Have you ever wondered why you look like your parents? Or even your siblings? The answer is because of inheritance. Genetic inheritance (not the type where you get all your Great Aunts money!) is when traits are transferred from parents to offspring through their DNA; during sexual and asexual reproduction, parents pass on their genetic material or DNA to their offspring. In this article, we discuss patterns of inheritance that follow Mendelian genetic ratios and the definition of monohybrid and dihybrid inheritance. You will learn how to draw a genetic diagram and predict the results of genetic crosses.
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Jetzt kostenlos anmeldenHave you ever wondered why you look like your parents? Or even your siblings? The answer is because of inheritance. Genetic inheritance (not the type where you get all your Great Aunts money!) is when traits are transferred from parents to offspring through their DNA; during sexual and asexual reproduction, parents pass on their genetic material or DNA to their offspring. In this article, we discuss patterns of inheritance that follow Mendelian genetic ratios and the definition of monohybrid and dihybrid inheritance. You will learn how to draw a genetic diagram and predict the results of genetic crosses.
Inheritance: Transferring parents to offspring during sexual or asexual reproduction.
Many people get confused between genetic and hereditary as they have very common features. Genetic diseases occur due to an abnormality in the person’s genome, whereas a heredity disease results from a mutation that is transferred from one generation to another. A genetic disease can be hereditary, but a mutational change in the genome always causes it.
Monohybrid inheritance refers to the inheritance of a single gene. This example discusses how monohybrid inheritance might be predicted through a genetic cross.
Genetic crosses are a helpful tool to predict traits, as outlined In Table 1.
Table 1. Steps to drawing a genetic cross diagram.
Steps | Example: Tall and short plants |
Usually, the first letter of one of the traits is selected. If possible, it is better to choose the letter in which the higher and lower case forms are easily distinguishable. | Choose between Tall (T) or Short (S) |
| Choose T because T and t are easily distinguishable, whereas S and s are harder to tell apart, especially when handwritten. |
Encircle the gametes to reinforce that they are separate from each other! | Let Tall = T and Short = t NOT Tall = T and Short = S |
| |
| Chance of dominant phenotype (tall) = 1/4+1/4+1/4=3/4. Chance of recessive phenotype (small) = 1/4 |
Genetic cross diagrams can predict the results of a cross between parents with known genotypes. For instance, by creating the genetic cross diagrams above, we predicted that there would be three tall offspring to every short offspring, giving us a ratio of 3:1. However, it is unlikely to obtain an exact 3:1 ratio from a real-life cross.
This is due to statistical error. Even when genes are entirely independent of one another (i.e., when inheriting one gene does not affect the chances of inheriting another), we cannot predict which gametes will fuse: it is up to chance. However, the larger the sample size, the closer the results match theoretical predictions.
Whereas monohybrid crosses look at only one gene at a time, dihybrid crosses look at the transfer of two genes across generations.
You might have already read our explanation on Gregor Mendel and his experiment with pea plants. He discovered that alleles could be dominant or recessive in what is now known as the law of segregation. Mendel also discovered what we now know as the law of independent assortment.
In his second series of experiments, Mendel studied two traits at a time. He crossed two plants with two contrasting traits, e.g., seed shape and seed colour. In his previous experiments, Mendel had concluded that the ’round seed’ trait was dominant over the ‘wrinkled seed’ trait and that the ‘yellow colour’ trait was dominant over the ‘green colour’ trait. Mendel crossed a homozygous plant with round, yellow seeds with a homozygous plant with wrinkled, green seeds. The resulting plants were all heterozygous, round and yellow. Mendel planted these seeds the next year, and the result was:
Law of independent assortment: Pairs of alleles separate independently during gamete formation.
Dihybrid crosses are used between non-linked autosomal genes. Non linked autosomal genes follow the law of independent assortment. During metaphase 1, homologous chromosomes line up randomly, meaning the mixture of chromosomes in each daughter cell after separation varies. Any one of the two alleles for one gene can thus freely combine with any of the alleles for the other gene. Any one of the four types of gamete can also be freely combined with any others.
It can be helpful to review the material on meiosis to understand why this is so!
Creating genetic diagrams for both crosses are very similar; however, there are more genotypes and phenotypes to keep track of for dihybrid crosses. It is important not to mix up alleles from different genes!
