Genetics- Part 1- GenesMendelMendel was an Austrian monk who
taught natural science and worked on plant breeding experiments.He
developed a basic understanding of genetics and inheritance.Mendels
WorkIt took him 2 years to select the pea plant as his subject.He
collected data for 10 years.His sample sizes were large; he
tabulated results from 28,000 pea plants.He replicated his
experiments.He analyzed his data with statistics (probability
theory).Characteristics of Garden Peas:Peas are easy to grow, and
take little space.They are inexpensive.They have a short generation
time compared to large animals so that a large number of offspring
can be obtained in a short amount of time.They have some distinct
characteristics that are easy to recognize. These characteristics
can be used when trying to determine patterns of inheritance.They
are easily self-fertilized or cross fertilized.Traits Studied by
Mendelsmooth or wrinkled seedsyellow or green seedspurple or white
flowersinflated or constricted podsgreen or yellow podsaxial or
terminal flowerstall or dwarf plantsMendels CrossesMendel used
pure-breeding individuals in the first (P1) generation.P1 yellow X
green F1 all yellow F23/4 yellow, 1/4 greenMendels Results for 7
different crossesP1F1F2F2ratio
smooth X wrinkled seedsall smooth5474 smooth1850
wrinkled2.96:1
yellow X green seedsall yellow6022 yellow2001 green3.01:1
axial X terminal flowersall axial651 axial207 terminal3.14:1
purple X white flowersall purple705 purple224 white3.15:1
inflated X constricted podsall inflated882 inflated299
constricted2.95:1
green X yellow podsall green428 green152 yellow2.82:1
tall X dwarf plantsall tall787 tall277 dwarf2.84:1
Conclusions from Mendel's CrossesThe F1generation showed only
one character that was present in the P1. The other character
reappeared in the F2(25%).The sex of the parent did not matter.The
traits did not blend.Mendel concluded that the F1plants must
contain 2 discrete factors, one for each character. The character
that was seen in the F1is calleddominant. The character not seen in
the F1is calledrecessive.Letters Can Represent GenesThe
characteristics studied by Mendel were due to single genes. On the
pair ofchromosomesdiagrammed below, the letter "A" represents a
gene for yellow seeds. The letter "a" on thehomologous
chromosomerepresents a gene for green seeds. By convention, upper
case letters are used to represent dominant genes and lower case
letters are used for recessive genes.
Because individuals arediploid, two letters can be used to
represent the genetic makeup of an individual. In the case of seed
color, the following three gene combinations are possible: AA, Aa,
and aa.
Heterozygote(also called hybrid) refers to an individual that
has two different forms of the gene. Example: AaHomozygoterefers to
an individual that has two identical genes. Example: AA or
aaAhybridis a heterozygote. Example: AaMeiosis, Gamete FormationThe
three diagrams below showmetaphase I,anaphase Iandtelophase Iin an
"Aa" individual.As can be seen in the diagrams, an "Aa" individual
can producegametesthat have "A" and gametes that have "a".Metaphase
1
Anaphase 1
Telophase 1
Principle of SegregationMendels principle of segregation states
that paired factors (genes) separate during gamete formation
(meiosis). Because the pair of genes (Aa, AA, or aa) separate, one
daughter cell will contain one gene and the other will contain the
other gene. (See diagram above.)GametesBecause pairs of chromosomes
separate during meiosis I, gametes arehaploid, that is, they carry
only one copy of each chromosome. An Aa individual therefore
produces two kinds ofgametes: A and a.
Below: An "AA" individual produces all "A" gametes. Similarly,
an "aa" individual produces all "a" gametes.
Individual (genotype)Type of gametes produced
AAall gametes will contain an "A"
Aa1/2 will contain "A" and 1/2 will contain "a"
aaall "a" gametes
Punnett SquaresSuppose that an "Aa" individual is crossed with
another "Aa" individual. One will produce "A" eggs and "a" eggs.
The other will produce "A" sperm and "a" sperm. What are all of the
possible combinations of eggs and sperm? A Punnett square can be
used to show all of these combinations.The Punnett square in the
diagram below is used to show between two Aa individuals.
The square below is used for this cross: AA X Aa.
