One of the most exciting aspects of 23andMe is that we're enabling you to watch a revolution unfold live during your lifetime, and I think that the decoding of the genome, in my opinion, is the most fascinating discovery of our lifetime, and you get to be part of it.
Anne Wojcicki
I think that the idea of people wanting to steal your genome remains a little bit in the world of science fiction. It's a new technology, and it's new science that people are becoming familiar with. It's critical for us to do everything we can to enable the privacy level that people want.
I think we're just scratching the surface. One of the most exciting aspects of 23andMe is that we're enabling you to watch a revolution unfold live during your lifetime, and I think that the decoding of the genome, in my opinion, is the most fascinating discovery of our lifetime, and you get to be part of it.
I think that the idea of people wanting to steal your genome remains a little bit in the world of science fiction.
Living in your genome is the history of our species.
Barry Schuler
By being able to write a genome and plug it into an organism, the software, if you will, changes the hardware.
Eventually we'll be able to sequence the human genome and replicate how nature did intelligence in a carbon-based system.
Bill Gates
Your genome isn't really secret.
Bill Maris
People think if you have deciphered the genome of humans that you can change everything. But you cannot change everything, because you do not know what the genes mean, and you have no methods for changing them, and you can't do experiments with humans like you can with animals.
Christiane Nusslein-Volhard
I respect and value the ideals of rugged individualism and self-reliance. But rugged individualism didn't defeat the British, it didn't get us to the moon, build our nation's highways, or map the human genome. We did that together. This is the high call of patriotism.
Cory Booker
We need 10,000 genomes, not 100, to start to understand the link between genetics, disease and wellness.
Craig Venter
Genome design is going to be a key part of the future. That's why we need fast, cheap, accurate DNA synthesis, so you can make a lot of iterations of something and test them.
We have 200 trillion cells, and the outcome of each of them is almost 100 percent genetically determined. And that's what our experiment with the first synthetic genome proves, at least in the case of really simple bacteria. It's the interactions of all those separate genetic units that give us the physiology that we see.
Each part of our genome is unique. We would not be alive if there was not a single mathematical solution for our chromosomes. We would just be scrambled goo.
If I had a weak ego, and doubts about this, the first genome would not yet have been completed with US and UK government funding.
Knowing what your parents have gives you hints of things, but your genome is a totally unique combination of and interchange of DNA from your parents. There is no one else like you genetically.
I'm hoping that these next 20 years will show what we did 20 years ago in sequencing the first human genome, was the beginning of the health revolution that will have more positive impact in people's lives than any other health event in history.
People think genes are an absolute cause of traits. But the notion that the genome is the blueprint for humanity is a very bad metaphor. If you think we're hard-wired and deterministic, there should indeed be a lot more genes.
I thought we'd just sequence the genome once and that would be sufficient for most things in people's lifetimes. Now we're seeing how changeable and adaptable it is, which is why we're surviving and evolving as a species.
I think I've achieved some good things; doing the first genome in history - my team on that was phenomenal and all the things they pulled together; writing the first genome with a synthetic cell; my teams at the Venter Institute, Human Longevity, and before that Celera.
The day is not far off when we will be able to send a robotically controlled genome-sequencing unit in a probe to other planets to read the DNA sequence of any alien microbe life that may be there.
The mouse genome is an invaluable tool to interpret the human genome.
Since my own genome was sequenced, my software has been broadcast into space in the form of electromagnetic waves, carrying my genetic information far beyond Earth. Whether there is any creature out there capable of making sense of the instructions in my genome, well, that's another question.
There have been lots of stories written about all the hype over getting the genome done and the letdown of not discovering lots of cures right after.
One of the things about genetics that has become clearer as we've done genomes - as we've worked our way through the evolutionary tree, including humans - is that we're probably much more genetic animals than we want to confess we are.
People think that Celera's trying to patent the whole human genome because it's been used as - I guess people in Washington learn how to do political attacks, and so it gets used as a political weapon, not as a factual one.
