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.

1
Q

Define:

gene

A

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.”

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
2
Q

Define:

phenotype

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
3
Q

Define:

genotype

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
4
Q

What term describes the position of a particular gene on a chromosome?

A

locus

(plural: loci)

Each locus falls at the same relative position in a species. This allows the construction of genetic maps.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
5
Q

Define:

allele

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
6
Q

Define:

polymorphism

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
7
Q

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?

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
8
Q

Explain the difference between a homozygous and a heterozygous genotype.

A
  • 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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
9
Q

What is the term “wild type” used to signify?

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
10
Q

Define:

complete dominance

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
11
Q

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?

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
12
Q

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?

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
13
Q

Explain codominance and give an example.

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
14
Q

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?

A

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).

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
15
Q

Explain incomplete dominance and give an example.

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
16
Q

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?

A

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).

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
17
Q

Define:

genetic leakage

A

Occurs when genes from one species travel into the gene pool of another.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
18
Q

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?

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
19
Q

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?

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
20
Q

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?

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
21
Q

Name Mendel’s two laws.

A
  1. The Law of Segregation (1st Law)
  2. The Law of Independent Assortment (2nd Law)
How well did you know this?
1
Not at all
2
3
4
5
Perfectly
22
Q

What term refers to the set of all genes present in a population?

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
23
Q

Explain Mendel’s Law of Segregation.

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
24
Q

Explain Mendel’s Law of Independent Assortment.

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
25
Q

What is a test cross used to determine?

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
26
Q

Label the diagram below with the P, F1, and F2 generations.

A

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.

How well did you know this?
1
Not at all
2
3
4
5
Perfectly
27
Q

Describe the proper setup of a Punnett square for a single-trait cross.

A
  1. Draw a large square divided into four smaller quadrants.
  2. 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.
  3. Along the left side of the square, do the same for the other parent’s genotype, now with one letter corresponding to each row.
  4. Fill in the smaller boxes with the corresponding letters - one from the top of the box, one from the left side.
  5. Each quadrant now contains a potential genotype for the offspring.
How well did you know this?
1
Not at all
2
3
4
5
Perfectly
28
Q

A condition that causes dwarfism displays incomplete dominance. BB individuals grow to normal height, Bb individuals have short limbs, and those with the bb genotype do not survive long after birth. Using a Punnett square, determine the probability that two parents with dwarfism will have a bb baby as their first child.

A

25%

Each parent has dwarfism, meaning that they are both heterozygous (Bb). The Punnett square below shows that a cross of two heterozygous individuals has a 1/4 chance of producing homozygous recessive offspring.

29
Q

What individuals are involved in a dihybrid cross?

A

It involves two separate traits. Specifically, both parents must be dihybrids, or heterozygous for both traits being observed.

Often, a dihybrid cross is preceded by crossing two strains that are pure-breeding (homozygous) for different traits. For example, a cross of AABB and aabb parents will yield 100% AaBb offspring, which are dihybrids and can be further crossed.

30
Q

What does the ratio “3:1” signify?

A

Assuming complete dominance, 3:1 reflects the ratio of dominant to recessive phenotypes in the offspring of a monohybrid cross.

For example, consider a cross between two heterozygous (Rr) organisms. Of the offspring, ¼ will be RR and ½ will be Rr, combining for a ¾ chance of exhibiting the dominant phenotype. Only the ¼ with the rr genotype will display the recessive phenotype.

31
Q

What does the ratio “9:3:3:1” signify?

A

Assuming complete dominance, 9:3:3:1 reflects the ratio of phenotypes obtained in a dihybrid cross.

Of every 16 offspring, 9 will display both dominant phenotypes. 3 will display one (Trait A) but not the other (Trait B), while an additional 3 will display Trait B but not Trait A. 1 individual of 16 will exhibit both recessive phenotypes.

32
Q

An organism with the genotype GgAA is crossed with a ggAa partner. What fraction of their offspring will have a genotype that matches one of the parents?

A

50%

As this Punnett square shows, the offspring have a 50% chance of having either a GgAA or ggAa genotype.

33
Q

In his famous experiments, Mendel did not consider many complex methods of inheritance. Which of Mendel’s laws is broken in cases that involve linked genes?

A

Mendel’s Law of Independent Assortment

Mendel hypothesized that the inheritance of one trait was unaffected by that of another, or that alleles “assorted independently.” However, genes are inherited as parts of chromosomes, not as individual alleles. If two genes are linked, or located on the same chromosome, they will likely assort into gametes together.

34
Q

Which process of genetic recombination occurs during prophase I of meiosis?

A

Crossing over, or the trading of DNA segments between homologous chromosomes, occurs when these chromosomes are paired together in prophase I.

35
Q

Explain the significance of single vs. double crossovers during meiosis.

A
  • A single crossover involves one double-stranded break and the exchange of one piece of genetic material.
  • A double crossover requires two breaks to occur, often resulting in a piece of material crossing back over to its original position.
36
Q

What is the maximum possible recombination frequency between two linked genes?

A

50%

Even unlinked genes, or those located on different chromosomes, will only form recombinant gametes 50% of the time. Linked genes, even those located very far apart on the same chromosome, cannot exceed this frequency.

37
Q

How many chromosomes do human cells contain?

A

46

Human chromosomes are organized into 23 homologous pairs, the members of which code for the same traits but are genetically different. Corresponding alleles are located on homologous chromosomes.

38
Q

What is the difference between a sex chromosome and an autosome?

A
  • Sex chromosomes determine whether an individual is male or female; human cells contain a single pair for a total of two chromosomes.
  • The remaining 22 pairs, or 44 chromosomes, are classified as autosomes.

Unlike autosomal pairs, the sex chromosomes X and Y are not fully homologous.

39
Q

What is the genotype of a male with regard to sex chromosomes?

A

XY

Since only males possess Y chromosomes, each man inherits his Y from his father. Therefore, his X chromosome invariably comes from his mother.

40
Q

What is the genotype of a female with regard to sex chromosomes?

A

XX

Females inherit an X chromosome from each parent.

41
Q

Which of the two sex chromosomes contains more genetic information?

A

The X chromosome is much larger and contains many more genes than the Y chromosome.

The most notable gene on the Y chromosome, SRY, is integral in the determination of male sexual development.

42
Q

Which sex chromosome is more commonly associated with sex-linked genes?

A

Since it carries much more genetic material, the X chromosome is generally associated with sex-linked disorders.

In fact, virtually all sex-linked traits on the MCAT will be X-linked.

43
Q

Which gender is more likely to suffer from X-linked disorders?

A

Males

They possess only one X chromosome, show a higher incidence of X-linked disorders. Since females have two X chromosomes, they are able to mask a single disease-carrying allele with a normal one.

Note that males cannot inherit X-linked disorders from their fathers, since men always donate their Y chromosome to their sons.

44
Q

A man’s mother and his father’s mother both suffer from colorblindness, an X-linked condition. What is the percent chance that the man is colorblind as well?

A

100%

Since a male acquires his Y chromosome from his father, his inheritance of X-linked disorders depends on his mother alone. If this man’s mother suffers from colorblindness, then both of her X chromosomes code for the disease and the man is guaranteed to have it as well.

45
Q

What is extranuclear inheritance, and with which eukaryotic organelle is it generally associated?

A

It refers to the transfer of DNA that is not located in the nucleus. In eukaryotes, this is associated with mitochondria, which contain their own genes.

Mitochondrial genes are inherited through the maternal line.

46
Q

What is a mutation, and how does it arise?

A

It is an alteration in DNA sequence. Mutations can arise spontaneously (often from errors in DNA replication) or be induced by mutagenic substances.

For the MCAT, remember that mutations never arise in response to selective pressure. For example, a resistant strain of bacteria did not mutate to become resistant; the mutation arose spontaneously and persisted due to its evolutionary advantage.

47
Q

A certain mRNA sequence reads 5’-AUGCCAUGU-3’. In this context, what term describes AUG, CCA, and UGU?

A

codons

A codon is a set of three nucleotides that corresponds to a particular amino acid.

48
Q

In the replication of a DNA strand, an adenine base is included instead of a cytosine. The rest of the strand is replicated normally. What type of mutation occurred?

A

Since one base was replaced with another, a substitution mutation occurred.

Such a mutation can also be described as a point mutation, since only a single base was altered.

49
Q

Name two types of mutation that lead to a frameshift.

A
  • Insertion
  • Deletion

Insertion is the addition of one or more nucleotides.

Deletion is the removal of one or more nucleotides.

Note that the insertion or deletion of a multiple of three nucleotides would not result in a frameshift.

50
Q

Which is more likely to be harmful: a base substitution or a frameshift mutation?

A

A frameshift mutation is much more likely to adversely affect the organism.

While a single-base substitution only changes at most a single codon, a frameshift causes the entire reading frame to be moved. This alters many or even all of the amino acids after the aberration, resulting in a drastically different or nonfunctional protein.

51
Q

What is the result of a missense mutation?

A

This replaces one amino acid with another.

For example, the codon AGU codes for the placement of a serine residue, while AGG codes for the placement of arginine. A simple substitution of G for U, then, can result in a missense mutation.

52
Q

What is the result of a nonsense mutation?

