WEBVTT 00:00:14.392 --> 00:00:25.019 You have about 20,000 genes in your DNA. 99:59:59.999 --> 99:59:59.999 They encode the molecules that make up your body, 99:59:59.999 --> 99:59:59.999 from the keratin in your toenails, to the collagen at the tip of your nose, 99:59:59.999 --> 99:59:59.999 to the dopamine surging around inside your brain. 99:59:59.999 --> 99:59:59.999 Other species have genes of their own. 99:59:59.999 --> 99:59:59.999 A spider has genes for spider silk. 99:59:59.999 --> 99:59:59.999 An oak tree has genes for chlorophyll, which turns sunlight into wood. 99:59:59.999 --> 99:59:59.999 So where did all those genes come from? 99:59:59.999 --> 99:59:59.999 It depends on the gene. 99:59:59.999 --> 99:59:59.999 Scientists suspect that life started on Earth about 4 billion years ago. 99:59:59.999 --> 99:59:59.999 The early life forms were primitive microbes 99:59:59.999 --> 99:59:59.999 with a basic set of genes for the basic tasks required to stay alive. 99:59:59.999 --> 99:59:59.999 They passed down those basic genes to their offspring 99:59:59.999 --> 99:59:59.999 through billions of generations. 99:59:59.999 --> 99:59:59.999 Some of them still do the same jobs in our cells today, like copying DNA. 99:59:59.999 --> 99:59:59.999 But none of those microbes had genes for spider silk or dopamine. 99:59:59.999 --> 99:59:59.999 There are a lot more genes on Earth today than there were back then. 99:59:59.999 --> 99:59:59.999 It turns out that a lot of those extra genes were born from mistakes. 99:59:59.999 --> 99:59:59.999 Each time a cell divides, it makes new copies of its DNA. 99:59:59.999 --> 99:59:59.999 Sometimes it accidentally copies the same stretch of DNA twice. 99:59:59.999 --> 99:59:59.999 In the process, it may make an extra copy of one of its genes. 99:59:59.999 --> 99:59:59.999 At first, the extra gene works the same as the original one. 99:59:59.999 --> 99:59:59.999 But over the generations, it may pick up new mutations. 99:59:59.999 --> 99:59:59.999 Those mutations may change how the new gene works, 99:59:59.999 --> 99:59:59.999 and that new gene may duplicate again. 99:59:59.999 --> 99:59:59.999 A surprising number of our mutated genes emerged more recently; 99:59:59.999 --> 99:59:59.999 Many in just the past few million years. 99:59:59.999 --> 99:59:59.999 The youngest evolved after our own species broke off from our cousins, the apes. 99:59:59.999 --> 99:59:59.999 While it may take over a million years for a single gene to give rise 99:59:59.999 --> 99:59:59.999 to a whole family of genes, 99:59:59.999 --> 99:59:59.999 scientists are finding that once the new genes evolve, 99:59:59.999 --> 99:59:59.999 they can quickly take on essential functions. 99:59:59.999 --> 99:59:59.999 For example, we have hundreds of genes for the proteins in our noses 99:59:59.999 --> 99:59:59.999 that grab odor molecules. 99:59:59.999 --> 99:59:59.999 The mutations let them grab different molecules, 99:59:59.999 --> 99:59:59.999 giving us the power to perceive trillions of different smells. 99:59:59.999 --> 99:59:59.999 Sometimes mutations have a bigger effect on new copies of genes. 99:59:59.999 --> 99:59:59.999 They may cause a gene to make its protein in a different organ, 99:59:59.999 --> 99:59:59.999 or at a different time of life, 99:59:59.999 --> 99:59:59.999 or the protein may start doing a different job altogether. 99:59:59.999 --> 99:59:59.999 In snakes, for example, there's a gene that makes a protein for killing bacteria. 99:59:59.999 --> 99:59:59.999 Long ago, the gene duplicated and the new copy mutated. 99:59:59.999 --> 99:59:59.999 That mutation changed the signal in the gene 99:59:59.999 --> 99:59:59.999 about where it should make its protein. 99:59:59.999 --> 99:59:59.999 Instead of becoming active in the snake's pacreas, 99:59:59.999 --> 99:59:59.999 it started making this bacteria-killing protein in the snake's mouth. 99:59:59.999 --> 99:59:59.999 So when the snake bit its prey, this enzyme got into the animal's wound. 99:59:59.999 --> 99:59:59.999 And when this protein proved to have a harmful effect, 99:59:59.999 --> 99:59:59.999 and helped the snake catch more prey, 99:59:59.999 --> 99:59:59.999 it became favored, 99:59:59.999 --> 99:59:59.999 so now what was a gene in the pancreas makes a venom in the mouth 99:59:59.999 --> 99:59:59.999 that kills the snake's prey. 99:59:59.999 --> 99:59:59.999 And there are even more incredible ways to make a new gene. 99:59:59.999 --> 99:59:59.999 The DNA of animals and plants and other species 99:59:59.999 --> 99:59:59.999 contain huge stretches without any protein coding genes. 99:59:59.999 --> 99:59:59.999 As far as scientists can tell, its mostly random sequences 99:59:59.999 --> 99:59:59.999 of genetic giberish that serve no function. 99:59:59.999 --> 99:59:59.999 These stretches of DNA sometimes mutate, just like genes do. 99:59:59.999 --> 99:59:59.999 Sometimes those mutations turn the DNA into a place 99:59:59.999 --> 99:59:59.999 where a cell cans start reading it. 99:59:59.999 --> 99:59:59.999 Suddenly the cell is making a new protein. 99:59:59.999 --> 99:59:59.999 At first, the protein may be useless, or even harmful, 99:59:59.999 --> 99:59:59.999 but more mutations can change the shape of the protein. 99:59:59.999 --> 99:59:59.999 The protein may start doing something useful, 99:59:59.999 --> 99:59:59.999 something that makes an organism healthier, stronger, 99:59:59.999 --> 99:59:59.999 better able to reproduce. 99:59:59.999 --> 99:59:59.999 Scientists have found these new genes at work in many parts of animal bodies. 99:59:59.999 --> 99:59:59.999 So our 20,000 genes have many origins, 99:59:59.999 --> 99:59:59.999 from the origin of life, to new genes still coming into existence from scratch. 99:59:59.999 --> 99:59:59.999 As long as life is here on Earth, it will be making new genes.