It appears that the human genome does indeed contain deserts, or large, gene-poor regions.
For each gene in your genome, you quite often get a different version of that gene from your father and a different version from your mother. We need to study these relationships across a very large number of people.
Once we all have our genomes, some of these extremely rare diseases are going to be totally predictable.
If there is a race, it is one to bring the benefits of genomes to human therapeutics. We all want to get there. We all want people to have much more meaningful and productive lives as they age.
Every single cancer is a genetic disease. Not necessarily inherited from your parents, but it's genetic changes which cause cancer. So as we sequence the genomes of tumours and compare those to the sequence of patients, we're getting down to the fundamental basis of each individual person's cancer.
Our genomes are evolving and changing every single day.
The food we eat goes beyond its macronutrients of carbohydrates, fat and protein. It's information. It interacts with and instructs our genome with every mouthful, changing genetic expression.
We're collecting about 100,000 telomere lengths in saliva samples and then looking at how those relate to both the extensive longitudinal clinical records that Kaiser is collecting and the genome sequence variations.
One of the central mysteries of biology is why the genome is largely identical from cell to cell, even though cells do different things.
I have had my genome fully sequenced and have learned a great deal about which medications I would respond to and which might or would induce major side effects, along with knowing many medical conditions for which I'm particularly susceptible.
The brain is the most complicated organ in the universe. We have learned a lot about other human organs. We know how the heart pumps and how the kidney does what it does. To a certain degree, we have read the letters of the human genome. But the brain has 100 billion neurons. Each one of those has about 10,000 connections.
I think there are people who's lives have been saved because of the study of the genome.
Cancer is a disease of the genome. And that's what happens. You make mistakes in a cell somewhere in your body that causes it to start to grow when it should've stopped, and that's cancer. And those mistakes are mistakes of DNA.
As a Christian, but also as a scientist responsible for overseeing the Human Genome Project, one of my concerns has been the limits on applications of our understanding of the genome. Should there be limits? I think there should. I think the public has expressed their concern about ways this information might be misused.
Though social eugenics was discredited long ago, we still often think of the genome in quasi-eugenic terms. When we read about the latest discovery of a link between a gene and a disease, we imagine that we've learned the cause of the disease, and we may even think we'll get a cure by fixing the gene.
The first thing you have to do is to sequence the Neanderthal genome, and that has actually been done. The next step would be to chop this genome up into, say, 10,000 chunks and then... assemble all the chunks in a human stem cell, which would enable you to finally create a Neanderthal clone.
What I really wanted was for everybody to have their genome and, ideally, everybody to share their genome, and for that, we needed to bring the price way down.
Every cell in our body, whether it's a bacterial cell or a human cell, has a genome. You can extract that genome - it's kind of like a linear tape - and you can read it by a variety of methods. Similarly, like a string of letters that you can read, you can also change it. You can write, you can edit it, and then you can put it back in the cell.
The goal of getting your genome done is not to tell you what you will die from, but it's how to learn how to take action to prevent disease.
If you get a personal genome, you should be able to get personal cell lines, stem cell derived from your adult tissues, that allow you to bring together synthetic biology and the sequencing so that you can repair parts of your body as you age or repair things that were inherited disorders.
Most people are excited about themselves. Personal genome will deliver for inexpensively something about science to which you can relate. Just like computers are becoming something to which you can relate. It should be even easier to relate to your own biology, and I hope that will be one of the ways we get broader literacy in science.
I think something very simple that everybody can do is they can participate in medical research as subjects. Personal genome project, for example, will take on as many subjects as we can find.
We will have to make a decision, as we go into new environments outside of earth, whether we want to drag along with us all our pathogens. We can, or we can't - it's up to us - but I consider that part of genome engineering is how we interact with the huge part of our genome which is our microbiome.
A few dozen changes to the genome of a modern elephant - to give it subcutaneous fat, woolly hair and sebaceous glands - might suffice to create a variation that is functionally similar to the mammoth. Returning this keystone species to the tundras could stave off some effects of warming.