One half of the offspring produced by this cross will be AA, the
other half will be Aa.The cross can also be written as shown below
because the AA parent can produce only one kind of gamete (all
A).
A Closer look atMendels Crosses(One Gene Locus)Y = yellow y =
greenP1 YY X yyF1 Yy Yy X Yy A cross between two individuals that
are heterozygous for a trait is called amonohybrid cross.F2The
above cross is illustrated below.
Genotype and PhenotypeThe genetic makeup of P1plants was
different from that of F1because the P1plants were true breeding
and the F1plants were not. The genetic makeup of an individual is
referred to as itsgenotype. Because the plants are diploid, two
letters can be used to write the genotype. In this case, the
genotype of the P1plants was YY; the genotype of the F1plants was
Yy.The characteristics of an individual are itsphenotpye. This word
refers to what the individual looks like so ddjectives are used to
write the phenotype. For example, "yellow" or "tall" are
phenotypes. The yellow P1plants looked like the F1; they had the
same phenotype but different genotypes.An individual with a
recessive phenotype has two recessive genes. A dominant phenotype
results from either one or two dominant genes. In the cross above,
YY or Yy are yellow; yy is green. The phenotype ratio in the F2 is
3 yellow:1 green. The genotype ratio is
1YY:2Yy:1yy.GenotypePhenotype
AA or AaYellow
aaGreen
Other CrossesS = smooth s = wrinkledP1 SS X ssF1 Ss Ss X Ss
F2genotyperatio = 1:2:1 (1SS : 2Ss : 1ss)phenotyperatio = 3:1
(3Smooth : 1 wrinkled)F = full f = constrictedP1 FF X ff F1 Ff Ff X
Ff
F2genotype ratio = 1:2:1 (1FF : 2Ff : 1ff)phenotype ratio = 3:1
(3full: 1 constricted)Alleles and LociGenes may have different
forms. For example, purple flowers and white flowers are to
different forms of the gene for flower color. Each of the different
forms of a gene arealleles.Alocus(plural:loci)is the location of a
gene on a chromosome. The gene for purple flowers and the gene for
white flowers are two different alleles at the same locus. A single
chromosome can have a gene for white flowers or a gene for purple
flowers but not both.There are two loci illustrated below, one is
for flower color and the other is for stem length. Flower color has
five alleles and stem length has two.
PracticeCrossesLet " A" represent the allele for yellow seeds
and " a" represent the allele for green seeds. For each cross
below, give the genotype of the gametes and the expected genotypes
and phenotypes in the offspring.CrossGametes1st parentGametes2nd
parentGenotypesPhenotypes
AA X AA
AA X Aa
AA X aa
Aa X Aa
Aa X aa
aa X aa
Click here to view the answers.ApplicationSickle-cell anemia is
an abnormality of hemoglobin, the molecule that carries oxygen in
our blood. Red blood cells of affected individuals often become
distorted in shape, they then may break down or clog blood vessels
causing pain, poor circulation, jaundice, anemia, internal
hemorrhaging, low resistance, and damage to internal organs.This
condition is caused by a recessive gene.A = normal hemoglobina =
sickle-cell hemoglobinAA = normalAa = normal (called sickle-cell
trait)aa =sickle-cell anemiaA man with sickle-cell trait marries a
normal woman. What is the probability that their children will have
sickle-cell trait?If both parents have sickle-cell trait, what
percentage of their children will:have a normal phenotype?have
sickle-cell trait?have sickle-cell anemia?Testcross - One Locuslet
A = purplea = whiteIs a purple flower AA or Aa?Solution: cross it
with aaP1 A? X aaThe A? individual can produce these kinds of
gametes: "A" and "?"gametes: A, ? and aF1 Aa and ?aIf the ?a
individual is purple, then ? = A. If it is white, then ? = a.Should
There Be FewerRecessiveAlleles?The population model described above
predicts that gene frequencies will not change from one generation
to the next even if there are more recessive alleles.There is
