- Human activities that threaten biodiversity
- Mutation as a source of variation
- Invasive species
- How did all dinosaurs except birds go extinct?
- Were dinosaurs undergoing long-term decline before mass extinction?
- Human impact on ecosystems review
- Introduced species and biodiversity
- How does climate change affect biodiversity?
- Demystifying ocean acidification and biodiversity impacts
- Biodiversity and extinction, then and now
- Threats to biodiversity
Natural selection relies on variation in populations, driving evolution. Variation arises from sexual reproduction, shuffling gene combinations, and mutations, creating new alleles or genes. Phenotypes, observable traits, stem from genotypes, genetic information. Mutations can be neutral, advantageous, or detrimental, influencing an organism's survival and reproduction. Created by Sal Khan.
Want to join the conversation?
- Is anyone else weirdly interested in genetic diseases? I actually find them fascinating for no reason that I can find. Since nothing's here, I figured I may as well start something so this page doesn't look sad and empty.(6 votes)
- Actually, I've examined genetic anomalies within my family, like how two of my sisters are blond even though my parents have dark brown hair...
The biggest genetic anomaly is that I've never encountered a person with my temper, which is hot enough to fuel every geyser in Yellowstone Park...(2 votes)
- Is anyone else weirdly interested in genetic diseases? I actually find them fascinating for no reason that I can find. Since nothing's here, I figured I may as well start something so this page doesn't look sad and empty.(0 votes)
- Umm... excuse me, it appears that you have copied and pasted my post? Is there a reason for that? I'm not upset, just curious.(4 votes)
- [Instructor] In many videos when we've discussed evolution and natural selection, we've talked about how variation in a population can fuel natural selection and evolution. So if you have a population of circles, obviously a very simple model here, maybe some of these circles are that off-white color, maybe some of them are blue, and maybe some of them are this salmon color. For certain traits, your environment might make certain of them better for reproduction, better for survival, evading predators, better for finding food. Now let's say these circles for whatever reason, they're in an environment where maybe being blue makes it a little bit easier to evade predators and a little bit easier to reproduce and find food. Well then, in the next generation, in the next generation, because the blue's more likely to be able to get to reproduction, because they weren't eaten, you're likely to have more blues. So we draw a few more blues. And maybe a little bit less of the other ones, because they're also competing for resources amongst each other, at least in this model that I'm doing. And so over time, if this blue phenotype, remember, phenotype is the expressed trait that's actually observable, versus a genotype, which is the overlying genetics, which is sometimes observable and sometimes not, but as you can see, if in this environment, blue seems to carry some advantage, even if it's a slight probabilistic advantage, over many generations, blue will start to dominate. And so you start to see that evolution of this population to being more blue as a species. So, you have these blue circles. One way to think about it is, you have variation in a species is really what natural selection is based off of. Certain variants might be more favorable than others, so that is what's really necessary for natural selection to fuel evolution. To fuel evolution. Now, a key question is, where does this variation in a population come from? And to think about that, we just have to remind ourselves where our phenotypes come from. How do these expressed traits get expressed? Well, in all the living organisms we're aware of, we have DNA. As human beings we have 23 pair of chromosomes, and each chromosome you can view as just a very very very long strand of DNA, and sections of that DNA code for various traits, and each of those sections that code for, say a certain protein or a part of an enzyme, we call those things genes. We call those things genes. We have multiple chromosomes. As human beings, different species have a different number, but as human beings we have 23 pair of chromosomes. Each chromosome you view as a long strand of DNA. Parts of that DNA code for specific genes, and then if you were to zoom in, if you were to zoom in on those genes, you would see those nucleotide sequences, and this is all a review. We've seen this in other videos, where you see your adenine, your guanine, your cytosine, your thiamine, in order that carries the information that will eventually be coded into MRNA, which then gets coded into protein. Now there's two primary sources of variation. One source of a variation is sexual reproduction. Sexual reproduction. Now, not all organisms reproduce sexually, but many of the ones that we know, including human beings, do, where a male member of the species and a female member of the species each contribute a random half of their chromosomes to the next organism. So one way to think about sexual reproduction is it keeps shuffling the different versions of the genes that you have in the population into different combinations of those versions of genes, and so that generates variation. But sexual reproduction by itself will not create new versions of genes, which we call alleles, or new genes entirely, and so the primary way that that happens is through mutations, and you might have guessed that we were gonna talk about that, 'cause I had this title up here. So, another source of variation, and you could almost view this as a more fundamental one because this would happen even in organisms that aren't reproducing sexually, is that over time, there can be just random mistakes. There could be edits to these genes, and it could be a random, maybe this G gets turned into a C randomly, or maybe this T and A gets cut out during the DNA replication process. These mutations, which are all about genotype, and let me make this very clear, so when we're looking at the sequence, we're thinking about genotype. Differences in genotype are not always obvious from expressed traits. Sometimes they do change phenotype where they're observable in phenotype. Sometimes they're not. But when they are observable in phenotype, as I just mentioned, many times it could be a negative change in phenotype where it makes it less viable for that organism or it's harder for them to survive and reproduce, but every now and then it could result in a variation in phenotype that is maybe neutral or even confers some type of advantage. So it might have been a random mutation that somehow turned one of these white circles into a blue circle, and there might have been another mutation that turned a white circle into a square, and that just wasn't even viable as an organism, but the blue circles happened to be, in the environment they're in, happened to be a favorable variation.