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This problem examines possible biochemical explanations for variations of Mendel’s 9:3:3:1 ratio. Except where indicated, compounds 1, 2, 3, and 4 have different colors, as do mixtures of these compounds. A and B are enzymes that catalyze the indicated steps of the pathway. Alleles A and B specify functional enzymes A and B, respectively; these are completely dominant to alleles a and b, which do not specify any of the corresponding enzyme. If functional enzyme is present, assume that the compound to the left of the arrow is converted completely to the compound to the right of the arrow. For each pathway, what
| a. | Independent pathways |
| b. | Redundant pathways |
| c. | Sequential pathway |
| d. | Enzymes A and B both needed to catalyze the reaction indicated. |
| e. | Branched pathways (assume enough of compound 1 for both pathways) |
| f. | Now consider independent pathways as in (a), but the presence of compound 2 masks the colors due to all other compounds. |
| g. | Next consider the sequential pathway shown in (c), but compounds 1 and 2 are the same color. |
| h. | Finally, examine the pathway that follows. Here, compounds 1 and 2 have different colors. The protein encoded by A prevents the conversion of compound 1 to compound 2. The protein encoded by B prevents protein A from functioning. |
a.
To determine:
The phenotypic ratio expected among the progeny if enzymes A and B follow independent pathways.
Introduction:
The pathways in which one enzyme converts a particular compound into another compound without interfering the catalytic action of another enzyme is termed as an independent pathway. For example, the reaction in which an enzyme A converts compound 1 into compound 2 and enzyme B converts compound 3 into compound 4 is an independent reaction.
Explanation of Solution
The genotype of both parents is as follows:
Parent 1: AaBb
Parent 2: AaBb
The alleles obtained from parent 1 are as follows:
AB, Ab, aB, and ab
The alleles obtained from parent 2 are as follows:
AB, Ab, aB, and ab
The cross between both the parents 2 is as follows:
| ♂/ ♀ | AB | Ab | aB | ab |
| AB | AABB | AABb | AaBb | AaBb |
| Ab | AABb | AAbb | AaBb | Aabb |
| aB | AaBB | AABb | aaBB | aaBb |
| ab | AaBb | Aabb | aaBb | aabb |
The alleles A and B are responsible for the activity of enzymes A and B. However, the alleles a and b are not responsible for the activity of an enzyme.
The above table represents that 9 progenies of parent 1 and 2 will contain enzyme A as they have both alleles A and B. 3 progenies will have enzyme A, 3 will have enzyme B and only 1 progeny would have no enzyme as it has only a and b alleles.
Thus, the phenotypic ratio expected among the progeny if enzyme A and B follow independent pathways is 9:3:3:1.
b.
To determine:
The phenotypic ratio expected among the progeny if enzymes A and B follow redundant pathways.
Introduction:
Redundant pathways are defined as the pathways in which a chemical reaction is catalyzed by more than one enzyme. In this type of pathways, two different enzymes are responsible for the conversion of one compound into another compound.
Explanation of Solution
The cross between both the parents 2 is as follows:
| ♂/ ♀ | AB | Ab | aB | ab |
| AB | AABB | AABb | AaBb | AaBb |
| Ab | AABb | AAbb | AaBb | Aabb |
| aB | AaBB | AABb | aaBB | aaBb |
| ab | AaBb | Aabb | aaBb | aabb |
Enzyme A and B follow the redundant pathways. They both convert compound 1 into compound 2. The presence of either allele A or B in the progeny can lead to the conversion of compound 1 into 2. There are 14 progenies that have either allele A or B, and there is one allele that has neither allele A nor B.
Thus, phenotypic ratio expected among the progeny if enzymes A and B follow redundant pathways is 15:1.
c.
To determine:
The phenotypic ratio expected among the progeny if enzymes A and B follow sequential pathways.
Introduction:
The pathway in which the conversion of one compound into another compound is a sequential process is termed as a sequential pathway. In this type of pathway, the enzyme A converts compound 1 into compound 2, and then the enzyme B convert compound 2 into compound 3. In this case, compound 1 is the reactant, while compound 3 is the product.
Explanation of Solution
The cross between both the parents 2 is as follows:
| ♂/ ♀ | AB | Ab | aB | ab |
| AB | AABB | AABb | AaBb | AaBb |
| Ab | AABb | AAbb | AaBb | Aabb |
| aB | AaBB | AABb | aaBB | aaBb |
| ab | AaBb | Aabb | aaBb | aabb |
The sequential pathway requires both the enzymes, enzyme A and enzyme B. This indicates that the progenies that have both the alleles A and B can have sequential pathways. According to the cross made between parents 1 and 2, there are 9 progenies that have both A and B alleles. These 9 progenies produce compound 3. However, the remaining 7 progenies will not produce compound 3. Out of these 7 progenies, 3 will produce compound 2 as they have allele A and 4 progenies will produce no compound.
