Parasite ‘matchmakers’ genetically alter plant cells to attract insects

Researchers have revealed how parasitic phytoplasmas manipulate plant biology to act as matchmakers, boosting male insect appeal by modulating hosts to attract more reproductive females.

eLife

Scientists have revealed a parasite’s role in boosting male insect appeal by modulating host processes to facilitate female attraction, thereby enhancing the parasite’s own transmission and survival. 

The study, published today as a Reviewed Preprint in eLife, is described by the editors as highlighting an important discovery: a bacterial pathogen's effector influences plant responses that in turn affect how the leafhopper insect carrier of the bacteria is attracted to the plants in a sex-dependent manner. They add that the research is backed by convincing analyses and sheds light on previously unexplored aspects of plant–bacteria–insect interactions.

Parasites – which rely on hosts for survival and propagation – have substantial control over their hosts, earning them the nickname ‘puppet masters’. This is especially the case for obligate parasites that rely on alternate hosts (vectors) for transmission. Phytoplasmas, parasites that cause disease in crops and other plants, are reliant on sap-feeding insects, such as leafhoppers, for transmission. They attract these vectors by triggering the growth of unusual plant structures and clustering of leaves through effector molecules, such as the virulence protein SAP54. However, the mechanisms underlying this process are largely unknown.  

“Our research focuses on the virulence protein SAP54, produced by phytoplasmas, which is known to induce the formation of leaf-like flowers in infected plants,” says lead author Zigmunds Orlovskis, a former postdoctoral scientist at the Department of Crop Genetic , John Innes Centre, Norwich, UK, and currently an independent project leader at Latvian Biomedical research and Study Centre. “Previously, we have demonstrated that leafhoppers are attracted to the leaves of infected plants, but this does not always depend on the presence of leaf-like flowers, so the exact mechanism is unclear.”

The team hypothesised that leafhopper attraction is influenced by proteins called MADS-box transcription factors (MTFs) that are involved in additional processes other than flowering, and this is what they set out to test.

They began by assessing the effect of SAP54 on male and female leafhoppers using choice tests – the insects were given the choice to feed and lay eggs on transgenic plants with and without SAP54. The team found that the leafhoppers produced more offspring on SAP54 plants than on those without. However, to their surprise, in the absence of male leafhoppers – there was no increase in offspring on the SAP54 plants. Similar results were seen with feeding preferences; the females secreted more honeydew (an indicator of feeding) on SAP54 plants in the presence of males and no obvious increase in honeydew when males were not present. Together, these results suggest that the attraction of female, fertile leafhoppers to SAP54 plants relies on the presence of male leafhoppers.

Next, the team focused on determining the signals behind these preferences. There were no differences in female leafhopper behaviours when they were placed in odour- and sound-proof containers, suggesting that the females are not using sound and smell for making their choices. This meant there must be some unique characteristic of the leaves in SAP54 plants that was attracting the females.

To explore this further, the team determined which genes were switching on and off in leaves of plants without and without SAP54 that were exposed to male and female leafhoppers. They found that SAP54 plants displayed a dramatically altered pattern of gene activity specifically when colonised by male leafhoppers, compared with the presence of female leafhoppers. Moreover, most of the genes belonged to cell defence and biotic stress pathways, and their activity was significantly lowered in the presence of the male leafhoppers. This could explain the female preference for plants with males already present. 

To address their original hypothesis that MTFs were involved in the leafhopper preferences, the team repeated the leafhopper choice tests in plants with mutated versions of different MTFs. They found that female preference for male-exposed SAP54 plants was dependent on a specific MTF protein called SHORT VEGETATIVE PHASE (SVP). Moreover, plants lacking SVP respond to male and female leafhoppers differently, suggesting that SVP influences the leaf’s response to herbivores in a way that is partly specific to the gender of the leafhoppers. 

