Tag Archives: immunotherapy

Top Ten Stories in Genetics in 2017

Mark it in your calendar: 2017 was the year when gene therapy (broadly defined) became something more than hypothetical.  Hard to talk about 2017 as a great year, but that’s the storyline in genetics.  Here’s the countdown:

  1. Ohio Bans Abortions for a Fetus Affected with Down Syndrome

In December 2017, Ohio became the 3rd state to criminalize abortion to avoid the birth of a child with a genetic condition. The first law was passed in North Dakota in 2013 and remains on the books, and a similar measure in Indiana that focuses specifically on Down syndrome was enjoined by court order after an ACLU challenge.

Ohio’s law makes it a felony to perform an abortion if the patient’s motivation is to avoid the birth of a child with Down syndrome. These laws appear unlikely to be enforced: unconstitutional under Roe v Wade, they should not survive a court challenge, and if they did, they would be incredibly difficult to enforce. Still, there are several reasons why it is worth paying attention to what must now officially be called a trend.

First, these laws didn’t pop up organically, and they indicate that therapeutic abortion is on the radar of anti-abortion groups. Expect more of the same, and battles on related fronts, including insurance coverage for prenatal testing.

Second, even if the law is never enforced, it could affect practice. A woman’s motivation is hard to prove, but the motivation of a genetic counselor or a physician discussing termination after a diagnosis of Down syndrome is crystal clear, and could put them at risk. Even a distant and unlikely threat of a felony prosecution is a great disincentive to any clinician. Discouraging counseling may pr may not prevent abortion but it absolutely deprives couples of the good, unbiased information that Down syndrome advocates have been working on for years. And as usual, it increases disparities in care for individuals with fewer resources or less education.

Third, polling suggests that a slim majority of the country believes abortion should be available for pregnant women when the fetus faces cognitive impairment, but it’s emotionally tricky territory and norms may shift to make therapeutic abortion more stigmatized. There’s a reason why the second and third iterations of the law specified Down syndrome: this is a public relations campaign and Down syndrome kids present a sweet and photogenic face. “Every Ohioan deserves a right to life, no matter how many chromosomes they have,” said the head of the Ohio Right to Life, neatly eliminating the difference between a fetus and a child.

Fourth, expect a whole lot more of this if we lose Roe v Wade.

  1. STAT names the Swiss Army Knife the top CRISPR metaphorScreen Shot 2017-12-29 at 7.26.31 PM.png

Bacteria have been using CRISPR for aeons, but humans have only had it in their gene editing toolkit for five years. In that short span, technical advancements have occurred so quickly that 2012 CRISPR is starting to feel a bit old school. Some of these innovations improve the original CRISPR search-and-delete functionality – reducing off target effects, for example, or improving the odds of replacing deleted DNA segments with a scripted sequence delivered via a template. Other advancements add new types of functionality. In 2017, researchers introduced a modified CRISPR system uses the same search function but doesn’t cut; instead, it alters gene expression by changing the elaborate system of packaging that turns gene on or off. In another iteration of CRISPR search-and-don’t-cut functionality, scientists from Harvard and the Broad Institute have pioneered a technique called base editing, which locates a specific spot in the DNA sequence and replaces a single base through a series of chemical reactions without the riskier business of inducing a double-stranded break. In October, researchers from China announced that they had tested base editing in human embryos, and were able to correct a mutation that causes the blood disease beta thalassemia 23% of the time.

The proliferation of CRISPR varietals led writers at STAT to give top honors to “the Swiss army knife” in a ranking of CRISPR metaphors (runner up: “organic photoshop”).

