2. Gregor Mendel
ï§ Modern genetics began in the
mid-1800s in an abbey garden,
where a monk named Gregor
Mendel documented inheritance
in peas
ï” used experimental method
ï” used quantitative analysis
ï§ collected data & counted them
ï” excellent example of scientific
method
AP Biology
3. Mendelâs work Pollen transferred from white
flower to stigma of purple flower
ï§ Bred pea plants P
ï” cross-pollinate
true breeding parents (P)
ï§ P = parental anthers
removed
ï” raised seed & then all purple flowers result
observed traits (F1)
ï§ F = filial F1
ï” allowed offspring
to self-pollinate
& observed next self-pollinate
generation (F2) F2
AP Biology
5. Looking closer at Mendelâs work
true-breeding true-breeding
X white-flower peas
P purple-flower peas
100%
F1 purple-flower peas
generation 100%
(hybrids)
self-pollinate
75% 25%
purple-flower peas white-flower peas 3:1
F2
generation
AP Biology
6. What did Mendelâs findings mean?
ï§ Traits come in alternative versions
ï” purple vs. white flower color
ï” alleles
ï§ different alleles vary in the sequence of
nucleotides at the specific locus of a gene
ï· some difference in sequence of A, T, C, G
purple-flower allele &
white-flower allele are two DNA
variations at flower-color locus
different versions of gene at
same location on homologous
chromosomes
AP Biology
7. Traits are inherited as discrete units
ï§ For each characteristic, an organism
inherits 2 alleles, 1 from each parent
ï” diploid organism
ï§ inherits 2 sets of chromosomes,
1 from each parent
ï§ homologous chromosomes
ï§ like having 2 editions of encyclopedia
ï· Encyclopedia Britannica
ï· Encyclopedia Americana
What are the
advantages of
being diploid?
AP Biology
8. What did Mendelâs findings mean?
ï§ Some traits mask others
ï” purple & white flower colors are Iâll speak for
separate traits that do not blend both of us!
ï§ purple x white â light purple
ï§ purple masked white
ï” dominant allele
allele producing mutant allele
ï§ functional protein functional protein malfunctioning
ï· affects characteristic protein
ï§ masks other alleles
homologous
ï” recessive allele chromosomes
ï§ no noticeable effect
ï§ allele makes a
AP Biology malfunctioning protein
9. Genotype vs. phenotype
ï§ Difference between how an organism
âlooksâ & its genetics
ï” phenotype
ï§ description of an organismâs trait
ï” genotype
ï§ description of an organismâs genetic
makeup
P X
Explain Mendelâs results using purple white
âŠdominant & recessive
âŠphenotype & genotype F1
AP Biology all purple
10. Making crosses
ï§ Can represent alleles as letters
ï” flower color alleles â P or p
ï” true-breeding purple-flower peas â PP
ï” true-breeding white-flower peas â pp
P X
PP x pp
purple white
F1
all purple
Pp
AP Biology
11. Looking closer at Mendelâs work
true-breeding true-breeding
X white-flower peas phenotype
P purple-flower peas
PP pp genotype
100%
F1 purple-flower peas
generation 100%
(hybrids)
Pp Pp Pp Pp
self-pollinate
75% 25%
purple-flower peas white-flower peas 3:1
F2
generation
AP Biology ? ? ? ?
12. Aaaaah,
phenotype & genotype
Punnett squares can have different
F1 Pp x Pp ratios
generation
(hybrids) % %
genotype phenotype
male / sperm
PP 25%
P p
Pp 75%
PP Pp 50%
Pp
P
p
female / eggs
Pp pp pp 25% 25%
AP Biology 1:2:1 3:1
13. Genotypes
ï§ Homozygous = same alleles = PP, pp
ï§ Heterozygous = different alleles = Pp
homozygous
dominant
heterozygous
homozygous
recessive
AP Biology
14. Phenotype vs. genotype
ï§ 2 organisms can have the same
phenotype but have different genotypes
purple PP homozygous dominant
purple Pp heterozygous Canât tell
by lookinâ
at ya!
How do you determine the
genotype of an individual with
with a dominant phenotype?
AP Biology
15. Test cross
ï§ Breed the dominant phenotype â
the unknown genotype â with a
homozygous recessive (pp) to
determine the identity of the unknown
allele
x How does
that work?
is it pp
PP or Pp?
AP Biology
16. How does a Test cross work?
x x
PP pp Pp pp
p p p p
P Pp Pp P Pp Pp
P Pp Pp p pp pp
AP Biology 100% purple 50% purple:50% white or 1:1
17. Mendelâs 1st law of heredity PP
P
ï§ Law of segregation
ï” during meiosis, alleles segregate P
ï§ homologous chromosomes separate
ï” each allele for a trait is packaged into
pp
a separate gamete p
p
Pp P
AP Biology
p
18. Law of Segregation
ï§ Which stage of
meiosis creates the
law of segregation?
Metaphase 1
Whoa!
And Mendel
didnât even know
DNA or genes
existed!
AP Biology
19. Monohybrid cross
ï§ Some of Mendelâs experiments followed
the inheritance of single characters
ï” flower color
ï” seed color
ï” monohybrid crosses
AP Biology
20. Dihybrid cross
ï§ Other of Mendelâs
experiments followed
the inheritance of 2
different characters
ï” seed color and
seed shape
ï” dihybrid crosses
Mendel
was working out
many of the
genetic rules!
