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Studied by 22 peopleNoteStudied by 25 peopleNoteStudied by 11 peopleNoteStudied by 8 peopleNoteStudied by 41 peopleNoteStudied by 65 people
Chapter 14: Human Heredity
14.1 Human Chromosomes
Karyotypes
A genome is the entire set of genetic information that an organism carries in its DNA
To see human chromosomes clearly, cell biologists take pictures of cells during mitosis, when the chromosomes are condensed and can be seen clearly
Scientists then cut out the chromosomes from the photographs and arrange the chromosome images into a picture known as a karyotype
A karyotype shows the complete diploid set of chromosomes
They are lined up together in pairs and arranged from largest to smallest
A typical human cell has 46 chromosomes, arranged in 23 pairs
Two of the 46 chromosomes in the human genome are known as sex chromosomes because they determine an individual’s sex
Females have two copies of the X chromosome and males have one X chromosome and one Y chromosome
The other 44 are autosomal chromosomes, or autosomes
Most of the genetic information in the cell is on the autosomes
Transmission of Human Traits
Many human traits follow a pattern of simple dominance
Some alleles for human genes are codominant
One example is the ABO blood group, the set of alleles that determines your blood type
The genes located on X and Y chromosomes show a pattern of inheritance called sex-linkage; a sex-linked gene is a gene on a sex chromosome
Only males have the genes on the Y chromosome; since only males have a Y chromosome, boys inherit it from their fathers
The X chromosome comes from their mother; the fact that males have only one X chromosome can cause genetic problems
A cell only needs one X chromosome to function normally
Female cells adjust to having two X chromosomes by randomly inactivating genes on one of them
The inactive chromosome makes a dense area in the nucleus called a Barr body
Human Pedigrees
A pedigree is a chart that shows the presence or absence of a trait according to the relationships within a family across several generations
A shaded circle or square indicates that a person expresses the trait
A horizontal line connecting a male and a female represents a marriage
A circle represents a female
A square represents a male
A vertical line and a bracket connect the parents to their children
A circle or square that is not shaded indicates that a person does not express the trait
We can often use a pedigree to figure out the genotypes of family members
The information learned from pedigrees helps determine the nature of genes and alleles associated with inherited human traits
14.2 Human Genetic Disorders
From Molecule to Phenotype
Genotype and phenotype are directly connected since changes in a gene’s DNA sequence can change proteins
Changes in a gene’s DNA sequence can change proteins by altering their amino acid sequences and may directly affect a person’s phenotype
Sickle-cell disease is caused by a flawed allele for a polypeptide in hemoglobin, the oxygen-carrying protein in red blood cells
Huntington’s disease is caused by a dominant allele for a protein found in brain cells; the allele for this disease has a long string of bases in which the codon CAG (which codes for the amino acid glutamine) repeats over and over again, more than 40 times
It is unknown why this long string of glutamine causes the disease
Cystic Fibrosis is usually caused by the deletion of three bases in the DNA of a single gene, causing the body not to make normal CFTR (a protein needed to transport chloride ions)
Diseases such as sickle cell disease and CF are still common in human populations, even though the alleles for these diseases can kill those who have them; sometimes having just one recessive allele can be an advantage
For example, people with one copy of the sickle cell allele are resistant to the parasite that causes malaria
People with a single CF allele were less likely to die from typhoid
Typhoid is caused by a bacterium that enters the body through cells in the digestive system; the protein made by the CF allele helps block this bacterium from entering the cells
Chromosomal Disorders
The most common error in meiosis occurs when homologous chromosomes do not separate, a mistake called nondisjunction
If nondisjunction occurs during meiosis, gametes may receive an abnormal number of chromosomes, a change that can lead to a disorder of chromosome numbers
If two copies of an autosomal chromosome fail to separate during meiosis, an individual may be born with three copies of that chromosome, a condition known as a trisomy
Nondisjunction of sex chromosomes also causes problems
A female who inherits only one X chromosome usually has Turner’s syndrome
A male with an extra X chromosome has Klinefelter’s syndrome
14.3 Studying the Human Genome
Manipulating DNA
Scientists study DNA by using tools that cut, separate, and then replicate DNA base by base; now they can read the base sequences in DNA from any cell
To study DNA, scientists first cut it into smaller pieces using bacterial enzymes called restriction enzymes, which cut a DNA molecule into exact pieces called restriction fragments
After DNA is cut, scientists use a technique called gel electrophoresis, a procedure used to analyze DNA fragments by placing a mixture of DNA fragments at one end of a porous gel and applying an electrical voltage to the gel
After the DNA fragments have been separated, researchers read, or sequence, the DNA
The Human Genome Project
The Human Genome Project had two main goals: to sequence all 3 billion base pairs of human DNA and to identify all human genes
First, scientists break up the whole genome into smaller pieces
Next, they determine the base sequences in regions of a DNA strand that are far apart
Using the markers, researchers can find and return to specific places in the DNA
Once researchers have marked the DNA strands, they cut them into random fragments and determine the base sequence of each fragment
Computer programs put the fragments in order using the markers in a method referred to as “shotgun sequencing”
The Human Genome Project was completed in 2003
One of the key research areas of the project was a new field called bioinformatics, the application of mathematics and computer science to store, retrieve, and analyze biological data
Bioinformatics also began a similar field of study known as genomics—the study of whole genomes including genes and their functions
Overall, the Human Genome Project pinpointed genes and matched some sequences in those genes with many diseases and disorders; it also identified about three million places where single-base DNA differences occur in humans