 

  1. Harvard’s George Church opens up the George Church Institute in ChinaScreen Shot 2017-12-10 at 4.37.03 PM.png

Synthetic DNA made significant steps forward this year, starting with an announcement in January that researchers at the Scripps Institute in La Jolla have produced a modified a strain of E coli whose DNA has six rather than the usual four base pairs. The following October, in a story that my be the epitome of 2017, Harvard professor George Church traveled to China to announce the opening of the eponymous George Church Institute of Regenesis. This collaboration with Chinese giant BGI has plans to develop clinical applications of synthetic biology. The investment of substantial resources in artificial life forms and bio-manufacturing is one indication of where we are headed; sadly, the decision by one of America’s great science talents to launch an ambitious project halfway across the world may also prove to be a sign of things to come.

 

  1. Popular Culture Discovers CRISPR

This was the year I read my first sci-fi novel about a world where children (and pets) are routinely gene-edited. Although it was a dystopian vision, I have to admit I was intrigued by the tiger-ized house cat…

CRISPR has definitely captured the imagination of a good part of the universe, and my sense is that the jury is out on whether our new powers of gene editing are going to be viewed as cool or creepy. Meanwhile, here’s some unexpected places where CRISPR popped up in 2017.

On Jeopardy!

Screen Shot 2017-11-25 at 5.24.41 PM.png

In Ashton Kutcher’s twitter feed:

Screen Shot 2017-12-07 at 9.42.57 AM.png

Graffitied on the mean streets of San Francisco:

Screen Shot 2017-11-25 at 5.24.13 PM.png

This is a sleeper pick at number 7, but I believe it’s important to understand that people are paying attention, because (like the rest of us) they don’t yet know what to think. The early uses of CRISPR will have a great impact on public opinion, and very likely on support for research, development and commercialization of gene editing down the road. It’s something to think about.

 

  1. The FDA Changes Direction on DTC Genetic Testing

The FDA executed a remarkable about-face on direct-to-consumer genetic testing in 2017, beginning in April when the agency approved a new iteration of their SNP scan for liability to disease, 3 ½ years after they shut down sales of the alpha version, claiming it posed a risk to the health of those who bought it. In addition to signing off on testing for 10 complex conditions where the genetic contribution is important but not definitive, the FDA announcement established some ground rules that could be applied to other tests and other companies. First, the decision identified 23andMe as what they called a ‘trusted provider’ and indicated that having been so designated, they would not have to jump through regulatory hoops for every new test, and would be exempt from premarket review. Second, the agency created a category called “genetic health risk (GHR)” tests, as distinct from genetic tests that were diagnostic, which were explicitly excluded from exemption.

Presumably, the agency’s goal was twofold: to remove impediments to the growth of DTC, while carving out some rules for what belonged in that realm, as distinct from what belonged in a clinical setting. In November, the FDA made this explicit, announcing its intention to establish a new regulatory structure for GHR tests which would formalize the ‘trusted provider’ approach through a one-day FDA review, allowing them to introduce non-diagnostic tests and carrier screens without further premarket scrutiny.

This change in governance is likely a response to what is happening in Washington, where anti-regulatory sentiment is rife, and may also be due to changes in the marketplace, with major players like Illumina and Google making sizeable bets on DTC genetic testing ventures. There is little question that the FDA moves have had a big impact, and the fledgling DTC industry appears to have spread its wings and taken off. Strong Christmas sales for both Ancestry.com and 23andMe indicate that consumers are willing to give genetic testing a try; sustained success may be contingent on how that experience goes for the recipients.

 

  1. First RNAi Drugs Show Promise in Human Trials

Many of the early targets of gene therapy are diseases caused by a single missing or defective protein, and the goal in these cases is to introduce a gene that will produce what the body is lacking. Despite the fact that we have not been very successful to date, it is a simple model; often replacing a small fraction of normal production is enough to treat or effectively cure the disease. In some diseases, however, the problem is not the absence of a normal protein but the presence of an abnormal one which disrupts function or damages healthy tissue. In these cases, you can’t simply (‘simply’) replace what you don’t have but must find a way to silence the gene product that is causing all the trouble.

