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Understanding Dominant and Recessive Genes: An Introduction to Inheritance Patterns, Lecture notes of Genetics

An overview of dominant and recessive traits, genes, alleles, and the law of dominance. It explains how an organism receives two genes for each trait, one from each parent, and how one gene may be stronger (dominant) and mask the other (recessive). The text also covers pure and hybrid traits, and includes activities and exercises for better understanding.

What you will learn

  • What is the difference between a dominant and recessive gene?
  • What happens when an organism receives two different alleles for a trait?
  • How does the Law of Dominance explain the inheritance of traits?

Typology: Lecture notes

2021/2022

Uploaded on 09/27/2022

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What Are Dominant and Recessive Traits?
Patterns of Inheritance
What traits have you inherited? Every living thing is a collection of traits that have been passed down
to them by their parents. These traits are controlled by something called genes. Genes are made up of DNA
and are located on the chromosomes. When pairs of chromosomes separate into sex cells during a process
called meiosis, pairs of genes also separate from one another. As a result, each sex cell winds up with one
form of a gene for each trait the organism shows. If the trait is for hairlines, then the gene in one sex cell may
control one form of the trait, such as common baldness—an “m-shaped” hairline. The gene for hairlines in the
other sex cell may control another form of the trait, such as a straight hairline. The different forms a gene may
have for a trait are called alleles (uh LEELZ). An allele is one pair of genes that can appear as alternatives in
heredity, and they are located on equivalent portions of chromosomes. Most cells in our bodies have two
alleles for every trait.
Two Genes for the Trait Determine Inheritance
Gregor Mendel, the father of genetics who studied the inherited traits of pea plants, noticed that
genes (hereditary factors) always came in pairs. Every organism that reproduces sexually receives two genes
for each trait; they receive one gene from each parent. Mendel noticed, however, that the genes were not
always equal. He wondered why some traits found in the parents showed up in their offspring, while other
traits did not. To find the answer, he experimented with pea plants. These experiments led to the principal of
genetics called the Law of Dominance.
The Law of Dominance states:
An organism receives two genes for each trait, one from each parent
One of the genes may be stronger; the trait of the stronger gene shows up and is called the dominant
gene. The trait of the weaker gene is “hidden’’ or does not show up and is called the recessive gene.
The trait that was always visible in the offspring was considered to be the stronger of the two. If the trait
always showed up in the offspring, he called that gene the dominant gene for that particular trait. The other
gene, weaker and usually hidden by the stronger gene, was called the recessive gene for that trait. If an
offspring receives two of the same genes (either two dominant genes or two recessive genes) the offspring will
inherit or have that trait. There are no other possibilities. An organism with two alleles for a trait that are
exactly the same is called homozygous (HO muh Zi gus). An organism with two different alleles for a trait is
called heterozygous (HET uh roh Zi gus).
Pure Traits
Pure traits can be either recessive or dominant. Pure traits may have two dominant genes or two
recessive genes. For example, a pea plant may have two genes for tallness, which is dominant trait in pea
plants. This plant is homozygous plant with a pure dominant trait for tallness. All of the offspring from this
plant will be tall. A pea plant with two genes for shortness is also a pure organism. However, shortness in pea
plants is a recessive trait. This plant is a homozygous plant with a pure recessive trait for height. The offspring
from this plant will be short if it pollinates with another plant that has two genes for shortness. If this plant
pollinates with a tall pea plant, the tall dominant gene will mask or cover up the recessive gene for shortness.
Both plants are homozygous or pure plants; one is a pure dominant pea plant, the other is a pure recessive pea
plant.
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What Are Dominant and Recessive Traits?

Patterns of Inheritance What traits have you inherited? Every living thing is a collection of traits that have been passed down to them by their parents. These traits are controlled by something called genes. Genes are made up of DNA and are located on the chromosomes. When pairs of chromosomes separate into sex cells during a process called meiosis, pairs of genes also separate from one another. As a result, each sex cell winds up with one form of a gene for each trait the organism shows. If the trait is for hairlines, then the gene in one sex cell may control one form of the trait, such as common baldness—an “m-shaped” hairline. The gene for hairlines in the other sex cell may control another form of the trait, such as a straight hairline. The different forms a gene may have for a trait are called alleles (uh LEELZ). An allele is one pair of genes that can appear as alternatives in heredity, and they are located on equivalent portions of chromosomes. Most cells in our bodies have two alleles for every trait.