“We found that SAP54 suppresses the plant’s biotic stress response pathways when exposed to male leafhoppers. This suppression is crucial in enhancing the plant’s attractiveness to female leafhoppers - the plants producing the phytoplasma effector SAP54 effectively act like a matchmaking service by drawing females to the males,” says Orlovskis. “The findings also suggest that the phytoplasma virulence factor improves male fitness”.

“Our research underscores the dual role of the phytoplasma effector SAP54 in altering host development and enhancing plant attractiveness to reproductive females in the presence of male insects,” concludes senior author Saskia Hogenhout, Professor and Group Leader in Advancing Plant Health, John Innes Centre. “This matchmaking effect is integral to the phytoplasma life cycle, because females lay eggs on the leaves and the leafhopper nymphs hatching from the eggs  will feed from the plant, thereby acquiring  the phytoplasmas that these insects may then vector to other plants. This finding provides profound insights into the extended reach of a single parasite gene in influencing host biology and vector behaviour.”

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About eLife

eLife transforms research communication to create a future where a diverse, global community of scientists and researchers produces open and trusted results for the benefit of all. Independent, not-for-profit and supported by funders, we improve the way science is practised and shared. In support of our goal, we have launched a new publishing model that ends the accept/reject decision after peer review. Instead, papers invited for review will be published as a Reviewed Preprint that contains public peer reviews and an eLife assessment. We also continue to publish research that was accepted after peer review as part of our traditional process. eLife receives financial support and strategic guidance from the Howard Hughes Medical Institute, Knut and Alice Wallenberg Foundation, the Max Planck Society and Wellcome. Learn more at https://elifesciences.org/about.

To read the latest Plant Biology research published in eLife, visit https://elifesciences.org/subjects/plant-biology.

 

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Journal

eLife

DOI

10.7554/eLife.98992.3 

Article Title

The phytoplasma SAP54 effector acts as a molecular matchmaker for leafhopper vectors by targeting plant MADS-box factor SVP

Article Publication Date

7-Jan-202

 

Complex drivers of phytoplankton bloom

The role of winds and currents in the productivity of the equatorial Atlantic

Helmholtz Centre for Ocean Research Kiel (GEOMAR)

The eastern equatorial Atlantic supports a highly productive marine ecosystem dependent on the supply of nitrate-rich waters. Peak productivity occurs during the Northern Hemisphere summer, driven by intensified easterly winds. These winds drive warm surface waters westward, allowing nutrient-rich deep waters to rise in the east. The Equatorial Undercurrent (EUC), a strong subsurface flow, transports cool, nutrient-laden waters eastward across the Atlantic. Seasonal wind patterns cause vertical oscillations of this current, while daily solar heating influences wind-driven mixing, further aiding nutrient transport.

“Our results highlight the complex interplay of wind forcing, currents and mixing in this ocean region,” says Professor Dr Peter Brandt, Professor of Experimental Oceanography at GEOMAR Helmholtz Centre for Ocean Research Kiel and lead author. “Three distinct processes govern the nutrient supply at the equator: upwelling in the east driven by zonal winds, the vertical movement of the EUC, and wind-driven mixing modulated by the daily solar radiation cycle. These processes, each triggered by different aspects of the wind field, drive the upward transport of nutrients to the surface capable of triggering plankton blooms at the equator.”

Measurements and Long-Term Data

To investigate these interactions, extensive measurements were taken during two research cruises with the German RV METEOR (M158 and M181). Data on temperature, salinity, nitrate concentration and current speeds were collected at various depths. Long-term observation data sets from equatorial moorings and Argo floats were also used.

“Turbulence measurements in the ocean are essential for understanding nutrient-supply processes,” explains Dr Mareike Körner, a former researcher at GEOMAR and now based at Oregon State University. “The turbulence data collected during our cruises, combined with similar data from moorings taken by our US collaborators, provided critical insight into the seasonal variations in nutrient mixing from the deeper ocean to the surface.”

Sensitive Interactions Between Winds and Currents

“The dynamics of the equatorial ocean are a finely tuned system of wind-driven processes,” says Peter Brandt. Even small changes, he warns, could disrupt this balance and have a significant impact: “Climate change could significantly alter this balance, impacting nutrient delivery to this crucial marine ecosystem and its productivity.”

Original Publication:

Brandt, P., Körner, M., Moum, J. N., Roch, M., Subramaniam, A., Czeschel, R., Krahmann, G., Dengler, M., & Kiko, R. (2024). Seasonal productivity of the equatorial Atlantic shaped by distinct wind-driven processes. Nature Geoscience.

DOI: 10.1038/s41561-024-01609-9

https://www.nature.com/articles/s41561-024-01609-9

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Journal

Nature Geoscience

DOI

10.1038/s41561-024-01609-9 

Method of Research

Data/statistical analysis

Article Title

Seasonal productivity of the equatorial Atlantic shaped by distinct wind-driven processes

Article Publication Date

6-Jan-2025

 

International collaboration aims to develop high-yielding pest-and disease-resistant cassava, maize and potatoes

Over 500,000 Rwandan farm households to benefit

Donald Danforth Plant Science Center

ST. LOUIS, MO, January 7, 2025 – An international collaboration has announced a public-private partnership to develop high-yielding pest-and disease-resistant cassava, maize and potatoes to benefit more than 500,000 farm households in Rwanda. The partnership, known as the Rwanda Agricultural Biotechnology Programme, aims to improve the productivity and resilience of the three staple crops that are critical to the food security and livelihood of farming families. 

The initiative will be coordinated by AATF and the Rwanda Agriculture and Animal Resources Development Board (RAB) and include the Donald Danforth Plant Science Center, the International Potato Center (CIP), Michigan State University (MSU), Bayer Company, the International Maize and Wheat Improvement Centre (CIMMYT). 

Speaking on behalf of the Minister for Agriculture and Animal Resources, Dr. Telesphore Ndabamenye, RAB Director General, said a partnership approach is key to the project’s success as it will ensure key stakeholders cooperate effectively to address food insecurity in a sustainable way. “By integrating research and extension services, we can equip farmers with the necessary tools and knowledge to boost productivity and resilience,” he said. “A clear road map, coupled with robust monitoring and evaluation, is essential to track progress and ensure that the project stays on course.” 

Dr. Canasius Kanangire, executive director of AATF, noted that the improved crops developed through the project will provide Rwandan farmers with the opportunity to access and plant new varieties that are resistant to devastating insect pests and diseases. “The destructive nature of diseases like cassava brown streak and potato late blight, along with insect pests such as stem borers and fall armyworm, are denying Rwanda’s farmers the full benefit of these widely grown staple food crops,” he said. 

The Virus Resistant Cassava for Africa (VIRCA) project, has been working in Rwanda with RAB since 2019 to develop and deploy cassava with resistance to cassava brown streak disease (CBSD). VIRCA is led by Dr. Nigel Taylor, member and Dorothy J. King Distinguished Investigator at the Danforth Center. “Support from the Rwanda Agricultural Biotechnology Programme brings important new opportunities to produce disease resistant cassava specifically developed to meet Rwandan farmer needs. Importantly, we also now have the resources needed to deliver these products to hundreds of thousands of farming households in Rwanda,” said Taylor.  “It is an exciting time to be working with our partners at RAB and others within the cassava seed systems in Rwanda.”

Potato production in Rwanda is limited by late blight disease, which is estimated to reduce yields by 13 to 60 percent, depending on the season. “CIP and partners have identified at least two potato varieties ready for deployment in Rwanda following adaptation trials,” said Dr. Dinah Borus, senior scientist, in charge of CIP operations in Rwanda. “The biotech potato varieties will be tested in Rwanda to ensure complete resistance to late blight disease and will be released after review and approval by Rwandan regulatory authorities.” 

Rwanda’s national maize average yield of 1.6 tons per hectare is well below the crop's potential, leading the country to spend over $23 million annually to import 100,000 tons of maize grain. Yields can be increased with the improved maize varieties that are drought tolerant and resistant to insect pests. “A pool of insect resistant and drought tolerant maize varieties has already been tested for different growing zones in Rwanda,” said Dr. Sylvester Oikeh, who leads biotech maize development at AATF. “They will be available to farmers, pending adaptation trials and approval by regulators.” 

The Rwanda Agricultural Biotechnology Programme is funded by the Bill & Melinda Gates Foundation and Gates Philanthropic Partners for five years, beginning October 2024. 

About the Danforth Plant Science Center
Founded in 1998, the Donald Danforth Plant Science Center is a not-for-profit research institute with a mission to improve the human condition through plant science. Research, education, and outreach aim to have an impact at the nexus of food security and the environment and position the St. Louis region as a world center for plant science. The Center’s work is funded through competitive grants from many sources, including the National Science Foundation, National Institutes of Health, U.S. Department of Energy, U.S. Agency for International Development, and the Bill & Melinda Gates Foundation, and through the generosity of individual, corporate, and foundation donors. Follow us on Twitter at @DanforthCenter.

About the Rwanda Agriculture and Animal Resources Development Board
RAB is a public agency of the Ministry of Agriculture and Animal Resources (MINAGRI) with a general mission of developing agriculture and animal resources through research, agricultural extension, and animal resources extension to increase agricultural and animal resources productivity and quality, as well as their derived products. For more information visit: https://www.rab.gov.rw/ 

About AATF 
AATF provides farmers in Sub-Saharan Africa (SSA) with practical technology solutions to overcome farm productivity constraints. Founded in 2003, AATF is driven by the vision of a prosperous, resilient, food and nutrition secure Africa, where smallholder farmers’ livelihoods are transformed through agricultural innovations. Active in 24 countries in East, Southern and West Africa, over the past two decades we have emerged as one of the continent’s foremost technology transfer facilitators, trusted by both private and public sector institutions. AATF works beyond the product development segment to help commercialise and scale sustainable, demand-based technologies designed to address specific agricultural challenges. For more information visit: https://www.aatf-africa.org/

DEI STEM

Arkansas Clean Plant Center leads global effort to wipe ‘phantom agents’ from pathogen regulatory lists

Action would improve agricultural efficiency and food security

University of Arkansas System Division of Agriculture

 

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Arkansas Clean Plant Center research program associate Shivani Singh examines plant tissue culture. Scientists from more than 40 countries are calling for reform in testing some regulated pathogens because there is no way to accurately test for them.

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Credit: U of A System Division of Agriculture photo

FAYETTEVILLE, Ark. — Wiping “phantom agents” from a list of suspected plant pathogens would improve agricultural efficiency and food security by updating regulations on international shipment of pathogen-free plant materials destined for countries where they are needed.

Phantom agents are suspected pathogens that have been reported in scientific literature going back to the early 1900s with no real evidence they exist, according to Ioannis Tzanetakis, professor of plant virology for the Arkansas Agricultural Experiment Station and director of the Arkansas Clean Plant Center. The experiment station is the research arm of the University of Arkansas System Division of Agriculture.

The Arkansas Clean Plant Center led the efforts of a team of 185 agricultural scientists from more than 40 countries that test for plant pathogens. They are calling for the removal of more than 120 phantom agents from regulation lists because they are outdated and impede access to plant materials clean of pathogens. Clean plants are needed for the sustainable production of crops.

India, for example, is the second-largest producer of fruits and vegetables in the world, but its lack of disease-free propagation material limits its yield potential, Tzanetakis said.

Most of these phantom agents were described before modern molecular techniques, and there are no samples or genome sequences available to study them. Despite the lack of evidence of their existence, the suspected pathogens made their way into international regulations that control the shipment of plant materials.

The result, Tzanetakis said, is a confusing mix of real and phantom agents on regulatory lists that must be ruled out by the sender before plants can be shipped from country to country.