One way to do this is to intercept the RNA messages before they are made into protein via RNA interference – designer RNA’s that find and bind to specific transcripts to prevent translation. Like many other forms of what might broadly be called gene therapy (I’m not into fights about semantics so don’t @ me), RNAi has not fulfilled it’s conceptual promise to date, but that seems to be on the verge of changing. In October Ionis Pharmaceuticals launched the first human trials of a RNAi drug for Huntington’s disease, and in November a Cambridge-based company called Alnylam announced that its RNAi drug for hereditary ATTR amyloidosis was showing success in phase 3 trials and might be up for FDA review in 2018.

 

  1. In Vivo Gene Editing Mitigates Deafness (in Mice)

Screen Shot 2017-12-29 at 7.00.23 PM.png

In another late entry into the Top Stories of 2017, researchers from the lab of David Liu published a December article in nature describing the use of in vivo gene editing to facilitate hearing in mice bred to exhibit a form of genetic deafness found in humans. Mice injected with CRISPR-Cas9 complexes showed more hair cells and improved response to auditory testing. While it is always good practice to remind ourselves that not everything that works in rodents works in people but… in vivo gene editing is a remarkable technical achievement with incredible potential. Brought to you, by the way, by a co-founder of Editas Medicine, so this maybe this blog post can double as a stock tip. 2017, ladies and gentlemen.

 

  1. A Gene Therapy Ready for Prime Time at Last!

We’ve been talking about gene therapy for so long it seems like old hat, except that this particular old hat has never been thrown into the ring… until now. On December 19th, the FDA approved Luxturna, a gene therapy for blindness. First of its kind, Luxturna introduces a gene into retinal cells by a viral vector and, in cells where uptake of the wildtype variant increases the production of normal protein.

Eyeballs are a uniquely accessible body part, making them low-hanging fruit for gene therapy, but low-hanging fruit is the place to start, and the take-home point here is that the new and improved gene editing technology and gene delivery systems are for real, as is (finally) gene therapy. Coming soon: gene therapies for blood-based diseases such as hemophilia and sickle cell. Still to be determined: how much all of this will cost.

 

  1. Immunotherapy Delivers a One-two Punch

The cancer field has been buzzing about Car-T therapy for years, hopeful that this new class of therapies designed to harness the body’s own immune system would not only expand the range of cancers we could fight, but do so in a targeted fashion that would reduce the toxicity associated with current chemotherapies. Immunotherapy has been through several rounds of hype-and-hate before getting out of the clinical trial phase, as stories about patients rescued from the deathbed have sent up smiley face trial balloons and deaths from unanticipated side effects have popped them.

After all the anticipation, approval of the first two Car-T drugs came only weeks apart, with Kymriah, a drug for pediatric leukemia, approved in August and Yescarta, for some forms of B-call lymphoma, following close behind. All the usual caveats apply – real-world safety and efficacy still to be worked out over time, and price price price price price plus access, but without setting that aside, I want to take a moment to congratulate everyone who worked to create and validate this new and important class of cancer therapies.

 

  1. The Boy who Got New Skin Is Everything You Ever Hoped For in a Stem Cell Success Story

Screen Shot 2017-12-29 at 7.38.53 PM.png

I was six paragraphs into Ed Yong’s story about a boy with epidermolysis bullosa when I realized it was going to be my top story in genetics for 2017. How many things are there to love about this story? First of all, it’s about a cure for EB, a disease that disrupts the normal structure of the skin, making it fragile, so that it is prone to rupture and blister. In bad cases, people are plagued with open sores that will not heal. It’s a biblical plague of a disease, and this kid was in terrible shape – shape – seven years old, and headed to hospice care.

And they fixed him.  This is also a stem cell success story, joining the list of finally-finally-at last therapeutic success stories in 2017. Doctors removed a small patch of precious intact skin from seven-year-old Hassan and sent it to researchers in Italy, who isolated and corrected skin stem cells, and then used them to grown sheets of skin in which to sheath the dying child. They replaced an astounding 80% of his old skin and – here’s the part from paragraph six – less than a year later he is back in school, playing sports and living the life of a normal child.