sometimes a misconception among students beginning to study
genetics that dominant traits are more common than recessive
traits. Sometimes this is true, sometimes it is not. For some
traits, the dominant is more common; for other traits, the
recessive is more common. For example, blood type O is recessive
and is the most common type of blood. Huntington's disease (a
disease of the nervous system) is caused by a dominant gene and the
normal gene is recessive. Fortunately, most people are recessive;
the dominant is uncommon.The misconception comes from the
observation that in a cross of Aa X Aa, 3/4 of the offspring will
show the dominant characteristic. However, the 3:1 ratio comes only
if the parents are both Aa. If there are many recessive genes in a
population, then most matings are likely to be aa X aa and most
offspring will be aa.In nature, natural selection may favor one-
either the dominant or the recessive- and that one will become more
common over time. Other forces such as genetic drift may also cause
one or the other allele to become more common. In the absence of
forces that change gene frequencies, there is no reason to expect
dominant genes to be more common.ProbabilityMultiplicative RuleThe
probability of two or moreindependentevents occurring is equal to
the product of their probabilities.Example: What is the probability
of tossing a coin two times and getting a heads both
times?Solution: The probability of getting a heads on one coin is
1/2. The probability of getting a heads on the second coin does not
depend on the outcome of the first coin, so the multiplicative rule
is used. The probability of getting a heads on two coins is 1/2 X
1/2 = 1/4.Additive RuleThe probability of two or moremutually
exclusiveevents occurring is equal to the sum of their
probabilities.What is the probability that a student will get an
?A? or a ?B? in a class if students generally earn the following
grades:A = 10% (or 0.10)B = 35% (or 0.35)C = 45%D = 10%Solution: In
this example, the two outcomes (getting an "A" or getting a "B")
are mutually exclusive because you can only get one or the other.
The additive rule is used to determine the overall probability of
getting an "A" or a "B". 10% + 35% = 45% (or 0.10 + 0.35 =
0.45).Consider Two Loci at the Same TimeIndependent AssortmentGenes
that are on different chromosomes assort independently. The
following are four different metaphase I allignment patterns that
are possible for a hypothetical species with a diploid chromosome
number of 6.
The alignment pattern shown in the diagram below will produce Sy
and sY gametes.
The alignment pattern shown in this diagram will produce SY and
sy gametes.
Both of the patterns illustrated above are possible because S
and Y are located on different chromosomes.Possible Gametesfor
Several Different GenotypesThe table below shows the kinds of
gametes that can be produced by several different kinds of
genotypes. Each gene locus (A and B) is on a different
chromosome.IndividualGametes
AABBAB
AABbAB, Ab
AaBBAB, aB
AaBbAB, Ab, aB, ab
AabbAb, ab
AAbbAb
aaBBaB
aaBbaB, ab
aabbab
Genotypes and Phenotypeslet A = purple, a = whitelet B = smooth,
b = wrinkledThe table below shows possible genotypes and
phenotypes.GenotypePhenotype
AABBpurple, smooth
AABbpurple, smooth
AaBBpurple, smooth
AaBbpurple, smooth
Aabbpurple, wrinkled
AAbbpurple, wrinkled
aaBBwhite, smooth
aaBbwhite, smooth
aabbwhite, wrinkled
LinkageIn peas, the locus for seed texture (smooth or wrinkled)
and seed color (yellow or green) are on two different chromosomes
so they assort independently.Suppose that they are on the same
chromosome as indicated in the diagram below. Independent
assortment will not occur because the "S" gene is on the same
chromosome as the "y" gene. Similarly, the "s" gene is on the same
chromosome as the "Y" gene. Unless crossing-over occurs, "S" will
always be found with a "y" and "s" will be found if there is a
"Y".
