Understanding Autosomal and Sex-Linked Inheritance - AP Biology
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What is an autosome?
What is an autosome?
Autosomes are all the chromosomes that do not determine an individual's sex. X and Y chromosomes both determine sex, and are sex chromosomes. The other 22 pairs of chromosomes are autosomes.
Autosomes are all the chromosomes that do not determine an individual's sex. X and Y chromosomes both determine sex, and are sex chromosomes. The other 22 pairs of chromosomes are autosomes.
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Fertilization results in __________.
Fertilization results in __________.
The union of two gametes is called fertilization, which results in a zygote. The zygote is a diploid cell that will grow into the entire organism.
The union of two gametes is called fertilization, which results in a zygote. The zygote is a diploid cell that will grow into the entire organism.
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Which of the following is true about alleles?
Which of the following is true about alleles?
Alleles are defined as "alternative forms of a given gene." Though Mendelian genetics tells us that the ideal model of a gene has only two alleles, dominant and recessive, we know this is not always the case, from things like codominance (blood type) and others. Some characteristics are defined by a combination of several alleles with varying weight of expression. Alleles on autosomes are inherited from both parents, but alleles in mitochondrial DNA are inherited from the mother only. Twins are an example of organisms with identical alleles, so the answers claiming that all organisms have different alleles is false.
Alleles are defined as "alternative forms of a given gene." Though Mendelian genetics tells us that the ideal model of a gene has only two alleles, dominant and recessive, we know this is not always the case, from things like codominance (blood type) and others. Some characteristics are defined by a combination of several alleles with varying weight of expression. Alleles on autosomes are inherited from both parents, but alleles in mitochondrial DNA are inherited from the mother only. Twins are an example of organisms with identical alleles, so the answers claiming that all organisms have different alleles is false.
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In this pedigree, affected individuals have a disease causing the person to be born with feathers instead of hair, called Disease P. Assume all individuals whose alleles cannot be determined do not carry the allele for the disease (are not heterozygous).
Disease P in the figure above is inherited in what manner?
In this pedigree, affected individuals have a disease causing the person to be born with feathers instead of hair, called Disease P. Assume all individuals whose alleles cannot be determined do not carry the allele for the disease (are not heterozygous).
Disease P in the figure above is inherited in what manner?
The first generation shows us a father with the disease and a mother without the disease. They produce three children, none of whom have the disease. Knowing that they do not have the disease allows us to eliminate dominant from consideration. In order for the third generation to be affected, the mother from the second generation must be a carrier. In the third generation, we see that the carrier mother has a male child with the disease with a father who does not have the disease. The male child will inherit the Y chromosome from his father, but must receive an X chromosome from the mother. He inherits the disease on this X chromosome.
Were the disease autosomal recessive, the father of the third generation child would need to be affected in order for him to inherit the trait. The disease must be X-linked recessive.
The first generation shows us a father with the disease and a mother without the disease. They produce three children, none of whom have the disease. Knowing that they do not have the disease allows us to eliminate dominant from consideration. In order for the third generation to be affected, the mother from the second generation must be a carrier. In the third generation, we see that the carrier mother has a male child with the disease with a father who does not have the disease. The male child will inherit the Y chromosome from his father, but must receive an X chromosome from the mother. He inherits the disease on this X chromosome.
Were the disease autosomal recessive, the father of the third generation child would need to be affected in order for him to inherit the trait. The disease must be X-linked recessive.
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In this pedigree, affected individuals have a disease causing the inability to walk forward, called Disease J. Assume all individuals whose alleles cannot be determined do not carry the allele for the disease (are not heterozygous).
How is Disease J inherited?
In this pedigree, affected individuals have a disease causing the inability to walk forward, called Disease J. Assume all individuals whose alleles cannot be determined do not carry the allele for the disease (are not heterozygous).
How is Disease J inherited?
The first generation shows an affected father and an unaffected mother. They produce both affected and unaffected children in the second generation, meaning that the disease cannot be recessive; if it were recessive, none of the second generation could be affected due to dominant alleles inherited from the mother. We can also conclude that the affected father is heterozygous.
