DP IB Biology: HL

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IBBiology: HLDPRevision Notes10. Genetics & Evolution (HL Only)10.2 Inheritance10.2.1 Unlinked Genes

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First teaching 2014

Last exams 2024

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10.2.1 Unlinked Genes

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Independent Assortment & Segregation


Unlinked genes segregate independently as a result of meiosis

  • Unlinked genes are genes that an organism carries on separate chromosomes
    • Not on homologous copies of the same chromosome
  • An example of a pair of unlinked genes in fruit flies (Drosophila melanogaster) is
    • The gene for curly wings on chromosome 2, and
    • The gene for mahogany eyes on chromosome 3
  • An example of a pair of unlinked genes in humans is
    • The gene for trypsin (a stomach enzyme) on chromosome 7, and
    • The gene for human growth hormone on chromosome 17
  • Assortment of chromosomes refers to their alignment in metaphase I of meiosis
    • Each bivalent assorts (aligns) itself independently of all the others
  • Segregation of chromosomes (ie. how they get separated) is governed by their pattern of assortment
    • Segregation just refers to which pole of the cell the whole chromosomes are pulled to in anaphase I
    • Segregation determines which combinations of alleles end up in which gamete cells by the end of meiosis II
  • By contrast, linked genes (on the same chromosome) tend to be inherited together

the-loci-of-selected-genes-in-the-human-genome

The loci of selected genes in the human genome

Trypsin and CFTR are linked genes (both on the same chromosome);

Human Growth Hormone and trypsin are unlinked genes (both on different chromosomes)

Punnett Squares for Dihybrid Traits

  • Monohybrid crosses look at how the alleles of one gene transfer across generations
  • Dihybrid crosses look at how the alleles of two genes transfer across generations
    • ie. dihybrid crosses can be used to show the inheritance of two completely different characteristics in an individual
  • The genetic diagrams for both types of cross are very similar
  • For dihybrid crosses, there are several more genotypes and phenotypes involved
  • When writing out the different genotypes, write the two alleles for one gene, followed immediately by the two alleles for the other gene.
  • Do not mix up the alleles from the different genes
    • For example, if there was a gene with alleles Y and y and another gene with alleles G and g an example genotype for an individual would be YyGg
  • Alleles are usually shown side by side in dihybrid crosses e.g. TtBb

Worked example

Worked example 1: Dihybrid genetic diagram

  • Horses have a single gene for coat colour that has two alleles:
    • B, a dominant allele produces a black coat
    • b, a recessive allele produces a chestnut coat
  • Horses also have a single gene for eye colour
    • E, a dominant allele produces brown eyes
    • e, a recessive allele produces blue eyes
  • Each of these genes (consisting of a pair of alleles) are inherited independently of one another because the two genes are located on different non-homologous chromosomes
    • Such characteristics are said to be unlinked
  • In this example, a horse that is heterozygous for both genes has been crossed with a horse that is homozygous for one gene and heterozygous for the other
Parental phenotypes: black coat, brown eyes x chestnut coat, brown eyes
Parental genotypes: BbEe x  bbEe
Parental gametes: BE or Be or bE or be x bE or be

determining-gamete-alleles-from-parental-genotypesdetermining-gamete-alleles-from-parental-genotypes

Determining the Alleles Carried by Gametes Based on the Parental Genotypes Using the FOIL (First, Outside, Inside, Last) Method

Dihybrid Cross Punnett Square Table
Dihybrid Cross Punnett Square Table

  • Predicted ratio of phenotypes in offspring =
    • 3 black coat, brown eyes :
    • 3 chestnut coat, brown eyes :
    • 1 black coat, blue eyes :
    • 1 chestnut coat, blue eyes
  • Predicted ratio of genotypes in offspring = 3 BbEE : 3 bbEE : 1 Bbee : 1 bbee

Worked example

Worked example 2: Dihybrid genetic diagram

In a separate cross to that shown in Worked Example 1, a horse that is heterozygous for both genes has been crossed with another horse that is heterozygous for both genes.

Parental phenotypes: black coat, brown eyes x black coat, brown eyes
Parental genotypes: BbEe x  BbEe
Parental gametes: BE or Be or bE or be x BE or Be or bE or be
Dihybrid Cross Punnett Square Table 2

dihybrid-cross-punnett-square-table-unlinked-genes-ib-

  • Predicted ratio of phenotypes in offspring =
    • 9 black coat, brown eyes :
    • 3 chestnut coat, brown eyes :
    • 3 black coat, blue eyes :
    • 1 chestnut coat, blue eyes

Exam Tip

For the double-heterozygous cross for unlinked genes above, you're expected to remember the phenotypic ratio 9:3:3:1. You won't need to remember the ratio of the genotypes but this can be worked out from a Punnett square like the one above.

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