Red Algae Could Be Used to Create a Drug for Coronavirus

Chemical research on Laurencia red algae began in 1965.
Photo Credit: 🇸🇮 Janko Ferlič

Laurencia red algae can be used as a basis for new drugs against the SARS-CoV-2 virus, biochemists have found. A team of scientists from the Ural Federal University, the Institute of Organic Synthesis of the Ural Branch of the Russian Academy of Sciences, together with colleagues from Australia and Germany, carried out molecular docking of 300 bioactive components (ligands) of red algae and found seven compounds with the required activity. The scientists published a description of the experiments and results in the journal Microbiology Research. 

"Laurencia belongs to the family Rhodomelaceae, which is considered one of the largest families of marine red algae, with an estimated 125 genera and 700 species worldwide. Laurencia has recently been the subject of active research. Since 2015, a total of 1,047 secondary metabolites with various useful properties have been isolated from Laurencia species alone," explains Grigory Zyryanov, Chief Researcher of the UrFU Laboratory of Advanced Materials, Green Methods and Biotechnology.

Predicting prostate cancer recurrence 15 months faster

Hector Gomez, a professor in Purdue University’s School of Mechanical Engineering, and his international collaborators have developed a patent-pending method and algorithm to predict the recurrence of prostate cancer in patients treated by radiation therapy.
Photo Credit: Purdue University/Vincent Walter

A Purdue University mechanical engineer and his international collaborators have developed a patent-pending method and algorithm to predict the recurrence of prostate cancer in patients treated by radiation therapy.­

Hector Gomez, a professor in Purdue University’s School of Mechanical Engineering, said data indicates the model-based predictors can identify relapsing patients a median of 14.8 months earlier than the current clinical practice.

Gomez said radiation is an effective treatment for patients of all ages to treat tumors ranging in risk from low to very high. According to Johns Hopkins Medicine, between 20% to 30% of patients will experience a recurrence after the five-year period, post-therapy.

“The detection of prostate cancer recurrence after radiation relies on the measurement of a sustained rise of the serum levels of a substance called prostate-specific antigen, or PSA,” Gomez said. “However, the recurrence may take years to occur, which delays the delivery of a secondary treatment to patients with recurring tumors.”

Study identifies biomarker that could lead to better treatment for autoimmune disease

Emily Vance and Ruth Napier, Ph.D., assistant professor of molecular microbiology and immunology, arthritis and rheumatic disease in the OHSU School of Medicine, a principal investigator with VA Portland, look through some of their microscope work.
Photo Credit: OHSU/Christine Torres Hicks

New research that helps explain the molecular processes involved in the painful autoimmune disease ankylosing spondylitis, or AS, may reduce the guessing game that health care providers currently play while attempting to treat the condition.

A team from Oregon Health & Science University and the VA Portland Health Care System has found a specific kind of AS treatment that is effective when used by patients who have a particular genetic mutation. Their study was published today in the journal Annals of the Rheumatic Diseases, and its findings could lead to more targeted, timely and patient-specific treatment recommendations.

“This is the first-time research has shown that we might be able to use genetic markers to determine which therapy ankylosing spondylitis patients should receive,” said the study’s senior researcher, Ruth Napier, Ph.D., assistant professor of molecular microbiology and immunology, arthritis and rheumatic disease in the OHSU School of Medicine, and principal investigator with VA Portland. “These promising findings are encouraging. This is the first time I can say that I’m on the cusp of making a difference for patients with ankylosing spondylitis who seek relief.”

Mushroom-derived materials could offer benefits for developing nations in Africa

Mycelium composites are a class of materials based on mycelium – the roots of mushrooms.
Photo Credit: Heidi-Ann Fourkiller | Scientific Frontline

A research team from the University of Bristol has suggested that mycelium composites could offer a sustainable alternative to traditional building materials and help address socio-economic and environmental challenges in Africa.

In a new paper published in the journal Advanced Sustainable Systems, Lead Author Stefania Akromah, a PhD student in the Centre for Doctoral Training in Composites Science, Engineering, and Manufacturing, suggests that while holding a lot of potential benefits, mycelium composite technology has yet to become established in the African continent.

