Question
In pea plants, tall plants (T) are dominant over short plants (t). If a heterozygous tall pea plant is crossed with a homozygous recessive short pea plant, what percentage of the offspring is expected to be tall.
(HINT: use a Punnett square to help you with this question)
(1 point)
Responses
0%
0%
50%
50%
75%
75%
25%
(HINT: use a Punnett square to help you with this question)
(1 point)
Responses
0%
0%
50%
50%
75%
75%
25%
Answers
GPT-4o mini
To determine the expected percentage of tall offspring when a heterozygous tall pea plant (Tt) is crossed with a homozygous recessive short pea plant (tt), we can use a Punnett square.
Here’s how the cross looks:
- Parent 1 (heterozygous tall): Tt
- Parent 2 (homozygous recessive short): tt
The Punnett square would look like this:
```
T t
----------------
t | Tt | tt |
----------------
t | Tt | tt |
----------------
```
From the square, we can see the possible genotypes of the offspring:
- Tt (tall) = 2 instances
- tt (short) = 2 instances
Thus, the expected genotypic ratio is:
- 2 Tt : 2 tt, which simplifies to 1 Tt : 1 tt.
This means 50% of the offspring are expected to be tall (Tt).
**Therefore, the answer is 50%.**
Here’s how the cross looks:
- Parent 1 (heterozygous tall): Tt
- Parent 2 (homozygous recessive short): tt
The Punnett square would look like this:
```
T t
----------------
t | Tt | tt |
----------------
t | Tt | tt |
----------------
```
From the square, we can see the possible genotypes of the offspring:
- Tt (tall) = 2 instances
- tt (short) = 2 instances
Thus, the expected genotypic ratio is:
- 2 Tt : 2 tt, which simplifies to 1 Tt : 1 tt.
This means 50% of the offspring are expected to be tall (Tt).
**Therefore, the answer is 50%.**
If a black chicken (BB) is crossed with a white chicken (WW) and incomplete dominance is observed, what are the expected phenotypes of the offspring?(1 point)
Responses
All gray
All gray
All black
All black
All white
All white
All red
Responses
All gray
All gray
All black
All black
All white
All white
All red
GPT-4o mini
In the case of incomplete dominance, when a black chicken (BB) is crossed with a white chicken (WW), the resulting offspring will show a blended phenotype rather than one of the parents' phenotypes.
For this cross:
- BB (black)
- WW (white)
The offspring will all inherit one allele from each parent, resulting in the genotype BW. Because of incomplete dominance, the phenotype associated with this genotype will not be entirely black or entirely white; instead, it will be a blend of the two.
Therefore, the expected phenotype of the offspring will be gray.
**So the answer is: All gray.**
For this cross:
- BB (black)
- WW (white)
The offspring will all inherit one allele from each parent, resulting in the genotype BW. Because of incomplete dominance, the phenotype associated with this genotype will not be entirely black or entirely white; instead, it will be a blend of the two.
Therefore, the expected phenotype of the offspring will be gray.
**So the answer is: All gray.**
In cattle, coat color is controlled by codominant alleles. A red-coated cow (RR) is crossed with a white-coated bull (WW). What are the expected phenotypes of the offspring?(1 point)
Responses
All pink coat
All pink coat
Red and white coat
Red and white coat
All red coat
All red coat
All white coat
Responses
All pink coat
All pink coat
Red and white coat
Red and white coat
All red coat
All red coat
All white coat
GPT-4o mini
In cattle, if coat color is controlled by codominant alleles, this means that both alleles are expressed equally in the phenotype when present together.
In the given scenario:
- A red-coated cow has the genotype RR.
- A white-coated bull has the genotype WW.
When these two are crossed (RR × WW), the resulting offspring will have the genotype RW.
In codominance, the offspring (RW) will display both traits distinctly. Therefore, the expected phenotypes of the offspring will be red and white coat colors.
**So the answer is: Red and white coat.**
In the given scenario:
- A red-coated cow has the genotype RR.
