Inheritance

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Angelina

Cards (24)

  • Single Gene Inheritance:
    • Some characteristics are controlled by a single gene, this is called monohybrid inheritance (mono = one)
    • 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 it is possible to have two different alleles for a gene
    • For example, two copies of a particular gene could contribute to eye colour but one allele could code for brown eyes and one allele could code for blue eyes
  • Single Gene Inheritance:
    • The observable characteristics of an organism is called the phenotype
    • For example: eye colour or blood type
    • The combination of alleles that control each characteristic is called the genotype and is usually represented using letters
    • For example: Bb might be a genotype for brown eyes
  • Allele types:
    • Alleles can be
    • Dominant: it only needs to be inherited from one parent in order for the characteristic to show up in the phenotype
    • Recessive: It needs to be inherited from both parents (have 2 copies of in the genotype) 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
  • Allele types:
    • 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
    • The recessive allele is given the same letter, but lower case
  • Alleles can be dominant or recessive:
  • Single Gene Crosses:
    • Monohybrid inheritance can be investigated 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
  • Pea plants:
    • Pea plants were used by the scientist Gregor Mendel to investigate monohybrid inheritance
    • 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
  • A pure breeding short plant is bred with a pure breeding tall plant
    • The term ‘pure breeding’ indicates that the individual is homozygous for that characteristic.
  • A pure-breeding genetic cross in pea plants. It shows that all offspring will have the tall phenotype.
  • A pure-breeding genetic cross in pea plants. It shows that all offspring will have the tall phenotype.
  • Crossing the offspring from the first cross:
  • Crossing the offspring from the first cross:
    • All of the offspring of the first cross have the same genotype, Tt (heterozygous), so the possible combinations of offspring bred from these are: TT (tall), Tt (tall), tt (short)
    • There is more variation in the second cross, with a 3:1 ratio of tall : short
    • The F2 generation is produced when the offspring of the F1 generation (pure-breeding parents) are allowed to interbreed
  • Crossing a heterozygous plant with a short plant:
    • The heterozygous plant will be tall with the genotype Tt
    • The short plant is showing the recessive phenotype and so must be homozygous recessive – tt
    • The results of this cross are as follows:
  • A cross between a heterozygous plant with a short plant:
  • A cross between a heterozygous plant with a short plant:
  • 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 percentage chances of offspring showing a specific characteristic or to determine the phenotypes of the offspring
  • How to construct Punnett squares:
    • Completing a Punnett square allows you to predict the probability of different outcomes from monohybrid crosses
  • Calculating probabilities from Punnett squares:
    • 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
    • However, you can also make predictions of the offsprings’ characteristics by calculating the probabilities of the different phenotypes that could occur
  • Calculating probabilities from Punnett squares:
    • For example, in the second genetic cross (F2 generation) that was given earlier (see above), two plants with the genotype Tt (heterozygous) were bred together
    • The possible combinations of offspring bred from these two parent plants are: TT (tall), Tt (tall), tt (short
    • The offspring penotypes showed a 3:1 ratio of tall : short
    • Using this ratio, we can calculate the probabilities of the offspring phenotypes
    • The probability of an offspring being tall is 75%
    • The probability of an offspring being short is 25%
  • Polygenic Inheritance:
    • Most characteristics are a result of multiple genes interacting, rather than a single gene
    • Characteristics that are controlled by more than one gene are described as being polygenic
    • Polygenic characteristics have phenotype that can show a wide range of combinations in features
    • An example of polygenic inheritance is eye colour – while it is true that brown eyes are dominant to blue eyes, it is not as simple as this as eye colour is controlled by several genes
    • Polygenic Inheritance:
    • This means that there are several different phenotypes beyond brown and blue; green and hazel being two examples
    • The inheritance of these polygenic characteristics is called polygenic inheritance (poly = many/more than one)
    • Polygenic inheritance is difficult to show using genetic diagrams because of the wide range of combinations
  • Sex Chromosomes:
    • Sex is determined by the 23rd pair of chromosomes
    • In females, the sex chromosomes are the same (XX)
    • In males, the sex chromosomes are different (XY)
    • The inheritance of sex can be shown using a genetic diagram (Punnett square), with the X and Y chromosomes taking the place of the alleles usually written in the boxes
  • Inheritance of sex: