity came from fossil fuels, yet we published an article this year that showed that agrivoltaics on just one per cent of the current agricultural land would eliminate the carbon emissions entirely. Less than one per cent of Alberta’s farm land dedicated to agrivoltaics, cuts all harmful emissions from Alberta’s electricity sector while making more food.

Read more: Growing farmland inequality in the Prairies poses problems for all Canadians

This is a win-win for the farmers, and consumers alike. As Alberta’s Conservatives are now able to lift the renewable energy ban knowing that the environment and the food system will be protected, they should ensure that large-scale solar in the province is encouraged to be agrivoltaic. Then all of us, regardless of party, can enjoy the conserved beauty of nature, lower-cost electricity and more food produced per acre. Whether or not this will result in lower costs at the grocery store checkout is a question yet to be answered — but we can hope.

This article is republished from The Conversation, a nonprofit news site dedicated to sharing ideas from academic experts.

Read more:

Is it worth investing in a battery for your rooftop solar? Here’s what buyers need to know (but often can’t find out)

Joshua M. Pearce has received funding for research from the Natural Sciences and Engineering Research Council of Canada, the Canada Foundation for Innovation, Mitacs, the U.S. Department of Energy (DOE) and the Advanced Research Projects Agency-Energy (ARPA-E), U.S. Department of Defense, The Defense Advanced Research Projects Agency (DARPA), and the National Science Foundation (NSF). In addition, his past and present consulting work and research is funded by the United Nations, the National Academies of Science, Engineering and Medicine, many non-profits and for-profit companies in the energy and solar photovoltaic fields. He is a founding member of Agrivoltaics Canada. He does not directly work for any solar manufacturer and has no direct conflicts of interests.
SCI-FI-TEK
Exclusive-Canada oil sands carbon capture project struggles to get key contract


A tailings pond at the Suncor tar sands mining operations near Fort McMurray.


By Steve Scherer

OTTAWA (Reuters) - Canada is struggling to get a key tool in place for major carbon capture and storage (CCS) projects, said a representative of one of the largest such ventures, as the country seeks to launch incentives vital to cutting emissions from Alberta's oil sands.

A government fund has told the Pathways Alliance, comprised of the six largest oil and gas producers in Canada, that their project is too large and too risky for a contract for difference, a tool which would lock in future carbon credit prices, the representative told Reuters.

The mechanism gives investors in CCS certainty about their future revenue by setting a minimum price for their carbon credits. Oil companies in the country's highest-emitting sector are counting on CCS to help dramatically cut emissions while continuing to pump oil and gas.

Pathways is still in talks with the government to set up such a contract, though probably not through the C$15 billion ($11 billion) Canada Growth Fund - a body set up last year by the Finance Ministry to help attract private investment in clean tech by mitigating financing risks - the representative said.

"We sincerely do want to figure out a path to work with them," said a finance ministry official who was not authorized to speak on the record.

Canada is the world's fourth-largest oil producer, and Prime Minister Justin Trudeau has made getting to net-zero by 2050 a guiding principle of his government in recent years.

However, Canada is lagging behind the U.S., which has offered massive incentives to clean tech companies under the U.S. Inflation Reduction Act (IRA) for more than a year now.

Related video: Carbon credits help expand Kenyan cookstove company (Reuters)
Duration 3:12  View on Watch

But Canada's system is more complex because, unlike the U.S., it has a carbon pricing system that will allow companies that capture or reduce emissions to sell carbon credits.

Carbon credits represent reduced or avoided carbon emissions, and companies use them to mitigate greenhouse gases they generate. However, environmental groups have said these schemes allow companies to appear to take climate action when in reality they are not cutting emissions.

The Pathways Alliance CCS hub would store emissions from 14 oil sands projects at an estimated cost of C$16.5 billion ($12.2 billion) by 2030. The project will take years to build and so Pathways is counting on government support to move forward.

The government has told Pathways that the Growth Fund may not be equipped to handle some projects, said the Pathways representative who asked not to be named. The alliance includes Canadian Natural Resources Ltd, Suncor Energy, Cenovus Energy, Imperial Oil, ConocoPhillips Canada and MEG Energy.

