Mendelian Genetics Notes

AP Biology—Unit 6 Name:

Mendelian Genetics Notes

I.  Genetic Info.

A.  DNA

i. Chromosome: coiled when cell divides

ii.  Chromatin: long, thin, uncoiled to unzip (when not dividing)

iii.  Chromatid: two sister strands of DNA (2 chromatids=1 chromosome)

B.  Chromosomes-2 types

i. Autosomes-come in homologous pairs (1 from mom, 1 from dad)- alike in size, info form same type of protein

ii.  Sex chromosome- you have 2…could be homologous (XX) or not (XY)

C.  Karyotype-photograph of chromosomes

i. Tells us: correct number of chromosomes, gender, correct length (couldn’t tell us about nucleotide changes

or about specific genes)

ii.  Why?

·  Test for disorders like Down’s Syndrome (Chromo. 21)-couldn’t survive w/extra or missing chromosome like #1 b/c it’s big and has too much info.

·  Also may use it for sport testing-women can have a condition in which they have an XY (Androgen Insensitivity Syndrome), these women tend to be tall, thin, athletic, etc.

iii.  Dark/light areas = banding—helps pair chromosomes up (just means they coil more/less tightly)

iv.  Look up karyotypes on internet for examples

D.  Gene-section of DNA w/info. for 1 protein

i. In humans, we have 24 chromosomes of genes b/c we have to count each sex chromosome

ii.  How many genes do we have? Not sure but # is getting smaller b/c 1 string of amino acids could code for more than 1 protein (~20,000 genes in 24 chromosomes)

iii.  Alleles: pair of genes for the same protein

II.  Meiosis-see picture and notes accompanying notes

III.  Gametogenesis-see picture and accompanying notes

IV.  Variation in Meiosis—see picture and accompanying notes

A.  Segregation: ½ sex cells get 1 of each chromosome and other ½ sex cells get other 1 of each chromosome (separation)

B.  Independent Assortment: position of chromatids @ Metaphase I is random; one pair does not influence what happens to other pairs

2n (n=number of pairs) possible gamete combinations

C.  Crossing Over:

i. in prophase I, 2 non-sister chromatids form a chiasma (crossing over region) and exchange equal bits of chromosomes

ii.  produces recombinant chromosomes (combines genes from both parents)

D.  Random Fertilization

i. 223 for egg * 223 for sperm= 70 trillion possibilities PLUS crossing over

E.  Non-Disjunction

i. Homologous pairs don’t separate properly in Anaphase I OR…

ii.  Chromatids don’t separate properly in Anaphase II

iii.  Result=aneuploidy (incorrect # of chromosomes)

·  Monosomic (missing 1 chromosome)

·  Trisomic (extra chromosome in a pair)

·  Polyploidy (extra entire set of chromosomes- only happens in plants-sometimes on purpose i.e. seedless plants)

V.  Mendelian Genetics-see problems

A.  Monohybrid cross (1 trait)-

i. Dominant- a trait that is expressed (G=green peas)

ii.  Recessive- only expressed when dominant is not present (g=yellow peas)

iii.  Homozygous- alleles are identical (GG or gg)

iv.  Heterozygous- alleles are not identical (Gg)

v.  Phenotype- a description of the trait-use words (green or yellow peas)

vi.  Example: Gg*Gg

½ G / ½ g
½ G / ¼ GG / ¼ Gg
½ g / ¼ Gg / ¼ gg

vii.  Example: Gg*gg

½ Gg

½ gg

viii.  Example: GG*gg

1Gg

If both homozygous then all same

If 1 heterozygous ½ and ½

If both heterozygous, ¼, 2/4, ¼

Not ½ because we need to do ratios (for genotype)

Can say ½ for phenotype

B.  Dihybrid Cross (2 traits)-
R-round G-green
r-wrinkled g-yellow
Genotypes of…
~heterozygous round, yellow? Rrgg
~wrinkled, homozygous green? rrGG
Phenotype of GgRr? Green and round peas

Examples:

1. Rrgg x RrGg
Look at each gene pair separately…
Rrgg x RrGg

¼ RR ½ Gg

2/4 Rr ½ gg

¼ rr

Now…multiply the gene pair probabilities together. We call this the law of multiplication. It would be a good idea to watch Bozeman if you’re confused…

Genotypic Ratio Phenotypic Ratios

1/8 RRGg 3/8 Round and green peas

1/8 RRgg 3/8 Round and yellow peas

2/8 RrGg 1/8 wrinkled and green peas

2/8 Rrgg 1/8 wrinkled and yellow peas

1/8 rrGg

1/8 rrgg
2. wrinkled yellow x homozygous round, heterozygous green
rrgg x RRGg

1 Rr ½ Gg

½ gg

Genotypic Ratio Phenotypic Ratio

½ RrGg ½ Round and green peas

½ Rrgg ½ Round and yellow peas
3. Chance of Rrgg from RrGg x RrGg

Chance of getting Rr = ½

Chance of getting gg = ¼

Multiply the two chances together…and the answer is… there is a 1/8 chance of getting Rrgg.

NOTE: I could reduce 2/4 to ½ for the Rr because we aren’t looking at ratios in this problem.

Add T-tall and t-short to others…

TTRrGg x ttrrgg

Give genotypic and phenotypic ratios for above cross

1Tt ½ Rr ½ Gg

½ rr ½ gg

Genotypic Ratios Phenotypic Ratios

¼ TtRrGg ¼ Tall, round and green

¼ TtRrgg ¼ Tall, round and yellow

¼ TtrrGg ¼ Tall, wrinkled and green

¼ Ttrrgg ¼ Tall, wrinkled and yello