AP Biology CMR @ SOHI ‘98 B.Rifepage 1 /8

III. Unit 3:

Patterns of Inheritance - Chapter 9

Genetics - The science that is concerned with the study of biological inheritance.

9.1 The science of genetics has ancient roots

Pangenesis - the ancient Greeks believed in the idea that particles governing the inheritance of each trait collect in eggs and sperm and are passed on to the next generation.

Darwin’s comprehensive theory of heredity and development, according to which all parts of the body give off gemmules which aggregate in he germ cells; during development, they are sorted out from one another and give rise to parts similar to those of their origin.

Based on artificial breeding, nineteenty-century observers believed in the “blending” hypothesis, in which traits from both parents blend in the offspring.

9.2 Experimental genetics began in an abbey garden

Gregor Mendel

At the time Mendel began his study of heredity, a blending theory of inheritance was popular.

Mendel chose to work with the garden pea, Pisum sativum

When these varieties self-pollinated (self-fertilize), they were true-breeding - the offspring were like the parent plants, and like each other.

Cross-fertilization - The fusion of sperm (pollen) and egg derived from two different individuals. (hybridization or cross)

Mendel called the original parents the P generation,the first generation offspring the F1(filial) generation and the second generation offspring of the F1 plants the F2 generation.

Mendel’s paper, published in an obscure journal in 1866, argued that there are discrete, “inheritable factors” that retain their individuality when transmitted from generation to generation.

Genes - are the units of heredity within the chromosomes.

9.3 Mendel’s principle of segregation describes inheritance of a single trait

Crosses that involve only one trait are called monohybrid crosses.

In Mendel’s cross of true P organisms, all F1 offspring were like the dominant trait (tall) of the P organisms and heterozygous (Tt).

In all crosses that he performed, he found a 3:1 ratio in the F2 generation.

A 3:1 ratio among the F2 offspring was possible if:

1. the F1 contained two separate copies (alleles) of each hereditary factor (genes), one of these being dominant and one being recessive.

2. the factors separated when the gametes were formed and each gamete carried only one copy (alleles) of each factor, and

3. random fusion of gametes occurred upon fertilization.

In this way, Mendel arrived at the first of his laws of inheritance:

Mendel’s Law of Segregation. Each organism contains two factors (alleles) for each trait (genes), and the factors segregate during the formation of gametes so that each gamete contains only one factor from each pair of factors. When fertilization occurs, the new organism will have two factors for each trait, one from each parent.

Modern Terminology

Alleles - is a pair of genes located at a particular location of homologous chromosomes called the gene locus. In genetic notation, the alleles are identified by letters. (Tt)

Dominant allele is named because of its ability to mask the expression of another allele and is identified by an uppercase (Capital) letter. (AA)

Recessive allele is identified with the same letter , but lowercase (small). (aa)

Homozygousis when an organism has two identical alleles (either both dominant or both recessive)

Heterozygousis when an organism has two different alleles (dominant & recessive) at a gene locus.

Genotype and Phenotype

The word genotyperefers to the alleles an individual receives at fertilization and is represented by letters.

The word phenotype refers to the physical appearance of the individual. The phenotype is a function of the dominant alleles. (blue eyes)

Genetics Problems

When solving a genetics problem, it is first necessary to know which characteristic is dominant.

When designating the gametes, it is necessary to keep in mind that although the individual may have two alleles for each trait, each gamete carries only one allele for each trait.

Punnett Square is a simple method to calculate the results of a cross. Fig 9.3 pg 152 show the results of a cross between two heterozygous organisms.

The genotype ratio is 1/4 PP : 1/2 Pp : 1/4 pp or 1:2:1

The phenotype ratio is 3 dominant to 1 recessive (Out of 929 F2 offspring, 705 were purple, 224 were white. The proportions are not exactly 3/4 and 1/4 because mating involves probabilities.)

Mendel observed that each of the seven traits exhibited the same inheritance pattern.