I promised myself never to talk about these high tech miracles without discussing cost and access, so here I raise relevant questions: what’s this going to cost, and who will be able to get it?   Honestly, I have no idea.   And for the record, this technique won’t work for all variants of the disease.  But there is a lot to celebrate.

It seems strange to talk about 2017 as a series of victories for humanity, but the year in genetics was full of hope and promise, and nowhere was that contrast more on display than here, in the a story of a global community coming together to save a life. A Syrian child, treated by German doctors together with Italian researchers who were mentored by an American pioneer…  It was the epitome of 2017 in genetics, though sadly not the epitome of 2017 in any other sphere.

 

Follow me on Twitter!

Leave a comment

Filed under Laura Hercher

TOP TEN STORIES IN GENETICS, 2016: An Adolescent Science Meets the Big World

Clinical genetics is a young science, not yet come of age – a new discipline. It’s early days, say the small group of clinicians and researchers who have watched over its formative years, dreaming like proud parents of a future where genetics and genomics are integral to clinical medicine. And as for many parents, it may sometimes have seemed that the all-consuming, semi-hermetic little laboratory of childhood would go on forever.

But guess what, people? I believe we have entered the teenage years.  I believe baby has borrowed the car keys and taken it out for a spin.  I see a field boasting a few real accomplishments, and on the cusp of so many changes, from therapies for genetic disease and cancer to a suddenly burgeoning DTC marketplace. And like all parents, geneticists are poised to discover the limits of our ability to control what we have nurtured. That’s exciting, more than a little bit scary, and the theme of this year’s top ten.

  1. FDA CANCELS PLANS TO REGULATE LDT’s

Over the past two decades, a single technological advancement has revolutionized the way we practice medicine.

I am talking, of course, about overnight delivery of packages.

Years ago, laboratory testing services were divided into large companies that sold test kits and devices nationwide, and the small labs in hospitals and other clinical settings providing services to their local providers. With limited resources, government regulators focused on the tests that affected more people, and agreed by convention that ‘laboratory-developed tests’ would not be subject to the same scrutiny. Today these distinctions are virtually meaningless, as giant companies like LabCorp and Quest perform tests ‘in-house’ on samples gathered worldwide, tossed in a box and sent overnight. Still laboratory-developed tests (or LDT’s) – a category that includes virtually all genetic tests – remain in regulatory limbo.

In 2010, the FDA announced its intention to address this loophole. In July 2014, they issued draft guidance detailing their plan for a regulatory structure that divided the LDT universe into high, low and medium risk tests. While some professional organizations disputed the FDA’s right to have a role in regulation of LDT’s and threatened legal action, others approved the framework in principle but disagreed on specifics, including how to handle the thorny new territory of exome and genome sequencing. A dialogue ensued with representatives of labs, clinicians and patients that has lasted two years and included multiple workshops and public meetings. That process, it was widely assumed, was nearing its end, with the resulting draft guidance expected to be sent to Congress for approval in the near term.

And then came November 8th and the election of Donald J. Trump, ushering in an executive opposed to regulation on principle, to join a similarly inclined House and Senate. Ten days later, the FDA ran up the white flag, announcing that the agency would not take steps to finalize its existing plan and would instead reopen the discussion with a new administration and a new Congress. What this means precisely is a matter of some interesting speculation, but in general it suggests that an industry that has been struggling for years to avoid too much regulation will have to consider the consequences of living with none at all.

 

  1. IS THIS THE FUTURE? CRISPR EXPERIMENT ADDS RARE PROTECTIVE VARIANTS TO HUMAN EMBRYOS

The second experimental use of CRISPR technology to alter human embryos was reported in May of 2016, again by a group out of China. Again, the embryos used were not viable, and no attempt was made to transfer them for reproductive purposes. While this experiment did not produce the same ethical firestorm as the first, it was in several ways a more significant indicator of both the potential and the peril of human germline engineering using CRISPR.