Mendel studied seven different characteristics in peas. Each of
these characteristics are on different chromosomes, so they assort
independently.Example: Two Gene LociLet S = smooth, s = wrinkledLet
Y = yellow, y = greenP1SMOOTH, YELLOW X wrinkled, greengenotypes:
SSYY ssyygametes: SY syF1SMOOTH, YELLOW X SMOOTH YELLOWgenotypes:
SsYy X SsYy? A cross between two individuals that are heterozygous
for two gene loci is called adihybrid cross.gametes: SY, Sy, sY,
syF2
Mendel's ResultsSMOOTH, YELLOW315
SMOOTH, green108
wrinkled, YELLOW101
wrinkled, green 32
556
A general rule for dihybrid crosses (AaBb X AaBb)TRAIT 1, TRAIT
2 X trait 1, trait 2 (upper case traits are dominant)9 - TRAIT 1
and TRAIT 2 expressed (A-B-)3 - TRAIT 1 expressed (A-bb)3 - TRAIT 2
expressed (aaB-)1 - No dominant traits expressed (all aabb)A
dihybrid cross is two monohybrid crossesRemember that each of the
individual traits in the dihybrid cross above behaves as a
monohybrid cross, that is, they will produce a 3:1 phenotype ratio
in the offspring.SMOOTH X wrinkledRefer to the F2data for the
SMOOTH, YELLOW X wrinkled, green cross above.The number of smooth
offspring was 315 + 108 = 423.The number of wrinkled was 101 + 32 =
133.The ratio of smooth to wrinkled is therefore 423:133 or
approximately 3:1.YELLOW X greenyellow = 315 + 101 = 416green = 108
+ 32 = 140ratio = 416:140 or approximately 3:1Combining
Probabilities9:3:3:1 can be obtained in a dihybrid cross by first
calculating probabilities for two monohybrid crosses and then
combining their probabilities.probability of round = 3/4probability
of wrinkled = 1/4probability of yellow = 3/4probability of green =
1/4probability of roundandyellow = 3/4 X 3/4 = 9/16probability of
roundandgreen = 3/4 X 1/4 = 3/16probability of wrinkledandyellow =
1/4 X 3/4 = 3/16probability of wrinkledandgreen = 1/4 X 1/4 =
1/16Other CrossesThe following steps can be used to determine the
expected number of offspring from any cross.1. Determine thekinds
of gametesthat can be produced by each parent.2. Determine all of
the possible combinations of gametes that can be produced. A
Punnett square may be useful for this.If you use a Punnett square,
the gametes of one parent are written across the top and the
gametes of the other parent written on one side. The number of
cells in the square is therefore equal to the number of gametes
that one parent can produce multiplied by the number of gametes
that the other parent can produce.Example:Let T = tall, t = short F
= inflated, f = constrictedList the phenotypes produced by the
following cross:TtFf X ttFfStep 1:List the kind of gametes produced
by each parent.TtFf can produced TF, Tf, tF and tf.ttFf can produce
tF and tf.Step 2:Construct a Punnett square.
The Punnett square above shows that eight different genotypes
are produced. The phenotype for each is listed in the table
below.GenotypePhenotype
tTFF, tTFf, tTfFtall, inflated
tTfftall constricted
ttFF, ttFf, ttfFshort inflated
ttffshort, constricted
Test Cross - Two LociY = yellow R = purpley = green r =
whiteWhat is the genotype of a plant with yellow seeds and purple
flowers?In the cross below, the symbols "-" and "?" represent
unknown alleles. "-" is either "Y" or "y". "?" is either "R" or
"r".The genotype of a plant with yellow seeds and purple flowers is
"Y-R?".Cross it with yyrr to find out the "-" and "?" alleles.Y-R?