Mycelium composites are a class of materials based on mycelium – the roots of mushrooms. These versatile materials, which have gained popularity in Europe and the US in the past decade, are produced by harnessing the ability of fungi to grow by feeding on organic biomass – eliminating the need for high-end manufacturing processes.  In fact, mycelium composites can be grown almost anywhere - even at home - without the need for extensive expertise or advanced equipment.

New Model Explains Precious Metals in Earth’s Mantle

Video Credit: Southwest Research Institute

Southwest Research Institute’s Dr. Simone Marchi collaborated on a new study finding the first geophysically plausible scenario to explain the abundance of certain precious metals — including gold and platinum — in the Earth’s mantle. Based on the simulations, or model, scientists found that impact-driven mixing of mantle materials scenario that could prevent the metals from completely sinking into the Earth’s core.

Early in its evolution, about 4.5 billion years ago, Earth sustained an impact with a Mars-sized planet, and the Moon formed from the resulting debris ejected into an Earth-orbiting disk. A long period of bombardment followed, the so-called “late accretion,” when planetesimals as large as our Moon impacted the Earth delivering materials including highly “siderophile” elements (HSEs) — metals with a strong affinity for iron — that were integrated into the young Earth.

“Previous simulations of impacts penetrating Earth’s mantle showed that only small fractions of a metallic core of planetesimals are available to be assimilated by Earth’s mantle, while most of these metals — including HSEs — quickly drain down to the Earth’s core,” said Marchi, who coauthored a Proceedings of the National Academy of Sciences (PNAS) paper outlining the new findings. “This brings us to the question: How did Earth get some of its precious metals? We developed new simulations to try to explain the metal and rock mix of materials in the present-day mantle.”

Space weather disrupts nocturnal bird migration

A Baltimore oriole in flight. Orioles are nocturnal migratory birds.
Photo Credit: Andrew Dreelin

It’s well-known that birds and other animals rely on Earth’s magnetic field for long-distance navigation during seasonal migrations.

But how do periodic disruptions of the planet’s magnetic field, caused by solar flares and other energetic outbursts, affect the reliability of those biological navigation systems?

University of Michigan researchers and their colleagues used massive, long-term datasets from networks of U.S. Doppler weather radar stations and ground-based magnetometers—devices that measure the intensity of local magnetic fields—to test for a possible link between geomagnetic disturbances and disruptions to nocturnal bird migration.

They found a 9%-17% reduction in the number of migrating birds, in both spring and fall, during severe space weather events. And the birds that chose to migrate during such events seemed to experience more difficulty navigating, especially under overcast conditions in autumn.

The new findings, published online Oct. 9 in Proceedings of the National Academy of Sciences, provide correlational evidence for previously unknown relationships between nocturnal bird migration dynamics and geomagnetic disturbances, according to the researchers.

Climate catastrophe produced instantaneous evolutionary change

A geocolor enhanced image captured by weather satellite GOES-16 shows Hurricane Harvey in the Gulf of Mexico as daylight approached Aug. 24, 2017, with nighttime features to the storm’s left and daytime features to its right.
Photo Credit: NOAA/NASA GOES Project

With species the world over on the move due to climate change, a unique experiment in the wake of 2017’s Hurricane Harvey has revealed a way that species can instantly evolve when they move in response to a climate catastrophe.

“With the profound and rapid changes, we’re seeing with the environment, movement is becoming critical for species’ survival,” said Rice University evolutionary biologist Scott Egan, senior author of a study published this week in Nature Ecology and Evolution. “The takeaway from this study is that while natural selection is still incredibly important, there’s another form of evolutionary change that’s directly related to movement, and it could make a huge difference in the evolution of organisms.”

Harvey, the most intense rainfall event in U.S. history, stalled over southeast Texas and dropped more than three feet of rain over thousands of square miles in a matter of days. Record flooding in and around Houston produced “mini extinctions” of insects and other species in areas that remained inundated for 10 or more days.

