Friday, June 02, 2023

Research project analyzes medical, nutritional and environmental applications of new Antarctic bacteria


Discovered by Uruguayan scientists in 2013, two psychrophilic (cold-adapted) species have been experimented with since 2018 by a partnership between IIBCE in Montevideo and the University of São Paulo in Brazil.

Peer-Reviewed Publication

FUNDAÇÃO DE AMPARO À PESQUISA DO ESTADO DE SÃO PAULO

New Antarctic bacteria 

IMAGE: RESEARCH PROJECT ANALYZES MEDICAL, NUTRITIONAL AND ENVIRONMENTAL APPLICATIONS view more 

CREDIT: INSTITUTO DE INVESTIGACIONES BIOLÓGICAS CLEMENTE ESTABLE



A scientific collaboration between the University of São Paulo (USP) in Ribeirão Preto, Brazil, and Clemente Estable Institute of Biological Research (IIBCE) in Montevideo, Uruguay, is experimenting with two new bacteria discovered in the Antarctic ten years ago, in order to verify the possibility of applications in healthcare, food processing and environmental rehabilitation.

An article describing part of the results appeared in the March issue of the journal ACS Synthetic Biology, a publication of the American Chemical Society. 

The use of bacteria in biotechnology offers many potential benefits for human beings and the planet, including the absence of toxic waste and lack of dependence on fossil energy sources. Bacteria are microscopic organisms that have the ability to adapt to various environments and perform a range of important functions. Bacteria retrieved from terrestrial extremes have even more interesting physiological characteristics. Antarctica is the coldest continent, with temperatures ranging from -10 °C to -60 °C in winter and from -5 °C to -20 °C in summer.

Bacteria with cold-adapted enzymes are known as psychrophiles. Enzymes are proteins that catalyze specific chemical reactions. The enzymes produced by psychrophiles are very important to biotechnological processes because they remain highly active even at low temperatures. As a result, they are less expensive and more sustainable than enzymes produced by bacteria in temperate environments.

“Bacteria isolated from the environment are often very hard to ‘domesticate’ with a view to using their enzymes. We studied two bacteria belonging to the genus Pseudomonas isolated from sediment in the Antarctic. They’re both new species that have never been described before. We set out to see if we could take advantage of their metabolism with our gene editing tools and succeeded in establishing the correct functioning of several plasmids in these two bacteria, facilitating their use for expression of psychrophilic enzymes in biotech applications,” said María Eugenia Guazzaroni, last author of the article and a professor in the Biology Department of the Ribeirão Preto School of Philosophy, Sciences and Letters (FFCLRP-USP). Her research is supported by FAPESP.

Applications 

Bacterial plasmids are small DNA molecules commonly used in bacterial cloning. Expression plasmids are used to produce specific proteins. The plasmid is introduced into a cell, where it replicates, and the protein is expressed by its DNA.

Expression plasmids are widely used in scientific research and by pharmaceutical and biotech firms to produce large quantities of specific recombinant proteins for the development of medical therapies with hormones or antibodies. 

Psychrophilic enzymes can also be used to produce refrigerated foods such as ice cream and yogurt with enhanced quality and texture. Yet another application involves additives in detergent and washing powder to improve the efficacy of stain and dirt removal. These enzymes function at comparatively low temperatures and can therefore be used for washing laundry in cold water, economizing energy. They also improve the quality of detergent and washing powder, so that clothes and other items made of fabric are less damaged and last longer.

Psychrophilic enzymes can also be used in bioremediation to remove pollutants from cold environments such as the Antarctic.

Cross-border collaboration

The study was conducted in collaboration with Uruguayan scientists who discovered the new bacteria in 2012 in the Antarctic and have been working with the Ribeirão Preto group since 2018. “Vanesa Amarelle, a co-author of the article, visited us as a postdoctoral fellow with a scholarship for training mobility at research institutes abroad in priority areas awarded by Uruguay’s National Research and Innovation Agency [ANII] in 2018,” said Guazzaroni, who has a PhD in biochemistry and molecular biology from Zaidín Experiment Station (EEZ) in Granada, run by Spain’s National Research Council (CSIC), with postdoctoral qualifications in environmental metagenomics and functional metagenomics of extreme environments, also earned in Spain, as well as postdoctoral studies at FFCLRP-USP.

Besides Guazzaroni and Amarelle, the other co-authors of the article are Diego M. Roldán and Elena Fabiano, both of whom are affiliated with IIBCE’s Department of Microbial Biochemistry and Genomics. 

About São Paulo Research Foundation (FAPESP)

The São Paulo Research Foundation (FAPESP) is a public institution with the mission of supporting scientific research in all fields of knowledge by awarding scholarships, fellowships and grants to investigators linked with higher education and research institutions in the State of São Paulo, Brazil. FAPESP is aware that the very best research can only be done by working with the best researchers internationally. Therefore, it has established partnerships with funding agencies, higher education, private companies, and research organizations in other countries known for the quality of their research and has been encouraging scientists funded by its grants to further develop their international collaboration. You can learn more about FAPESP at www.fapesp.br/en and visit FAPESP news agency at www.agencia.fapesp.br/en to keep updated with the latest scientific breakthroughs FAPESP helps achieve through its many programs, awards and research centers. You may also subscribe to FAPESP news agency at http://agencia.fapesp.br/subscribe.

Little-known microbes could help predict climate tipping points

Rising temperatures could push ocean plankton and other single-celled creatures toward a carbon tipping point that fuels more warming. But new research shows it’s also possible to detect early distress signals before they get there.

