Genetics Flashcards
Feeling a bit rusty with the Hardy-Weinberg equation? Having trouble remembering the difference between incomplete dominance and codominance? Use these cards to master Mendelian genetics as it appears on the Biological & Biochemical Foundations section.
Define:
gene
A nucleic acid sequence that determines some trait of an organism. In eukaryotes, genes are composed of DNA and located on chromosomes.
Many aspects of inheritance were discovered by Gregor Mendel, though the term “gene” had not yet been coined. Instead, Mendel called genes “factors.”
Define:
phenotype
It refers to a physical or observable characteristic of an organism, determined by its genotype.
For example, if a pea plant is homozygous for the Y allele and is yellow in color, “yellow” would be its phenotype.
Define:
genotype
It refers to the actual set of alleles possessed by an organism.
For example, if a pea plant is homozygous for the Y allele and is yellow in color, “YY” would be its genotype.
What term describes the position of a particular gene on a chromosome?
locus
(plural: loci)
Each locus falls at the same relative position in a species. This allows the construction of genetic maps.
Define:
allele
A variation of a specific gene, usually denoted by a single letter. Humans always have two alleles at each genetic locus.
For example, the B and b alleles might code for brown and blue eye color, respectively.
Define:
polymorphism
Occurs when a single species displays discrete phenotypic forms, such as Mendel’s green and yellow peas.
At the DNA level, polymorphisms refer to minor variations in the sequence of a gene that occur relatively frequently in a population.
In dogs, the C locus determines the extent to which melanin is expressed. Possible alleles at this locus include C (full expression), Cb (gray fur), and c (albino), among others. What inheritance pattern does this trait exemplify?
This is an example of multiple allelism, in which three or more alleles exist for each a particular trait.
Note that a normal individual still cannot possess more than two alleles per locus.
Explain the difference between a homozygous and a heterozygous genotype.
- A homozygous genotype includes two copies of the same allele.
- A heterozygous individual possesses two different alleles.
Let’s say that a plant species has two alleles that determine height, T (tall) and t (short). TT and tt individuals would be homozygous while Tt organisms would be heterozygous.
What is the term “wild type” used to signify?
Refers to the allele or phenotype that naturally predominates in a population.
On the MCAT, experiments with bacteria often compare a wild type strain with one or more sets of mutants. Wild type bacteria exist as they would in nature, while mutants either lack a normal function or gain an abnormal one.
Define:
complete dominance
This is the simplest inheritance pattern tested on the MCAT. One allele is dominant, meaning that it determines the phenotype whenever present. The other allele is recessive and only affects the phenotype when the dominant allele is not present.
Mendel observed complete dominance in his experiments with pea plants.
In a certain population, the R allele codes for red color and the r allele codes for white color. If 100% of individuals with an Rr genotype appear red, how would we describe the r allele?
recessive
In complete dominance, heterozygotes always display the dominant phenotype. In this example, that allele would be R. The recessive allele is completely “masked” in such cases.
A female child is born with cystic fibrosis, but neither her father nor her mother suffers from the disease. What pattern of inheritance must cystic fibrosis display?
autosomally recessive
With any mode of inheritance, at least one parent must have the disease allele for the child to suffer from the disease. Since neither parent has cystic fibrosis, another allele must have the ability to mask its action.
How do we know this disorder is not sex-linked? The child suffering from CF is female, meaning that she would need both X chromosomes to carry the CF allele. Since her father is healthy, he must possess a normal X chromosome, which he would pass down to his daughter.
Explain codominance and give an example.
It is an inheritance pattern in which two alleles contribute equally to an individual’s phenotype.
On the MCAT, the most common example of codominance occurs in blood typing, where three alleles (A, B, and O) exist.
Both A and B are dominant over O, and both will be expressed simultaneously in an AB individual.
A woman is heterozygous for blood type but displays the type A phenotype. If this woman has a child with an AB man, what is the probability that this child will carry two dominant alleles with regard to blood type?
50%
First, note that the A and B alleles are both dominant over O. Heterozygous individuals with type A blood have a genotype of AO, with A being dominant over O. Therefore, the woman in this question must have an AO genotype. The cross described in this question is pictured below. The child has a 50% chance of being either AA or AB (two dominant alleles), leaving a 50% probability of either AO or BO (one dominant and one recessive allele).