Knowing that the trait is dominant, we must determine if it is autosomal or sex-linked. The trait can affect females, so it cannot be on the Y chromosome. The female in the second generation is affected, even though her mother is not, meaning she must be heterozygous. If the trait is on the X chromosome, it will be passed from the affected father to all female offspring, meaning that both females in the second generation would be affected. Because one female is not affected, she must have inherited an unaffected autosomal allele from the heterozygous father.
As such, the allele for the disease must be autosomal dominant.
The first generation shows an affected father and an unaffected mother. They produce both affected and unaffected children in the second generation, meaning that the disease cannot be recessive; if it were recessive, none of the second generation could be affected due to dominant alleles inherited from the mother. We can also conclude that the affected father is heterozygous.
Knowing that the trait is dominant, we must determine if it is autosomal or sex-linked. The trait can affect females, so it cannot be on the Y chromosome. The female in the second generation is affected, even though her mother is not, meaning she must be heterozygous. If the trait is on the X chromosome, it will be passed from the affected father to all female offspring, meaning that both females in the second generation would be affected. Because one female is not affected, she must have inherited an unaffected autosomal allele from the heterozygous father.
As such, the allele for the disease must be autosomal dominant.
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Color blindness is determined by a sex-linked recessive allele found on the X chromosome. A family has a daughter that sees normally, but a son that is color blind. The mother and father both have normal vision. The maternal grandfather also has normal vision.
Based on this family history, which statement is true?
Color blindness is determined by a sex-linked recessive allele found on the X chromosome. A family has a daughter that sees normally, but a son that is color blind. The mother and father both have normal vision. The maternal grandfather also has normal vision.
Based on this family history, which statement is true?
In order to solve the problem, trace the colorblind allele all the way to the grandparent's alleles. It is possible that the daughter is a carrier, but this is not a guarantee. Males can not be carriers, as they only have one X chromosome; they either have the allele or they do not. Finally, the maternal grandmother may be colorblind, but this is not guaranteed.
All that we know is that at least one of the maternal grandmother's alleles codes for colorblindness. The maternal grandmother passed this allele to the mother. The color blind son inherits his Y chromosome from his father, and his only X chromosome from his mother; thus, the mother must be a carrier to pass down a color blind X chromosome to the son.
In order to solve the problem, trace the colorblind allele all the way to the grandparent's alleles. It is possible that the daughter is a carrier, but this is not a guarantee. Males can not be carriers, as they only have one X chromosome; they either have the allele or they do not. Finally, the maternal grandmother may be colorblind, but this is not guaranteed.
All that we know is that at least one of the maternal grandmother's alleles codes for colorblindness. The maternal grandmother passed this allele to the mother. The color blind son inherits his Y chromosome from his father, and his only X chromosome from his mother; thus, the mother must be a carrier to pass down a color blind X chromosome to the son.
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A human somatic cell has how many chromosomes?
A human somatic cell has how many chromosomes?
A somatic cell is a diploid cell so it will have 22 pairs of autosomes and one pair of sex chromosomes for a total of 46 chromosomes.
A somatic cell is a diploid cell so it will have 22 pairs of autosomes and one pair of sex chromosomes for a total of 46 chromosomes.
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If an autosomal trait skips a generation, it ___________; however, if an autosomal trait does not skip a generation, it ___________.
If an autosomal trait skips a generation, it ___________; however, if an autosomal trait does not skip a generation, it ___________.
If an autosomal trait skips a generation, it must be recessive; however, if an autosomal trait does not skip a generation, it can be either recessive or dominant.
These concepts can be easily seen when outlined via a pedigree analysis. A dominant trait cannot skip a generation; any presence of the allele will lead to expression, thus if the trait is not expressed in a given generation, it cannot be passed down (cannot skip). A recessive allele can be masked by carriers and reappear in a later generation.
If an autosomal trait skips a generation, it must be recessive; however, if an autosomal trait does not skip a generation, it can be either recessive or dominant.
These concepts can be easily seen when outlined via a pedigree analysis. A dominant trait cannot skip a generation; any presence of the allele will lead to expression, thus if the trait is not expressed in a given generation, it cannot be passed down (cannot skip). A recessive allele can be masked by carriers and reappear in a later generation.
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Which of the following statements about X-linked traits is true?
Which of the following statements about X-linked traits is true?