AP Biology
21. Dihybrid cross
true-breeding true-breeding
P yellow, round peas
x green, wrinkled peas
Y = yellow YYRR yyrr y = green
R = round r = wrinkled
F1 yellow, round peas
generation 100%
(hybrids)
YyRr
self-pollinate
9:3:3:1
F2
generation 9/16 3/16 3/16 1/16
yellow green yellow green
round round wrinkled wrinkled
AP Biology peas peas peas peas
22. Whatâs going on here?
ï§ If genes are on different chromosomesâŠ
ï” how do they assort in the gametes?
ï” together or independently?
YyRr Is it this? Or this? YyRr
YR yr YR Yr yR yr
Which system
explains the
AP Biology data?
23. YyRr YyRr
or
Is this the way it works?
YR yr YR Yr yR yr
YyRr x YyRr
9/16
yellow
round
YR yr 3/16
green
round
Well, thatâs
YR
YYRR YyRr NOT right!
3/16
yellow
wrinkled
yr YyRr yyrr
1/16
green
wrinkled
AP Biology
24. YyRr YyRr
or
Dihybrid cross
YR yr YR Yr yR yr
YyRr x YyRr
9/16
yellow
round
YR Yr yR yr
3/16
YR YYRR YYRr YyRR YyRr green
round
Yr YYRr YYrr YyRr Yyrr
BINGO!
3/16
yellow
wrinkled
yR YyRR YyRr yyRR yyRr
1/16
yr YyRr Yyrr yyRr yyrr green
wrinkled
AP Biology
25. Can you think
of an exception
Mendelâs 2nd law of heredity to this?
ï§ Law of independent assortment
ï” different loci (genes) separate into gametes
independently
yellow ï§ non-homologous chromosomes align independently
green ï§ classes of gametes produced in equal amounts
ï· YR = Yr = yR = yr
round ï§ only true for genes on separate chromosomes or
on same chromosome but so far apart that crossing
wrinkled over happens frequently
YyRr
Yr Yr yR yR YR YR yr yr
1
AP Biology : 1 : 1 : 1
26. Law of Independent Assortment
ï§ Which stage of meiosis
creates the law of
independent assortment?
Remember Metaphase 1
Mendel didnât
even know DNA
âor genesâ
existed!
EXCEPTION
ï§ If genes are on same
chromosome & close together
ï§ will usually be inherited
together
ï§ rarely crossover separately
AP Biology ï§ âlinkedâ
27. The
chromosomal
basis of Mendelâs
lawsâŠ
Trace the genetic
events through
meiosis, gamete
formation &
fertilization to
offspring
AP Biology
28. Review: Mendelâs laws of heredity
ï§ Law of segregation
ï” monohybrid cross
ï§ single trait
ï” each allele segregates into separate gametes
ï§ established by Metaphase 1
ï§ Law of independent assortment
ï” dihybrid (or more) cross
ï§ 2 or more traits
ï” genes on separate chromosomes
assort into gametes independently
ï§ established by Metaphase 1
EXCEPTION
AP Biology ï§ linked genes metaphase1
29. Mendel chose peas wisely
ï§ Pea plants are good for genetic research
ï” available in many varieties with distinct
heritable features with different variations
ï§ flower color, seed color, seed shape, etc.
ï” Mendel had strict control over
which plants mated with which
ï§ each pea plant has male & female
structures
ï§ pea plants can self-fertilize
ï§ Mendel could also cross-pollinate
plants: moving pollen from one plant
AP Biology
to another
30. Mendel chose peas luckily
ï§ Pea plants are good for genetic research
ï” relatively simple genetically
ï§ most characters are controlled by a single gene
with each gene having only 2 alleles,
ï· one completely dominant over
the other
AP Biology
He studied at the University of Vienna from 1851 to 1853 where he was influenced by a physicist who encouraged experimentation and the application of mathematics to science and a botanist who aroused Mendelâs interest in the causes of variation in plants. After the university, Mendel taught at the Brunn Modern School and lived in the local monastery. The monks at this monastery had a long tradition of interest in the breeding of plants, including peas. Around 1857, Mendel began breeding garden peas to study inheritance.
P = parents F = filial generation
In a typical breeding experiment, Mendel would cross-pollinate ( hybridize ) two contrasting, true-breeding pea varieties. The true-breeding parents are the P generation and their hybrid offspring are the F 1 generation . Mendel would then allow the F 1 hybrids to self-pollinate to produce an F 2 generation.
In a typical breeding experiment, Mendel would cross-pollinate ( hybridize ) two contrasting, true-breeding pea varieties. The true-breeding parents are the P generation and their hybrid offspring are the F 1 generation . Mendel would then allow the F 1 hybrids to self-pollinate to produce an F 2 generation.
Wrinkled seeds in pea plants with two copies of the recessive allele are due to the accumulation of monosaccharides and excess water in seeds because of the lack of a key enzyme. The seeds wrinkle when they dry. Both homozygous dominants and heterozygotes produce enough enzyme to convert all the monosaccharides into starch and form smooth seeds when they dry.