In the first experiment investigators attempted to alter a gene variant responsible for causing hemoglobinopathy, with limited success – proof in principle that it could be done, but nothing to assure worried observers that it could be done safely. In version 2.0 there were fewer off target effects, but researchers were not able to consistently control the content of changes introduced in place of the edited DNA. This is not inconsistent with what we know so far about CRISPR: if we envision it as a word processing search-and-replace function, it is good at the finding and erasing part, but hit or miss when it comes to  putting in a replacement.

What stands out about the second experiment is that the goal was not to eliminate a disease-causing gene, but to insert a rare and protective one – in this case, the CCR5Δ32 allele that offers the bearer reduced susceptibility to AIDS. Gene editing is often envisioned as a way that individuals whose children are at risk can avoid or change genes that cause disease, but in the vast majority of these cases there are simpler and better established tools such as PGD if the goal is to obtain embryos that do not carry a specific variant associated with some catastrophic risk. Why use technology to substitute out a pathogenic BRCA variant or a double dose of the sickle cell genes when the parents are perfectly capable of producing a healthy embryo themselves? What CRISPR and related technologies can do that is not available through other means is to introduce a gene that neither parent carries. That is a powerful new option, and it is both exciting and scary in the manner of all things powerful and new.

 

8. GENETIC DISCRIMINATION MAKES A CAMEO

Many wise observers have noted that for all our deeply felt concerns about genetic discrimination, to date the examples are few, far between, and usually more clumsy than systemic (looking at you, Burlington Northern Santa Fe Railroad). These arguments, redux, were on display in 2016 as Canada debated and ultimately passed its own national genetic discrimination law. Yes, Globe and Mail Guy, there is little evidence of a big problem, and a look at law suits filed between 2010 and 2015 under GINA, America’s genetic discrimination law, proves the point. But one real unanswered question remains: is the absence of institutionalized discrimination a sign that it is destined to be a bit player in the big picture of genomics, or is it only too soon to tell? Big companies, whether they are offering insurance or providing employment, may not have had an incentive to weather a PR shitstorm in order to use genetic information to limit their exposure to risk when not that many people have been tested, and the reliability of the data is debatable – which it has been in these early days. Genetic discrimination, in other words, may be making an appearance in Act II.

Two stories got some attention in 2016; whether they are one off events or signs of the future – well, that’s crystal ball territory. Are they important? They are something to which we should be paying attention. Attention should be paid.

In January, Stephanie Lee at Buzzfeed published an account of a boy named Colman Chadam who was asked to leave his Palo Alto, CA school because he carried two mutations commonly associated with cystic fibrosis, although he did not have any signs or symptoms of the disease. The results of genetic testing, inappropriately revealed by a teacher at the school, were taken, also inappropriately, as diagnostic. The reason this got him thrown out of school was to avoid contact with another student who did have CF. The emphasis on keeping children with CF apart, which sounds weird if you don’t know much about the disease, was about the only appropriate thing that happened, because individuals with CF are at risk of passing one another dangerous and life-limiting infections.

Although Colman did not have to leave the school, and the Chadam’s lawsuit against the school district has settled, the case continues to raise issues about how genotype as distinct from phenotype can be used under the law. In addition, it may signal the need for measures to protect personal privacy (no such thing, I know, I know) in an age when genetic testing is commonplace.

Three weeks later, Christina Farr wrote an article for Fast Company about a woman who was turned down for life insurance because she had a risk-conferring BRCA1 variant. Unlike the Chadam case, this is not a result of genetic illiteracy, and it is not a violation of any law: GINA does not cover insurance for life or long-term care. It is, in fact, exactly the kind of genetic discrimination that ethicists and patients thinking about genetic testing have worried about over the years, and if systemic, would certainly be an important point for genetic counselors to raise in pretest counseling (if pretest counseling is still something we do, which is an issue unto itself…but related). According to the article, genetic testing for cancer susceptibility is not required by any insurance company, although nothing stops them from doing that, but companies are starting to request to see test results when they exist. Failure to answer questions honestly can invalidate policies if you are caught.

