You may not know what clustered regularly interspersed short palindromic repeats means, but when you see or hear the word CRISPR it all takes on new meaning, thanks to the efforts of UC Berkeley’s Jennifer Doudna and her collaborator Emmanuelle Charpentier, who developed this revolutionary method of genomic editing.
Her work has literally changed the world with her research, with tremendous benefits for the future of humankind and the planet.
The discovery of CRISPR-Cas9 genetic engineering technology has changed human and agricultural genomics research forever. This genome-editing technology enables scientists to change or remove genes quickly and with extreme precision. Labs worldwide have changed the course of their research programs to incorporate this new tool, creating a CRISPR revolution with huge implications across biology and medicine.
This talk marks the occasion of Doudna receiving the UC San Diego Scripps Institution of Oceanography’s 2019 Nierenberg Prize for Science in the Public Interest.
Watch — Editing the Code of Life: Into the Future with CRISPR Technology with Jennifer Doudna – 2019 Nierenberg Prize for Science in the Public Interest
Science fiction has long promised an age of interplanetary human existence. Scenes of spaceships hopping from one galaxy to the next are so common, it seems almost inevitable that future generations will one day vacation on Mars. But, if we are ever going to achieve life on other planets, we first have to figure out if the human body can tolerate it.
Some of the best data we have on the subject comes from American astronaut Scott Kelly. Kelly spent a year living on the International Space Station while his twin brother Mark, also an astronaut, was on Earth. Scientists from all over the country studied the impact life in space had on Scott Kelly, and compared changes in his body to his brother.
One of those scientists was UC San Diego Professor of Medicine, Michael G. Ziegler, MD. In a recent talk at UC San Diego Extension’s Osher Lifelong Learning Institute, Ziegler detailed some of the more interesting findings from the study. Scott Kelly lost weight. There were significant changes to his gene expression. He lost collagen. His carotid artery thickened. His bones became less dense. His eye shape changed, forcing him to wear glasses. While he was in space, his performance on cognitive tests improved. But, his performance plummeted after returning to Earth, and never quite returned to pre-launch levels.
Despite all of this, Ziegler has reason to be hopeful about long-term space travel. He says the year in space study illuminated many of the challenges, and gave researchers some ideas of how to overcome them. Still, it’s probably a little early to start planning your trip to the red planet.
Watch — How a Year in Space Affects the Human Body with Dr. Michael G. Ziegler — Osher UC San Diego
Svante Pääbo once said, “We are all Africans, either living in Africa or in recent exile from Africa.”
It is now abundantly clear that Africa was the “cradle of humanity,” with multiple waves of hominins arising on that continent and spreading across the old world, eventually being effectively displaced by our own species, which also arose in Africa.
Given these facts, it is not surprising that the strong emphasis of anthropogeny is on the continent of Africa with wide-ranging studies including genetic, paleontological, archeological, primatological, climatological, sociocultural and more.
This CARTA symposium focuses on the contributions of scientists and scholars of anthropogeny who live and work in Africa.
Browse more programs in Anthropogeny: The Perspective from Africa.
Mosquitos are the deadliest animal on Earth. They spread diseases like yellow fever, chikungunya, West Nile virus and malaria. Malaria alone killed 435,000 people and infected another 219 million in 2017 according to the World Health Organization. There are widespread efforts to combat mosquito-borne illnesses, including revolutionary new gene editing techniques.
Ethan Bier and Valentino Gantz, biologists at UC San Diego, have been researching gene drives – systems that allow scientists to quickly push genes through entire populations. Typically, genetic information from each parent is combined and passed down to their children. Think back to Punnett squares from high school biology. If one parent has blonde hair and the other has brown hair, the brunette would have to carry a recessive blonde gene for any of their children to be blonde. But, gene drives change that. Gantz and Bier came up with a way to use the CRISPR gene-editing technique to insert self-editing genes into mosquitos, so preferred traits are always passed down. Their research shows these traits can take over entire populations within 10 generations, one to two years for mosquitos.
In a recent talk at UC San Diego Extension’s Osher Lifelong Learning Institute, Bier dove into the details of exactly how gene drives work, and their many potential applications.
Watch — Engineering Mosquitos to Fight Malaria with Ethan Bier — Osher UC San Diego