Pathways aims to sequester 14 megatonnes of carbon per year and the federal benchmark for credits in 2030 is set at C$170 per tonne. The contract would help pay for capital and operating costs, Pathways says.

Canada set up the Growth Fund last year, which is run through the Public Sector Pension Investment Board, a federal Crown corporation.

Jessica Eritou, a spokesperson for the Finance Ministry, said the government and the Growth Fund are speaking with many commercial project proponents to understand the demand for carbon contracts for difference, and how "we can best facilitate these."

A number of other industries are also looking to use contracts for difference. Adam Auer, president of the Cement Association of Canada, said the contracts are vital to attracting foreign investment.

"We need to have the details finalized and to get some contracts in place before we have the level of certainty that's needed to get some of that foreign capital into our country."

($1 = 1.3591 Canadian dollars)

(Reporting by Steve Scherer; Editing by Denny Thomas and Josie Kao)

 

Can an artificial nose detect food spoilage?


Peer-Reviewed Publication

WILEY




Researchers have developed an energy-efficient computing-based chip with smell-sensing units that can detect food spoilage and provides real-time conditions continuously throughout the spoilage process. The system is described in a study published in Advanced Science.

Other electronic noses, or artificial olfactory systems (AOSs), have been developed in the past, but they have numerous limitations, including high energy consumption, time delays, and data loss.

The AOS developed in this study requires little energy and integrates sensing and computing units on the same chip. It detects food spoilage by employing thin zinc oxide films that sense even very low levels of hydrogen sulfide and ammonia gases, which are high-protein food spoilage markers.

When investigators tested it during the spoilage process of chicken tenderloin, the system continuously tracked freshness scores and food conditions over time. The platform could be used for various applications by adjusting the gas-sensing materials and other parameters.

“Our artificial olfactory system is extremely energy- and area-efficient since the sensing and processing units are integrated and operate concurrently like a biological olfactory system,” said corresponding author Jong-Ho Lee, PhD, of Seoul National University.

URL: https://onlinelibrary.wiley.com/doi/10.1002/advs.202302506

 

Additional Information
NOTE: 
The information contained in this release is protected by copyright. Please include journal attribution in all coverage. For more information or to obtain a PDF of any study, please contact: Sara Henning-Stout, newsroom@wiley.com.

About the Journal
Advanced Science, part of the prestigious Wiley Advanced portfolio, is an open access interdisciplinary science journal publishing the best-in-class fundamental and applied research in materials science, physics, chemistry, medical and life sciences, and engineering. Our mission is to give top science the maximum accessibility through open access publishing.

About Wiley
Wiley is a knowledge company and a global leader in research, publishing, and knowledge solutions. Dedicated to the creation and application of knowledge, Wiley serves the world’s researchers, learners, innovators, and leaders, helping them achieve their goals and solve the world's most important challenges. For more than two centuries, Wiley has been delivering on its timeless mission to unlock human potential. Visit us at Wiley.com. Follow us on FacebookTwitterLinkedIn and Instagram.

 

Synchronizing your internal clocks may help mitigate jet lag, effects of aging


A hearty breakfast instead of a midnight snack could lead to better sleep when traveling


Peer-Reviewed Publication

AMERICAN INSTITUTE OF PHYSICS

Schematic of the mathematical model. 

IMAGE: SCHEMATIC OF THE MATHEMATICAL MODEL. THE MODEL CONSISTS OF TWO POPULATIONS OF COUPLED OSCILLATORS, WHERE ONE POPULATION REPRESENTS THE CENTRAL CLOCK IN THE BRAIN, ENTRAINED BY LIGHT, AND THE OTHER POPULATION REPRESENTS THE PERIPHERAL CLOCKS, ENTRAINED BY FOOD. view more 

CREDIT: HUANG ET AL.




WASHINGTON, Sept. 5, 2023 -- Traveling to faraway places is a great way to seek out new experiences, but jet lag can be an unpleasant side effect. Adjusting to a new time zone is often accompanied by fatigue, difficulty sleeping, and a host of other problems that can turn an otherwise exciting adventure into a miserable trip.

