Title: MENDELIAN GENETICS
1MENDELIAN GENETICS
2ANNOUNCEMENTS
- The first set of genetics problems will be posted
on the course web site by end of today! - Exam II will be held in 1.5 weeks
- No class on July 4th
3OBJECTIVES
- Understand Mendels principles/laws governing
genetics - Understand the meaning of relevant vocabulary
discussed in class - Be able to predict results of a mono dihybrid
cross using a Punnett square - Know exceptions to the rules
4INTRODUCTION TO GENETICS TERMINOLOGY
- Diploid
- Cell (or organism) with pairs of homologous
chromosomes - Haploid
- Cell/org. with only one chromosome of each kind
5GENETICS TERMINOLOGY
- Gene (Character)
- A feature that is heritable
- Locus
- Specific area on chromosome where a gene is found
- Allele (Trait)
- Variation of a character.
- Diff. forms of the SAME gene.
- Genotype
- The genetic makeup of an organism (combination of
genes in its nucleus) - Phenotype
- The physical appearance of an organism
Brown Eyes
Blue Eyes
Black Hair
Red Hair
6GENETICS
- Genetics
- The scientific study of heredity
- Heredity
- The transmission of traits from parents to
offspring
7MENDEL
- Gregor Mendel
- Interested in basic patterns governing the
transmission of traits from parent to offspring
8MENDEL
- Mendels work precedes Darwin and an
understanding of meiosis/genes/chromosomes
9HISTORICAL HYPOTHESES REGARDING INHERITANCE
- The Blending Inheritance Hypothesis
- Offspring represent a blend of characteristics
from two parents - The Inheritance of Acquired Characteristics
Hypothesis - Traits present in parents are modified through
use and passed on to offspring in modified form
10 MENDEL
- Mendel performed crosses between true breeding
lines of garden peas - Began studying inheritance of ONE trait
- Monohybrid cross
- Total of 7 traits were studied
- Later multiple traits studied together
11MENDELS CROSSES
- Mendels plants had two observable forms
(alleles) of each character (gene) - Green or Yellow seeds
12Forms of Trait (Phenotype)
Trait
or
Seed shape
Round
Wrinkled
Round
Wrinkled
or
Seed color
Green
Yellow
Yellow
Green
Pod shape
or
Constructed
Inflated
Smooth
Constricted
or
Pod color
Green
Yellow
Green
Yellow
13Trait
Forms of Trait (Phenotype)
or
Flower color
Purple
White
White
Purple
or
Flower and pod position
Axial (on stem)
Terminal (at tip)
Axial (on stem)
Terminal (at tip)
or
Stem length
Dwarf
Tall
Tall
Dwarf
14MENDEL
- Looked at traits exhibited by progeny of crosses
- He studied phenotype and INFERRED GENOTYPE!
- Mendel found observable evidence of how parents
transmit genes to offspring
15MENDELS PEA PLANTS
- Pisum sativum
- Can self fertilize
- Male female parts on same flower
16- Male parts anthers
- Pollen grain contain sperm
- Female parts pistil
- Ovule eggs
SELF FERTILIZATION
Stigma (receives pollen)
Anthers (produce pollen grains which contain
male gametes)
Ovules (produce female gametes)
17MENDELS PEA PLANTS
- Controlled Mating
- Cut off reproductive organ to stop self
fertilization - Cross fertilize plants in a controlled fashion
- Plant that contributes pollen is considered
male - Plant that receives the pollen is considered
female
18CROSS-POLLINATION
1. Remove anthers from one plant.
2. Collect pollen from a different plant.
3. Transfer pollen to stigma of the 1st
plant (plant without anthers)
19FIRST HALF OF RECIPROCAL CROSS
to stigma of wrinkled-seeded parent
Pollen from round- seeded parent
20SECOND HALF OF RECIPROCAL CROSS
Polen from wrinkled- seeded parent
To stigma of round-seeded parent
21MENDELS CROSSES
Round Parent
x
Wrinkled Parent
All Round Offspring (F1)
(Wrinkled trait disappeared!)
Reciprocal cross (control for sex) produced
same results
22MENDELS CROSSES
- Next Mendel crossed F1 (bro-sis mating)
-
-
-
-
Round (F1)
Round
x
Get both types of offsrping (F2)
Wrinkled trait re-emerges in F2
23MENDELS CROSSES
- Mendel Determines (Phenotypic) Ratio
-
- F2 5474 Round 1850 Wrinkled
- Nearly 3 1
- Similar pattern observed in other 6 traits
24MENDELS CONCLUSIONS
Genes do not blend together. The hereditary
determinants or genes maintain their integrity
from generation to generation. They do not
blend together and they do not acquire
characteristics in response to actions by an
individual
1.
