The fears and the hopes of genetically engineering the human race have been haunting the modern mind for the better part of a century, although only in the last decade have techniques been developed that might give us the power to modify the genomes of human beings at the embryonic stage. Foremost among these has been the CRISPR-Cas9 system \u2014 a set of bacterial enzymes first identified in the late 1980s, and during just the last few years harnessed as a gene-editing tool. What sets CRISPR apart from earlier genetic modification techniques is its accuracy and versatility: the enzymes that cut the targeted DNA are guided by short sequences of RNA that can be custom-designed for any site in the genome. Earlier genetic engineering methods required different enzymes to target different locations in the genome, but by using RNA instead, CRISPR makes that targeting process much easier. (Although there are some differences in what the terms \u201cgenetic engineering,\u201d \u201cgenetic modification,\u201d and \u201cgene editing\u201d mean, they are for the most part interchangeable.)<\/p>\n
This new gene-editing tool has rapidly become ubiquitous in molecular biology, with many applications beyond gene therapy. For instance, scientists have used CRISPR to remove retroviral sequences<\/a> from the genomes of pig embryos in the hope of producing pigs with organs that can be transplanted more safely into humans. Because CRISPR is relatively easy to use, some journalists have even speculated that the technique might lead to the democratization of genetic engineering, with \u201chome hobbyists\u201d using it for who-knows-what<\/a>. This claim seems overblown. While it is true that CRISPR makes the specific task of editing DNA much easier, there are other technically complicated steps and procedures involved in most forms of genetic engineering. To alter genes in a child or adult, human cells need to be cultivated and modified in a lab before being transplanted back into the person\u2019s body, all of which represents a significant technical challenge. And modifying the genes of human embryos would mean first conducting in vitro fertilization \u2014 a procedure that would be very difficult for an amateur hobbyist and is made no simpler by CRISPR.<\/p>\n Still, it seems as though CRISPR may be poised to overcome the major technical hurdles to genetically engineering human beings \u2014 namely, being able reliably and precisely to modify the DNA sequences of human cells, including embryos. Scientists have already used it to create genetically modified mice, pigs, and non-human primates. There have even been two published<\/a> studies<\/a> describing the use of CRISPR by Chinese scientists to modify human embryos (which they subsequently destroyed); it is generally believed that scientists in China have conducted numerous similar experiments without publishing their results. In the published studies, the error rates in the genetic modifications were very high, but other researchers have discovered<\/a> ways<\/a> to improve the accuracy of the technique significantly, and so it may soon be precise enough for clinical use.<\/p>\n The scientific and media interest in CRISPR has renewed longstanding debates about the ethics of genetically engineering human beings. The questions we face: Should we design our descendants? And if so, how? What are the proper ethical boundaries around this new power, and what are the proper ends to which we should direct it? What are our obligations to future generations \u2014 should we take control over our evolution so that our descendants may transcend human nature, or ought we to consider human nature to be a gift from our ancestors for the present generation to steward faithfully for the good of generations to come?<\/p>\n\n