Tan Rasab

Antibiotic resistance – the ability of harmful bacteria to survive treatment by antibiotics – is a  growing threat . It is making it harder to treat life-threatening infections, including  tuberculosis ,  MRSA , and  gonorrhoea  – and increasing the risks of even minor surgery.  In order to solve antibiotic resistance, one thing researchers first need to understand is how to stop resistance from happening to begin with.  A recent study  conducted at the University of Oxford has helped increase that understanding by showing bacteria can cleverly rearrange their genetics in order to evade the effects of an antibiotic. Bacteria have multiple ways of evolving resistance. They can mutate to prevent antibiotics from targeting them, which can be done by modifying the proteins within the cell where antibiotics act. They can also acquire genes that help them produce antibiotic-destroying molecules, called enzymes. https://elifesciences.org/articles/62474

Imagine there are arrows that are lethal when fired on your enemies yet harmless if they fall on your friends. It's easy to see how these would be an amazing advantage in warfare, if they were real. However, something just like these arrows does indeed exist, and they are used in warfare ... just on a different scale. These weapons are called tailocins, and the reality is almost stranger than fiction. "Tailocins are extremely strong protein nanomachines made by  bacteria ," explained Vivek Mutalik, a research scientist at Lawrence Berkeley National Laboratory (Berkeley Lab) who studies tailocins and phages, the bacteria-infecting viruses that tailocins appear to be remnants of. "They look like phages but they don't have the capsid, which is the 'head' of the phage that contains the viral DNA and replication machinery. So, they're like a spring-powered needle that goes and sits on the  target cell , then appears to poke all the way through the  cell me...

A state-wide genomic sequencing infrastructure not only helps address COVID-19 today but is also a tool that enhances public health effectiveness in the long-term. Without sequencing data, public health authorities are blind to viral mutations that may reduce the efficacy of current response tools (for example, safety protocols, tests, vaccines, and clinical care) and are unable to take precise public health action. Sequencing is a powerful tool that enables public health authorities to improve precision, efficacy, and efficiency of public health response. Sequencing can be used for more efficient source identification of foodborne disease (for example, norovirus, E. coli, Salmonella, and Hepatitis A), ascertaining the origins of 'outlier' cases—those with no known connection to other cases—to contain further outbreaks (as was done in the latter phases of the 2014–16 Ebola outbreak in Guinea),6 and developing diagnostics and vaccines for novel viruses (as was the case w...

A new study by Stanford University biologists finds an explanation for the idea that physical characteristics such as skin pigmentation are "only skin deep." Using genetic modeling, the team has found that when two populations with distinct traits combine over generations, traits of individuals within the resulting "admixed" population come to reveal very little about individuals' ancestry. Their findings were published March 27 in a special edition of the  American Journal of Physical Anthropology  on race and racism. https://onlinelibrary.wiley.com/doi/10.1002/ajpa.24261

Researchers have identified 76 overlapping genetic locations that determine the shapes of our faces and our brains. The genetic signals that influence face and brain shape are enriched by regions of the genome that regulate gene activity during embryogenesis. https://neurosciencenews.com/face-brain-shape-genetics-18174/