Solve Trihybrid Cross Problem: Phenotypic Ratio 27:9:9:9:3:3:3:1

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Discussion Overview

The discussion centers around solving a trihybrid cross problem involving coat color in rabbits, specifically examining the phenotypic ratio resulting from a cross between two heterozygous rabbits (AaTtBb). Participants explore the genetic interactions and the resulting phenotypes based on the alleles present.

Discussion Character

  • Homework-related
  • Mathematical reasoning
  • Technical explanation

Main Points Raised

  • One participant asks for help in determining the phenotypic ratio from a trihybrid cross, stating they believe the ratio is 27:9:9:9:3:3:3:1.
  • Another participant suggests using a Punnett square to visualize the genetic combinations, noting that the phenotypic ratio will differ from a scenario where each locus encodes a completely different trait.
  • A participant confirms their setup of a Punnett square with 64 squares and questions whether the ratio could be something like 27:9:28 due to having only three possible phenotypes.
  • One participant explains how to evaluate the offspring's genotypes to determine their phenotypes based on the presence of dominant alleles.
  • Another participant inquires about alternative methods to solve the problem without using a Punnett square, expressing concerns about time consumption.
  • Participants discuss the efficiency of evaluating phenotypes based on dominant alleles rather than writing out every genotype, while still recommending the use of Punnett squares for clarity and error-checking.
  • A later reply confirms the participant's calculations of the phenotypic ratios as 27/64 black, 28/64 colorless, and 9/64 tan, expressing satisfaction with the assistance received.

Areas of Agreement / Disagreement

Participants generally agree on the method of using a Punnett square and the evaluation of phenotypes based on dominant alleles. However, there is no consensus on the final ratios, as one participant suggests a different interpretation of the ratios based on the phenotypes available.

Contextual Notes

The discussion reflects varying approaches to solving the problem, including the use of Punnett squares and alternative reasoning methods. There are unresolved aspects regarding the interpretation of the phenotypic ratios and the implications of allele interactions.

predentalgirl1
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[SOLVED] Trihybrid Cross Problem

Hi, I need help trying to figure out how to solve this question:

Assume that in rabbits there are three different independently assorting autosomal loci that affect coat color. A colorless-pigment precursor V is converted to a colorless precursor W by action of the A allele. W is converted to a tan pigment by action of the T allele, and the tan pigment is converted to black pigment by action of the B allele:

A- T- B- (reaction proceeds)
V-----> W-----> tan-----> black
aa tt bb (reaction blocked)

The homozygous recessive condition at each locus results in loss of enzyme activity for the reaction controlled by that gene. A cross of trihybrid bunnies (AaTtBb X AaTtBb) would be expected to give rise to what phenotypic ratio in the offspring?


I know the phenotypic ratio is 27:9:9:9:3:3:3:1. I can't figure out how to work this out. Can someone help me?
 
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Have you tried setting up a Punnett Square yet?

Also, the phenotypic ratio will not be the same as if each loci was encoding a completely different trait. Instead, the alleles at each loci are dependent upon the other two loci for the phenotypic expression pattern. You only have three possible phenotypes: colorless, tan, black.
 
Yes I did set up a punnett square (with 64 squares). I got these set up on the left and top side of it: ATB, Atb, AtB, ATb, aTB, atb, aTb, atB. Did I do this entirely wrong? Also, would the ratio be something like 27:9:28...since there are only 3 possible phenotypes? I don't understand how to get the final answer.
 
You have the right set up for the Punnett square.

Yes, you're much closer now on the ratio. Basically, you have to look at each of the genotypes for the offspring and evaluate in order:
Does it have A_ genotype? Yes, then continue. No, then colorless.
Does it have T_ genotype? Yes, then continue. No, then colorless (Keep in mind that either A or a are still colorless if T and B are not present.)
Does it have B_ genotype? Yes, then black. No, then tan.

Now see if you can figure out the ratio for each color.
 
Also, is there any other way to solve this without using the Punnett square? It took a lot of time to do that.
 
predentalgirl1 said:
Also, is there any other way to solve this without using the Punnett square? It took a lot of time to do that.

The mathematicians around here would likely tell you yes, there's another way, but it's not likely to be any faster than just sketching out a quick Punnett square. The trick on one like this is not to spend a lot of time writing out every genotype for the offspring. Instead, you can run down a row very quickly by looking at the alleles for a single parent and determining phenotype as you go. For example, in the row and column where each parent has ATB as their alleles, you can mark the entire row as black (the contribution from the second parent is irrelevant if the other is dominant for all three traits). Then, if your next column has ATb for one parent's alleles, you only need to look at whether the other parent has B or b to determine if the offspring are Black or Tan. But, while still learning, I encourage you to keep using Punnett squares so you really see how the combinations are arising...it's easier to double check for mistakes that way too.
 
Moonbear said:
You have the right set up for the Punnett square.

Yes, you're much closer now on the ratio. Basically, you have to look at each of the genotypes for the offspring and evaluate in order:
Does it have A_ genotype? Yes, then continue. No, then colorless.
Does it have T_ genotype? Yes, then continue. No, then colorless (Keep in mind that either A or a are still colorless if T and B are not present.)
Does it have B_ genotype? Yes, then black. No, then tan.

Now see if you can figure out the ratio for each color.


Ok, I use your method with the punnett square and I got 27/64 black, 28/64 colorless, and 9/64 tan. Is this right?
 
Moonbear said:
The mathematicians around here would likely tell you yes, there's another way, but it's not likely to be any faster than just sketching out a quick Punnett square. The trick on one like this is not to spend a lot of time writing out every genotype for the offspring. Instead, you can run down a row very quickly by looking at the alleles for a single parent and determining phenotype as you go. For example, in the row and column where each parent has ATB as their alleles, you can mark the entire row as black (the contribution from the second parent is irrelevant if the other is dominant for all three traits). Then, if your next column has ATb for one parent's alleles, you only need to look at whether the other parent has B or b to determine if the offspring are Black or Tan. But, while still learning, I encourage you to keep using Punnett squares so you really see how the combinations are arising...it's easier to double check for mistakes that way too.

Ok...thanks. I will do that the next time I have a trihybrid problem because writing everything down took up a lot of time and I won't have that much time when I take my test. Thanks very much. :)
 
predentalgirl1 said:
Ok, I use your method with the punnett square and I got 27/64 black, 28/64 colorless, and 9/64 tan. Is this right?

Yep, you got it! :smile:
 
  • #10
Moonbear said:
Yep, you got it! :smile:

Yes! Thanks very much for your help. I was stumped on this question for over an hour. Thanks again. :)
 

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