9.4 Homologous chromosomes bear the two alleles for each trait

Chromosomes come in pairs called homologous chromosomes because they carry genes for the same traits.

Although Mendel knew nothing about chromosomes, our knowledge of chromosome arrangements (in homologous pairs) strongly supports the principle of segregation.

Alleles of a gene reside at the same locus on homologous chromosomes. Fig 9.4 pg 153

9.5 The principle of independent assortment is revealed by tracking two traits at once

Dihybrid Inheritance

Dihybrid crosses are crosses between two organisms that differ in two traits.

Mendel’s Law of Independent Assortment: Members of one pair of factors segregate (assort) independently of members of another pair of factors. Therefore, all possible combination of factors can occur in the gametes.

All possible combinations of alleles located on different chromosomes occur in the gametes because homologous pairs of chromosomes separate independently during meiosis. (Only one letter of each kind may appear in a gamete.)

Mendel always observed a 9:3:3:1 ratio among the F2 generation of a dihybrid cross.

1 = first characteristic 2 = second characteristic

D = dominantr = recessive

D1 chance = 3/4 r1 chance = 1/4

D2 chance = 3/4r2 chance = 1/4

chance of D1 D2 phenotype = 3/4 x 3/4 = 9/16 9

chance of D1 r2 phenotype = 3/4 x 1/4 = 3/163

chance of r1 D2 phenotype = 1/4 x 3/4 = 3/163

chance of r1 r2 phenotype = 1/4 x 1/4 = 1/161

See Fig 9.5 pg 154

9.6 Geneticists use the testcross to determine unknown genotypes

The Monohybrid Testcross

In a testcross, an individual with a dominant phenotype is crossed with an individual having the recessive phenotype. The testcross allows one to determine whether the dominant phenotype is homozygous dominant or heterozygous dominant.

9.7 Mendel’s principles reflect the rules of probability

Laws of Probability is another method of calculating the expected ratios. The chance or probability that two or more independent events will occur together is the product of their chances of occurring separately.

(Rule of Multiplication)

The chance of an event that can occur in two or more independent ways is the sum of the individual chances. (Rule of Addition)

Example

Chance of E (unattached earlobe) = 1/2

Chance of e (attached earlobe) = 1/2

Chance of EE = 1/2 x 1/2 = 1/4(Rule of Multiplication)

Chance of Ee = 1/2 x 1/2 = 1/4

Chance of eE = 1/2 x 1/2 = 1/4

Chance of ee = 1/2 x 1/2 = 1/4

Chance of phenotype with unattached earlobes

Ee + eE + ee = 1/4 + 1/4 + 1/4 = 3/4 (Rule of Addition)

9.8 Mendel’s principles apply to the inheritance of many human traits

Many human traits are thought to be determined by simple dominant-recessive inheritance, and sometimes the ratio of dominant-to-recessive phenotype exhibits a Mendelian ratio. (Do class count on some traits in figure 9.8)

The terms dominant and recessive refer only to whether or not a trait is expressed in the heterozygote, not to whether it is the most common.

9.9 The relationship of genotype to phenotype is rarely simple.

The inheritance of many traits among all eukaryotes follows the principles that Mendel discovered. However, most traits are inherited in ways that follow more complex patterns. (incomplete dominance, multiple alleles at a gene locus, pleiotrophy, and polygenic inheritance.

9.10 Incomplete dominance results in intermediate phenotypes

Incomplete dominance describes the situation where one allele is not completely dominant in the heterozygote; the heterozygote usually exhibits characteristics intermediate between both homozygous conditions.

Inheritance of alleles that relate to hypercholesterolemia

Normal individuals, HH, have normal amounts of LDL receptors proteins

hh individuals (1 : 106) have no receptors and five times the amount of blood cholesterol

Hh individuals (1 : 500) have half the number o receptors and twice the amount of blood cholesterol.

9.11 Many genes are represented by more than two alleles

The ABO blood groups in humans follow this pattern, in which individuals can have two alleles from a set of three possible alleles.

The surfaces of red blood cells contain genetically determined blood group antigens (agglutinogens) (carbohydrates) and the plasma of many persons contains genetically determined antibodies (agglutinins) against the blood group antigens which they do not have. The ABO and Rh blood grouping systems are based on antigen-antibody responses.

ABO blood grouping

TypeAgglutinogen AgglutininsCompatible Incompatible

(Carbohydrate)(antibodies)Donor BloodDonor Blood

AAbA, OB, AB

BBaB, OA, AB

ABA, B--A, B, AB, O--

O--a, bOA, B, AB

Type O (unversal donor) has neither carbohydrate and can receive no other type.

Type AB (universal recipient) has both carbohydrates A & B and thus no antibodies and can receive any type of blood.

9.12 A single gene may affect many phenotypic characteristics

In pleiotropy, the alleles of a single gene locus affect many phenotypic traits.

A relatively uncommon example is the inheritance of an allele that codes for abnormal hemoglobin and, in the homozygous condition, causes sickle-cell anemia.

The normal and abnormal alleles are codominant, so heterozygous individuals (carriers) can exhibit some symptoms, although normally they are healthy.

The incidence of the allele is relatively high in individuals of African descent, because sickle-cell carriers are somewhat protected from malaria.

9.13 A single trait may be influenced by many genes

In polygenic inheritance, a trait is controlled by several genes, and each allele adds quantitatively to the phenotype. The variations are continuous - there are many intermediate phenotypes - and the phenotypic distribution follows a bell-shaped curve.

9.14 Chromosome behavior accounts for Mendel’s principles

We have already seen that the fact that there are homologous pairs of chromosomes accounts for the principle of segregation.

The fact that there are several sets of homologous pairs of chromosomes accounts for the principle of independent assortment. Mendel’s seven garden pea traits all sorted independently of each other because the genes governing each trait are all on separate chromosomes.

9.15 Genes on the same chromosome tend to be inherited together

Linked genes are located close together on the same chromosome.

The inheritance of such genes does not follow the pattern described by the principle of independent assortment because the two genes are normally inherited together on the adjoining portions of the same chromosome.

The phenotypic ratios of such dihybrid crosses approach that of a monohybrid cross (3:1), rather than the typical pattern of the dihybrid cross. (9:3:3:1).

9.16 Crossing over produces new combinations of alleles

Cross over recombines linked genes into assortments of alleles not found in parents. Early examples of recombination were demonstrated in fruit flies by embryologist T. H. Morgan and colleagues in the early 1900s.

9.17 Geneticists use crossover data to map genes

A.H. Sturtevant, one of Morgan’s colleagues, developed a technique of using crossover data to map the locations of genes on chromosomes on which they were linked. Sturtevant assumed that the rate of recombination is proportional to the distance apart two genes are on a a chromosome.

The crossing-over frequency (equivalent tot he recombinant phenotype frequency) in crosses involving linked genes indicates the distance between genes on the chromosomes. (inc. frequency --> inc. dist. btw. loci (Morgan Units)

Example

% crossing over: AB 1%, AC 29%, AE 32%, CE 3%, BC 30%, BE 33%, BD 57%, CD 27%

______

9.18 Chromosomes determine sex in many species

In humans, XX individuals are female, and XY are male

In other species, other patterns of sex chromosomes exist.

In some species, sex is determined by chromosome number rather that chromosome type.

(XX female, XO (one X) male)

In some invertebrates (ants & bees) diploid individuals are female and haploid are male.

9.19 Sex-linked genes exhibit a unique pattern of inheritance

Sex chromosomes contain genes specifying sex and other genes for traits unrelated to sex. Because of linkage and location, the inheritance of these traits follows peculiar patterns. In humans, most (known) sex-linked traits result from genes on the X chromosome.

Some X-linked genes can control traits that have nothing to do with sex characteristics. Males have only one copy of these genes, and if they inherit a recessive allele, it will be expressed. (Hemophilia, Color Blindness)