In simple terms
A friendly intro before the formal notes — no formulas yet.
Your Genetic Blueprint
Inheritance is how alleles — the alternative versions of a gene — are passed from parents to offspring, and it follows rules predictable enough to be written out as a diagram and counted as a ratio.
Think of each parent as holding a pair of cards for a trait, but able to pass only one card into any egg or sperm. Which of the pair goes in is decided fairly, like the toss of a coin — that is the principle of segregation. The offspring's hand is simply one card from each parent, and a Punnett square is just the tidy way of listing every possible pairing so you can read off how likely each hand is.
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First, write the parents' genotypes using a chosen letter — capital for the dominant allele, the same letter in lower case for the recessive one (for example Pp and pp).
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Next, work out the gametes: because the two alleles segregate, each gamete carries just one allele of the pair. Circle or box each gamete so it is clear.
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Then draw a Punnett square, putting one parent's gametes along the top and the other's down the side, and fill each cell by combining the alleles that meet there.
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Finally, read off and count the offspring genotypes and their phenotypes to state the expected ratios or probabilities.
Explore the concept
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Full topic notes
Formal explanation with the rigour you need for the exam.
The language of inheritance
Genetics has a precise vocabulary, and examiners award — or withhold — marks on exactly these words. A gene is a length of DNA that codes for a characteristic and occupies a fixed position, or locus, on a chromosome. An allele is one of the alternative versions of a gene. Because chromosomes come in pairs, an individual carries two alleles for each gene; that pair is its genotype. A genotype with two identical alleles (PP or pp) is homozygous, and one with two different alleles (Pp) is heterozygous. The phenotype is the observable characteristic the genotype produces. A dominant allele (capital letter) is expressed in the phenotype whenever it is present, even in a heterozygote, while a recessive allele (lower-case letter) is expressed only when homozygous, because a dominant allele masks it. A heterozygote that shows the dominant phenotype but carries a hidden recessive allele for a condition is called a carrier.
Genotype = the pair of alleles carried (e.g. Pp); phenotype = the observable trait (e.g. purple flowers).
Homozygous = two identical alleles (PP or pp); heterozygous = two different alleles (Pp).
Dominant allele (capital) is expressed even in a heterozygote; recessive allele (lower case) needs to be homozygous to show.
A carrier is a heterozygote that hides a recessive allele without showing the condition.
The principle of segregation
Mendel's central insight is the principle of segregation: the two alleles of a gene separate from one another during the formation of gametes, so that each gamete receives only one allele of the pair. Biologically this happens at meiosis, when the members of each homologous pair of chromosomes are pulled into different cells. A homozygous parent (PP or pp) can therefore make only one kind of gamete for that gene, while a heterozygous parent (Pp) makes two kinds — half carrying P and half carrying p — in equal proportion. Fertilisation then brings one allele from each parent together at random, restoring the paired genotype in the offspring. This is why a genetic diagram always shows single alleles in the gametes, never pairs.
Monohybrid crosses and Punnett squares
A monohybrid cross follows the inheritance of a single characteristic. To predict its outcome we lay out a genetic diagram: state and define the allele symbols, write the two parental genotypes, work out the gametes each parent can make (one allele each, by segregation), then combine them in a Punnett square — one parent's gametes along the top, the other's down the side — and fill every cell to list the possible offspring. Reading the completed square gives two ratios: the genotype ratio (how many of each allele combination) and the phenotype ratio (how many show each observable trait). Keep them separate: a Pp × Pp cross gives a genotype ratio of 1 PP : 2 Pp : 1 pp but a phenotype ratio of 3 dominant : 1 recessive, because PP and Pp look the same.
Test crosses
An organism showing a dominant phenotype hides an ambiguity: its genotype could be homozygous (PP) or heterozygous (Pp), and you cannot tell by looking. A test cross resolves this by crossing the individual with a homozygous recessive partner (pp), which can only contribute recessive alleles. If the tested individual is homozygous dominant, all offspring inherit a dominant allele and show the dominant phenotype; if it is heterozygous, about half the offspring are homozygous recessive and show the recessive phenotype. So the appearance of even one recessive offspring proves the parent was heterozygous — the homozygous recessive partner acts as a genetic 'developer' that reveals the hidden allele.