“We have tried to clean the list of regulated pathogens to make this process much more mainstream,” Tzanetakis said. “What we call phantom agents are names where there’s not really any knowledge of what they are, nor are there any places on this planet where you can go pick this plant and say it is infected with agent X.”

In a Plant Disease article recently published by the American Phytopathological Society, Tzanetakis and a broad host of co-authors identify phantom agents in eight crops that still appear on regulated pathogen lists even though there is no way to accurately test for them.

The article is titled “Streamlining Global Germplasm Exchange: Integrating Scientific Rigor and Common Sense to Exclude Phantom Agents from Regulation.”

“With today’s technology, if an indicator plant shows symptoms, it would undergo analysis by high-throughput sequencing, also known as HTS,” Tzanetakis explained. “If this process identifies a novel agent, it’s unlikely to be attributed to a phantom. Instead, it would be recognized as a new pathogen of the host. As a result, phantom agents tend to persist indefinitely.”

High-throughput sequencing is a scientific method that allows researchers to quickly sequence DNA from a large numbers of samples and/or organisms simultaneously.

Start clean, stay clean

The Arkansas Clean Plant Center, or ACPC for short, is the newest center for berries in the National Clean Plant Network. The network, also known as the NCPN, was created to protect U.S. specialty crops from the spread of economically harmful plant pests and diseases. The U.S. Department of Agriculture funds the NCPN, which includes scientists, educators, state and federal regulators, nurseries and growers who work together to make sure plant propagation material is clean and available.

Labs like the Arkansas Clean Plant Center conduct testing to identify and verify the presence of plant pathogens like those on regulatory lists. The ACPC also provides “clean-up” services to ensure that plant material is the best quality possible before providing it to nurseries, breeding companies and growers.

Tzanetakis said cleaning plant material might be responsible for the elimination of some of the pathogens on the list of phantom agents. Suspected pathogens could also be caused by either a single or multiple viruses now known under a different name, or possibly even eliminated through resistance in modern cultivars.

For example, among the list of phantom agents is “Strawberry band mosaic virus,” something described as a disease once in Hungary in the 1960s on an old cultivar by its display of symptoms based on a single picture present in a publication.

“Given the limited information provided in the single report, the agent cannot be studied further,” Tzanetakis and his co-authors noted.

The ACPC lab is one of only two in the National Clean Plant Network with in-house HTS capabilities, which streamlines the testing and clean-up processes for breeding lines that improve quality control in pathogen testing.

The goal, Tzanetakis said, is to improve crop production and ensure that farmers have access to high-quality, disease-free plants without unnecessary obstacles.

“Those regulations are in place even though we have so many better tools to test for a disease,” Tzanetakis said.

New tools in the toolbox

Tzanetakis said that NCPN labs like the Arkansas Clean Plant Center are designed to test for and eliminate viruses from plants.

Once the plants are “clean” — that is, free from systemic pathogens like viruses — the ACPC maintains “G1” — Generation 1 — materials to offer “the highest level of protection against re-infection by systemic pathogens,” Tzanetakis added.

“This ensures the long-term maintenance of G1 materials, providing breeders and stakeholders with confidence in the quality and integrity of their advanced selections,” Tzanetakis said.

Along with HTS-based virus diagnostic tools and robotics for nucleic acid extraction, Tzanetakis noted that the ACPC is also staffed by a team of experts.

The collective experience, facilities, equipment and staff, Tzanetakis said, add up to “smooth virus elimination operations, offering solutions for selections that are difficult to propagate in vitro, while also keeping pace with and tailoring new protocols for virus elimination.”

To learn more about the Division of Agriculture research, visit the Arkansas Agricultural Experiment Station website. Follow us on X at @ArkAgResearch, subscribe to the Food, Farms and Forests podcast and sign up for our monthly newsletter, the Arkansas Agricultural Research Report. To learn more about the Division of Agriculture, visit uada.edu. Follow us on X at @AgInArk. To learn about extension programs in Arkansas, contact your local Cooperative Extension Service agent or visit uaex.uada.edu.

