Archaeologists uncover ancient mosaics on the shore of the Sea of Galilee

JGU students recording the outlines of the mosaic – with a tall waterside plant with blossoms and small green leaves on three stems in the exposed portion and the stern and rudder of a boat on the lower left
Credit: Hans-Peter Kuhnen

With the help of geomagnetic surface surveys and subsequent hands-on digging, an excavation team from Johannes Gutenberg University Mainz (JGU) has revealed new insights into the area in which the caliph's palace of Khirbat al-Minya was built on the shores of the Sea of Galilee. According to these findings, there had already been a settlement occupied by Christian or Jewish inhabitants in the immediate vicinity long before the palace was built.

"This time we have really hit the jackpot with our excavations," said site director and archaeologist Professor Hans-Peter Kuhnen with regard to the outcome of the most recent undertakings in the area around the early Islamic caliph's palace Khirbat al-Minya in Israel. The team of archaeologists from Mainz made this major discovery using geomagnetic methods and by digging test pits on the basis of the findings. They discovered that in the early 8th century the caliph had commissioned the building of his palace, with its incorporated mosque and a 15-meter-high gateway tower, not – as hitherto suspected – on greenfield land on the unoccupied shore of the Sea of Galilee, but adjacent to and respectfully co-existing with a prior settlement. The research project was initially conceived as a means of training students in archeological field work. It was undertaken with the support of the Israel Antiquities Authority and financed by the Fritz Thyssen Foundation, the Axel Springer Foundation, the Santander Foundation, and the German Academic Exchange Service (DAAD). The team was accommodated in the Tabgha Pilgerhaus guesthouse run by the German Association of the Holy Land (DVHL), which has owned the site of the excavations on the northwest shore of the Sea of Galilee since 1895.

Study shows how turtles fared decade after oil spill

Dr. Josh Otten, who graduated in May from UToledo with a Ph.D. in biology, holds a turtle while downloading data to his computer on the Kalamazoo River. Otten is lead author of a new study that confirmed turtles rehabilitated in the aftermath of an oil spill disaster 12 years ago on the river had high long-term survival rates.
Source: University of Toledo

Twelve years after an oil spill coated nearly 35 miles of the Kalamazoo River, new research at The University of Toledo confirms that turtles rehabilitated in the aftermath of the disaster had high long-term survival rates.

Turtles were the most commonly captured oiled animals following a ruptured Enbridge pipeline near Marshall, Mich., in July 2010 that spilled 843,000 gallons of oil into a tributary creek of the river, one of the largest inland oil spills in U.S. history.

Dr. Josh Otten, who graduated in May from UToledo with a Ph.D. in biology, holds a turtle while downloading data to his computer on the Kalamazoo River. Otten is lead author of a new study that confirmed turtles rehabilitated in the aftermath of an oil spill disaster 12 years ago on the river had high long-term survival rates.

Immediately following the spill, nearly 8% of recovered northern map turtles died.

One of the first environmental responders on the scene was biologist Dr. Josh Otten, lead author of the new study published in the journal Environmental Pollution who graduated in May from UToledo with a Ph.D. in biology.

Revealing the Genome of the Common Ancestor of All Mammals

An international team has reconstructed the genome organization of the earliest common ancestor of all mammals. The reconstructed ancestral genome could help in understanding the evolution of mammals and in conservation of modern animals. The earliest mammal ancestor likely looked like this fossil animal, Morganucodon, which lived about 200 million years ago.
Image via Wikipedia by user Funkmonk, Creative Commons Attribution-Share Alike 3.0 Unported license.

Every modern mammal, from a platypus to a blue whale, is descended from a common ancestor that lived about 180 million years ago. We don’t know a great deal about this animal, but the organization of its genome has now been computationally reconstructed by an international team of researchers. The work is published in Proceedings of the National Academy of Sciences.

“Our results have important implications for understanding the evolution of mammals and for conservation efforts,” said Harris Lewin, distinguished professor of evolution and ecology at the University of California, Davis, and senior author on the paper.

The researchers drew on high-quality genome sequences from 32 living species representing 23 of the 26 known orders of mammals. They included humans and chimps, wombats and rabbits, manatees, domestic cattle, rhinos, bats and pangolins. The analysis also included the chicken and Chinese alligator genomes as comparison groups. Some of these genomes are being produced as part of the Earth BioGenome Project and other large-scale biodiversity genome sequencing efforts. Lewin chairs the Working Group for the Earth BioGenome Project.