Thus, the phenotypic ratio expected among the progeny if enzymes A and B follow sequential pathways is 9:4:3.
d.
To determine:
The phenotypic ratio expected among the progeny if enzymes A and B both are required to catalyze a reaction.
Introduction:
The set of alleles that provide characteristics to an organism are known as genotype. The characteristics that are expressed by the genotype are termed as phenotypic traits. The genotype controls the phenotypes. The ratio of all the phenotypes that are produced in the progenies is termed as the phenotypic ratio.
Explanation of Solution
The cross between both the parents 2 is as follows:
| ♂/ ♀ | AB | Ab | aB | ab |
| AB | AABB | AABb | AaBb | AaBb |
| Ab | AABb | AAbb | AaBb | Aabb |
| aB | AaBB | AABb | aaBB | aaBb |
| ab | AaBb | Aabb | aaBb | aabb |
According to the above table, there are only 9 progenies that can have both A and B enzymes. This is because only these 9 progenies have alleles A and B. The enzyme A is produced by the allele A while the enzyme B is produced by the allele B. However, the rest 7 progenies cannot produce both enzymes A.
Thus, the phenotypic ratio expected among the progeny if enzymes A and B both are required to catalyze a reaction is 9:7.
e.
To determine:
The phenotypic ratio expected among the progeny if enzymes A and B follow branched pathways.
Introduction:
The pathway in which a reactant can be converted into two different pathways by the action of two different enzymes is termed as a branched pathway. For example, compound 1 is a reactant. The enzyme A acts on it and converts it into compound 2. Another enzyme called B acts on this same reactant and produced another compound 3.
Explanation of Solution
The active enzyme A acts on compound 1 and produces compound 2. Similarly, the active enzyme B leads to the production of compound 3 from compound 1. In case both the enzymes are present, then both the compounds 2 and 3 are produced.
There are 9 progenies that produce the compounds, 3 produce only compound 2 and 3 progenies produce compound 3. There is only one progeny that do not produce any compound.
Thus, the phenotypic ratio expected among the progeny if enzymes A and B follow branched pathways is 9:3:3:1.
f.
To determine:
The phenotypic ratio expected among the progeny if enzymes A and B follow independent pathways and compound 2 masks color due to all compounds.
Introduction:
The enzyme A acts on compound 1 and converts it into another compound 2. In case the compound 2 masks the color due to the presence of all other compounds, then the presence or absence of enzyme B is immaterial.
Explanation of Solution
The cross between both the parents 2 is as follows:
| ♂/ ♀ | AB | Ab | aB | ab |
| AB | AABB | AABb | AaBb | AaBb |
| Ab | AABb | AAbb | AaBb | Aabb |
| aB | AaBB | AABb | aaBB | aaBb |
| ab | AaBb | Aabb | aaBb | aabb |
The above table represents a total of 16 progenies. There are 12 progenies that have active enzyme A as they have allele A. However, the rest four progenies do not have an active enzyme. This is because they lack the allele A. There are 3 progenies out of these 4 progenies that can produce active enzyme B as they have allele B. The remaining one progeny does not produce any active enzyme as it lacks both alleles A and B.
Thus, the phenotypic ratio expected among the progeny if enzymes A and B follow independent pathways and compound 2 masks color due to all compounds is 12:3:1.
g.
To determine:
The phenotypic ratio expected among the progeny if enzymes A and B follow sequential pathways given that compound 1 and 2 are of the same color.
Introduction:
The same color of compounds 1 and 2 indicate that the presence or absence of enzyme A that does not affect the sequential pathway. The enzyme responsible for the conversion of compound 2 into compound 3 is enzyme B.
Explanation of Solution
The genotype of both parents is as follows:
Parent 1: AaBb
Parent 2: AaBb
The alleles obtained from parent 1 are as follows:
AB, Ab, aB, and ab
The alleles obtained from parent 2 are as follows:
AB, Ab, aB, and ab
The cross between both the parents 2 is as follows:
| ♂/ ♀ | AB | Ab | aB | ab |
| AB | AABB | AABb | AaBb | AaBb |
| Ab | AABb | AAbb | AaBb | Aabb |
| aB | AaBB | AABb | aaBB | aaBb |
| ab | AaBb | Aabb | aaBb | aabb |
The above table represents that there are 9 progenies that have both enzymes A and B as they have alleles A and B. Out of these 9 progenies, 3 have enzyme A but not B. This reflects that compound 2 will be formed from these progenies. The rest 7 progenies will not have the same color as they do not have both enzymes A and B.
Thus, the phenotypic ratio expected among the progeny if enzymes A and B follow sequential pathways given that compound 1 and 2 are of the same color is 9:7.
h.
To determine:
The phenotypic ratio of the pathway in which protein A and B are associated with the conversion of compound 1 into compound 2.
Introduction:
The protein A is the inhibitory factor that prevents the conversion of compound 1 into compound 2. Another protein named B inhibits the functioning of protein A. The protein A can perform its function only in the absence of protein B.
