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Sources cited in this episode include the following:
The November 3rd, 2020 Globe and Mail post, “Broadcasting bill targets online streaming services” at https://www.theglobeandmail.com/politics/article-ottawa-says…lion-from/
The November 3rd, 2020 TVOntario post, “The pandemic is killing government transparency” at https://www.tvo.org/article/the-pandemic-is-killing-government-transparency.
A genetic disposition that plays a role in the development of the heart in the embryo also appears to play a key role in the human immune system. This is shown by a recent study led by the University of Bonn (Germany). When the gene is not active enough, the immune defense system undergoes characteristic changes, causing it to lose its effectiveness. Doctors speak of an aging immune system, as a similar effect can often be observed in older people. In the medium term, the results may contribute to reduce these age-related losses. The study is published in the journal Nature Immunology.
The gene with the cryptic abbreviation CRELD1 has so far been a mystery to science. It was known to play an important role in the development of the heart in the embryo. However, CRELD1 remains active after birth: Studies show that it is regularly produced in practically all cells of the body. For what purpose, however, was previously completely unknown.
The Bonn researchers used a novel approach to answer this question. Nowadays, scientific studies with human participants often include so-called transcriptome analyses. By these means, one can determine which genes are active to what extent in the respective test subjects. Researchers are also increasingly making the data they obtain available to colleagues, who can then use it to work on completely different matters. “And this is exactly what we did in our study,” says Dr. Anna Aschenbrenner from the LIMES Institute at the University of Bonn and member of the ImmunoSensation² Cluster of Excellence.
The deep-sea is one of the most mysterious and unexplored extreme environments, holding great potential and interest for science. Despite extensive studies on deep-sea prokaryotes, the diversity of fungi, one of the most ecologically important groups of eukaryotic micro-organisms, remains largely unknown. However, the presence of fungi in these ecosystems is starting to be recognised. Many fungi have been isolated by culture-dependent methods from various deep-sea environments, with the majority showing similarity to terrestrial species. However, culture-independent methods have revealed many novel fungal phylotypes, including novel fungal lineages recently described as Cryptomycota, which are suspected to lack typical fungal chitin-rich cell walls. Although true fungal diversity and its role in deep-sea environments is still unclear, the intention of this review is to assess current knowledge of the diversity of fungi in these ecosystems and to suggest future direction for deep-sea fungal research.
Metabolites from marine fungi have hogged the limelight in drug discovery because of their promise as therapeutic agents. A number of metabolites related to marine fungi have been discovered from various sources which are known to possess a range of activities as antibacterial, antiviral and anticancer agents. Although, over a thousand marine fungi based metabolites have already been reported, none of them have reached the market yet which could partly be related to non-comprehensive screening approaches and lack of sustained lead optimization. The origin of these marine fungal metabolites is varied as their habitats have been reported from various sources such as sponge, algae, mangrove derived fungi, and fungi from bottom sediments. The importance of these natural compounds is based on their cytotoxicity and related activities that emanate from the diversity in their chemical structures and functional groups present on them. This review covers the majority of anticancer compounds isolated from marine fungi during 2012–2016 against specific cancer cell lines.
Marine fungi are important source of secondary metabolites useful for the drug discovery purposes. Even though marine fungi are less explored in comparison to their terrestrial counterparts, a number of useful hits have been obtained from the drug discovery perspective adding to their importance in the natural product discovery (Molinski et al., 2009; Butler et al., 2014), which have yielded a wide range of chemically diverse agents with antibacterial, antiviral and anticancer properties in animal systems. Starting with the celebrated example of cephalosporins, marine fungi have provided unique chemical skeletons that could be used to develop drugs of clinical importance (Bhadury et al., 2006; Saleem et al., 2007; Javed et al., 2011; Sithranga and Kathiresan, 2011). Fungi, in general, have been generous source of drugs as evidenced by the isolation of many drugs in use such as paclitaxel, camptothecin, vincristine, torreyanic acid and cytarabine to name a few.
The fast food chain is radically rethinking what the Golden Arches experience looks like, from a new loyalty program to more high-tech drive-thrus.
Gonzalez thinks that Tesla taxis could help reinvigorate the city’s yellow-cab industry, which has taken a major hit from ride-hailing services like Uber, Via, and Lyft. He also predicts that the city could, for sustainability reasons, start mandating electric cabs, so he’s looking to get ahead of the curve, even if the commercial charging infrastructure isn’t quite there yet.
Drive Sally plans to bring hundreds of Teslas to New York’s streets in the near future, but for now, the company is still working out the kinks. Gonzalez suspects that the EVs may be better suited for for-hire “black cars” than yellow cabs, and he also said that the more-spacious Model Y would likely work better as a cab than the Model 3, but they’re still too expensive.
Former service members and families of those killed on active duty will have “free access to the iconic and treasured lands they fought to protect.”
A different demonstration by the CAEIT shows the drones being launched from a helicopter.
“They’re still in the early development stage and the technical problems are yet to be resolved,” an insider from the People’s Liberation Army told SCMP. “One of the key concerns is the communications system and how to stop it from getting jammed.”
Experts are worried that drone swarms could be used to confuse and overwhelm air defense systems by quickly being able to approach them from multiple angles.
Host Mark Sackler and panelists discuss the challenges of getting governments and the public on board with one of the basic principles of longevity research: that the cause of all chronic diseases of aging is aging itself.
Three-dimensional (3D) nanostructured materials—those with complex shapes at a size scale of billionths of a meter—that can conduct electricity without resistance could be used in a range of quantum devices. For example, such 3D superconducting nanostructures could find application in signal amplifiers to enhance the speed and accuracy of quantum computers and ultrasensitive magnetic field sensors for medical imaging and subsurface geology mapping. However, traditional fabrication tools such as lithography have been limited to 1-D and 2-D nanostructures like superconducting wires and thin films.
Now, scientists from the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory, Columbia University, and Bar-Ilan University in Israel have developed a platform for making 3D superconducting nano-architectures with a prescribed organization. As reported in the Nov. 10 issue of Nature Communications, this platform is based on the self-assembly of DNA into desired 3D shapes at the nanoscale. In DNA self-assembly, a single long strand of DNA is folded by shorter complementary “staple” strands at specific locations—similar to origami, the Japanese art of paper folding.
“Because of its structural programmability, DNA can provide an assembly platform for building designed nanostructures,” said co-corresponding author Oleg Gang, leader of the Soft and Bio Nanomaterials Group at Brookhaven Lab’s Center for Functional Nanomaterials (CFN) and a professor of chemical engineering and of applied physics and materials science at Columbia Engineering. “However, the fragility of DNA makes it seem unsuitable for functional device fabrication and nanomanufacturing that requires inorganic materials. In this study, we showed how DNA can serve as a scaffold for building 3D nanoscale architectures that can be fully “converted” into inorganic materials like superconductors.”
