Non-Random Mating - Online Tutor, Practice Problems & Exam Prep

We've said that a major assumption of Hardy Weinberg is random mating. So now we want to take a closer look at what happens with non-random mating. Non-random mating, we're just going to define as when certain genotypes are more likely to mate with each other. Now remember for Hardy Weinberg, we said it's like taking all the alleles in the population and putting them in one bag, or you can think here it's like taking all the gametes from the population and putting them in one bag and then just shaking up that bag and seeing what comes out for the next generation.

Well, if certain organisms are more likely to reproduce with each other, it's not like taking all those gametes, putting them in one bag, and shaking it up. What's going to happen is that this alters genotype frequencies. It's going to push that population out of Hardy Weinberg equilibrium. But importantly, we said it's not going to alter allele frequencies, and that's important because a change in allele frequencies is a measure of evolution.

So non-random mating on its own will push a population out of Hardy Weinberg equilibrium, but it will not cause evolution. It's important to note here, and a little bit of misconception sometimes people have, we are not talking about sexual selection when we're talking about non-random mating; we're still assuming that everyone gets to mate. All the same alleles are still getting passed on. They're just not getting paired together in a random way. Sexual selection is about the ability to obtain mates. We're going to take a closer look at that when we talk about natural selection.

For non-random mating though, we're going to say that this happens a lot just because organisms are often more likely to mate with, we're going to say here, relatives or related individuals, and that's often just due to proximity. Organisms are more likely to mate with organisms that live close to them. For example, this map shows the distribution of white oak trees, and we can see here in green the white oak trees are found basically in most of the Eastern United States.

Now, oak trees are wind-pollinated. Wind pollination, that sounds pretty random to me. Just where the wind blows. But we have this question here: Is an oak tree in Maine likely to mate with an oak tree in Texas? Well, it turns out pollen only travels in the wind something like 200 meters. So these trees up in Maine, they are not going to mate with the trees in Texas. The wind just is not going to blow that far. These trees are mating with those organisms in their immediate proximity. Over time, that leads to inbreeding. And inbreeding, we're just going to say, is mating between relatives. When that happens, the way that this population gets pushed out of Hardy Weinberg is that it increases homozygosity. And homozygosity is just a measure of how many homozygotes there are in the population.

Populations with inbreeding have more homozygotes than you would otherwise expect. This leads to what we call inbreeding depression. Inbreeding depression is a fitness decrease, due to an increase of homozygotes with deleterious recessive alleles. Rare recessive alleles, in a population, their phenotypes are normally masked because they're paired with the more common dominant alleles. But if there's inbreeding, if you have excess homozygotes, those rare recessive alleles are more likely to be paired with each other. And if those alleles are deleterious, well, those phenotypes get exposed, and it reduces the fitness of those individuals. You may think fitness difference. That sounds like it's going to lead to evolution.

It will, but it's going to require natural selection to then change the allele frequency. The non-random mating just made them more homozygous. Natural selection can then push the allele frequency and cause the population to change afterward. Well, practice has more coming up. I'll see you there.

The table below shows the genotype frequencies and allele frequencies for two populations, population 1 and 2. Now in one of these populations, there's been random mating, and in the other population, there has been inbreeding. We need to identify in which population you think random mating has occurred and in which population there has been inbreeding, then answer the question below. Alright. So let's take a look at the table.

We have two populations with 1000 individuals, population 1 and population 2. We see the three different genotypes here, and we have the different counts. You can see that they have very different numbers there, and then we also see the allele frequencies. And we see that these two populations have the same allele frequencies. Both of them are p and q both equal 0.5.

Alright. So just take a second. Look at that. Think about what you would expect under inbreeding and under random mating, and see if you can figure this out. Alright.

I'm going to do some calculations in a second just to prove it to myself. But remember, under inbreeding, we said you get excess homozygosity. You get more homozygotes in the population than you would otherwise expect. So population 2, well, it has a lot more homozygotes. So I think population 2 has inbreeding.

Now I can sort of figure out what my Hardy-Weinberg expectation would be just by doing p², 2pq, and q² for my three genotypes here. So p², well, 0.5×0.5, that's 0.25. 2pq, that's going to equal 0.5, if you do the math. And q², well, it's also 0.5×0.5, that also equals 0.25. And you get the actual counts, well, there's 1000 individuals.

I'd multiply that by 1000, and you can see that matches population 1 perfectly. So population 1 is in Hardy Weinberg equilibrium. Population 2 is way out because there are way too many homozygotes. So now I feel really good about saying that the population with random mating is population 1, because it is in Hardy Weinberg equilibrium.

The population with inbreeding, I say population 2, because it has way more homozygotes than I would otherwise expect. Alright. Now we have to answer c here, and I'm going to scroll down, so that we can see this a little bit better. And c says well, it's a little bit of a word salad. We got to straighten it out.

It says fill in the sentence below using the words allele and genotype. Both words will be used twice. Alright. What it says here is for an actual population, knowing the blank frequency will tell you the blank frequency. But knowing the blank frequency does not tell you the blank frequency.

Alright. And we've got to put allele and genotype on those lines to make it make sense. Now this kind of makes me want to cry a little bit. That feels really confusing, but let's break this down. Let's just look at the first half of it first.

For an actual population, knowing the genotype frequency will tell you the allele frequency. Alright. When we got an actual population, which thing did we sort of get to count, and which thing did we have to calculate? Well, when we had an actual population, we were given the genotype frequency. And from that, we could calculate the allele frequency.

Right? We would calculate the allele frequency from the genotype frequency for an actual population. But then it says, but knowing the allele frequency does not tell you the genotype frequency. Right? If I know the allele frequency, I can't predict the genotype frequency for an actual population.

Right? You can see here in our table, well, we have identical allele frequencies, but we cannot calculate the genotype frequencies. Now we could go the other way. We didn't do all that math out. We could go the other way, though, and figure out that both of those have allele frequencies of 0.5.

So here I am going to say that knowing the allele frequency does not tell you the genotype frequency. Now you may be saying, wait a second, we spent a lot of time calculating genotype frequency from allele frequency. Yes. But that was when we assumed the population was in Hardy Weinberg equilibrium. Here, this is an actual population.

We cannot make that assumption for actual populations. Alright. With that, we figured it out. We got more practice to come. Check it out.

It'll be fun. At least, I think it will be.