Because males only have one X chromosome, while females have two, they are more likely to be affected by a problematic X chromosome. Females can mask recessive X-linked alleles as carriers; males will express all alleles on their singular X chromosome.
Males only pass on a Y chromosome to their sons, so it is impossible for them to pass an X-linked trait to a son. Furthermore, Y chromosomes are virtually free of contributing to inheritance-linked diseases.
Because males only have one X chromosome, while females have two, they are more likely to be affected by a problematic X chromosome. Females can mask recessive X-linked alleles as carriers; males will express all alleles on their singular X chromosome.
Males only pass on a Y chromosome to their sons, so it is impossible for them to pass an X-linked trait to a son. Furthermore, Y chromosomes are virtually free of contributing to inheritance-linked diseases.
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A man with a sex-linked disorder for color-blindness and a woman with a normal genotype have two children. What is the probability that both of them will be carriers?
A man with a sex-linked disorder for color-blindness and a woman with a normal genotype have two children. What is the probability that both of them will be carriers?
The man's genotype can be written as 
, where 
represents the allele with the disorder. The woman, who has a normal genotype, is therefore 
.
Their possible children are represented by the Punnett square shown here:
Any sons will inherit the 
chromosome from the father and an unaffected 
from their moth. Any daughters will inherit 
chromosomes from both parents. By necessity, all daughters will inherit an normal 
from the mother and an affected 
from the father. All of the couple's daughters will be carriers, while all of their sons will be phenotypically normal; therefore, there is a 50% chance that their child will be a carrier.
For two children, the probability is 
.
The man's genotype can be written as
Their possible children are represented by the Punnett square shown here:
Any sons will inherit the
For two children, the probability is
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Colorblindness is a recessive X-linked disorder. A genotypically normal man and a colorblind woman have two sons and one daughter. What is the probability that one son is colorblind and the other two children are phenotypically normal?
Colorblindness is a recessive X-linked disorder. A genotypically normal man and a colorblind woman have two sons and one daughter. What is the probability that one son is colorblind and the other two children are phenotypically normal?
The Punnett square below represents the couple's possible offspring, with the mother having genotype 
and the father having genotype 
.
Since the disorder is X-linked, we know that any sons will necessarily inherit an affected allele from the mother. Any daughters will inherit an 
chromosome from each parent; by necessity, any daughters will be heterozygous carriers. The probability of any daughters being phenotypically normal is 100%, and the probability of any sons being colorblind is also 100%.
The question states that the couple had two sons and one daughter, and asks the probability that one son is colorblind, one son is normal, and one daughter is colorblind. These probabilities are 100%, 0%, and 100%, respectively.
There is a 0% chance that this combination of children is possible.
The Punnett square below represents the couple's possible offspring, with the mother having genotype
Since the disorder is X-linked, we know that any sons will necessarily inherit an affected allele from the mother. Any daughters will inherit an
The question states that the couple had two sons and one daughter, and asks the probability that one son is colorblind, one son is normal, and one daughter is colorblind. These probabilities are 100%, 0%, and 100%, respectively.
There is a 0% chance that this combination of children is possible.
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Scientists have characterized a new genetic disorder that only affects males. What is the most likely explanation of how this disorder is passed from generation to generation?
Scientists have characterized a new genetic disorder that only affects males. What is the most likely explanation of how this disorder is passed from generation to generation?
If only males display the disorder, it is most likely a Y-linked genetic disorder. The only possible way to inherit this disease, then, would be through the inheritance of the father's Y-chromosome.
Women have two X-chromosomes, one from each parent, and could not possibly pass down the disorder.
Epigenetic inheritance could potentially explain a genetic disorder, but, if this were the case, it should not differentiate between males and females. Abnormal testosterone levels may be a result of the disorder, but they do no explain how the disorder is inherited.
If only males display the disorder, it is most likely a Y-linked genetic disorder. The only possible way to inherit this disease, then, would be through the inheritance of the father's Y-chromosome.
Women have two X-chromosomes, one from each parent, and could not possibly pass down the disorder.
Epigenetic inheritance could potentially explain a genetic disorder, but, if this were the case, it should not differentiate between males and females. Abnormal testosterone levels may be a result of the disorder, but they do no explain how the disorder is inherited.
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A human haploid cell will have how many chromosomes?
A human haploid cell will have how many chromosomes?