Let’s take the pea plant example.
A pea plant has a single gene for colour, which has the alleles Y, a dominant allele that produces yellow peas, and y, a recessive allele that produces green peas. The plant also has a single gene for pea type: R, dominant round, and r, for recessive wrinkled. A plant that is homozygous dominant for both genes crosses with a plant that is homozygous recessive for both.
All offspring from the F1 generation have the same genotype, YyRr, which corresponds to the phenotype yellow and round. Therefore, these offspring could produce four types of gametes (YR, Yr, yR, yr).
When offspring from the F1 generation crossed, giving us the F2 generation, we obtained the following results: Round Yellow: Round Green: Wrinkled Yellow: Wrinkled Green in the ratio 9:3:3:1.
We can investigate inheritance by performing genetic crosses. Gregor Mendel used pea plants. He first performed heredity experiments on pea plants for several reasons.
Today, we choose model organisms for investigating inheritance that follow the same principles. Two commonly used model organisms are Drosophila, commonly known as the fruit fly, and Fast Plant® (Brassica rapa), sometimes known as wild mustard. They have short life cycles and thus are easy to grow in a laboratory environment. Very large batches can be produced at once, which allow for experiments with large sample sizes.
They also have easily identifiable physical traits that correspond to singular genes. In Drosophila, a single gene with two alleles controls wing length: the dominant lead to the long, wild type allele, whereas the recessive leads to a short, vestigial type allele. In Fast Plant®, a single gene with two alleles also controls the production of the pigment anthocyanin. The dominant allele produces anthocyanin and thus purple stems, whereas homozygous recessive plants lack this pigment and therefore have green stems.
Down syndrome is a disorder caused by either an extra chromosome 21 or an extra portion of chromosome 21. This additional portion on the chromosome causes an excessive amount of specific proteins to be formed in the cells, disturbing normal growth in the body.
Three main types of chromosome abnormalities cause down syndrome:
Monohybrid inheritance is the inheritance of a single gene, while dihybrid inheritance is a pair of genes.
Genetic cross diagrams predict the results of a cross between parents with known genotypes. These often include Punnett squares. Genetic crosses may not always match theoretical predictions due to statistical error.
The law of independent assortment states that each member of a pair of alleles may combine randomly with either or another pair.
Model organisms are chosen for their convenience and rapid life cycles.
Drosophila and Fast Plant® are commonly used to investigate inheritance.
In genetics, inheritance refers to the way genes are passed on from generation to generation. Monohybrid inheritance refers to the inheritance of a single gene, while dihybrid inheritance refers to the inheritance of two genes.
Down syndrome is a genetic disease caused by a random alteration of the number of chromosomes in an individual’s genome. It can have one of three main genetic causes:
Trisomy 21, the most common case wherein all of the cells of the body have three copies of chromosome 21.
Mosaic trisomy 21, wherein only some cells have three copies of chromosome 21 and the rest have the normal two.
Translocation trisomy 21, where the individual has 23 chromosome pairs but some sections of chromosome 21 are attached to another chromosome.
However, while the disease is genetic, it is usually not inheritable. This is because the genetic error that leads to Down syndrome occurs randomly. When homologous chromosomes (in this case, chromosome 21) do not separate from one another correctly during cell division, it is called nondisjunction. If nondisjunction happens randomly in one of the parent’s gametes, or if nondisjunction happens during foetal development, the child could have Down syndrome.
The exception is Translocation trisomy 21, which occurs through a different mechanism can be inherited.
Autosomal dominant, autosomal recessive, X-linked dominant, X-linked recessive.
Studying inheritance allows us to understand sexual reproduction and how diseases are passed down generations as well as allowing us to use genetics to our advantage and obtain desired traits.
Gregor Mendel.
What is monohybrid inheritance?
Monohybrid inheritance is the inheritance of a single gene.
Why don’t the results of genetic crosses always match theoretical predictions?
Statistical error
The law of independent assortment states that each member of a pair of ______ may combine ________ with either of another pair
alleles; randomly
Give the scientific names of two examples of model organisms used to investigate inheritance.
Drosophila and Brassica rapa
Which of the following is the phenotypic ratio we would expect from an F1 cross?
9:3:3:1
Why do we use species as model organisms?
Convenience
short life cycles
physical traits that correspond to singular genes
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