Robert Klitzman, M.D.

Robert Klitzman M.D.

Am I My Genes?

10th Anniversary of Mapping Human Genome: What it All Means

10 years ago today, human DNA was first mapped, yielding insights and challenges

Posted Apr 14, 2013

“It’s like Star Wars,” a woman with the Huntington Disease mutation recently told me. This lethal gene had killed her relatives in every generation for hundreds of years, but she could now test her embryos to ensure that her children did not get it. “I don’t understand it all,” she told me, “but the peace of mind is huge.”

April 14th 2013 marks the 10th anniversary of the completion of the Human Genome Project — the successful mapping of the entire human genome, the three billion molecules that are the blueprints for us as human beings. This event ranks with NASA’s response to Sputnik as one of the great achievements of modern science supported by public funds. Over the past decade, researchers have continued to make incredible strides, discovering genes associated with diabetes, depression, schizophrenia, bipolar disorder, and other diseases. The future possibilities are enormous.

But we should use this anniversary as an opportunity to not only celebrate, but reflect. These miraculous discoveries present us too with countless dilemmas, and are far outpacing our abilities to grasp and address their ethical, legal, social and psychological implications. The genome is far more complicated than anyone imagined. The more we learn, the more we realize how much we don’t know. Uncertainties and controversies abound.

Mice have about 20,000 genes. Hence, scientists initially thought humans must have at least 50,000 to 150,000. In fact, we have about the same number as rodents and flies. We share 99.9% of our genes with each other, 80% with dogs, and 69% with chickens. Rice has more genes than do humans (46,000) since our system is more parsimoniously designed.

Over the past 10 years, the costs of sequencing a human genome have also plummeted from $100 million per person to less than $1,000. Thus, more people are getting sequenced and medical centers are trying to gather and store this information on as many patients as possible in huge biobanks. These data can help researchers find genes associated with diseases and successful treatments. Eventually, doctors will be able to choose certain medications for each of us based on our unique genomes, so-called “personalized medicine”.

Yet genetic discoveries can also be patented, earning hundreds of millions of dollars for private companies, and sometimes universities. Myriad Genetics, for instance, owns the patents for the breast cancer genes, and charges over $3,000 for these tests. Unfortunately as a result, millions of women around the world cannot afford them.

For patients who can pay, doctors can now use genetic tests to screen embryos and fetuses for ever more diseases. Some patients can eliminate certain deadly mutations, such as that for Huntington’s, from their descendants. But doctors and patients increasingly face quandaries regarding which diseases to test for and remove. Many physicians and patients are, for instance, screening out embryos with a breast cancer mutation, though these genes wouldn’t cause symptoms until adulthood, and would do so only about 50% of the time.

The wealthy are thus eliminating certain diseases from their descendants, while the poor cannot, widening the gap between the haves and the have-nots. Parents may soon, for instance, abort fetuses that have a 20% chance of developing autism. Some doctors say they will in the near future be able to select embryos that will have blond hair and blue eyes. This billion-dollar industry is largely unregulated by the government. As a society, we are thus confronting quandaries of whether federal or state governments or professional medical organizations should ban some of the practices, and if so, which and how.

Unfortunately, understanding of genetics among physicians, patients, and policymakers also remains low. Media headlines still announce “The Fat Gene”, “The IQ Gene”, “The Addiction Gene", "The Gay Gene” and “The God Gene”. Beliefs in “genetic essentialism” persist (that single genes cause common diseases and traits). In fact, most lethal mutations cause only very rare diseases. Common diseases such as diabetes and asthma appear to result from complex interactions of multiple genetic and environmental factors. The human genome evolved to resist the effects of single lethal mistakes. Multiple, not single, genetic errors are usually needed to kill us.

The degrees to which genetics may be involved in psychiatric disorders and psychological traits and behaviors is even more complex, and far less predictable. Nonetheless, popular myths linger -- many people will say, "he takes after his father's side" or "his mother's side of the family".

Unfortunately, most physicians don’t fully understand how to incorporate genetics into practice, and may over- or under- order tests. Doctors who graduated medical school before the Human Genome Project started differ markedly from later graduates. Increasingly, doctors will be offering us genetic tests that may yield results with ambiguous or unknown meanings.

Genetic discrimination also perseveres, at times fueled by misunderstandings. The 2008 Genetic Information Nondiscrimination Act (or GINA) covers health insurance, but not disability, life or long-term care insurance. Some patients still face subtle discrimination at work too, e.g. passed over for promotion because they have a mutation. How people view and respond to others' mutations remains unclear.

Other controversies continue as well, concerning how many genetic tests to perform on pregnant women and newborns, and whether to modify genetically ever more animals and plants.

On this anniversary, we should celebrate the incredible advances of the past 10 years, but we should also begin to prepare ourselves for the many psychological challenges that we will all increasingly face over the next decade. No one could have foreseen how far science has progressed. What seemed science fiction is now reality. Yet we now need not only research, but more public and professional education about it, and attention to how it is and should affect our lives, and our views and understandings of ourselves, our family and others.

The science of genetics is evolving more quickly than our ability to understand and make sense of it. We need to strive further to keep up.

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