A haploid cell has only one set of chromosomes as compared to the two sets normally found in diploid cells. In a haploid cell there are 22 autosomes and 1 sex chromosome for a total of 23 chromosomes.
A haploid cell has only one set of chromosomes as compared to the two sets normally found in diploid cells. In a haploid cell there are 22 autosomes and 1 sex chromosome for a total of 23 chromosomes.
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Individuals with Klinefelter syndrome are phenotypically male, but experience reduced sperm production and breast development in adolescence. Klinefelter individuals have two X-chromosomes and one Y-chromosome (they are XXY instead of XY). What meiotic error gives rise to this condition?
Individuals with Klinefelter syndrome are phenotypically male, but experience reduced sperm production and breast development in adolescence. Klinefelter individuals have two X-chromosomes and one Y-chromosome (they are XXY instead of XY). What meiotic error gives rise to this condition?
Aneuploidy is a chromosomal condition in which there are an abnormal number of chromosomes in the cells of the body. Aneuploidy typically refers to monosomy (one chromosome copy) or trisomy (three chromosome copies), and arises due to nondisjunction during meiosis and gametogenesis. Nondisjuction causes one daughter cell to receive three or four chromatids, and the other to receive one or zero. If this gamete is used to form a zygote, all cells in the resulting offspring will carry the abnormal chromosome number.
Translocation occurs when chromosomal fragments join non-homologous chromosomes. Polyploidy is a condition in which a cell has more than two complete chromosomal sets; in this example, only one set of chromosomes carries three copies. Duplication is the presence of additional segments within a single chromosome.
Aneuploidy is a chromosomal condition in which there are an abnormal number of chromosomes in the cells of the body. Aneuploidy typically refers to monosomy (one chromosome copy) or trisomy (three chromosome copies), and arises due to nondisjunction during meiosis and gametogenesis. Nondisjuction causes one daughter cell to receive three or four chromatids, and the other to receive one or zero. If this gamete is used to form a zygote, all cells in the resulting offspring will carry the abnormal chromosome number.
Translocation occurs when chromosomal fragments join non-homologous chromosomes. Polyploidy is a condition in which a cell has more than two complete chromosomal sets; in this example, only one set of chromosomes carries three copies. Duplication is the presence of additional segments within a single chromosome.
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Red-green colorblindness is an X-linked recessive disorder. Which of the following scenarios is not a possible method by which this disorder can be inherited?
Red-green colorblindness is an X-linked recessive disorder. Which of the following scenarios is not a possible method by which this disorder can be inherited?
X-linked disorders are inherited when a parent passes on his or her X-chromosome. Since females have two X-chromosomes, they are less likely to exhibit symptoms of a recessive disorder than males, who have only one. Females are capable of carrying a recessive X-linked trait without expressing it, while males are not. A male must inherit his Y-chromosome from the father and an X-chromosome from the mother, while a female must inherit X-chromosomes from both parents.
If a genotypically healthy mother and a colorblind father have a son, then this child must inherit an X-chromosome from the mother and a Y-chromosome from the father. The mother's chromosome are both genotypically normal, and do not possess the colorblind allele. This means that the son cannot possibly inherit a colorblind allele if the mother is genotypically normal.
All other presented answer represent scenarios that are possible.
X-linked disorders are inherited when a parent passes on his or her X-chromosome. Since females have two X-chromosomes, they are less likely to exhibit symptoms of a recessive disorder than males, who have only one. Females are capable of carrying a recessive X-linked trait without expressing it, while males are not. A male must inherit his Y-chromosome from the father and an X-chromosome from the mother, while a female must inherit X-chromosomes from both parents.
If a genotypically healthy mother and a colorblind father have a son, then this child must inherit an X-chromosome from the mother and a Y-chromosome from the father. The mother's chromosome are both genotypically normal, and do not possess the colorblind allele. This means that the son cannot possibly inherit a colorblind allele if the mother is genotypically normal.
All other presented answer represent scenarios that are possible.
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In flies, red eyes is a wildtype trait with the allele 
. This gene is found on the X-chromosome.
A wild type parent and a white-eyed parent are crossed. 50% of daughters have white eyes and 50% of sons have white eyes.
What are the genotypes of the parents?