- A white-coated bull has the genotype WW.
When these two are crossed (RR × WW), the resulting offspring will have the genotype RW.
In codominance, the offspring (RW) will display both traits distinctly. Therefore, the expected phenotypes of the offspring will be red and white coat colors.
**So the answer is: Red and white coat.**
Complete the mRNA sequence that will be formed from the DNA sequence below, then identify the amino acids using the codon chart provided above.
(6 points)
Put responses in the correct input to answer the question. Select a response, navigate to the desired input and insert the response. Responses can be selected and inserted using the space bar, enter key, left mouse button or touchpad. Responses can also be moved by dragging with a mouse.
TAC CGC CCC
mRNA Response area Response area Response area
Amino Acid Response area Response area Response area
(6 points)
Put responses in the correct input to answer the question. Select a response, navigate to the desired input and insert the response. Responses can be selected and inserted using the space bar, enter key, left mouse button or touchpad. Responses can also be moved by dragging with a mouse.
TAC CGC CCC
mRNA Response area Response area Response area
Amino Acid Response area Response area Response area
GPT-4o mini
To transcribe the DNA sequence into mRNA, you need to replace each DNA base with its complementary RNA base:
- Adenine (A) in DNA pairs with Uracil (U) in RNA.
- Thymine (T) in DNA pairs with Adenine (A) in RNA.
- Cytosine (C) in DNA pairs with Guanine (G) in RNA.
- Guanine (G) in DNA pairs with Cytosine (C) in RNA.
Given the DNA sequence:
- TAC CGC CCC
The corresponding mRNA sequence will be:
- AUG GCG GGG
Next, to identify the amino acids using the codon chart based on the mRNA sequence:
1. AUG - Methionine (Met) (this is often a start codon)
2. GCG - Alanine (Ala)
3. GGG - Glycine (Gly)
### Final Responses:
#### mRNA:
- AUG
- GCG
- GGG
#### Amino Acids:
- Met
- Ala
- Gly
Feel free to fill in the responses in the designated response areas!
- Adenine (A) in DNA pairs with Uracil (U) in RNA.
- Thymine (T) in DNA pairs with Adenine (A) in RNA.
- Cytosine (C) in DNA pairs with Guanine (G) in RNA.
- Guanine (G) in DNA pairs with Cytosine (C) in RNA.
Given the DNA sequence:
- TAC CGC CCC
The corresponding mRNA sequence will be:
- AUG GCG GGG
Next, to identify the amino acids using the codon chart based on the mRNA sequence:
1. AUG - Methionine (Met) (this is often a start codon)
2. GCG - Alanine (Ala)
3. GGG - Glycine (Gly)
### Final Responses:
#### mRNA:
- AUG
- GCG
- GGG
#### Amino Acids:
- Met
- Ala
- Gly
Feel free to fill in the responses in the designated response areas!
Use the codon chart below to determine the bases that will code for the amino acid Methionine (Met).
(1 point)
Uracil Cytosine Adenine Guanine
First Base
Second Base
Third Base
(1 point)
Uracil Cytosine Adenine Guanine
First Base
Second Base
Third Base
GPT-4o mini
Methionine (Met) is coded by the codon AUG in mRNA. To determine the bases that correspond to each position of the codon, we can break it down as follows:
- **First Base:** A (Adenine)
- **Second Base:** U (Uracil)
- **Third Base:** G (Guanine)
So, using the codon chart to code for Methionine (Met), we have:
1. **First Base:** A
2. **Second Base:** U
3. **Third Base:** G
This corresponds to the mRNA codon AUG, which codes for Methionine.
- **First Base:** A (Adenine)
- **Second Base:** U (Uracil)
- **Third Base:** G (Guanine)
So, using the codon chart to code for Methionine (Met), we have:
1. **First Base:** A
2. **Second Base:** U
3. **Third Base:** G
This corresponds to the mRNA codon AUG, which codes for Methionine.