About the Division of Agriculture

The University of Arkansas System Division of Agriculture’s mission is to strengthen agriculture, communities, and families by connecting trusted research to the adoption of best practices. Through the Agricultural Experiment Station and the Cooperative Extension Service, the Division of Agriculture conducts research and extension work within the nation’s historic land grant education system.

The Division of Agriculture is one of 20 entities within the University of Arkansas System. It has offices in all 75 counties in Arkansas and faculty on five system campuses.

The University of Arkansas System Division of Agriculture offers all its Extension and Research programs and services without regard to race, color, sex, gender identity, sexual orientation, national origin, religion, age, disability, marital or veteran status, genetic information, or any other legally protected status, and is an Affirmative Action/Equal Opportunity Employer.

  

A blackberry plant leaf is examined at the Arkansas Clean Plant Center.

Dr. Shivani Singh, program associate at the Arkansas Clean Plant Center, examines plant tissue for pathogens.

Dr. Dan Edward Veloso Villamor, research scientist for the Arkansas Clean Plant Center.

Ioannis Tzanetakis is professor of plant virology and director of the Arkansas Clean Plant Center for the Arkansas Agricultural Experiment Station, the research arm of the University of Arkansas System Division of Agriculture.

Credit

U of A System Division of Agriculture photo

Journal

Plant Disease

DOI

10.1094/PDIS-04-24-0745-FE 

Method of Research

Observational study

Subject of Research

Cells

Article Title

Streamlining Global Germplasm Exchange: Integrating Scientific Rigor and Common Sense to Exclude Phantom Agents from Regulation

SPAGYRIC HERBALISM

Compound derived from Brazilian plant exhibits action against parasite that causes visceral leishmaniasis

The researchers synthesized a molecule inspired by a substance present in Nectandra leucantha (canela-seca or canela-branca). Animal trials have produced promising results.

Fundação de Amparo à Pesquisa do Estado de São Paulo

 

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Electron microscope image of Leishmania, structure of synthetic compound, and rat 

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Credit: André Gustavo Tempone

A compound derived from Nectandra leucantha, a tree native to southern Brazil (local names canela-seca or canela-branca), has the potential to be used to treat visceral leishmaniasis, a neglected tropical disease associated with poverty, malnutrition, poor housing and lack of basic sanitation. 

The disease is almost always fatal if left untreated. Most cases occur in Brazil, East Africa and India, according to the World Health Organization (WHO). An estimated 50,000-90,000 new cases and 20,000-50,000 deaths occur worldwide annually, with only 25%-45% of cases being reported to WHO.

The disease is caused by a protozoan parasite transmitted by sandfly bite, and characterized by long bouts of fever, loss of weight and muscle strength, enlargement of the spleen and liver, and anemia.

An article by researchers affiliated with institutions in Brazil, the United Kingdom and Portugal, published in the journal Antimicrobial Agents and Chemotherapy, reports the findings of a study showing that the substance killed Leishmania infantum, the parasite that causes the disease, selectively (i.e. without affecting host cells).

The first step in the study, which was supported by FAPESP, was synthesis of a compound similar to dehydrodieugenol B, a neolignan found naturally in N. leucantha and isolated originally by João Lago, full professor at the Federal University of the ABC (UFABC) in São Paulo state, Brazil. The synthesis was performed by Edward Anderson, a professor of organic chemistry at the University of Oxford in the UK. 

“We used this substance as a prototype, a model based on which we could design novel versions of the molecule [with minor structural variations] and test them one by one on the parasite in vitro with the aim of optimizing its action,” said André Gustavo Tempone, principal investigator for the study and a researcher at Butantan Institute’s Physiopathology Laboratory in Brazil. 

In this manner, the researchers obtained a molecule four times more powerful than the prototype. However, in vivo tests involving animals were disappointing because the optimized compound circulated in the rodents’ organism for less than ten minutes, and the study was unable to make progress. “The fact that the substance circulated for such a short time in the rats’ bodies suggested that the ensuing stages of the research would fail. It became clear that the substance wouldn’t produce the expected results,” Tempone said.