A test cross mates an individual of unknown genotype (dominant phenotype) with a homozygous recessive (pp).
All offspring dominant → the tested parent was most likely homozygous (PP).
Any recessive offspring → the tested parent must have been heterozygous (Pp), and a roughly 1:1 phenotype ratio is expected.
The recessive partner contributes only recessive alleles, so the offspring's phenotypes directly reveal the tested parent's second allele.
Codominance and multiple alleles: the ABO blood groups
Not all alleles show simple dominance. In codominance, both alleles of a heterozygote are expressed fully and separately in the phenotype, so both characteristics appear at once. The standard example is the human ABO blood group system, which also illustrates multiple alleles — a gene with more than two alleles in the population. There are three ABO alleles: and , which produce the A and B antigens and are codominant with each other, and , which is recessive to both. Any one person still carries only two of the three. This gives four blood groups: group A ( or ), group B ( or ), group AB (, both antigens expressed), and group O (, neither antigen). Because and are codominant, an person is genuinely AB — not an intermediate blend.
Sex determination and sex-linked inheritance
In humans, sex is determined by the sex chromosomes: females are XX and males are XY. Eggs always carry an X, whereas sperm carry either an X or a Y, so it is the sperm that determines the sex of the offspring, and the expected ratio is 1 male : 1 female. The X chromosome is much larger than the Y and carries genes that have nothing to do with sex; a gene on the X is described as sex-linked (X-linked). Because a male has only one X, a single recessive allele on it is expressed with no second copy to mask it, so X-linked recessive conditions — such as haemophilia and red-green colour blindness — affect many more males than females. A female must inherit the recessive allele on both X chromosomes to be affected; a female with just one copy is an unaffected carrier. X-linked alleles are written as superscripts on the X, with a bare Y for the Y chromosome.
For sex-linkage questions always write the alleles as superscripts on the sex chromosomes — for example for a carrier female, for an affected male, for an unaffected male. This notation makes the link to the X chromosome explicit and stops you from writing an impossible genotype. Remember a male can never be a carrier: with a single X he is either affected or unaffected.
Reading pedigree charts
A pedigree chart is a family tree that tracks a single trait across generations, and analysing its pattern lets you deduce the mode of inheritance. By convention, circles are females and squares are males, a horizontal line joins a mating pair, vertical lines lead down to their offspring, and a shaded symbol marks an affected individual. Work through the chart asking a few diagnostic questions: does the trait appear in every generation, or does it skip? Do two unaffected parents ever produce an affected child? Are affected individuals overwhelmingly male? The answers point to whether the condition is dominant or recessive, and autosomal or X-linked.
Autosomal recessive: can skip generations; two unaffected (carrier) parents can have an affected child; affects males and females about equally.
Autosomal dominant: appears in every generation; every affected child has at least one affected parent; affects males and females about equally.
X-linked recessive: affects many more males than females; can skip generations through carrier females; an affected father passes the allele to all his daughters (making them carriers) but to none of his sons.
A useful shortcut: two unaffected parents with an affected child means the condition is RECESSIVE; if it is also mostly males affected, suspect X-linked recessive.
Common mistakes examiners penalise
Confusing genotype with phenotype — a genotype is the alleles (Pp); a phenotype is the trait (purple). Give the ratio the question asks for and label it: the genotype ratio (1:2:1) is not the phenotype ratio (3:1).
Mixing up homozygous and heterozygous — homozygous means two IDENTICAL alleles (PP or pp), heterozygous means two DIFFERENT alleles (Pp). A heterozygote shows the dominant phenotype but carries the recessive allele.
Putting whole genotypes in the gametes — gametes carry ONE allele each because the alleles segregate; writing 'Pp' in a gamete circle shows a misunderstanding and loses the method mark.
Not defining the allele symbols — always state what each letter means before the cross; an undefined or ambiguous symbol (like C/c) can cost a mark.
