Tyler O'Neal, Staff Editor HEALTH

TU Dresden scientists determine the structure of glass-shaping protein in sponges

Sponges are some of the oldest animals on Earth. They live in a wide range of waters, from lakes to deep oceans. Remarkably, the skeleton of some sponges is built out of a network of highly symmetrical glass structures. These glass scaffolds have intrigued researchers for a long time. How do sponges manipulate disordered glass into the skeletal elements which are so regular? Researchers from B CUBE – Center for Molecular Bioengineering at TU Dresden together with the teams from the Center for Advancing Electronics Dresden (cfaed) and the Swiss Light Source at the Paul Scherrer Institute in Switzerland are the first to determine the three dimensional (3D) structure of a protein responsible for glass formation in sponges. They explain how the earliest and, in fact, the only known natural protein-mineral crystal is formed. The results were published in the journal “PNAS.”

Glass sponges – as the name suggests – have a glass-based skeleton composed of a network of glass needles, hooks, stars, and spheres. To achieve such a unique architecture they have to manipulate the shape of the disordered glass to form highly regular and symmetrical elements. Thin crystalline fibers made of a protein, known as silicatein, are present in channels inside of these glass elements. It is known that silicatein crystals are responsible for glass synthesis in sponges and for shaping the glass skeleton. However, until now efforts to determine the 3D structure of this protein, describe how it assembles into crystals, and how those form the glass skeleton were unsuccessful. Mainly, because nobody was able to reproduce these crystals in the lab. Glass skeleton of the Demosponge Tethya aurantium imaged with non-invasive X-ray microtomography © Ronald Seidel/Igor Zlotnikov{module INSIDE STORY}

A team of researchers led by Dr. Igor Zlotnikov from the B CUBE –Center for Molecular Bioengineering at TU Dresden tried an unusual approach. Instead of producing silicatein in the lab and trying to obtain lab-grown crystals to study the structure, the researchers decided to take the glass needles from a sponge skeleton and analyze the tiny crystals that already exist inside.

The Zlotnikov group together with researchers from the Dresden Center for Nanoanalysis (DCN) at the Center for Advancing Electronics Dresden (cfaed) used high-resolution transmission electron microscopy (HRTEM) to take a closer look at silicatein crystals packed inside the glass needles. “We have observed an exceptionally ordered and at the same time complex structure. Analyzing the sample we have seen that it is a mixture of organic and inorganic matter. Meaning that both proteins and glass form a hybrid superstructure that somehow shapes the skeleton of sponges,” explains Dr. Zlotnikov.

A traditional way of obtaining a 3D structure of a protein is to expose its crystal to a beam of X-rays. Each protein crystal scatters the X-rays in a different way providing a unique snapshot of its internal arrangement. By rotating the crystal and collecting such snapshots from many angles, the researchers can use computational methods to determine the 3D protein structure. Such an approach is widely used and is the basis of modern structural biology. It works well for crystals of at least 10 microns in size. However, the Zlotnikov group wanted to analyze silicatein crystals which were about 10 times smaller. When exposed to X-rays they were almost immediately damaged, making it impossible to collect a complete data set of snapshots from multiple angles.

With support from the team at PSI’s Swiss Light Source (SLS), the researchers used a newly emerging method known as serial crystallography. “You combine diffraction images from many crystals,” says Filip Leonarski, beamline scientist at PSI, who was involved in the study. “With the traditional method, you shoot a movie. With the new method, you get many snapshots which you combine afterward to decipher the structure.” Each snapshot is taken at a different part of the tiny crystal or even from a different crystal.

In total, the researchers collected more than 3500 individual X-ray diffraction snapshots from 90 glass needles at completely random orientations.  Using state-of-the-art computational methods they were able to find order within the chaos and assemble the data to determine the first complete 3D structure of silicatein.

“Before this study, the structure of silicatein was hypothesized based on its similarity to other proteins,” says Dr. Zlotnikov. Using the newly obtained 3D structure of silicatein, the researchers were able to understand its assembly and function inside the glass skeleton of the sponge. They built a computational model of the superstructure within the glass needle and explained the initial complex images of the protein-glass superstructures obtained with the HRTEM.

“We provided detailed information on the existence of a functional 3D protein-glass superstructure in a living organism. In fact, what we describe is the first known naturally occurring hybrid mineral-protein crystalline assembly,” concludes Dr. Zlotnikov.

Japanese scientists study killer electrons in strumming sky lights

Tyler O'Neal, Staff Editor HEALTH

Wisps of pulsating aurora lights are a rare, yet magical sight. Now, scientists suggest they could be associated with the destruction of part of the ozone.