Jet lag is caused by a difference between the circadian system — the body’s internal clock — and the surrounding environment. Around the turn of the century, scientists began to recognize that the body has multiple internal clocks, calibrated in different ways, and that jet lag-like symptoms can result when these clocks drift out of sync with each other. This can happen in several ways and grows more prevalent with age.

In Chaos, from AIP Publishing, a team of scientists from Northwestern University and the Santa Fe Institute developed a theoretical model to study the interactions between multiple internal clocks under the effects of aging and disruptions like jet lag.

Modern research has shown that circadian clocks are present in almost every cell and tissue in the body. Each relies on its own set of cues to calibrate; the brain’s clock depends on sunlight, for instance, while the peripheral organs calibrate at mealtime.

“Conflicting signals, such as warm weather during a short photoperiod or nighttime eating — eating when your brain is about to rest — can confuse internal clocks and cause desynchrony,” said author Yitong Huang.

At this point, little is known about how the body’s various internal clocks affect each other. The added complexity of accounting for multiple clocks means researchers tend to use simplified models.

“Most studies primarily focus on one particular time cue or a single clock,” said Huang. “Important gaps remain in our understanding of the synchronization of multiple clocks under conflicting time cues.”

Huang and her colleagues took a different approach, building a mathematical framework that accounts for this complex interplay between systems. Their model features two populations of coupled oscillators that mimic the natural rhythms of circadian cycles. Each oscillator influences the others while simultaneously adjusting based on unique external cues.

Using this model, the team was able to explore how such a coupled system could be disrupted and what makes the effect worse. They found that common symptoms of aging, such as weaker signals between circadian clocks and a lower sensitivity to light, result in a system that is more vulnerable to disruptions and slower to recover.

They also landed on a new method to speed up recovery from jet lag and similar disruptions. According to their results, the way to better sleep is through the stomach.

“Having a larger meal in the early morning of the new time zone can help overcome jet lag,” says Huang. “Constantly shifting meal schedules or having a meal at night is discouraged, as it can lead to misalignment between internal clocks.”

The authors plan to investigate the other side of the equation and identify the factors that result in more resilient internal clocks. Such discoveries could result in recommendations to prevent jet lag in the first place, or to keep the circadian system healthy into old age.

The article, "A minimal model of peripheral clocks reveals differential circadian re-entrainment in aging," is authored by Yitong Huang, Yuanzhao Zhang, and Rosemary Braun. It will appear in Chaos on Sept. 5, 2023 (DOI: 10.1063/5.0157524). After that date, it can be accessed at https://doi.org/10.1063/5.0157524.

ABOUT THE JOURNAL

Chaos is devoted to increasing the understanding of nonlinear phenomena in all areas of science and engineering and describing their manifestations in a manner comprehensible to researchers from a broad spectrum of disciplines. See https://pubs.aip.org/aip/cha.

###

 

Why are male kidneys more vulnerable to disease than female kidneys? USC Stem Cell-led mouse study points to testosterone


Peer-Reviewed Publication

KECK SCHOOL OF MEDICINE OF USC

female mouse kidney 

IMAGE: TWO OF THE GENES—GSTA4 IN RED AND CYP4A14 IN GREEN—THAT ARE MORE ACTIVE IN FEMALE MOUSE KIDNEYS (BLUE). view more 

CREDIT: IMAGE BY JING LIU/MCMAHON LAB




Female kidneys are known to be more resilient to disease and injury, but males need not despair. A new USC Stem Cell-led study published in Developmental Cell describes not only how sex hormones drive differences in male and female mouse kidneys, but also how lowering testosterone can “feminize” this organ and improve its resilience.

“By exploring how differences emerge in male and female kidneys during development, we can better understand how to address sex-related health disparities for patients with kidney diseases,” said Professor Andy McMahon, the study’s corresponding author, and the director of the Eli and Edythe Broad Center for Regenerative Medicine and Stem Cell Research at the Keck School of Medicine of USC. 

First authors Lingyun “Ivy” Xiong and Jing Liu from the McMahon Lab and their collaborators identified more than 1,000 genes with different levels of activity in male and female mouse kidneys, in a study supported by the National Institutes of Health. The differences were most evident in the section of the kidney’s filtering unit known as the proximal tubule, responsible for reabsorbing most of the nutrients such as glucose and amino acids back into the blood stream. Most of these sex differences in gene activity emerged as the mice entered puberty and became even more pronounced as they reached sexual maturity. 

Because female kidneys tend to fare better in the face of disease or injury, the researchers were interested how the gene activity of kidneys becomes “feminized” or “masculinized”—and testosterone appeared to be the biggest culprit.

To feminize the kidneys of male mice, two strategies worked equally well: castrating males before puberty and thus lowering their natural testosterone levels, or removing the cellular sensors known as androgen receptors that respond to male sex hormones. 

Intriguingly, three months of calorie restriction—which is an indirect way to lower testosterone—produced a similar effect. Accordingly, calorie restriction has already been shown to mitigate certain types of kidney injuries in mice. 

To re-masculinize the kidneys of the castrated males, the researchers only needed to inject testosterone. Similarly, testosterone injection masculinized the kidneys of females who had their ovaries removed before puberty.

The scientists performed some similar experiments with mouse livers. Although this organ also displays sex-related differences, the hormones and underlying factors driving these differences are very different than those at play in the kidney. This suggests that these sex-related organ differences emerged independently during evolution.

To test whether the same genes are involved in sex-related kidney differences in humans, the scientists analyzed a limited number of male and female donor kidneys and biopsies. When it came to genes that differed in their activity between the sexes, there was a modest overlap of the human genes with the mouse genes. 

“There is much more work to be done in studying sex-related differences in normal human kidneys,” said McMahon. “Given the divergent outcomes for male and female patients with kidney disease and injury, this line of inquiry is important for making progress toward eventually closing the gap on these sex-related health disparities.”

Additional authors are Kari Koppitch, Jin-Jin Guo, Megan Rommelfanger, and Adam L. MacLean from USC; Zhen Miao and Junhyong Kim from the University of Pennsylvania; Fan Gao, Ingileif B. Hallgrimsdottir, and Lior Pachter from the California Institute of Technology. 

One hundred percent of this work was supported by federal funding from the National Institutes of Health (grants R01DK126925 and R35GM143019) and the National Science Foundation (DMS2045327). 

 

Linking two solar technologies is a win-win for efficiency and stability


Peer-Reviewed Publication

PRINCETON UNIVERSITY, ENGINEERING SCHOOL




While conventional silicon-based solar cells have had an unmistakable impact on the buildout of renewable energy resources around the world, additional performance improvements have become increasingly difficult to make as the devices approach their practical efficiency limits. This constraint has prompted scientists to seek out new technologies that can be combined with silicon cells to unlock higher efficiencies.

Solar cells made with crystals called perovskites are one such technology that have rapidly emerged as an appealing low-cost add-on, but perovskite cells are notoriously susceptible to voltage-induced changes — the shade cast from an overhanging tree branch or nearby plant can zap an entire module within minutes.

Now, researchers from Princeton University and the King Abdullah University of Science and Technology (KAUST) have connected the well-established silicon solar cell with the up-and-coming perovskite in a tandem solar cell to not only boost overall efficiency, but also to strengthen stability. The results, reported in Joule on Sep. 5, illustrate that the connection protects the frail perovskite solar cell from voltage-induced breakdown while attaining greater efficiencies than either cell can achieve on their own.

“Tandem solar cells have already demonstrated power conversion efficiencies that are greater than either silicon or perovskite solar cells alone,” said Barry Rand, research leader and professor of electrical and computer engineering and the Andlinger Center for Energy and the Environment. “We thought that in addition to their higher efficiencies, tandem solar cells could also solve some of the stability challenges facing perovskites by linking them with silicon cells, which are much more stable.”

To test their hypothesis, the researchers built three strings of solar cells: one containing only silicon solar cells, one with only perovskites, and one composed of tandem solar cells, with the two technologies connected in a series. The researchers then shaded one of the cells in the string to simulate the partial shading conditions that a solar array may encounter at least once in its decades-long lifespan.