X yyrrgametes: YR, Y?, -R, -? (parent 1) and yr (parent 2)
If the unknown alleles (- and ?) are recessive, the phenotype
ratio will be 1:1:1:1.Incomplete (Partial) DominanceIn the cases
that are discussed above, blending does not occur. Flowers are
either red or white but are never pink. Seeds are either yellow or
green but not yellowish-green. In these cases, if a dominant gene
is present, it is expressed. Some genes, however are neither
dominant nor recessive and when mixed, blending occurs.Example:
SnapdragonsA = Red flowers A' = white flowersA heterozygote (AA')
is pink.Codominance and Multiple Alleles- Example: ABO blood
groupUp to this point, we have discussed two possible alleles for
any gene locus. For example, at the flower color locus, there is
either the red or the white allele (A or a). With human blood
types, there are three alleles: A, B, or O. This is referred to
asmultiple alleles.I is dominant to i.There are two forms of I:
IAand IBbut only one form of i.6 possible genotypes, 4
phenotypes:IAIAand IAi = blood type AIBIBand IBi = blood type
BIAIB= blood type ABi i = blood type OPeople with blood type A have
a specific kind of carbohydrate chain on the surface of their red
blood cell. The carbohydrate chain is attached to a membrane
protein or lipid. Blood type B cells have have a different
carbohydrate chain. Type AB cells have both A and B chains. IAand
IBarecodominantbecause both phenotypes are expressed; there is no
blendingCodominanceis different thanIncomplete
dominance(blending).PleiotropyGenes that affect more than one trait
are called pleiotropic.For example, people withMarfan syndromemay
be tall, thin, have long legs, arms and fingers, and may be
nearsighted. Their connective tissue is defective. If unrepaired,
the connective tissue surrounding the aorta will eventually rupture
and kill the person. All of these characteristics are due to a
single gene.EpistasisAlleles at one locuspreventthe expression of
alleles at another locus. This interaction is referred to as
epistasis.Example: Flower color in peas enzyme 1 enzyme 2 AA or Aa
BB or Bbcompound A -------> compound B -------> pigmentAn
individual with AA or Aa genotypes will have flowers. AA or Aa
individuals could have white flowers if the individual also has a
"bb" genotype (example: AAbb). In this case, the locus for enzyme 2
prevents the expresson of the locus for enzyme 1.Genomic
Imprintingsometimes an allele is expressed differently if it is
inherited from the mother than if it is inherited from the
father.Example: Huntington's disease is expressed earlier if
inherited from the father.The symptoms of Huntington's disease are
caused by a slow deterioration of brain cells that begins at middle
age. It is characterized by involuntary jerking movements of the
body including facial muscles and slurred speech. Later, there is
difficulty swallowing, loss of balance, mood swings, impaired
reasoning, and memory loss. The person eventually dies, usually to
pneumonia or heart failure.Polygenic InheritanceA polygenic trait
is due to more than one gene locus. It
involvesactiveandinactivealleles.Active alleles function
additively.Example: 3 loci (polygenic)Height (tallness) in humans
is polygenic but the mechanism of gene function or the number of
genes involved is unknown.Suppose that there are 3 loci with 2
alleles per locus (A, a, B, b, C, c).Assume that:Each active allele
(upper case letters: A, B, or C) adds 3 inches of height.The effect
of each active allele is equal, A = B = C.Males (aabbcc) are 5'
tall.Females (aabbcc) are 4'7".GenotypeMalesFemales
aabbcc5'0"4'7"
Aabbcc (or aaBbcc etc.)5'3"4'10"
AaBbcc etc.5'6"5'1"
AaBbCc etc.5'9"5'4"
AaBbCC etc.6'0"5'7"
AaBBCC etc.6'3"5'10"
AABBCC6'6"6'1"
The following is a cross between two people of intermediate
height.AaBbCc X AaBbCcIf there is independent assortment, the
following gametes will be produced in equal numbers:ABC, ABc, AbC,
aBC, abC, aBc, Abc, abcPunnett square analysis:
The Punnett square above can be summarized as
follows:GenotypeMalesFemalesFrequency
AABBCC6'6"6'1"1/64
AaBBCC etc.6'3"5'10"6/64
AaBbCC etc.6'0"5'7"15/64
AaBbCc etc.5'9"5'4"20/64
AaBbcc etc.5'6"5'1"15/64
Aabbcc etc.5'3"4'10"6/64
aabbcc5'0"4'7"1/64
The frequency column in the table above can be plotted to
produce the graph below.
VariabilityVariability results in a bell-shaped curve (see the
diagram above).Traits with many loci produce many categories. In
the example above, 3 loci produced 7 possible heights because a
person could have anywhere from 0 to 6 active alleles. If a trait
were determined by 4 loci (AABBCCDD for example) there would be 9
possible categories because a person could have anywhere from 0 to
8 active alleles.HeritabilityVariability in polygenic traits can
result from genetics and also from the environment. A measure of
the relative contribution of genetics is calledheritability.A trait
with a high heritability is determined mostly by genes. A trait
with a low heritability is determined mostly by the environment.For
example, skin pigmentation (darkness) is determined by 2 or 3 pairs
of alleles, but exposure to sunlight (UV radiation) also causes the
skin to darken due to the deposition of protective
pigments.Examples of polygenic traitsstatureperformance on IQ
testsskin colorneural tube defects (spina bifida, anencephaly)cleft
lip/palate
