CRISPRCas9

CRISPRCas9

CRISPR-Cas9 is a method of genome editing that exploits a natural DNA-snipping enzyme in bacteria, called Cas9 (CRISPR-associated protein 9) to target and edit particular genes. CRISPR stands for Clustered regularly interspaced short palindromic repeats, which are segments of DNA of a particular structure found widely in bacteria and archaea (prokaryotes). In the wild, the CRISPR-Cas9 system is part of the prokaryotic immune system, which can snip out of the genome DNA acquired from foreign sources such as phages (bacterial viruses). The same molecular machinery is now being used to enable genetic material to be cut from and pasted into the genomes of other organisms, including eukaryotes such as humans. It might offer a tool for curing genetically based diseases.

DNA has become a versatile polymeric substrate for making nanotechnological structures and artificial molecular-scale machinery for computation, pattern formation, and nanoscale assembly. For several decades now, these efforts have drawn on methods developed in and for biotechnology, and similarly they are likely to find ways of exploiting the advantages of the new technique called CRISPR/Cas9 for manipulating DNA. #CRISPRCas9

CRISPR-Cas9 is a method of genome editing that exploits a natural DNA-snipping enzyme in bacteria, called Cas9 (CRISPR-associated protein 9) to target and edit particular genes. CRISPR stands for Clustered regularly interspaced short palindromic repeats, which are segments of DNA of a particular structure found widely in bacteria and archaea (prokaryotes). In the wild, the CRISPR-Cas9 system is part of the prokaryotic immune system, which can snip out of the genome DNA acquired from foreign sources such as phages (bacterial viruses). The same molecular machinery is now being used to enable genetic material to be cut from and pasted into the genomes of other organisms, including eukaryotes such as humans. It might offer a tool for curing genetically based diseases.

DNA has become a versatile polymeric substrate for making nanotechnological structures and artificial molecular-scale machinery for computation, pattern formation, and nanoscale assembly. For several decades now, these efforts have drawn on methods developed in and for biotechnology, and similarly they are likely to find ways of exploiting the advantages of the new technique called CRISPR/Cas9 for manipulating DNA.

BACTERIOPHAGES: SMALL THINGS CONSIDERED

Bacteriophages ("phages", for short) are viruses that infect prokaryotes (bacteria and archaea), harnessing the resources of the host cell to replicate vast numbers of themselves, eventually causing the cell to lyse and release the phage progeny, which then find new hosts and repeat the cycle. But that's just the textbook definition. What really hooks us in that some phages look just like lunar landers sent from alien spaceships. Merry Youle, one of STC's very own, has written a charming paean to her beloved subjects, a full length book all about "what makes the phages so fascinating, so intriguing, and so important."

Youle tells us, "This book was born of love, exasperation, and wonderment." Youle holds that phages are deserving of far more ink, and respect, than they've thus far received. They exist everywhere where their hosts thrive, including hydrothermal vents, acidic springs, the arctic tundra, and your own gut. They impact geothermal cycles, algal booms, and biodiversity. They are useful tools for genetic manipulation in the lab as well as in nature. and can serve as allies in treating bacterial infections.

Enterobacteriophage T4

http://schaechter.asmblog.org/schaechter/2017/07/a-star-studded-phantastic-voyage-of-phages.html