Such partial shading usually spells doom for perovskites, as the still-illuminated cells force charge to flow through the now-shaded and inactive cell, quickly degrading both it and the entire module. Silicon solar cells, on the other hand, are much more resilient to voltage fluxes, and can endure periods of partial shading with fewer issues.

As expected, the perovskite-only solar module quickly deteriorated after partial shading, while the silicon solar module was only minimally impacted. Interestingly, however, the tandem solar module was just as resilient as the silicon-only module, implying that by connecting the two solar technologies, the silicon cell was able to mask the frailty of the perovskite.

“When you combine two different materials to form a final product, usually it’s the weakest link that ends up determining the overall strength of the chain,” said co-author Stefaan De Wolf, professor of material science and engineering at KAUST. “But in this case, it’s actually the stronger component that protected the weaker one.”

The researchers said their findings demonstrate that partial shading — which has been a major obstacle to perovskite-only modules — may be a negligible concern for series-connected tandem solar devices.

The team also said that the findings bode well for the commercialization prospects of perovskites, because they imply that perovskites may have the most potential when deployed in complement with silicon solar cells, for which a mature manufacturing ecosystem already exists. Instead of having to build a competing manufacturing process, perovskites could be added onto the commercially proven production process for silicon solar cells.

While the team noted that several challenges in addition to partial shading remain to be solved before tandem solar cells achieve the lifespan expected of commercial solar technologies, such as their poor resilience to heat, they said that tandem devices could enable solar research to continue evolving after silicon solar cells hit their upper power conversion efficiency limits.

“If some other stability challenges can be solved, tandem solar cells could essentially take an already successful commercial technology and make it even better,” Rand said. “Our results make a strong case that tandem devices should be an all-hands-on-deck area for future solar research.”

The paper, “Reverse-bias resilience of monolithic perovskite/silicon tandem solar cells,” was published September 5 in Joule. In addition to Rand and De Wolf, co-authors include Zhaojian Xu of Princeton; Helen Bristow, Maxime Babics, Badri Vishal, Erkan Aydin, Randi Azmi, Esma Ugur, Bumin Yildirim, and Jiang Liu of the KAUST Solar Center; and Ross Kerner of the National Renewable Energy Laboratory (NREL).

The work was supported by KAUST under contract numbers OSR-CRG2020-4350, OSR-CARF/CCF-3079, and OSR-CRG2022-5035. The research was authored in part by NREL under contract number DE-AC36-08GO28308, and the researchers also received support from NREL’s Laboratory Directed Research and Development (LDRD) program.

 

3D-printed ‘living material’ could clean up contaminated water


Peer-Reviewed Publication

UNIVERSITY OF CALIFORNIA - SAN DIEGO

'Living material’ could clean up contaminated water 

VIDEO: A "LIVING MATERIAL," MADE OF A NATURAL POLYMER COMBINED WITH GENETICALLY ENGINEERED BACTERIA, COULD OFFER A SUSTAINABLE AND ECO-FRIENDLY SOLUTION TO CLEAN POLLUTANTS FROM WATER. view more 

CREDIT: UC SAN DIEGO JACOBS SCHOOL OF ENGINEERING




Researchers at the University of California San Diego have developed a new type of material that could offer a sustainable and eco-friendly solution to clean pollutants from water.

Dubbed an “engineered living material,” it is a 3D-printed structure made of a seaweed-based polymer combined with bacteria that have been genetically engineered to produce an enzyme that transforms various organic pollutants into benign molecules. The bacteria were also engineered to self-destruct in the presence of a molecule called theophylline, which is often found in tea and chocolate. This offers a way to eliminate them after they have done their job.

The researchers describe the new decontaminating material in a paper published in the journal Nature Communications.

“What’s innovative is the pairing of a polymer material with a biological system to create a living material that can function and respond to stimuli in ways that regular synthetic materials cannot,” said Jon Pokorski, a professor of nanoengineering at UC San Diego who co-led the research.

The work was a collaboration among engineers, materials scientists and biologists at the UC San Diego Materials Research Science and Engineering Center (MRSEC). Co-principal investigators of the multidisciplinary team include molecular biology professors Susan Golden and James Golden and nanoengineering professor Shaochen Chen.

“This collaboration allowed us to apply our knowledge of the genetics and physiology of cyanobacteria to create a living material,” said Susan Golden, a faculty member in the School of Biological Sciences. “Now we can think creatively about engineering novel functions into cyanobacteria to make more useful products.”

To create the living material in this study, the researchers used alginate, a natural polymer derived from seaweed, hydrated it to make a gel and mixed it with a type of water-dwelling, photosynthetic bacteria known as cyanobacteria.

The mixture was fed into a 3D printer. After testing various 3D-printed geometries for their material, the researchers found that a grid-like structure was optimal for keeping the bacteria alive. The chosen shape has a high surface area to volume ratio, which places most of the cyanobacteria near the material’s surface to access nutrients, gases and light.

The increased surface area also makes the material more effective at decontamination.

As a proof-of-concept experiment, the researchers genetically engineered the cyanobacteria in their material to continually produce a decontaminating enzyme called laccase. Studies have shown that laccase can be used to neutralize a variety of organic pollutants including bisphenol A (BPA), antibiotics, pharmaceutical drugs and dyes. In this study, the researchers demonstrated that their material can be used to decontaminate the dye-based pollutant indigo carmine, which is a blue dye that is widely used in the textile industry to color denim. In tests, the material decolorized a water solution containing the dye.

The researchers also developed a way to eliminate the cyanobacteria after the pollutants have been cleared. They genetically engineered the bacteria to respond to a molecule called theophylline. The molecule triggers the bacteria to produce a protein that destroys their cells.

“The living material can act on the pollutant of interest, then a small molecule can be added afterwards to kill the bacteria,” said Pokorski. “This way, we can alleviate any concerns about having genetically modified bacteria lingering in the environment.”

A preferable solution, the researchers note, is to have the bacteria destroy themselves without the addition of chemicals. This will be one of the future directions of this research.

“Our goal is to make materials that respond to stimuli that are already present in the environment,” said Pokorski.

“We’re excited about the possibilities that this work can lead to, the exciting new materials we can create. This is the kind of research that can result when researchers with cross-disciplinary expertise in materials and biological sciences join forces. This is all made possible thanks to our interdisciplinary research group at the UC San Diego MRSEC.”

Paper title: “Phenotypically Complex Living Materials Containing Engineered Cyanobacteria.” Co-authors include Debika Datta*, Elliot L. Weiss*, Daniel Wangpraseurt, Erica Hild, Shaochen Chen, James W. Golden, Susan S. Golden and Jonathan K. Pokorski, all at UC San Diego.

*These authors contributed equally to this work.

This work was supported in part by the UC San Diego Materials Research Science and Engineering Center (UC San Diego MRSEC) and the National Science Foundation (DMR-2011924).

UC San Diego researchers have developed a "living material," made of a natural polymer combined with genetically engineered bacteria, that could offer a sustainable and eco-friendly solution to clean pollutants from water.

CREDIT

David Baillot/UC San Diego Jacobs School of Engineering

Will it slip or will it grip: scientists ask, “what is snail mucus?”


A new study breaks down the complex structure of snail mucus and identifies novel proteins


Peer-Reviewed Publication

ADVANCED SCIENCE RESEARCH CENTER, GC/CUNY

Snail Mucus Dendrogram 

IMAGE: A DENDROGRAM (TREE) SHOWING THE GENETIC SIMILARITY BETWEEN 71 PROTEINS AGAINST ~180 RELATED PROTEINS THAT WERE FOUND PREVIOUSLY IN OTHER MOLLUSKS. THE RESULTS CONFIRM THAT EVEN WHEN COMPARED AGAINST HUNDREDS OF OTHER PROTEINS SIMULTANEOUSLY, SIMILAR PROTEINS STILL CLUSTER TOGETHER. THE BLACK BRACKET ON THE RIGHT SIGNIFIES THE “OUTGROUP,” A GROUP OF PROTEINS THAT IS INTENTIONALLY UNRELATED FROM THE REST. view more 

CREDIT: ANTONIO CERULLO




NEW YORK, September 5, 2023 — What is snail mucus? That was the question posed by researchers in a new study that examines the molecular composition of snail mucus. When analyzing the mucus of a common garden snail, they found it contained a complex collection of proteins, some identified as entirely novel.