If this becomes the status quo, it may affect uptake of genetic testing. If it is curbed through regulation, genetic testing may change the way the insurance industry operates. Act II is going to be interesting! I am having a couple of stiff drinks and heading back to my seat.

 

7. TYPE II DIABETES: RESISTANT TO INSULIN AND EASY ANSWERS

Genome wide association studies (GWAS), a way of looking at common variants in the gene pool to identify genetic susceptibility to common diseases, have been unable to explain the degree to which liability to these common diseases is inherited, although it clearly is. If you are in genetics and this is news to you, you have not been paying attention.

Many reasons for this have been proposed, and many are likely a part of the answer. One thought was that individually rare variants might be collectively common enough to play a big role in generating risk, which would not be picked up by GWAS, as it traditionally looked only at variants carried by at least 5% of the population (“the population,” as though there was only one!). Looking at rare variants takes a village, but that is what a googleplex of Type II Diabetes researchers did to produce an epic July 2016 paper in Nature.

Okay 300 authors on the paper so close enough.

The report by first author Christian Fuchsberger showed that MEGA*GWAS produced the most GWAS-y result possible: intellectually interesting, informative and ultimately inadequate. Using exome and whole genome data to capture a broader range of variation, the study found significant association to a handful of previously unknown common variants, and then failed to replicate a good chunk of what we thought we knew. Uncommon variation? The researchers found 23 loci that appeared significant, which was meaningful, but nowhere near enough to validate the rare variant hypothesis as the smoking gun in the Mystery of the Missing Heritability. “A comprehensive and extremely well written paper,” said Dan Koboldt at MassGenomics, and you can almost hear him sigh.

 

6. DATABASES: IT’S NOT JUST FOR WHITE PEOPLE ANYMORE

We don’t have enough diversity in our databases. It’s not exactly news, and yet publication of an article called “Genetic Misdiagnoses and the Potential for Health Disparities” in the August issue of the New England Journal of Medicine felt like a slap in the face.

The methodology was not complex. For hypertrophic cardiomyopathy patients, doctors use genotyping to identify individuals and family members at risk for sudden and catastrophic cardiac events. Identification as ‘at risk’ is a traumatic and often life changing event, requiring ongoing medical screening and behavioral modifications. For these families, a lot rides on whether or not a variant is considered pathogenic. One bioinformatics tool is to look at databases, because there are limits on how bad a variant can be if it shows up regularly in healthy individuals. The study checked variants labeled pathogenic against an increasing wealth of exome data available in public databases and found that a number were common in the African-American population. Result: reclassification from pathogenic to benign of multiple variants affecting primarily African-American families.

“Simulations,” said the authors, “showed that the inclusion of even small numbers of black Americans in control cohorts probably would have prevented these misclassifications.

 

5. IMMUNOTHERAPY: A NEW STAR BURNS BRIGHT AND HOT

Earlier this week, my sister-in-law was telling me about a friend with a cancer deemed treatable but not curable. “But if they get it in remission,” she said, “and he has more time, maybe there will be something new.” There it was – the cancer prayer. May There Be Something New. And I thought, has there ever been a moment when those words felt more hopeful than right now?

Hopes have been raised before, by promises that money would bring answers, and we wandered down blind alleys and into mazes waving cash as though the scent of it would draw the answers to us, but this time, progress is lighting the way like street lamps, and money follows hope instead of the other way round. Immunotherapy – engineered cells meant to light the bodies own defenses into a controlled burn that destroys cancer cells and leaves the rest untouched – has burst onto the scene since 2015. Cancer researchers report on progress in Hemingway stories, terse narratives of a few more days, an extra month or two, and that’s a win, but suddenly we are getting Gabriel Garcia-Marquez fables of magic beans and people rising from their deathbed.

