Inheritance: definitions
Inheritance is the transmission of genetic information from one generation to the next generation
A gene is a short length of DNA found on a chromosome that codes for a particular characteristic (expressed by the formation of different proteins)
Alleles are variations of the same gene
As we have two copies of each chromosome, we have two copies of each gene and therefore two alleles for each gene
One of the alleles is inherited from the mother and the other from the father
This means that the alleles do not have to ‘say’ the same thing
For example, an individual has two copies of the gene for eye colour but one allele could code for brown eyes and one allele could code for blue eyes
The observable characteristics of an organism (seen just by looking - like eye colour, or found – like blood type) is called the phenotype
The combination of alleles that control each characteristic is called the genotype
Alleles can be dominant or recessive
A dominant allele only needs to be inherited from one parent in order for the characteristic to show up in the phenotype
A recessive allele needs to be inherited from both parents in order for the characteristic to show up in the phenotype.
If there is only one recessive allele, it will remain hidden and the dominant characteristic will show
If the two alleles of a gene are the same, we describe the individual as being homozygous (homo = same)
An individual could be homozygous dominant (having two copies of the dominant allele), or homozygous recessive (having two copies of the recessive allele)
If the two alleles of a gene are different, we describe the individual as being heterozygous (hetero = different)
When completing genetic diagrams, alleles are abbreviated to single letters
The dominant allele is given a capital letter and the recessive allele is given the same letter, but lower case
We cannot always tell the genotype of an individual for a particular characteristic just by looking at the phenotype – a phenotype associated with a dominant allele will be seen in both a dominant homozygous and a dominant heterozygous genotype
If two individuals who are both identically homozygous for a particular characteristic are bred together, they will produce offspring with exactly the same genotype and phenotype as the parents - we describe them as being ‘pure breeding’ as they will always produce offspring with the same characteristics
A heterozygous individual can pass on different alleles for the same characteristic each time it is bred with any other individual and can therefore produce offspring with a different genotype and phenotype than the parents - as such, heterozygous individuals are not pure breeding
What is monohybrid inheritance?
Monohybrid inheritance is the inheritance of characteristics controlled by a single gene (mono = one)
This can be determined using a genetic diagram known as a Punnett square
A Punnett square diagram shows the possible combinations of alleles that could be produced in the offspring
From this the ratio of these combinations can be worked out
Remember the dominant allele is shown using a capital letter and the recessive allele is shown using the same letter but lower case
Monohybrid Inheritance Example
The height of pea plants is controlled by a single gene that has two alleles: tall and short
The tall allele is dominant and is shown as T
The small allele is recessive and is shown as t
The term ‘pure breeding’ indicates that the individual is homozygous for that characteristic
What is a monohybrid cross?
A monohybrid cross is the genetic mix between two individuals which determines a characteristic controlled by a single gene
A genetic diagram is used to predict the possible outcome of a cross
How to construct Punnett squares
Determine the parental genotypes
Select a letter that has a clearly different lower case, for example: Aa, Bb, Dd
Split the alleles for each parent and add them to the Punnett square around the outside
Fill in the middle four squares of the Punnett square to work out the possible genetic combinations in the offspring
You may be asked to comment on the ratio of different allele combinations in the offspring, calculate a percentage chances of offspring showing a specific characteristic or just determine the phenotypes of the offspring
Completing a Punnett square allows you to predict the probability of different outcomes from monohybrid crosses
Identifying an unknown genotype
Breeders can use a test cross to find out the genotype of an organism showing the dominant phenotype
This involves crossing the unknown individual with an individual showing the recessive phenotype - if the individual is showing the recessive phenotype, then its genotype must be homozygous recessive
By looking at the ratio of phenotypes in the offspring, we can tell whether the unknown individual is homozygous dominant or heterozygous
The short plant is showing the recessive phenotype and so must be homozygous recessive - tt
Determining genotypes from offspring
If the tall plant is homozygous dominant, all offspring produced will be tall
If the tall plant is heterozygous, half the offspring will be tall and the other half will be short
What is the difference between dominant and recessive alleles?
How do you determine the genotype and phenotype ratios in a monohybrid cross?
What is the significance of homozygous and heterozygous genotypes in monohybrid inheritance?
How can you use a test cross to determine an unknown genotype?
What are some examples of traits that follow monohybrid inheritance patterns?
How do mutations affect monohybrid inheritance?