Peas have two versions or alleles of each gene.
This is also true for many other organisms.
2.
Each gamete contains one allele of each gene.
Pairs of alleles segregate during the formation
of gametes
3.
Males and females contribute equally to the
genotype of their offspring. When gametes
fuse offspring acquire a total of two
allelesone from each parent.
4.
Some alleles are dominant to others. When a
dominant and recessive allele for the same gene
are found in the same individual that individual
exhibits the dominant phenotype.
5.
25MENDELS SYMBOLS
- Mendel developed system of assigning symbols to
hereditary characters - Letters represent versions of a gene (alleles)
- Ex If Letter r represents a gene then
- R symbolizes dominant allele
- r symbolizes recessive allele
26PUNNETT SQUARE
- R.C. Punnett a leading geneticist in the early
1900s invented a technique called the Punnett
Square - Place gamete possibilities for 2 parents along
axes - Internal boxes represent union of gametes
- Used to predict genotype and phenotype of
potential zygote
27MENDELS CROSS OF PURE LINE PEA PLANTS
PARENT R R
R is round r is wrinkled
PARENT r r
hint gametes along top whole people on
inside
28MENDELS CROSS OF PURE LINE PEA PLANTS
R Dominant allele for seed shape (round)
r Recessive allele for seed shape (wrinkled)
Round-seeded Father
Wrinkled-seeded Mother
Parental generation (homozygous)
Meiosis
Gametes
Fertilization
F1 generation
Rr
Rr
Rr
Rr
All have Rr genotype (heterozygous) and round
seed phenotype
29MENDELS CROSS OF F1 PLANTS
Crossing the F1s Rr x Rr
R round r wrinkled
30PROBABILITY THEORY
- In Diploid Organisms
- Each allele has 50 chance of being found in a
particular gamete - To calculate likelihood of two alleles combining
(i.e. fertilization) - Multiply probabilities together
31MENDELS CROSS OF F1 PLANTS
Round- phenotype Wrinkled phenotype
Mother
R Dominant allele (round) r Recessive allele
(wrinkled)
Rr
Female gametes
r
R
R
R
Father
Rr
RR
Male gametes
Rr
r
Rr
rr
Resulting genotypes 1/4 RR 1/2 Rr
1/4 rr
Resulting phenotypes 3/4
1/4
32POSSIBLE GENOTYPES
- Three possible genotypes for each gene in a
diploid cell - Homozygous
- Cell (diploid) with two doses of same allele
- Homozygous Dominant
- Both alleles of a gene are of the Dominant
variety (RR) - Homozygous Recessive
- Both alleles of a gene are of the Recessive
variety (rr) - Heterozygous
- Cell (diploid) with two differing alleles for a
gene - One dominant and one recessive version of gene
Mendel DID NOT use these terms only inferred
them!
33MENDELS CROSSES
- Dihybrid Crosses
- Mendel used pea plants to follow inheritance of
TWO traits - Another pattern began to emerge
34MENDELS SYMBOLS
- Seed Shape
- R is dominant allele (Round)
- r is recessive allele (Wrinkled)
- Seed Color
- Y is dominant allele (Yellow)
- y is recessive allele (Green)
35IN CLASS EXERCISE
- Make a Punnett Square to predict offspring of a
homozygous dominant individual crossed with a
homozygous recessive individual! - What are the genotypes of the parents
- What are the genotypes of the gametes
- What about the offspring
36IN CLASS EXERCISE
- Outcome of Dihybrid Cross With Pure Bred Parents
37MENDELS CROSSES WITH PEAS THAT DIFFER IN TWO
TRAITS
R Dominant allele for seed shape (round)
r Recessive allele for seed shape (wrinkled)
Y Dominant allele for seed color (yellow)
y Recessive allele for seed color (green)
Father
Mother
Parental generation
Meiosis
Gametes
Fertilization
F1 generation
38 IN CLASS EXERCISE
- Now cross the F1s
- What is the phenotypic ratio of the offspring
- (What Mendel Observed)
- What about the genotypic ratio
39PUNNETT SQUARE FOR TWO TRAITS
R Dominant allele for seed shape (round) r
Recessive allele for seed shape (wrinkled) Y
Dominant allele for seed color (yellow) y
Recessive allele for seed color (green)
Parental generation
rryy
RRYY
RrYy
F1 generation
ALL
Female gametes
RrYy
1/4 RY
1/4 Ry
1/4 rY
1/4 ry
1/4 RY
RRYY
RrYy
RrYY
RRYy
1/4 Ry
RrYy
Rryy
RRyy
RRYy
RrYy
Male gametes
1/4 rY
rrYy
RrYY
RrYy
rrYY
1/4 ry
rryy
rrYy
Rryy
RrYy
Resulting genotypes
9/16R-Y-
3/16R-yy
3/16rrY-
1/16rryy
9/16
3/16
3/16
1/16
Resulting phenotypes
40F2 OFFSPRING FROM DIHYBRID CROSS
Yellow Green Wrinkled Round
F2 generation phenotype
Mendels Numbers
315
101
108
32 556
Fraction of progeny
9/16
3/16
3/16
1/16 1
Note New mixtures of traits are observed in
F2!!