A

This transforms an amino acid into a stop codon, resulting in a shortened and often nonfunctional protein.

The three stop codons are UGA, UAA, and UAG. The start codon is AUG, which corresponds to methionine.

53
Q

Which is more likely to be harmful: a missense or a nonsense mutation?

A

A nonsense mutation is much more likely to adversely affect the organism.

While a missense mutation only changes a single amino acid to another, a nonsense mutation causes the entire process of translation to be prematurely stopped. This results in a shorter and often functionally useless protein.

54
Q

With regard to mutations, what is an inversion?

A

It is a chromosomal mutation in which a nucleotide sequence is completely reversed.

55
Q

With regard to DNA, what is a translocation?

A

A chromosomal mutation in which a nucleotide sequence moves to another position, either within the same or between different chromosomes.

56
Q

A student argues that a species without mutations would be evolutionarily favorable, since its genetic code would be free of errors. Describe the major flaw in this student’s reasoning.

A

Mutations provide genetic variation, which is evolutionarily vital.

In bacteria, for example, mutations can result in the survival advantage of antibiotic resistance. Without these mutations, the entire species would be equally susceptible to attack.

57
Q

Define:

degeneracy

A

It refers to the property of the genetic code that allows multiple codons to code for the same amino acid.

Specifically, there are 64 possible codons and only 20 relevant amino acids. Codons for the same amino acid often differ at the position of their third base.

58
Q

Some changes in DNA sequence, known as silent mutations, do not affect the organisms in which they occur. Describe two situations that could lead to a silent mutation.

A
  • A mutation in an intron, or noncoding, sequence.
  • A mutation that replaces one degenerate codon with another.
59
Q

A mutagen is a chemical or other substance that can induce changes in DNA. In what related category are many mutagens included?

A

These are often classified as carcinogens, or cancer-causing substances.

60
Q

What is genetic drift?

A

It describes changes in allele frequencies that result from random events.

Often, genetic drift involves situations where part of the population experiences some disaster or becomes isolated from the rest. For example, consider a rat population where allele freqencies for coat color are fairly even. If a flood happens to kill most of the white rats, the resulting decrease in the “white” allele is a result of genetic drift.

61
Q

Name three events or mechanisms that increase a population’s genetic diversity.

A
  • Mutation
  • Migration between populations
  • Sexual reproduction, especially homologous recombination (crossing over)
62
Q

In a hypothetical situation, allele frequencies in a population remain unchanged over multiple generations. Though this condition does not occur naturally, it is often used as the basis for mathematical models. What term describes this situation?

A

Hardy-Weinberg equilibrium

63
Q

Name the five prerequisites for Hardy-Weinberg equilibrium.

A
  1. Large population size
  2. No mutation
  3. No inward or outward migration
  4. No natural selection
  5. Random mating
64
Q

A very large, mutation-free population of finches is entirely isolated within their geographic area. Males tend to grow bright feathers to attract potential mates. What condition(s) of Hardy-Weinberg equilibrium does this population violate?

A

random mating

A large population size, lack of mutation, and lack of migration all fit Hardy-Weinberg criteria. However, if mates are chosen based on certain characteristics, mating is not random and equilibrium is violated.

65
Q

What two equations can be used when a population is assumed to be in Hardy-Weinberg equilibrium?

A

The main Hardy-Weinberg equation is p2 + 2pq + q2 = 1. Since this statement assumes that only two alleles are present, and these alleles are represented by “p” and “q,” p + q = 1 is also relevant.

For these equations to hold true, the proportion of each allele must be described in decimal form. For example, if the A allele comprises 36% of the gene pool, its frequency would be 0.36.

66
Q

In the Hardy-Weinberg equation, what variable or expression refers to the frequency of the dominant allele in the gene pool?

A

p

When dealing with Hardy-Weinberg, remember that alleles are denoted by single letters. Conventionally, the dominant allele is “p” and the recessive allele is “q.”

67
Q

In the Hardy-Weinberg equation, what variable or expression refers to the frequency of the heterozygous genotype in the gene pool?

A

2pq

Remember that genotypes in the Hardy-Weinberg equation are denoted by expressions, not single letters. p2 represents the proportion of homozygous dominant individuals, while q2 represents the frequency of the homozygous recessive genotype.

68
Q

A and a are the only two alleles that exist for a certain trait. In a stable population, 9% of individuals have the aa genotype. What percentage of individuals are heterozygous?

A

42%

The frequency of the homozygous recessive genotype, q2, is 0.09. From this information, it can be found that q = 0.3. Since p + q = 1, p must be equal to 0.7. The heterozygote frequency, 2pq, is thus (2)(0.7)(0.3) or 0.42.