Two Genes for the Trait Determine Inheritance Gregor Mendel, the father of genetics who studied the inherited traits of pea plants, noticed that genes (hereditary factors) always came in pairs. Every organism that reproduces sexually receives two genes for each trait; they receive one gene from each parent. Mendel noticed, however, that the genes were not always equal. He wondered why some traits found in the parents showed up in their offspring, while other traits did not. To find the answer, he experimented with pea plants. These experiments led to the principal of genetics called the Law of Dominance.

The Law of Dominance states:

An organism receives two genes for each trait, one from each parent One of the genes may be stronger; the trait of the stronger gene shows up and is called the dominant gene. The trait of the weaker gene is “hidden’’ or does not show up and is called the recessive gene. The trait that was always visible in the offspring was considered to be the stronger of the two. If the trait always showed up in the offspring, he called that gene the dominant gene for that particular trait. The other gene, weaker and usually hidden by the stronger gene, was called the recessive gene for that trait. If an offspring receives two of the same genes (either two dominant genes or two recessive genes) the offspring will inherit or have that trait. There are no other possibilities. An organism with two alleles for a trait that are exactly the same is called homozygous (HO muh Zi gus). An organism with two different alleles for a trait is called heterozygous (HET uh roh Zi gus).

Pure Traits Pure traits can be either recessive or dominant. Pure traits may have two dominant genes or two recessive genes. For example, a pea plant may have two genes for tallness, which is dominant trait in pea plants. This plant is homozygous plant with a pure dominant trait for tallness. All of the offspring from this plant will be tall. A pea plant with two genes for shortness is also a pure organism. However, shortness in pea plants is a recessive trait. This plant is a homozygous plant with a pure recessive trait for height. The offspring from this plant will be short if it pollinates with another plant that has two genes for shortness. If this plant pollinates with a tall pea plant, the tall dominant gene will mask or cover up the recessive gene for shortness. Both plants are homozygous or pure plants; one is a pure dominant pea plant, the other is a pure recessive pea plant.

Hybrid Traits Organisms that have two unlike genes for a certain trait are called hybrid. A pea plant with one recessive gene for shortness and one dominant gene for tallness is a hybrid for that trait. A hybrid is called heterozygous, as it has two different alleles. The offspring from a pure tall pea plant, cross-pollinated with a pure short pea plant, will result in a heterozygous plant for tallness. No organism has all dominant or all recessive genes. An organism may be pure in certain traits and hybrid others. Remember, that a dominant trait in one kind of organism may be a recessive trait in another organism.

Homozygous Traits

Heterozygous Traits

Human genetics is very difficult to study, because the life span of humans is so long compared to the life span of other animals and plants. As a result, scientists cannot study all of the offspring produced in many generations of one family. Another difficulty in the study of human genetics is the number of offspring. Humans produce fewer offspring than other animals and plants. It is difficult to compare traits with fewer offspring to observe. Scientists use what they learn from studying other animals and plants to learn more about human genetics. How many of the traits in the table below do you recognize in yourself?

Dominant Recessive Brown eyes Blue eyes Curly hair Straight hair Freckles No freckles Nearsighted eyes Normal eyes Long eyelashes Short eyelashes Detached earlobes Attached earlobes Dimples No dimples Widow’s peak hairline Straight hairline

Predicting Human Traits Use the information in the table above to predict offspring traits in the chart below. The first example is done for you.

Mother Father Offspring

Dominant / Recessive Hybrid / Pure

  1. Normal eyesight Nearsighted Nearsighted Dominant Hybrid
  2. Straight hair Straight hair
  3. Freckles Freckles
  4. Long lashes Short lashes
  5. No dimples Dimples
  6. Detached lobes Detached lobes
  7. blue eyes Brown eyes
  8. Widow’s peak Straight hairline