Libraesva rolled out an emergency update for its Email Security Gateway (ESG) solution to fix a vulnerability exploited by threat actors believed to be state sponsored.
The email security product protects email systems from phishing, malware, spam, business email compromise, and spoofing, using a multi-layer protection architecture.
According to the vendor, Libraesva ESG is used by thousands of small and medium businesses as well as large enterprises worldwide, serving over 200,000 users.
In a study of human immune cells infected with HIV, the virus that causes AIDS, scientists at Johns Hopkins Medicine say a molecule within HIV itself can be manipulated and amplified to force the virus into long-term dormancy, a state in which HIV does not replicate.
The Johns Hopkins team that conducted the new study had previously shown that the molecule of interest, an “antisense transcript,” or AST, is produced by HIV’s genetic material and is part of a molecular pathway that essentially puts the virus to sleep, a state known as viral latency.
The study’s leader, Fabio Romerio, Ph.D., associate professor of molecular and comparative pathobiology at the Johns Hopkins University School of Medicine, says the new findings add to a growing body of evidence that may help researchers develop a gene therapy that boosts AST production. A report on the research, funded by the National Institutes of Health, was published May 9 in Science Advances.
A self-learning memristor is our closest step yet to recreating synapses in the human brain.
Severe infection can lead to sepsis. In sepsis, the host mounts an inappropriately large inflammatory response in an attempt to clear the invading pathogen. This sustained high level of inflammation may cause tissue injury and organ failure. Later in sepsis, a paradoxical immunosuppression occurs, where the host is unable to clear the preexisting infection and is susceptible to secondary infections. A major issue with sepsis treatment is that it is difficult for physicians to ascertain which stage of sepsis the patient is in. Sepsis treatment will depend on the patient’s immune status across the spectrum of the disease, and these immune statuses are nearly polar opposites in the early and late stages of sepsis. Furthermore, there is no approved treatment that can resolve inflammation without contributing to immunosuppression within the host.
Membrane proteins are crucial for numerous biological processes and serve as important drug targets. For decades, scientists have relied on detergents to extract membrane proteins from cell membranes for structural studies.
While detergent-based approaches have significantly advanced our understanding of membrane protein structures, they present certain limitations, such as resource-intensive detergent screening and the absence of native membrane lipids, which can hinder investigations into lipid-mediated regulation.
To address these challenges, a research team led by Prof. Dang Shangyu from the Division of Life Science at the Hong Kong University of Science and Technology (HKUST) has developed a novel vesicle-based method that preserves the native lipid environment of membrane proteins, which can advance structural and functional studies.
There’s always some debate around what style of architecture is best for certain computing applications, with some on the RISC side citing performance per watt and some on the CISC side citing performance per line of code. But when looking at instruction sets it’s actually possible to eliminate every instruction except one and still have a working, Turing-complete computer. This instruction is called subleq or “subtract and branch if less-than or equal to zero ”. [Michael] has built a computer that does this out of discrete components from scratch.
We’ll save a lot of the details of the computer science for [Michael] or others to explain, but at its core this is a computer running with a 1 kHz clock with around 700 transistors total. Since the goal of a single-instruction computer like this is simplicity, the tradeoff is that many more instructions need to be executed for equivalent operations. For this computer it takes six clock cycles to execute one instruction, for a total of about 170 instructions per second. [Michael] also created an assembler for this computer, so with an LCD screen connected and mapped to memory he can write and execute a simple hello world program just like any other computer.
[Michael] does note that since he was building this from Logisim directly he doesn’t have a circuit schematic, but due to some intermittent wiring issues might have something in the future if he decides to make PCBs for this instead of using wire on a cardboard substrate. There’s plenty of other information on his GitHub page though. It’s a unique project that gets to the core of what’s truly needed for a working computer. There are a few programming languages out there that are built on a similar idea.
Conquering aging via TRCS — the telomere DNA AND ribosomal DNA co-regulation model for cell senescence — bilu huang — CSO, fuzhuang therapeutics.
Bilu Huang (https://biluhuang.com/) is a visionary scientist dedicated to finding solutions to some of the most pressing challenges facing humanity. His interdisciplinary work spans multiple fields, including biological aging, dinosaur extinction theories, geoengineering for carbon removal, and controlled nuclear fusion technology.
Born in Sanming City, Fujian Province, Huang is an independent researcher whose knowledge is entirely self-taught. Driven by curiosity and a relentless pursuit of scientific exploration, he has achieved numerous research results through his dedication and passion for science.
As a talented theoretical gerontologist, he proposed the Telomere DNA and ribosomal DNA co-regulation model for cell senescence (TRCS) and he is now using this latest theory to develop biotechnology to rejuvenate cells which will be used to completely cure various age-related degenerative diseases and greatly extend human life at Fuzhuang Therapeutics (https://lab.fuzhuangtx.com/en/).
#Aging #Longevity #BiluHuang #FuzhuangTherapeutics #TelomereDNAAndRibosomalDNACoRegulationModelForCell #Senescence #TRCS #DinosaurExtinctionResearch #CarbonRemovalTechnology #ControlledNuclearFusion #TelomereDNA #RibosomalDNA #CellularAging #GeneticProgram #Telomere #P53