Supercomputer simulations explain how electrons with wide-ranging energies rain into Earth's upper and middle atmosphere during a phenomenon known as the pulsating aurora. The findings, published in the journal Geophysical Research Letters, suggest that the higher-energy electrons resulting from this process could cause the destruction of the part of the ozone in the mesosphere, about 60 kilometers above Earth's surface. The study was a collaboration between scientists in Japan, including at Nagoya University, and colleagues in the US, including from NASA.

The northern and southern lights that people are typically aware of, called the aurora borealis and australis, look like colored curtains of reds, greens, and purples spreading across the night skies. But there is another kind of aurora that is less frequently seen. The pulsating aurora looks more like indistinct wisps of clouds strumming across the sky. Low-energy (blue) and high-energy (yellow) electrons form during the process that generates the pulsating aurora. The high-energy 'relativistic' electrons could cause localized destruction of the ozone. (Credit: PsA project){module INSIDE STORY}

Scientists have only recently developed the technologies enabling them to understand how the pulsating aurora forms. Now, an international research team, led by Yoshizumi Miyoshi of Nagoya University's Institute for Space-Earth Environmental Research, has developed a theory to explain the wide-energy electron precipitations of pulsating auroras and conducted supercomputer simulations that validate their theory.

Their findings suggest that both low- and high-energy electrons originate simultaneously from interactions between chorus waves and electrons in the Earth's magnetosphere.

Chorus waves are plasma waves generated near the magnetic equator. Once formed, they travel northwards and southwards, interacting with electrons in Earth's magnetosphere. This interaction energizes the electrons, scattering them down into the upper atmosphere, where they release the light energy that appears as a pulsating aurora.

The electrons that result from these interactions range from lower-energy ones, of only a few hundred-kilo electron volts, to very high-energy ones, of several thousand-kilo electron volts, or 'mega electron' volts.

Miyoshi and his team suggest that the high-energy electrons of pulsating auroras are 'relativistic' electrons, otherwise known as killer electrons, because of the damage they can cause when they penetrate satellites.

"Our theory indicates that so-called killer electrons that precipitate into the middle atmosphere are associated with the pulsating aurora, and could be involved in ozone destruction," says Miyoshi.

The team next plans to test their theory by studying measurements taken during a space rocket mission called 'loss through auroral microburst pulsations' (LAMP), which is due to launch in December 2021. LAMP is a collaboration between NASA, the Japan Aerospace Exploration Agency (JAXA), Nagoya University, and other institutions. LAMP experiments will be able to observe the killer electrons associated with the pulsating aurora.

OU's Crossley wins $2 million NSF grant to advance polymer recycling tech

Tyler O'Neal, Staff Editor HEALTH

Young researcher to explore the advancement of polymer recycling technologies in hopes of sending less multi-layer plastics to landfills

Steven Crossley, associate professor at the University of Oklahoma School of Chemical, Biological and Materials Engineering, has been awarded a four-year, $2 million collaborative grant by the Emerging Frontiers in Research and Innovation program of the National Science Foundation to advance polymer recycling technologies in hopes of sending less multi-layer plastics to landfills.

Not all plastics are created equally - from milk jugs and soda bottles, which are readily recyclable, to multi-layered packaging that increases shelf life and requires less material but is less recyclable - the challenge is for researchers to design a process that allows more of the plastics we use in our everyday lives to end up in our recycling bins rather than the local landfill. But not only does this require scientists to design innovative ways to break down these various types of plastic, but it also must be economical for the plastic producers and recyclers. crossly 9af6e{module INSIDE STORY}

Impurities, such as food and drink in the bottom of a plastic container, is another challenge scientists face in the recycling process. These contaminants are difficult to eliminate, and once melted down, degrade the quality of the recycled material.

"But, what if," Crossley asks, "we could design catalysts that target and convert those impurities to either make them more compatible with the rest of the plastic - or convert them selectively to carbon dioxide or light gases that could easily be removed, producing a pure stream of higher value."

Crossley's research group's efforts will be complemented by computational simulations led by Bin Wang, associate professor, and experimental efforts in a scaled-up continuous system led by Lance Lobban, professor, both in the School of Chemical, Biological and Materials Engineering at the University of Oklahoma.

In addition to the upgrading of mixed plastic waste streams using catalysts, Adam Feltz, associate professor of psychology at OU, will incorporate public perception surveys to determine

how best to motivate appropriate public participation in plastic waste collection systems.

The project includes an outreach component for underrepresented and middle and high school students to attend a summer camp, led by Lobban.

Crossley, a registered Native American and faculty advisor to OU's American Indian Science and Engineering Society chapter, will also involve underrepresented undergraduate students in the research during the course of the project.

Christos Maravelias, professor of chemical and biological engineering at Princeton University, and his team will focus on modeling of economic scenarios. These cost estimates will be invaluable as the project evaluates the fiscal efficiencies of these potential new processes.