Calling a male a carrier for an X-linked trait — a male (XY) has only one X, so he is affected or unaffected, never a carrier. Only females can be carriers.
Treating codominance as a blend — in codominance BOTH alleles are fully expressed (I^A I^B is genuinely AB), not an intermediate; a blended heterozygote would be incomplete dominance instead.
Dropping the sex chromosome from the notation — write X-linked alleles as , , Y, not as bare letters, or the link to sex is lost and impossible genotypes creep in.
Model answer — marked the way our engine marks it
A genetic-diagram question is marked analytically: the marks are split between method marks (M) for setting the cross out correctly and answer marks (A) for the ratios you read off it. Crucially, error-carried-forward (ECF) applies — if you make an early slip but your Punnett square is then completed correctly from the gametes you wrote, you still earn the method and any ratios that follow consistently. Study how each mark below is tied to a specific part of the diagram, not to loose wording.
Where this leads
The genetic-diagram habit built here — define alleles, segregate them into gametes, recombine in a Punnett square, count the ratios — is the template for every inheritance problem you will meet. At HL it extends to dihybrid crosses, where two genes are followed at once and the classic 9:3:3:1 phenotype ratio appears, and to more complex patterns of inheritance. Master the single-gene method now, keeping genotype and phenotype ratios distinct and laying every step out on the page, and those harder crosses become just more of the same careful bookkeeping.
Worked examples
See the formulas applied — reveal one step at a time, like the exam.
In pea plants, the allele for tall stems (T) is dominant to the allele for dwarf stems (t). A homozygous tall plant is crossed with a dwarf plant, and the resulting F1 plants are then self-pollinated. Determine the expected phenotypic ratio of the F2 generation. [4]
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Symbols. T = tall (dominant), t = dwarf (recessive).
A woman with blood group A and a man with blood group B have a child with blood group O. Using a genetic diagram, determine the probability that their next child will have blood group AB. [4]
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Symbols. = A antigen, = B antigen (codominant); = no antigen (recessive to both).
Haemophilia is caused by an X-linked recessive allele (). A woman who is a carrier for haemophilia has children with a man who is unaffected. Using a genetic diagram, determine the expected proportion of their SONS that will have haemophilia. [4]
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Symbols. = normal allele (dominant), = haemophilia allele (recessive), on the X chromosome; Y carries no allele.
A heterozygous purple-flowered plant (Pp) is crossed with a white-flowered plant (pp). Using a Punnett square, determine the expected genotype and phenotype ratios of the offspring. [4]
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Model answer. Symbols: P = purple (dominant), p = white (recessive).
How it all connects
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Tap a linked idea to see how it connects back to the main topic — that connection is what examiners reward.
Glossary
Try to recall each definition before you reveal it.
Quick check
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Revision flashcards
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Gene vs allele
A gene is a length of DNA that codes for a particular characteristic and sits at a fixed locus on a chromosome. An allele is one of the alternative versions of that gene (for example, the tall allele or the dwarf allele of the height gene).
Key takeaways
Review these before you close the topic — retrieval beats re-reading.
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Genotype = the pair of alleles carried (e.g. Pp); phenotype = the observable trait (e.g. purple flowers).
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Homozygous = two identical alleles (PP or pp); heterozygous = two different alleles (Pp).
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Dominant allele (capital) is expressed even in a heterozygote; recessive allele (lower case) needs to be homozygous to show.
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A carrier is a heterozygote that hides a recessive allele without showing the condition.
Practice — then mark it
The whole point: a real Cambridge question, marked mark-by-mark.
Get a Paper 2 question marked: set out a full genetic diagram and predict the offspring ratios with method marks and ECF
Get a Paper 2 question marked: set out a full genetic diagram and predict the offspring ratios with method marks and ECF
Extra simulations & links
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Frequently asked
Checkpoint
One marked question is worth ten re-reads — close the loop before you move on.
Reading it isn’t knowing it — prove it.
Before you move on: do Get a Paper 2 question marked: set out a full genetic diagram and predict the offspring ratios with method marks and ECF on paper, snap a photo, and get examiner-style feedback on exactly where you win and lose marks.