Peer-Reviewed Publication

DUKE UNIVERSITY

Tipping-point detection 

IMAGE: FOUND IN LAKES AND RIVERS WORLDWIDE, SINGLE-CELLED CREATURES LIKE THESE PARAMECIUM BURSARIA CAN BOTH EAT AND PHOTOSYNTHESIZE. MICROBES LIKE THIS PLAY A DOUBLE ROLE IN CLIMATE CHANGE, RELEASING OR ABSORBING CARBON DIOXIDE -- THE HEAT-TRAPPING GREENHOUSE GAS THAT IS THE PRIMARY DRIVER OF WARMING -- DEPENDING ON WHETHER THEY RELY ON AN ANIMAL-LIKE LIFESTYLE OR A PLANT-LIKE LIFESTYLE. view more 

CREDIT: DANIEL J. WIECZYNSKI, DUKE UNIVERSITY



DURHAM, N.C. -- Researchers studying a group of widespread but often overlooked microbes have identified a climate feedback loop that could accelerate climate change. But it’s not all bad news: this one comes with an early warning signal.

Using a computer simulation, a team of scientists from Duke University and the University of California, Santa Barbara, showed that most of the world’s ocean plankton and many other single-celled creatures in lakes, peatlands and other ecosystems could cross a threshold where instead of soaking up carbon dioxide, they start doing the opposite. That’s because of how warming affects their metabolism.

Because carbon dioxide is a greenhouse gas, that in turn could drive up temperatures further -- a positive feedback loop that could lead to runaway change, where small amounts of warming have an outsized impact.

But by carefully monitoring the abundances of these organisms, we might be able to anticipate the tipping point before it gets here, the researchers report in a study published June 1 in the journal Functional Ecology.

In the new study, researchers focused on a group of tiny organisms called mixotrophs, so named because they mix up two modes of metabolism: they can photosynthesize like a plant or hunt food like an animal, depending on conditions.

“They're like the Venus fly traps of the microbial world,” said first author Daniel Wieczynski, a postdoctoral associate at Duke.

During photosynthesis, they soak up carbon dioxide, a heat-trapping greenhouse gas. And when they eat, they release carbon dioxide. These versatile organisms aren’t considered in most models of global warming, yet they play an important role in regulating climate, said senior author Jean P. Gibert of Duke.

Most of the plankton in the ocean -- things like diatoms, dinoflagellates -- are mixotrophs. They’re also common in lakes, peatlands, in damp soils and beneath fallen leaves.

“If you were to go to the nearest pond or lake and scoop a cup of water and put it under a microscope, you’d likely find thousands or even millions of mixotrophic microbes swimming around,” Wieczynski said.

“Because mixotrophs can both capture and emit carbon dioxide, they're like ‘switches’ that could either help reduce climate change or make it worse,” said co-author Holly Moeller, an assistant professor at the University of California, Santa Barbara.

To understand how these impacts might scale up, the researchers developed a mathematical model to predict how mixotrophs might shift between different modes of metabolism as the climate continues to warm.

The researchers ran their models using a 4-degree span of temperatures, from 19 to 23 degrees Celsius (66-73 degrees Fahrenheit). Global temperatures are likely to surge 1.5 degrees Celsius above pre-industrial levels within the next five years, and are on pace to breach 2 to 4 degrees before the end of this century.

The analysis showed that the warmer it gets, the more mixotrophs rely on eating food rather than making their own via photosynthesis. As they do, they shift the balance between carbon in and carbon out.

The models suggest that, eventually, we could see these microbes reach a tipping point -- a threshold beyond which they suddenly flip from carbon sink to carbon source, having a net warming effect instead of a cooling one.

This tipping point is hard to undo. Once they cross that threshold, it would take significant cooling -- more than one degree Celsius -- to restore their cooling effects, the findings suggest.

But it’s not all bad news, the researchers said. Their results also suggest that it may be possible to spot these shifts in advance, if we watch out for changes in mixotroph abundance over time.

“Right before a tipping point, their abundances suddenly start to fluctuate wildly,” Wieczynski said. “If you went out in nature and you saw a sudden change from relatively steady abundances to rapid fluctuations, you would know it’s coming.”

Whether the early warning signal is detectable, however, may depend on another key factor revealed by the study: nutrient pollution.

Discharges from wastewater treatment facilities and runoff from farms and lawns laced with chemical fertilizers and animal waste can send nutrients like nitrate and phosphate into lakes and streams and coastal waters.

When Wieczynski and his colleagues included higher amounts of such nutrients in their models, they found that the range of temperatures over which the telltale fluctuations occur starts to shrink until eventually the signal disappears and the tipping point arrives with no apparent warning.

The predictions of the model still need to be verified with real-world observations, but they “highlight the value of investing in early detection,” Moeller said.

“Tipping points can be short-lived, and thus hard to catch,” Gibert said. “This paper provides us with a search image, something to look out for, and makes those tipping points -- as fleeting as they may be -- more likely to be found.”

This research was supported by grants from the Simons Foundation (689265), the National Science Foundation (1851194), and the U.S. Department of Energy (DE-SC0020362).

CITATION: "Mixotrophic Microbes Create Carbon Tipping Points Under Warming," Daniel J. Wieczynski, Holly V. Moeller and Jean P. Gibert. Functional Ecology, May 23, 2023. DOI:  10.1111/1365-2435.14350

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