Explanation of Solution
The protein A inhibits the formation of compound 2. This reflects that all the progenies that have protein A should not produce compound 2. The progenies that lack the allele A cannot produce the protein A. However, if the progenies have protein B along with protein A, then compound 2 can be produced. This reflects that the progenies that have both the proteins A and B can produce the same colored compounds. Similarly, the progenies that have proteins B and not A will also produce a colored compound 2. The progenies with proteins A but not B will produce a particular colored compound.
Thus, the phenotypic ratio of the pathway in which protein A and B are associated with the conversion of compound 1 into compound 2 is 12:3:1.
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Chapter 3 Solutions
Genetics: From Genes to Genomes
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If a mutant allele that predisposed to breast and ovarian cancer was inherited in Sarahs family, she, her sister, and any of her own future children could be at risk for inheriting this mutation. The counselor told her that genetic testing is available that may help determine if this mutant allele is present in her family members. Adams paternal family history has a very strong pattern of early onset heart disease. An autosomal dominant condition known as familial hypercholesterolemia may be responsible for the large number of deaths from heart disease. As with hereditary breast and ovarian cancer, genetic testing is available to see if Adam carries the mutant allele. Testing will give the couple more information about the chances that their children could inherit this mutation. Adam had a first cousin who died from Tay-Sachs disease (TSD), a fatal autosomal recessive condition most commonly found in people of Eastern European Jewish descent. Because TSD is a recessively inherited disorder, both of his cousins parents must have been heterozygous carriers of the mutant allele. If that is the case, Adams father could be a carrier as well. If Adams father carries the mutant TSD allele, it is possible that Adam inherited this mutation. Because Sarah is also of Eastern European Jewish ancestry, she could also be a carrier of the gene, even though no one in her family has been affected with TSD. If Adam and Sarah are both carriers, each of their children would have a 25% chance of being afflicted with TSD. A simple blood test performed on both Sarah and Adam could determine whether they are carriers of this mutation. Would you decide to have a child if the test results said that you carry the mutation for breast and ovarian cancer? The heart disease mutation? The TSD mutation? The heart disease and the mutant alleles?arrow_forwardPedigree analysis is a fundamental tool for investigating whether or not a trait is following a Mendelian pattern of inheritance. It can also be used to help identify individuals within a family who may be at risk for the trait. Adam and Sarah, a young couple of Eastern European Jewish ancestry, went to a genetic counselor because they were planning a family and wanted to know what their chances were for having a child with a genetic condition. The genetic counselor took a detailed family history from both of them and discovered several traits in their respective families. Sarahs maternal family history is suggestive of an autosomal dominant pattern of cancer predisposition to breast and ovarian cancer because of the young ages at which her mother and grandmother were diagnosed with their cancers. If a mutant allele that predisposed to breast and ovarian cancer was inherited in Sarahs family, she, her sister, and any of her own future children could be at risk for inheriting this mutation. The counselor told her that genetic testing is available that may help determine if this mutant allele is present in her family members. Adams paternal family history has a very strong pattern of early onset heart disease. An autosomal dominant condition known as familial hypercholesterolemia may be responsible for the large number of deaths from heart disease. As with hereditary breast and ovarian cancer, genetic testing is available to see if Adam carries the mutant allele. Testing will give the couple more information about the chances that their children could inherit this mutation. Adam had a first cousin who died from Tay-Sachs disease (TSD), a fatal autosomal recessive condition most commonly found in people of Eastern European Jewish descent. Because TSD is a recessively inherited disorder, both of his cousins parents must have been heterozygous carriers of the mutant allele. If that is the case, Adams father could be a carrier as well. If Adams father carries the mutant TSD allele, it is possible that Adam inherited this mutation. Because Sarah is also of Eastern European Jewish ancestry, she could also be a carrier of the gene, even though no one in her family has been affected with TSD. If Adam and Sarah are both carriers, each of their children would have a 25% chance of being afflicted with TSD. A simple blood test performed on both Sarah and Adam could determine whether they are carriers of this mutation. Would you want to know the results of the cancer, heart disease, and TSD tests if you were Sarah and Adam? 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Because TSD is a recessively inherited disorder, both of his cousins parents must have been heterozygous carriers of the mutant allele. If that is the case, Adams father could be a carrier as well. If Adams father carries the mutant TSD allele, it is possible that Adam inherited this mutation. Because Sarah is also of Eastern European Jewish ancestry, she could also be a carrier of the gene, even though no one in her family has been affected with TSD. If Adam and Sarah are both carriers, each of their children would have a 25% chance of being afflicted with TSD. A simple blood test performed on both Sarah and Adam could determine whether they are carriers of this mutation. If Sarah carries the mutant cancer allele and Adam carries the mutant heart disease allele, what is the chance that they would have a child who is free of both diseases? Are these good odds?arrow_forward
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