So which story is more 2016: Sean Parker’s 250 million dollar cancer institute, connecting Silicon Valley money with Car-T cells that he describes as “little computers,” and presenting to the NIH in comic sans? Or the unexpected lethal immune response that shut down a Car-T trial by Juno Therapeutics in November, after four people died of cerebral edema?

It’s the two in conjunction that tell the tale. Immunotherapy is truly a candle in the wilderness, but it’s a candle that burns rocket fuel. Or perhaps I should say, in the spirit of the season: catch a falling star and put it in your pocket – bet it burns a hole in your ass.

 

4. A NEW DTC GENETICS EMERGES WITH HELIX

In October, Helix announced the first fruit of its partnership with DNA-lifestyle start-up Exploragen and it’s grapes: Vinome, a company that promises to sell you wine tailored to your genetic profile for something like fifty bucks a bottle. I’m not a wine drinker and that sounds like a lot of money but, hey, you do you.

For Helix, the Illumina spinoff that debuted in 2015, this was one of a series of 2016 announcements giving us a more concrete vision of their plans for a sequence-once-access-often platform for DTC genomics. The structure of it is like Apple, if your IPhone didn’t even pretend to be a phone, and existed entirely as a vehicle for apps. With your first purchase, Helix will underwrite the cost of sequencing and storing your entire exome, and then sell it back to you bit by bit in the guise of applications created by partners.

Effectively, the Helix model lowers the barrier of entry for any product based on DNA testing, by spreading out the cost over a myriad of marketing opportunities. Some current players in the DTC universe have signaled their interest in playing in Helix’s playground; Geno 2.0, National Geographic’s version of ancestry testing, is already available on the Helix website. Others may take their toys and stay at home. Daniel MacArthur of the Broad Institute once penned an April Fool’s Day account of a company named Helix Health’s plans for a hostile takeover of 23andMe using Somali pirates, but for real the entry of an Illumina-backed company into the DTC space must have some Mountain View observers concerned that the current industry thought leader might end up the Blockbuster Video of the genomics world.

The uncorking of Vinome raises a few questions that existing partnerships with, say, the Mayo Clinic or the Icahn School of Medicine at Mt Sinai do not. One role that Helix could potentially play is to provide the vetting service much needed in the consumer genomics world, with its mishmash of pharmacogenetics and Warrior Gene testing and supplements designed just for your DNA.

As for Vinome, the eminently quotable Jim Evans called it “silly” in an article by Rebecca Robbins in STAT. “Their motto of ‘A little science and a lot of fun’ would be more accurately put as ‘No science and a lot of fun,’” said Evans — which I guess is true, if paying fifty dollars for a bottle of wine is your idea of fun. But like Apple, Helix is going to have to make some hard decisions about how much it takes responsibility for the quality of the partners it allows to come play in its sandbox.

 

3. GENOMES OF MASS DESTRUCTION

In February, for the first time but probably not the last, the U.S. Director of National Intelligence’s assessment of worldwide threats included genome editing as a weapon of mass destruction. Congratulations, genetics: we’ve made the big time.

The report pointed to the widespread use of new genetic technologies like CRISPR in countries with different regulatory and ethical standards, its low cost and the rapid pace of change as pre-conditions that might lead to intentional or unintentional misuse, though it was vague as to what form they thought the threat might take. More specific concerns were articulated later in the year by the Pentagon’s Defense Advanced Research Projects Agency (called DARPA of course, because…government) in announcing a program called Safe Genes intended to establish a military response to of dangerous uses engineered genes. DARPA, which Scientific American reports has been a major funder of synthetic biology, will support projects that look at ways to remove engineered genes from a variety of habitats and in a variety of circumstances, including those spread through gene drive.

