CRISPR concernsĬRISPR may be the most precise way to cut DNA we've yet discovered, but it's not always perfect. The tool opens up new ways of creating antimicrobials to combat rising levels of antibiotic resistance, targeted manipulation of agricultural crops such as wheat to make them hardier or more nutritious, and, potentially, the ability to design human beings, gene by gene. Using mouse models, researchers have demonstrated the efficacy of such treatments but human gene therapies using CRISPR remain untested.Īnd CRISPR's potential benefits don't end there. Correcting a defective gene is known as gene therapy, and CRISPR is potentially the most powerful way to perform it. And that's just one of the many trials underway using CRISPR edited cells to fight particular types of cancer.īeyond cancer, CRISPR has the potential to treat diseases caused by a mutation in a single gene, such as sickle cell anemia or Duchenne muscular dystrophy. A Chinese clinical trial extracted T cells from patients, used CRISPR to delete a gene that usually acts as an immune system brake, and then reintroduced them into the patients in an effort to combat lung cancer. One particular leap in cancer therapy options is the genetic modification of T cells, a type of white blood cell that's critical for the human immune system. With better models of say, cancer, researchers are able to fully understand the pathology and how it develops, and that could lead to improved treatment options. The CRISPR/Cas9 system has been adapted to enable gene editing in organisms including yeast, fungi, rice, tobacco, zebrafish, mice, dogs, rabbits, frogs, monkeys, mosquitoes and, of course, humans - so its potential applications are enormous.įor research scientists, CRISPR is a tool that provides better, faster tinkering with genes, allowing them to create models of disease in human cell lines and mouse models with much higher proficiency. If it can find a match, Cas9 is able to chop up the invading DNA. Cas9 uses the CRISPR database to match the stored fingerprints with those of the new invader. If invaded again, the bacteria produce an enzyme called Cas9 that acts like a fingerprint scanner. The leftover DNA is like a fingerprint, stored in the CRISPR database. This kills the virus and the bacteria stores some of the leftover DNA. When a virus enters the bacteria, it fights back by cutting up the virus' DNA. Studying the sequences more intensely revealed that CRISPR forms an integral part of the "immune system" in bacteria, allowing them to fight off invading viruses. The sequences kept appearing in other microbes and in 2002, the unusual DNA structures were given a name: Clustered regularly interspaced short palindromic repeats. Six years later, another microbiologist, Francisco Mojica, noted the sequences in a different single-celled organism, ![]() It could even alter the entire gene pool of a species.ĬRISPR has the potential to be used in editing human embryos to create "designer babies." Science Photo Library/Getty Images What is CRISPR?įew predicted how important CRISPR would become for gene editing upon its discovery 30 years ago.Īs early as 1987, researchers at Osaka University studying the function of Escherichia coli genes first noticed a set of short, repeated DNA sequences, but they didn't understand the significance. Its potential applications are far-reaching, affecting conservation, agriculture, drug development and how we might fight genetic diseases. ![]() Often described as "a pair of molecular scissors," CRISPR is widely considered the most precise, most cost-effective and quickest way to edit genes. ![]() In 2012, a pair of scientists developed a new tool to modify genes, reshaping the entire field of gene-editing forever: CRISPR. Though scientists have made great inroads into understanding human genetics, editing our genes has remained a complex process requiring imprecise, expensive technology, years of expertise and just a little luck, too. Since the 1970s, they've experimentally switched them on and off, uncovering their functions mapped their location within our genome and even inserted or deleted them in animals, plants and human beings.Īnd in November 2018, a Chinese scientist claimed to have created the world's first genetically modified human beings. We are in the midst of a gene-editing revolution.įor four decades, scientists have tinkered with our genes.
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