Boeing, Nammo Ramjet 155 Test Sets Distance Record

A Boeing and Nammo team set a record for longest indirect fire test of a ramjet-powered artillery projectile.
Photo Credit: U.S. Army photo

A Boeing and Nammo team set a record for longest indirect fire test of a ramjet-powered artillery projectile alongside officials from the U.S. Army — firing a Ramjet 155 munition from a 58-caliber Extended Range Cannon Artillery (ERCA) at Yuma Proving Ground, Ariz. The test advances development efforts for the Army’s top modernization priority, Long Range Precision Fires.

“Our objective was to demonstrate the ability to safely operate from the ERCA system and validate our performance. Both objectives were met.” said Gil Griffin, executive director of Boeing Phantom Works. “The team is working to deliver a superior, affordable precision strike weapon that can neutralize critical targets at long distances.”

The success follows last year’s Boeing-Nammo test recording the longest-ever indirect fire test of a Ramjet 155 munition. That test was completed using a 39-caliber towed artillery cannon at the Andøya Test Center in Norway.

Vacuum cleaner-effect in fungi can hold nanoplastics at bay

Photo Credit: Flockine

Using micro-engineered soil models, researchers at Lund University in Sweden have investigated the effect of tiny polystyrene particles on bacteria and fungi. While these nanoplastics reduced both bacterial and fungal growth, the fungus actually managed to "clean up" their surroundings, thereby easing the effect of the plastics.

“Plastic waste is a huge global problem. Whether carelessly discarded into nature, leaking from landfills or scoring from materials such as car tires and synthetic clothes – large amounts of micro- and nanoplastics end up in our soils,” says Micaela Mafla Endara, biology researcher at Lund University.

Nanoplastics have been proven to induce toxicity in diverse organisms, yet very little is known how this new pollutant is affecting the soil ecosystem. To study these nanoparticles of polystyrene, the researchers used microfluidic chips, a growth system that allowed them to observe interactions of single cells with the plastics under the microscope.

De­ci­pher­ing the in­tens­ity of past ocean cur­rents

In the 6x11 meter flume tank, an ar­ti­fi­cial con­tin­ental slope was re­cre­ated by hand. The cir­cu­lar photo shows first au­thor Hen­ri­ette Wil­ck­ens form­ing the slope from sed­i­ment. The wa­ter-filled tank can be seen in the back­ground.
Photo Mont­age Credit: MARUM – Cen­ter for Mar­ine En­vir­on­mental Sci­ences, Uni­versity of Bre­men, E. Mira­montes

Ocean cur­rents de­term­ine the struc­ture of the deep-sea ocean floor and the trans­port of sed­i­ments, or­ganic car­bon, nu­tri­ents and pol­lut­ants. In flume-tank ex­per­i­ments, re­search­ers from MARUM – Cen­ter for Mar­ine En­vir­on­mental Sci­ences at the Uni­versity of Bre­men have sim­u­lated how cur­rents shape the sea­floor and con­trol sed­i­ment de­pos­ition. This will help in re­con­struc­tions of past mar­ine con­di­tions. They have now pub­lished their res­ults in the Nature journal Communications Earth & Environment.

De­tails of past cli­mate con­di­tions are re­vealed to re­search­ers not only by sed­i­ment samples from the ocean floor, but also by the sur­face of the sea­floor, which is ex­posed to cur­rents that are con­stantly al­ter­ing it. De­pos­its shaped by near-bot­tom cur­rents are called con­tour­ites. These sed­i­ment de­pos­its con­tain in­form­a­tion about past ocean con­di­tions as well as clues to cli­mate. Con­tour­ites are of­ten found on con­tin­ental slopes or around deep-sea moun­tains. But they can be found in any en­vir­on­ment where strong cur­rents oc­cur near the sea­floor. The mech­an­isms that con­trol them are not yet well un­der­stood. Ex­per­i­ments in flume tanks will help to change this through the de­pic­tion of de­pos­ition in fu­ture mod­els.