 

2. A BREAKTHROUGH DEFIES CONVENTION AND GEOGRAPHY

On April 6, 2016, a baby was born after the transfer of his mother’s nuclear DNA into an enucleated donor egg in an effort to avoid the mitochondrial disease that killed the couple’s two previous children. The success of mitochondrial transfer therapy itself was not a shock, since earlier experiments had demonstrated good outcomes in animal models and in in vitro human embryos. The circumstances, however, were startling: the procedure was done in Mexico, for Jordanian parents, with the help of a New York-based fertility doctor with no known expertise in mitochondrial disease.

Some have argued that mitochondrial transfer therapy represents a violation of international norms forbidding any germline genetic change, which were meant to provide a clear dividing line between somatic changes associated with gene therapy and genetic engineering with the potential to impact future generations. Pretty clear in theory, but all of these divisions are less clear in reality – there are no guarantees that gene therapy doesn’t affect eggs or sperm, and mitochondrial DNA itself challenges any simple equivalence between the molecular structure of DNA and the intellectual concept of our ‘germline’.

Mitochondrial transfer is illegal in the United States but permitted in Great Britain under a 2015 law, and applications for clinical use have been approved for 2017. Its apparent success – independent sources confirm that the baby appears to have traces of maternal mt DNA associated with Leigh syndrome but no sign of disease – is a cause for celebration for the families whose children are at risk. The step forward is a milestone, but so is the way in which it occurred, which demonstrates the extent to which geography and national laws are no match for money and access in determining what is possible.

Personal note: on my wish list for 2017, can we PLEASE stop cheapening the concept of parenthood by using the term ‘3-parent babies’? If I donated a kidney, that person would have some of my DNA, but it wouldn’t make me their momma.

 

1. WHITE SUPREMACISTS LOVE GENETICS, BUT GENETICS DOES NOT LOVE THEM BACK

Nothing about the year 2016 was more disturbing than the empowerment of the alt right, an all-purpose term for the angry souls that crept out from under rocks to preach hate and division. Here at home and all around the world, narratives of race and ancestry emerged as powerful drivers in political and social movements based on appeals to base and tribal instincts – fear mongering about immigrants, Islamaphobia, white supremacy. In October, Elspeth Reeve at Vice ran a story about white supremacists posting their 23andMe results to prove their whiteness.

This embrace of a science that does not love them back is evident even without a deep dive into the world of Stormfront and 4chan.  Twitter trolls talk about ‘founder effects’ and ‘genetic drift’. A Breitbart tech editor, now barred from twitter, writes gleefully about associations between race, behavior and intelligence, mocking disbelievers as prisoners of an “all-consuming cult of equality.”  The L.A. Times describes the alt-right as “young, web-savvy racists who are trying to intellectualize and mainstream bigotry.”   These viewpoints aren’t mainstream, but their proponents can no longer be dismissed as fringe, with Breitbart’s founder about to be ensconced in the White House as chief strategist, and reports suggesting that the presumptive next National Security Advisor Michael Flynn taking meetings with the head of an Austrian political party founded by former Nazis.

The connection between white nationalism and population genetics is proof once again that genetics as a field is uniquely susceptible to misuse by agenda-driven movements intent on the subjugation of others. Donald Trump ran against political correctness, but his rise has proven the importance of language. As Michelle Obama says, “words matter.” Push back against the misuse of genetics to fuel ‘racialist’ theory. Ancestry sites should think very hard about the manner in which they present their findings, which stress differences without acknowledging the greater than 99% of DNA that we all share. Scientists need to address and refute the ways in which their work can be misconstrued to reinforce prejudice and unsubstantiated visions of racial differences. We all have to be careful not to promote explanations of genetic effects that oversell the determinative power of genes.

Genetics is a science of the future. Let’s not let it be used to drag us back into a tribal past. Peace out, Genetics, and here’s to a better year in 2017.

 

 

Follow me on twitter

7 Comments

Filed under Laura Hercher