Chapter 14: Human Heredity
14.1 Human Chromosomes
Karyotypes
A genome is the entire set of genetic information that an organism carries in its DNA
To see human chromosomes clearly, cell biologists take pictures of cells during mitosis, when the chromosomes are condensed and can be seen clearly
Scientists then cut out the chromosomes from the photographs and arrange the chromosome images into a picture known as a karyotype
A karyotype shows the complete diploid set of chromosomes
They are lined up together in pairs and arranged from largest to smallest
A typical human cell has 46 chromosomes, arranged in 23 pairs
Two of the 46 chromosomes in the human genome are known as sex chromosomes because they determine an individual’s sex
Females have two copies of the X chromosome and males have one X chromosome and one Y chromosome
The other 44 are autosomal chromosomes, or autosomes
Most of the genetic information in the cell is on the autosomes
Transmission of Human Traits
Many human traits follow a pattern of simple dominance
Some alleles for human genes are codominant
One example is the ABO blood group, the set of alleles that determines your blood type
The genes located on X and Y chromosomes show a pattern of inheritance called sex-linkage; a sex-linked gene is a gene on a sex chromosome
Only males have the genes on the Y chromosome; since only males have a Y chromosome, boys inherit it from their fathers
The X chromosome comes from their mother; the fact that males have only one X chromosome can cause genetic problems
A cell only needs one X chromosome to function normally
Female cells adjust to having two X chromosomes by randomly inactivating genes on one of them
The inactive chromosome makes a dense area in the nucleus called a Barr body
Human Pedigrees
A pedigree is a chart that shows the presence or absence of a trait according to the relationships within a family across several generations
A shaded circle or square indicates that a person expresses the trait
A horizontal line connecting a male and a female represents a marriage
A circle represents a female
A square represents a male
A vertical line and a bracket connect the parents to their children
A circle or square that is not shaded indicates that a person does not express the trait
We can often use a pedigree to figure out the genotypes of family members
The information learned from pedigrees helps determine the nature of genes and alleles associated with inherited human traits
14.2 Human Genetic Disorders
From Molecule to Phenotype
Genotype and phenotype are directly connected since changes in a gene’s DNA sequence can change proteins
Changes in a gene’s DNA sequence can change proteins by altering their amino acid sequences and may directly affect a person’s phenotype
Sickle-cell disease is caused by a flawed allele for a polypeptide in hemoglobin, the oxygen-carrying protein in red blood cells
Huntington’s disease is caused by a dominant allele for a protein found in brain cells; the allele for this disease has a long string of bases in which the codon CAG (which codes for the amino acid glutamine) repeats over and over again, more than 40 times
It is unknown why this long string of glutamine causes the disease
Cystic Fibrosis is usually caused by the deletion of three bases in the DNA of a single gene, causing the body not to make normal CFTR (a protein needed to transport chloride ions)
Diseases such as sickle cell disease and CF are still common in human populations, even though the alleles for these diseases can kill those who have them; sometimes having just one recessive allele can be an advantage
For example, people with one copy of the sickle cell allele are resistant to the parasite that causes malaria
People with a single CF allele were less likely to die from typhoid
Typhoid is caused by a bacterium that enters the body through cells in the digestive system; the protein made by the CF allele helps block this bacterium from entering the cells
Chromosomal Disorders
The most common error in meiosis occurs when homologous chromosomes do not separate, a mistake called nondisjunction
If nondisjunction occurs during meiosis, gametes may receive an abnormal number of chromosomes, a change that can lead to a disorder of chromosome numbers
If two copies of an autosomal chromosome fail to separate during meiosis, an individual may be born with three copies of that chromosome, a condition known as a trisomy
Nondisjunction of sex chromosomes also causes problems
A female who inherits only one X chromosome usually has Turner’s syndrome
A male with an extra X chromosome has Klinefelter’s syndrome
14.3 Studying the Human Genome
Manipulating DNA
Scientists study DNA by using tools that cut, separate, and then replicate DNA base by base; now they can read the base sequences in DNA from any cell
To study DNA, scientists first cut it into smaller pieces using bacterial enzymes called restriction enzymes, which cut a DNA molecule into exact pieces called restriction fragments
After DNA is cut, scientists use a technique called gel electrophoresis, a procedure used to analyze DNA fragments by placing a mixture of DNA fragments at one end of a porous gel and applying an electrical voltage to the gel
After the DNA fragments have been separated, researchers read, or sequence, the DNA
The Human Genome Project
The Human Genome Project had two main goals: to sequence all 3 billion base pairs of human DNA and to identify all human genes
First, scientists break up the whole genome into smaller pieces
Next, they determine the base sequences in regions of a DNA strand that are far apart
Using the markers, researchers can find and return to specific places in the DNA
Once researchers have marked the DNA strands, they cut them into random fragments and determine the base sequence of each fragment
Computer programs put the fragments in order using the markers in a method referred to as “shotgun sequencing”
The Human Genome Project was completed in 2003
One of the key research areas of the project was a new field called bioinformatics, the application of mathematics and computer science to store, retrieve, and analyze biological data
Bioinformatics also began a similar field of study known as genomics—the study of whole genomes including genes and their functions
Overall, the Human Genome Project pinpointed genes and matched some sequences in those genes with many diseases and disorders; it also identified about three million places where single-base DNA differences occur in humans
NoteStudied by 22 peopleNoteStudied by 25 peopleNoteStudied by 11 peopleNoteStudied by 8 peopleNoteStudied by 41 peopleNoteStudied by 65 people