Explain incomplete dominance and give an example.
It is an inheritance pattern in which the heterozygous phenotype is a blend of the two homozygous traits.
The most familiar example of incomplete dominance involves flower color. In this pattern, if RR individuals display red coloring and rr individuals are white in color, then Rr flowers would be expected to be pink.
The gene for height in a wild horse species exhibits incomplete dominance, with tall, medium, and short phenotypes. When a tall horse is crossed with the offspring of a tall and a short horse, what potential phenotypes can result?
Offspring from this cross can display either tall or medium phenotypes.
Use T to denote the “tall” allele and t to denote the “short” one. The tall parent must have a genotype of TT. Though the genotype of the second parent is less obvious, it results from the cross of a tall (TT) and a short (tt) horse. The second parent, then, must have a Tt genotype. Crossing a TT and a Tt horse can only result in two phenotypes: the same as those of the parents, tall (TT) and medium (Tt).
Define:
genetic leakage
Occurs when genes from one species travel into the gene pool of another.
The dominant allele K codes for a kidney disease, but 20% of individuals with the K allele have normal kidney function and no other symptoms. What term in genetics is most relevant to this example?
Penetrance refers to the percentage of individuals who express the phenotype expected from their genotype. Since 20% of people in this example possess the disease phenotype but do not have the disease, the K allele is not completely penetrant.
Unless mentioned otherwise, it can be assumed that all alleles on the MCAT show complete, or 100%, penetrance.
The dominant allele M codes for a heart malformation. All individuals with the M allele have the disorder, but some die immediately after birth while others experience few symptoms. What term in genetics is most relevant to this example?
Expressivity refers to the extent to which an individual’s phenotype is affected by their genotype, and is often a range. Since those with the M allele can range from very sick to fairly healthy, this allele shows variable expressivity.
Expressivity is more nuanced than penetrance. While penetrance simply describes whether someone has a trait at all, expressivity describes the range between the most and least extreme examples of the trait.
A certain recessive immune disorder exhibits reduced penetrance. If a man with the disorder has a son with a female carrier, what is the probability that this child will suffer from the disease?
Not enough information is given.
While the description of the parents is sufficient to predict the child’s genotype, this disease does not display full, or 100%, penetrance. Therefore, even a child with two recessive alleles might not suffer from the disease at all. To find the answer, it is necessary to know how penetrant this disease is, which is never mentioned.
Name Mendel’s two laws.
- The Law of Segregation (1st Law)
- The Law of Independent Assortment (2nd Law)
What term refers to the set of all genes present in a population?
The gene pool
A diverse gene pool allows a species to more easily adapt to changes in its environment. This quality is referred to as genetic variation.
Explain Mendel’s Law of Segregation.
An organism carries two alleles for each trait, but these alleles “segregate” during the formation of gametes. Thus, a parent organism will only pass one allele per trait to its progeny.
Though Mendel did not know this at the time, segregation of alleles occurs during anaphase of meiosis I.
Explain Mendel’s Law of Independent Assortment.
Mendel hypothesized that the inheritance of one trait will be unaffected by another. In other words, alleles at different loci assort independently.
This law only holds true when genes are not located on the same chromosome.
What is a test cross used to determine?
It is used to find the genotype of an individual with a dominant phenotype. The unknown organism is crossed with a homozygous recessive individual. If any of the offspring are recessive, the unknown parent must be heterozygous.
A test cross would be unnecessary for an organism with a recessive phenotype. Such individuals can only have one genotype: homozygous recessive.
Label the diagram below with the P, F1, and F2 generations.
P refers to the parent generation, shown in the first cross. F1 is the generation made up of their offspring, while F2 is the generation that results when F1 individuals are crossed.
Describe the proper setup of a Punnett square for a single-trait cross.
- Draw a large square divided into four smaller quadrants.
- Along the top of the Punnett square, write the first letter of the first parent’s genotype above the left-hand column. Write the second letter above the right-hand column.
- Along the left side of the square, do the same for the other parent’s genotype, now with one letter corresponding to each row.
- Fill in the smaller boxes with the corresponding letters - one from the top of the box, one from the left side.
- Each quadrant now contains a potential genotype for the offspring.