Novel imaging system could mean near-instant biopsy results

Tissue biopsied with a novel imaging system based on 2-photon fluorescence microscopy (TPFM) is showing promising results. The system, described in the journal JAMA Dermatology, was developed by University of Rochester biomedical engineer Michael Giacomelli.
Photo credit: Giacomelli lab

Medicine has advanced dramatically during the last century. But when it comes to getting biopsy results, very little has changed. Consider, for example, what happens when a patient comes in to have a skin lesion biopsied for nonmelanoma skin cancer.

“The surgeon will take a little piece of the skin out,” says Michael Giacomelli, an assistant professor of biomedical engineering and of optics at the University of Rochester. “Someone in pathology will look at it weeks or even a month later under a microscope. And then, depending on what they find, the patient is notified that everything’s fine, don’t worry about it, or we need you to come back for a second appointment so we can treat you.”

Giacomelli is developing a novel imaging system, contained on a portable cart, to shorten this process to two minutes. This would enable a surgeon to immediately determine whether the lesion is cancerous and, if so, to “treat the patient during the same visit instead of stretching it out over the next month and multiple visits.”

The system—using two-photon fluorescence microscopy (TPFM)—demonstrated remarkable accuracy in a pilot study summarized recently in JAMA Dermatology. When tested on 15 biopsies of known nonmelanoma skin cancer, the technology was able to detect basal cell carcinoma with perfect accuracy (100 percent sensitivity and specificity) and squamous cell carcinoma with high accuracy (89 percent sensitivity and 100 percent specificity).

Seawater could have provided phosphorous required for emerging life

Artist Concept of an Early Earth 
Credit: NASA

The problem of how phosphorus became a universal ingredient for life on Earth may have been solved by researchers from the University of Cambridge and the University of Cape Town, who have recreated primordial seawater containing the element in the lab.

Their results, published in the journal Nature Communications, show that seawater might be the missing source of phosphate, meaning that it could have been available on a large enough scale for life without requiring special environmental conditions.

“This could really change how we think about the environments in which life first originated,” said co-author Professor Nick Tosca from Cambridge's Department of Earth Sciences.

The study, which was led by Matthew Brady, a PhD student from Cambridge's Department of Earth Sciences, shows that early seawater could have held one thousand to ten thousand times more phosphate than previously estimated — as long as the water contained a lot of iron.

Phosphate is an essential ingredient in creating life’s building blocks — forming a key component of DNA and RNA — but it is one of the least abundant elements in the cosmos in relation to its biological importance. When in its mineral form, phosphate is also relatively inaccessible — it can be hard to dissolve in water so that life can use it.

Magnetic Field Helps Thick Battery Electrodes Tackle Electric Vehicle Challenges

Source: University of Texas at Austin

As electric vehicles grow in popularity, the spotlight shines more brightly on some of their remaining major issues. Researchers at The University of Texas at Austin are tackling two of the bigger challenges facing electric vehicles: limited range and slow recharging.

The researchers fabricated a new type of electrode for lithium-ion batteries that could unleash greater power and faster charging. They did this by creating thicker electrodes – the positively and negatively charged parts of the battery that deliver power to a device – using magnets to create a unique alignment that sidesteps common problems associated with sizing up these critical components.

The result is an electrode that could potentially facilitate twice the range on a single charge for an electric vehicle, compared with a battery using an existing commercial electrode.

“Two-dimensional materials are commonly believed as a promising candidate for high-rate energy storage applications because it only needs to be several nanometers thick for rapid charge transport,” said Guihua Yu, a professor in UT Austin’s Walker Department of Mechanical Engineering and Texas Materials Institute. “However, for thick-electrode-design-based next-generation, high-energy batteries, the restacking of nanosheets as building blocks can cause significant bottlenecks in charge transport, leading to difficulty in achieving both high energy and fast charging.”

The key to the discovery, published in the Proceedings of the National Academy of Sciences, uses thin two-dimensional materials as the building blocks of the electrode, stacking them to create thickness and then using a magnetic field to manipulate their orientations. The research team used commercially available magnets during the fabrication process to arrange the two-dimensional materials in a vertical alignment, creating a fast lane for ions to travel through the electrode.

To Stop Viruses, SDSU Researchers are Figuring Out How They're Built

Multiple protein subunits (green, purple and red) of a plant-infecting virus have separate nucleation and growth phases similar to the MS2 bacteria-infecting virus (right).
Source: Protein Data Bank.