The team then focused on additional optimization of the molecule with the aim of enhancing its bioavailability so that it would remain for longer in the animal’s organism. After several chemical optimization processes conducted in vitro in partnership with Maiara Amaral, a student of Tempone’s who was on an internship at Oxford University and used the project as her PhD thesis, they arrived at a more potent molecule whose mean plasma half-life reached 21 hours.

Pharmacokinetic studies measuring the time required for the substance to be absorbed, distributed, metabolized and excreted showed that it circulated in the rat’s organism for a period 100 times longer than that observed initially.

Based on the in vitro analysis, the researchers concluded both that the novel substance was more potent in combating L. infantum, and that it did no damage to host cells. They also investigated its action mechanism, showing that it caused an irreversible collapse of the parasite’s energy mechanism (ATP) due to an increase in calcium, while reducing host cell inflammation, a key factor in the treatment of visceral leishmaniasis. With these good results behind them, the scientists plan to advance farther in animal trials. “We need to analyze the action of the compound in rodents with leishmaniasis in order to assess its efficacy and the doses required for treatment,” Tempone said. 

Their long-term goal is to use the compound to produce medications against visceral leishmaniasis, but a great deal of work still has to be done to achieve this objective. As Tempone recalled, novel drugs take around 15 years to come to market, the development process involving rigorous tests and trials to ensure that the active ingredient is totally safe before clinical trials involving humans can be approved. 

This research is extremely important, he added, as the large pharmaceutical companies are not interested in developing drugs for neglected diseases such as visceral leishmaniasis. “Brazil has one of the most outstanding biodiversities in the world, and a huge abundance of available chemical structures that can be copied and used in medications. If we don’t invest in combating this disease, the rich countries where it isn’t endemic certainly won’t,” he said. 

About 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.

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Journal

Antimicrobial Agents and Chemotherapy

DOI

10.1128/aac.00831-24 

Article Title

Synthesis of a dehydrodieugenol B derivative as a lead compound for visceral leishmaniasis—mechanism of action and in vivo pharmacokinetic studies

 

Exploring the eco-friendly future of antibiotic particles

How goji berries can be used to create silver nanoparticles

American Institute of Physics

 

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An illustration of the preparation of goji berries for silver nanoparticle synthesis.

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Credit: Kamran Alam et al.

WASHINGTON, Jan. 7, 2025 – As the search for sustainability permeates all fields, researchers are turning to a unique organic source for creating antibacterial silver nanoparticles (Ag-NPs) – the humble goji berry.

Goji berries are a ubiquitous superfood known for a multitude of health benefits, including their antibiotic properties. In research published in AIP Advances, by AIP Publishing, researcher Kamran Alam from Sapienza University of Rome along with others from NED University of Engineering and Technology and King Saud University found an effective way to harvest silver nanoparticles from these berries.

“Silver nanoparticles are responsible for disrupting the cell membrane structure, which can generate reactive oxygen species used for inhibiting bacterial growth,” explained Alam.

Silver nanoparticles can be generated using a number of chemical techniques, but green solutions that use biological sources like fruit or leaf extracts are preferred because they save on energy and are nontoxic, nonhazardous, and biologically compatible with humans.

In this interdisciplinary undertaking, Alam and researchers demonstrated a technique for the synthesis of silver nanoparticles using store-bought goji berries.

“Goji berries are easily and locally available in the botanic garden and are rich in bioactive compounds that have natural reducing and stabilizing agents, eliminating the need for additional capping agents during processing,” Alam said.

Alam and the team created silver nanoparticles by drying, grinding, and then filtering the goji berries to create an extract. Then, they added chemical silver nitrate (AgNO3) and reduced the solution.