41How does the 9 3 3 1 ratio for two
traits relate to the 3 1 ratio for one trait
Round seeds Wrinkled seeds
315 108 101 32
423 133
3 1
Yellow seeds Green seeds
315 101 108 32
416 140
3 1
42MENDELS PRINCIPLE OF SEGREGATION
- Principle of Segregation
- Holds true for one or two traits
- For a single trait 31 ratio (dominant
recessive) - For two traits 9331 ratio
- Each trait considered individually showed 31
ratio
43PRINCIPLE OF SEGGREGATION
44MENDELS PRINCIPLE OF INDEPENDENT ASSORTMENT
- Law of Independent Assortment
- Genes residing on different chromosomes separate
without regard for one another
45Hypothetical Example of Independent Assortment
During meiosis I tetrads can line up two
different waysbefore homologs separate.
OR
Brown eyesBlack hair
Blue eyesRed hair
Blue eyesBlack hair
Brown eyesRed hair
46THE TEST CROSS
- To determine genotype of an individual cross
with a homozygous recessive individual
47THE TEST CROSS
Homozygous recessive parent
YOUR HOMEWORK!
rryy
ry
All
1/4
1/4
1/4
1/4
48MENDEL
- Why Mendel Was Successful
- Unbiased
- Selected good model organism
- Used pure breeds as parents
- Large sample size
- Quantitative analysis
- Controlled experiments
- Studied obvious traits
49EXTENSION OF MENDELS RULES
- Phenotypic variation is not always due to simple
dominance/recessive-ness of genes
50EXTENSION OF MENDELS RULES
- Some Traits Deviate from Mendelian Patterns
- Incomplete Dominance
- No allele is completely dominant over another
- Co Dominance
- Two alleles are dominant expressed
- Environmental Effects
- Environmental conditions help determine trait
- Quantitative Traits
- Trait due to interaction between more than one
gene
51INCOMPLETE DOMINANCE
- No Allele Is Completely Dominant
- Neither red nor white allele is completely
dominant
52Incomplete dominance in flower color
Parental generation
X
RR
rr
F1 generation All Heterozygotes
Rr
Self-fertilization
F2 generation
1/4 RR
1/4 Rr
1/4 Rr
1/4 rr
Red
Pink
White
53INCOMPLETE DOMINANCE
- Red allele red pigment
- Two copies needed for
- flower to be red
- White allele no pigment
- Need two copies for flower to be white
- In heterozygous form neither allele dominates
- Red allele specifies enough pigment to make
flowers pink but not red - NOT blending because red and white flowers
appear in F2
54CODOMINANCE
- Two alleles specify different phenotypes but one
does not mask expression of the other - Type AB Blood
55CODOMINANCE
- Blood type
- Determined by type of glycoprotein on RBC
membrane - 3 possible alleles
- A
- B
- O
- A B are dominant to O but co-dominant to each
other - The existence of more than two alleles at a gene
locus is called multiple allelism (polymorphism)
56CODOMINANCE
- Blood Type
- With alleles AA or AO you have type A blood
- With alleles BB or BO you have type B blood
- With alleles OO you have type O blood
- With alleles AB you have type AB blood
- Both alleles expressed Codominance
57CODOMINANCE
- ABO Blood System
- Three alleles
- Six genotypes
- Four phenotypes
58ENVIRONMENTAL EFFECTS
- Environmental conditions help
- determine expression of genotype
- Ex Siamese cat
- Himalayan rabbit
- Both carry allele specifying heat-sensitive
enzyme for melanin production
59ENVIRONMENTAL EFFECTS
- Temp. sensitive enzyme acts at surface of body
- In cold areas enzyme is more active
- fur is darker
60QUANTITIVE TRAITS
A result of more than one gene contributing to
phenotype
- Some traits show continuous variation
- Eye color
- Human skin color
- Height
- The greater the number of genes influencing
trait the greater the variation in traits
expressed
