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​On February 10, KAUST announced new research demonstrating that corals pass patterns of DNA to their offspring. The groundbreaking research marks the first time that this process has been observed in animals within the field of biology.


Through their research, Manuel Aranda, KAUST associate professor of marine science; KAUST postdoctoral fellow Yi Jin Liew; and University of Wollongong postdoctoral fellow Emily Howells show that corals cannot only adapt to changes in their environment but also pass those learned traits on to their offspring through DNA methylation patterns. The process has previously only been observed in plants.

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Image: KAUST Associate Professor Manuel Aranda and a team of researchers examined intergenerational epigenetic inheritance in corals in work recently published in Nature Climate Change. File photo.

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​On February 4, the University announced that Carlos M. Duarte, KAUST professor of marine science and the Tarek Ahmed Juffali research chair in Red Sea ecology, received a Frontiers of Knowledge Award for Ecology and Conservation Biology from Fundación BBVA in Spain.

Originally from Spain, Duarte has participated in research expeditions worldwide to further the understanding of the diverse marine ecologies that shape environments around the globe. The award recognizes his leadership in researching the global marine science problems of our time, including contributions to Vision 2030, the Kingdom of Saudi Arabia's blueprint of achievement for the new decade.

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Image: Carlos M. Duarte, KAUST professor of marine science and the Tarek Ahmed Juffali research chair in Red Sea ecology, recently received a Frontiers of Knowledge Award for Ecology and Conservation Biology from Fundación BBVA in Spain. File photo.

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Scientists have discovered dozens of new coral species on a recent voyage along the length of the Great Barrier Reef that will provide valuable insights to aid conservation and management of Australia's unique World Heritage site.

The team of researchers from King Abdullah University of Science and Technology (KAUST), James Cook University (JCU) and University of Technology Sydney (UTS) completed the 21-day expedition ranging from the Capricorn Bunkers off Gladstone to Thursday Island in the Torres Strait last month.

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Image: Dr. Francesca Benzoni, Associate Professor of Marine Science at KAUST discovers new corals on the Great Barrier Reef. Photo credit: Professor Andrew Baird, ARC Centre of Excellence for Coral Reef Studies at James Cook University.

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​A novel salt-tolerant bacterium cultured from the Red Sea effectively removes nitrogen from salty wastewater, suggests research from Pascal Saikaly’s team at KAUST. The bacterium could be used to treat sewage coming from toilets that use seawater for flushing in place of freshwater.

Less than one percent of Earth’s water is fresh and also accessible for human use. The world’s population is expected to grow to about ten billion by 2050 and will continue to place increasing pressure on this already rare resource.

Currently, toilet flushing accounts for about 30 percent of the world’s total domestic water demand, with an average human flushing a whopping 50 liters per day. Using seawater to flush toilets could partially alleviate pressure on freshwater resources.

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Image: Flushed toilet water accounts for about 30 percent of domestic wastewater.
© 2020 Muhammad Ali

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​Lipid droplets normally involved in storing fats have recently been revealed as key players in many cancer cell processes, including their ability to resist treatment. These lipids can now be quantitatively identified more easily than ever using a microscopy technique developed at KAUST.

The chemical bonds holding molecules together produce unique vibrations when excited by a light source. Researchers are now exploiting this effect to characterize living cells and tissue through stimulated Raman scattering microscopy. In this approach, ultrafast laser pulses are used to vibrate biomolecules throughout the volume of a sample. The resulting signals can then help visualize components, including lipids at speeds suitable for video imaging.

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Image: Stimulated Raman microscopy of lipid droplets. Two laser beams with different colors nonlinearly interact inside the lipid droplet. The variation in their intensity holds chemical information.
© 2019 Andrea Bertoncini

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​Conventional wastewater disinfection using chlorine could facilitate the spread of antimicrobial resistance in bacteria1. Treating some types of wastewater with ultraviolet (UV) light instead could be part of the solution2, according to a study at KAUST’s Water Desalination and Reuse Center, published in the journal Environmental Science & Technology.

Bacteria are rapidly developing mechanisms to evade the effects of antimicrobial drugs, and this resistance is increasingly threatening public health. Pharmaceutical compounds and resistant bacteria that reach municipal and agricultural wastewater are partially to blame. Interestingly, the antimicrobial resistance of bacteria in wastewater entering water treatment plants is lower than after the wastewater leaves the treatment plant.

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Image: Mutagens, such as disinfection byproducts, in treated wastewater elicit a colorimetric response in this 96-well plate.
© 2019 KAUST

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​An iterative machine learning approach has identified elusive 800 million-year-old amino acid patterns that are responsible for facilitating protein interactions.

Leucine-aspartic acid (LD) motifs are short amino acid sequences embedded within some proteins to link them to cellular molecules that control cell adhesion, motility and survival. They are known to also play a role in cancer cell spreading and in cardiovascular and infectious diseases. LD motifs were first revealed in 1996 in a family of proteins called paxillin. Only three other LD motif-containing proteins have been discovered since then, and scientists do not know the importance of LD motifs or how many other types of proteins contain them.

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Image: The researchers used AI methods to predict the interaction (shown by the dashed lines) of short, linear protein segments (green stick model) with their target proteins (molecular representation on the left). Predictions were experimentally confirmed as shown by the imprint of the ligand on the surface of the target protein (blue, magenta and pink colored surfaces).
© 2019 Rayan Naser

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​A metabolite in plants that regulates the growth of anchor roots—vital for sustaining water and nutrient uptake in plants—has been identified and may have useful applications in agriculture.

Pigment compounds called carotenoids are found in all plants and play a key role in successful photosynthesis and the generation of plant hormones and metabolites. These products are formed when enzyme activity causes carotenoid molecules to split—a process known as cleavage. While many carotenoid products are known to play key biological roles, less is known about one group of cleavage molecules called di-apocarotenoids.

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Image: A newly identified metabolite that stimulates anchor root growth in Arabidopsis plants may have potential applications in promoting plant growth in nutrient-deficient soils. The two plants treated with anchorene (right) show anchor root formation while untreated plants do not show anchor root formation.
© 2019 KAUST

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​An electronic biosensor powered using the glucose in bodily fluids has been developed by KAUST researchers. The device pairs an electron-transporting polymer with an enzyme that extracts electrons from its reaction with glucose to drive its circuitry. The plastic biosensor could act as a continuous monitor of key health indicators, such as blood sugar levels in diabetes patients.

“Quick, accurate and early detection of abnormalities in metabolism is of paramount importance to monitor, control and prevent many diseases, including diabetes,” says David Ohayon, a Ph.D. student in Sahika Inal's lab who led led the research with postdoctoral colleague Georgios Nikiforidis. “Today's glucose monitors are mainly limited to finger-pricking devices, which are often painful,” he says. Implantable glucose-sensing devices are being developed, but their batteries complicate implantation and must eventually be recharged or replaced.

An ideal alternative technology would be implantable polymer biosensors that are able to power themselves using molecules around them.

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Image: A schematic of the all-polymer biofuel cell, which draws energy from the glucose naturally present in saliva.
© 2019 KAUST; Heno Hwang