In a newly published paper in Nature Communications, scientists profile the mucus of Cornu aspersum — a species used in beauty product formulation and eaten as escargot — and detail the composition of three unique types of secretions — one that hydrates and protects its skin, another that works as a glue-like adhesive, and another that lubricates to allow the animal to move freely across surfaces.

“We were surprised that the mucus compositions were quite different, despite being produced by the same species,” said lead author Antonio Cerullo, a biochemistry Ph.D. student at the CUNY Graduate Center. “Even more so, the adhesive snail glue and the lubricious snail trail, which have completely opposite purposes, come from the same part of the snail. It was exciting to discover that very subtle differences in mucus compositions have huge impacts on their biological and material properties.”

The researchers say the hydrogels contain ions, sugars, and more than 70 proteins, including enzymes, mucins, lectins, and matrix proteins. About one-third of the proteins found in the mucus shared no similarity with any proteins in the global databases that were searched, said the researchers. In short, the secretions contain many proteins that are unlike any others known to science.

Snail mucus is widely used in cosmetics, moisturizers, anti-aging creams, wound care treatments, and antimicrobials. Beauty products containing snail mucus are a multi-billion-dollar global industry.

There are still many open questions about the macromolecular structure of mucus. Even human mucus, which has been studied much more extensively than snail mucus, is not well understood.

“Everyone is fascinated and disgusted by mucus. However, most people don’t realize just how complex and elegant these secretions are,” said the study’s principal investigator Adam Braunschweig, who is a faculty member with the Nanoscience Initiative at the Advanced Science Research Center at the CUNY Graduate Center (CUNY ASRC) and a professor of chemistry and biochemistry at the Graduate Center and Hunter College.

The data revealed subtle differences that accounted for vast differences in properties of the mucus. One example involves the use of calcium.=

Calcium holds mucus networks together and solidifies the network. As a result, lubricating mucus has the least amount of calcium and the highest amount of calcium-binding proteins, while binding mucus has the opposite composition.

Snail mucus is currently being studied for applications in biomedicine, including surgical glues, as lubricants for eyes, joints, and medical implants, as well as drug delivery systems. More uses of snail mucus are being discovered every day, Braunschweig said.

Xi Chen, a CUNY ASRC researcher and professor at The City College of New York and the Graduate Center and Mandë Holford, a chemistry professor at the CUNY Graduate Center and Hunter College were collaborators on the study.

The study was funded by the National Science Foundation, the Air Force Office of Scientific Research, and the U.S. Space Force. Collaborators were supported by the Office of Naval Research, the Allen Institute, and the National Institutes of Health.

 

About the Graduate Center of The City University of New York
The CUNY Graduate Center is a leader in public graduate education devoted to enhancing the public good through pioneering research, serious learning, and reasoned debate. The Graduate Center offers ambitious students nearly 50 doctoral and master’s programs of the highest caliber, taught by top faculty from throughout CUNY — the nation’s largest urban public university. Through its nearly 40 centers, institutes, initiatives, and the Advanced Science Research Center, the Graduate Center influences public policy and discourse and shapes innovation. The Graduate Center’s extensive public programs make it a home for culture and conversation.

About the Advanced Science Research Center at the CUNY Graduate Center
The Advanced Science Research Center at the CUNY Graduate Center (CUNY ASRC) is a world-leading center of scientific excellence that elevates STEM inquiry and education at CUNY and beyond. The CUNY ASRC’s research initiatives span five distinctive, but broadly interconnected disciplines: nanoscience, photonics, neuroscience, structural biology, and environmental sciences. The center promotes a collaborative, interdisciplinary research culture where renowned and emerging scientists advance their discoveries using state-of-the-art equipment and cutting-edge core facilities.