Using visualization techniques such as X-ray diffraction, Ultraviolet-Visible (UV-Vis) Spectroscopy, and Fourier Transform Infrared (FT-IR) Spectroscopy, the team confirmed the presence of silver nanoparticles. The nanoparticles were also viewed under a microscope and tested for their antimicrobial activity against Staphylococcus aureus, a gram-positive bacterium that causes staph infections among other diseases.

In the future, Alam plans to study the cellular toxicity and biocompatibility of the nanoparticles synthesized from these berries, which could positively contribute to biomedical research.

“This is a simple and straightforward synthesis method which does not need additional chemicals or complex equipment and can be scaled up for industrial applications,” he said.

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The article “Ecofriendly synthesis of silver nanoparticles using metallic solution-based goji berry extract for their antibacterial properties” is authored by Abdul Rauf Jamali, Waseem Khan, Salahuddin Khan, Ahmed Ahmed Ibrahim, and Kamran Alam. It will appear in AIP Advances on Jan. 7, 2025 (DOI: 10.1063/5.0237276). After that date, it can be accessed at https://doi.org/10.1063/5.0237276.

ABOUT THE JOURNAL

AIP Advances is an open access journal publishing in all areas of physical sciences—applied, theoretical, and experimental. The inclusive scope of AIP Advances makes it an essential outlet for scientists across the physical sciences. See https://pubs.aip.org/aip/adv.

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Journal

AIP Advances

DOI

10.1063/5.0237276 

Article Title

Ecofriendly synthesis of silver nanoparticles using metallic solution-based goji berry extract for their antibacterial properties

Article Publication Date

7-Jan-2025

 

University of Minnesota scientists advance nanobody technology to combat deadly Ebola virus

University of Minnesota Medical School

MINNEAPOLIS/ST. PAUL (1/7/2025) – Ebola virus, one of the deadliest pathogens, has a fatality rate of about 50%, posing a serious threat to global health and safety. To address this challenge, researchers at the University of Minnesota and the Midwest Antiviral Drug Discovery (AViDD) Center have developed the first nanobody-based inhibitors targeting the Ebola virus.

Nanobodies are tiny antibodies derived from animals like alpacas. Their small size allows them to access areas of the virus and human tissues that larger antibodies cannot. During the COVID-19 pandemic, the team created nine nanobodies to fight COVID-19. Now, they’ve used this technology to develop two new nanobody inhibitors for Ebola: Nanosota-EB1 and Nanosota-EB2.

The nanobodies work in different ways to stop Ebola. The virus hides the part it uses to attach to human cells under a protective layer. Nanosota-EB1 prevents this layer from opening, blocking the virus from attaching to cells. Nanosota-EB2 targets a part of the virus essential for breaking into cells, stopping its spread. In lab tests, Nanosota-EB2 was especially effective, greatly improving survival rates in Ebola-infected mice.

These nanobodies represent a major step toward treatments for other viruses in the same family, like Sudan and Marburg viruses. This adaptability comes from a new nanobody design method recently developed by the team.

The study, published in PLOS Pathogens, was led by Dr. Fang Li, co-director of the Midwest AViDD Center and a professor of Pharmacology. The research team included graduate student Fan Bu, research scientist Dr. Gang Ye, research assistants Alise Mendoza, Hailey Turner-Hubbard, and Morgan Herbst (Department of Pharmacology), Dr. Bin Liu (Hormel Institute), and Dr. Robert Davey (Boston University). The research was funded by NIH grant U19AI171954.

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Journal

PLOS Pathogens

DOI

10.1371/journal.ppat.1012817 

Method of Research

Experimental study

Subject of Research

Cells

Article Title

Discovery of Nanosota-EB1 and -EB2 as Novel Nanobody Inhibitors Against Ebola Virus Infection

COI Statement

M.A. and B.E. are employees of Laulima Government Solutions, LLC. B.E.W. and B.S. are co-founders of Turkey Creek Biotechnology. The University of Minnesota has filed patents on Nanosota-EB1 and Nanosota-EB2 with F.L, F.B., and G.Y. as inventors.