In flies, red eyes is a wildtype trait with the allele
A wild type parent and a white-eyed parent are crossed. 50% of daughters have white eyes and 50% of sons have white eyes.
What are the genotypes of the parents?
We know that red eyes are the dominant allele, which means white eyes are the recessive allele. Both sexes of offspring present the recessive allele. It is especially important to note that the daughters can express the recessive allele. This means that they must have inherited one recessive allele from each parent, while the sons must have inherited the recessive allele from the mother (they inherit the Y-chromosome from the father).
White-eye daughters: 
White-eye sons: 
Each parent must have at least one recessive, white-eye allele. Since the father has only one X-chromosome, this chromosome must carry the white eye allele. We know that they father must have white eyes.
Father: 
Since one parent has white eyes and the other has red eyes, we know the mother must have red eyes. She also carries the recessive allele, meaning that she is heterozygous.
Mother: 
From this cross, we are able to get the percentages reported in the question. 50% of daughters will have red eyes and 50% will have white. The same percentages will be seen for the sons.
We know that red eyes are the dominant allele, which means white eyes are the recessive allele. Both sexes of offspring present the recessive allele. It is especially important to note that the daughters can express the recessive allele. This means that they must have inherited one recessive allele from each parent, while the sons must have inherited the recessive allele from the mother (they inherit the Y-chromosome from the father).
White-eye daughters:
White-eye sons:
Each parent must have at least one recessive, white-eye allele. Since the father has only one X-chromosome, this chromosome must carry the white eye allele. We know that they father must have white eyes.
Father:
Since one parent has white eyes and the other has red eyes, we know the mother must have red eyes. She also carries the recessive allele, meaning that she is heterozygous.
Mother:
From this cross, we are able to get the percentages reported in the question. 50% of daughters will have red eyes and 50% will have white. The same percentages will be seen for the sons.
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Genes that are on the same chromosome are called __________.
Genes that are on the same chromosome are called __________.
Linked genes are found on the same chromosome, and do not always separate according to independent assortment. Alleles are different versions of a gene. Codominance is a mode of inheritance in which both alleles, if present, are fully expressed.
Linked genes are found on the same chromosome, and do not always separate according to independent assortment. Alleles are different versions of a gene. Codominance is a mode of inheritance in which both alleles, if present, are fully expressed.
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What is the name for a genome that contains an abnormal number of chromosomes?
What is the name for a genome that contains an abnormal number of chromosomes?
If cell division occurs incorrectly, and the resulting cell contains an abnormal number of chromosomes, that cell is considered to be aneuploid. Polyploidy is the presence of an entire extra copy of the genome in a cell. Euploid (true ploid) refers to a cell with the correct number of chromosomes.
If cell division occurs incorrectly, and the resulting cell contains an abnormal number of chromosomes, that cell is considered to be aneuploid. Polyploidy is the presence of an entire extra copy of the genome in a cell. Euploid (true ploid) refers to a cell with the correct number of chromosomes.
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A man has a copy of an X-linked dominant trait. Is it possible for his son to also possess the trait?
A man has a copy of an X-linked dominant trait. Is it possible for his son to also possess the trait?
Although X-linked dominant traits tend to be rare, it is certainly possible that the boy would inherit it from an affected mother. A father only gives a Y chromosome to his sons. This means that the boy could not inherit the X-linked dominant trait from his father.
Although X-linked dominant traits tend to be rare, it is certainly possible that the boy would inherit it from an affected mother. A father only gives a Y chromosome to his sons. This means that the boy could not inherit the X-linked dominant trait from his father.
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When two human haploid cells fuse together the resulting cell will have how many chromosomes?
When two human haploid cells fuse together the resulting cell will have how many chromosomes?
Haploid cells have 23 chromosomes each (22 autosomes and 1 sex chromosome) so when they fuse the resulting cell will have 46 chromosomes (44 autosomes and 2 sex chromosomes). This idea is demonstrated during fertilization, where two haploid cells (gametes) fuse to form the zygote, which is diploid.
Haploid cells have 23 chromosomes each (22 autosomes and 1 sex chromosome) so when they fuse the resulting cell will have 46 chromosomes (44 autosomes and 2 sex chromosomes). This idea is demonstrated during fertilization, where two haploid cells (gametes) fuse to form the zygote, which is diploid.
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