An SDSU team, along with Harvard and UCLA collaborators, are researching how distantly related viruses self-organize to improve disease-fighting tactics.

Without a multi-page instruction manual or a commanding Captain America, how do viruses assemble hundreds of individual pieces into elaborate structures capable of spreading disease?

Solving the secret of self-assembly can pave the way for engineering advancements like molecules and robots that put themselves together. It could also contribute to more efficient packaging, automated delivery and targeted design of medicine in the fight against viruses that cause colds, diarrhea, liver cancer and polio.

“If we understand the physical rules of how viruses assemble, then we can try to make them form incorrect structures to hinder their spread,” said Rees Garmann, a chemist at San Diego State University and lead author of a new paper published in the journal PNAS that fills in a piece of the puzzle.

An ocean inside the Earth? Water hundreds of kilometers down

The diamond from Botswana revealed to the scientists that considerable amounts of water are stored in the rock at a depth of more than 600 kilometers.
Photo credit: Tingting Gu, Gemological Institute of America, New York, NY, USA

The transition zone between the Earth's upper and lower mantle contains considerable quantities of water, according to an international study involving the Institute for Geosciences at Goethe University in Frankfurt. The German-Italian-American research team analyzed a rare diamond formed 660 meters below the Earth's surface using techniques including Raman spectroscopy and FTIR spectrometry. The study confirmed something that for a long time was only a theory, namely that ocean water accompanies subducting slabs and thus enters the transition zone. This means that our planet's water cycle includes the Earth's interior. 

Study published in the journal Nature Geoscience.

An ocean inside the Earth? Water hundreds of kilometers down It is located at a depth of 410 to 660 kilometers. The immense pressure of up to 23,000 bar in the TZ causes the olive-green mineral olivine, which constitutes around 70 percent of the Earth's upper mantle and is also called peridot, to alter its crystalline structure. At the upper boundary of the transition zone, at a depth of about 410 kilometers, it is converted into denser wadsleyite; at 520 kilometers it then metamorphoses into even denser ringwoodite.

Is SARS-CoV-2 hiding in your fat cells?

Left: Catherine Blish, MD, PhD, professor of infectious diseases. Right: Tracey McLaughlin, MD, professor of endocrinology.
Source: Stanford Medicine | Stanford University

A study by Stanford Medicine investigators shows that SARS-CoV-2 can infect human fat tissue. This phenomenon was seen in laboratory experiments conducted on fat tissue excised from patients undergoing bariatric and cardiac surgeries, and later infected in a laboratory dish with SARS-CoV-2. It was further confirmed in autopsy samples from deceased COVID-19 patients.

Obesity is an established, independent risk factor for SARS-CoV-2 infection as well as for the patients’ progression, once infected, to severe disease and death. Reasons offered for this increased vulnerability range from impaired breathing resulting from the pressure of extra weight to altered immune responsiveness in obese people.

But the new study provides a more direct reason: SARS-CoV-2, the virus that causes COVID-19, can directly infect adipose tissue (which most of us refer to as just plain “fat”). That, in turn, cooks up a cycle of viral replication within resident fat cells, or adipocytes, and causes pronounced inflammation in immune cells that hang out in fat tissue. The inflammation even converts uninfected “bystander” cells within the tissue into an inflammatory state.

Discovery of Er Blood Group System

Scientists from the University of Bristol and NHS Blood & Transplant (NHSBT) have discovered a rare new blood group system. The findings, published in Blood, the journal of the American Society of Hematology, also solve a 30-year mystery.

A person’s blood type is determined by the presence or absence of proteins known as blood groups that are present on the surface of red blood cells. Although most people are familiar with the concept of blood groups such as ABO or Rh (the plus or minus), there are many other important blood groups. Where mismatches exist between one person’s blood and that of another, the possibility of alloimmunization (the process by which a person generates an antibody against a blood group antigen that they do not carry) arises. The presence of alloantibodies can have clinical consequences in transfusion or pregnancy by triggering an attack by the immune system

Researchers from Bristol’s School of Biochemistry and NHSBT’s International Blood Group Reference Laboratory (IBGRL) spearheaded an international collaboration which sought to investigate a 30-year mystery surrounding the basis of three known, but genetically uncharacterized, antigens that did not fit into any known blood group system.