100% satisfaction guarantee Immediately available after payment Both online and in PDF No strings attached
logo-home
Bio 101 Chapter 10 Notes $11.99   Add to cart

Class notes

Bio 101 Chapter 10 Notes

 1 view  0 purchase

This is a comprehensive and detailed note on Chapter 10 patterns of inheritance. *Essential Study Material!!

Preview 3 out of 20  pages

  • October 11, 2024
  • 20
  • 2022/2023
  • Class notes
  • Prof. tracy
  • All classes
All documents for this subject (3)
avatar-seller
anyiamgeorge19
Chapter 10 - Patterns of Inheritance
10.2 Tracking Traits
Early Thoughts about Heredity
● In the nineteenth century, people thought that hereditary material must be some
type of fluid, with fluids from both parents blending at fertilization like milk into
coffee.
● However, the idea of “blending inheritance” failed to explain what people could
see with their own eyes.
● Children sometimes have traits such as freckles that do not appear in either
parent, for example. A cross between a black horse and a white one does not
produce gray offspring.
● At the time, no one knew that hereditary information is divided into discrete units
(genes), an insight that is critical to understanding how traits are inherited.
● Around 1850, Gregor Mendel began an extended series of experiments breeding
pea plants, which vary in traits such as flower color, height, and so on.
● Mendel, an Austrian monk, crossed thousands of plants, and kept careful records
of the traits of parents and offspring.
● Through these experiments, he gained insight into the nature of inheritance.
Mendel’s Pea Plant
● Mendel cultivated the garden pea.
● This species is naturally self-fertilizing, which means its flowers produce male
and female gametes that form viable seeds when they meet up.
● In order to study inheritance, Mendel had to carry out controlled matings
(crosses) between individuals with specific traits.
● First, he removed the pollen-bearing parts (anthers) from pea flowers.
● Removing anthers from a pea flower prevents it from self-fertilizing.
● Second, he cross-fertilized the flowers by brushing their egg-bearing parts
(carpels) with pollen from other plants.
● Third, he collected seeds that formed from the cross-fertilized flowers, planted
them, and recorded the traits of the resulting pea plant offspring .
● Many of Mendel’s experiments started with plants that “breed true” for particular
traits such as white flowers or purple flowers.
● Breeding true for a trait means that, new mutations aside, all offspring have the
same form of the trait as the parent(s), generation after generation.
● For example, all offspring of pea plants that breed true for white flowers also
have white flowers.
● As you will see in the next section, Mendel cross-fertilize pea plants that breed
true for different forms of a trait, and discovered that the traits of the offspring
often appear in predictable patterns.
● Mendel’s meticulous work breeding pea plants and tracking their traits led him to

, conclude (correctly) that hereditary information passes from one generation to
the next in distinct units.
● He published his work in 1866, but apparently it was read by few and understood
by no one at the time.
● In 1871 he was promoted, and his pioneering experiments ended.
● When he died in 1884, he did not know that his work with pea plants would be
the starting point for modern genetics.
Inheritance in Modern Terms
● Today, we know that Mendel’s “hereditary units” are genes. Individuals of a
species share certain traits because their chromosomes carry the same genes.
● Each gene occurs at a specific location on a particular chromosome
● Diploid cells have pairs of homologous chromosomes, so they have two copies of
each gene; in most cases, both copies are expressed at the same level.
● The two copies of any gene may be identical, or they may be different alleles.
Homozygous and Heterozygous
● An individual with the same allele of a gene on both homologous chromosomes
is homozygous for the allele (homo- means “the same”).
● Organisms breed true for a trait because they are homozygous for alleles
governing the trait.
● By contrast, an individual with different alleles of a gene is heterozygous for the
allele (hetero- means “different”).
● A hybrid is a heterozygous individual produced by a cross or mating between
parents that breed true for different forms of a trait.
Genotype and Phenotype
● Homozygous and heterozygous describe genotype, the particular set of alleles
that an individual carries.
● Genotype is the basis of phenotype, which refers to the individual’s observable
traits.
● “White-flowered” and “purple-flowered” are examples of pea plant phenotypes
that arise from differences in genotype.
Dominant and Recessive
● The phenotype of a heterozygous individual depends on how the products of its
two different alleles interact.
● In many cases, the product of one allele influences the effect of the other, and
the outcome of this interaction is reflected in the individual’s phenotype.
● An allele is dominant when its effect masks that of a recessive allele paired with
it.
● A dominant allele is often represented by an uppercase italic capital letter such
as A; a recessive allele, with a lowercase italic letter such as a.
Overall Message
● Genotype refers to the particular set of alleles that an individual carries.

, Genotype is the basis of phenotype, which refers to the individual’s observable
traits.
● A homozygous individual has two identical alleles of a gene. A heterozygous
individual has two nonidentical alleles.
● A dominant allele masks the effect of a recessive allele paired with it in a
heterozygous individual.

10.3 Mendelian Inheritance Patterns
Segregation of Genes into Gametes
● Meiosis separates the homologous chromosomes of a pair and packages each in
a different gamete.
● Thus, alleles on the homologous chromosomes end up in different gametes.
● Let’s use our pea plant alleles for purple and white flowers in an example.
● A plant homozygous for the dominant allele (PP) can only make gametes that
carry the dominant allele P.
● A plant homozygous for the recessive allele (pp) can only make gametes that
carry the recessive allele p.
● If the two homozygous plants are crossed (PP × pp), only one outcome is
possible: A gamete carrying allele P meets up with a gamete carrying allele p.
● All offspring of this cross will have both alleles—they will be heterozygous (Pp).
● A grid called a Punnett square is helpful for predicting the outcome of crosses
like this one.
Monohybrid Crosses
● Mendel did not know what alleles were, but he discovered that they segregate
into gametes and recombine in offspring.
● Experiments called monohybrid crosses were key to this discovery.
● A monohybrid cross is a cross between individuals that are identically
heterozygous for alleles of one gene (Aa × Aa, for example).
● The experiment begins with a cross between individuals that breed true for
different forms of a trait.
● The cross produces F1 (first-generation) hybrid offspring.
● A cross between two of these F1 individuals is the monohybrid cross, and it
produces F2 (second-generation) offspring.
● The frequency at which the two forms of the trait appear among the F2 offspring
offers information about a dominance relationship between alleles governing the
trait.
● A cross between two purple-flowered heterozygous plants (Pp × Pp) offers an
example of a monohybrid cross. Each of these plants makes two types of
gametes: gametes that carry a P allele, and gametes that carry a p allele.
● The two types of gametes can meet up in four possible ways at fertilization.
● Three of the four possible combinations include the dominant allele P. In other

The benefits of buying summaries with Stuvia:

Guaranteed quality through customer reviews

Guaranteed quality through customer reviews

Stuvia customers have reviewed more than 700,000 summaries. This how you know that you are buying the best documents.

Quick and easy check-out

Quick and easy check-out

You can quickly pay through credit card or Stuvia-credit for the summaries. There is no membership needed.

Focus on what matters

Focus on what matters

Your fellow students write the study notes themselves, which is why the documents are always reliable and up-to-date. This ensures you quickly get to the core!

Frequently asked questions

What do I get when I buy this document?

You get a PDF, available immediately after your purchase. The purchased document is accessible anytime, anywhere and indefinitely through your profile.

Satisfaction guarantee: how does it work?

Our satisfaction guarantee ensures that you always find a study document that suits you well. You fill out a form, and our customer service team takes care of the rest.

Who am I buying these notes from?

Stuvia is a marketplace, so you are not buying this document from us, but from seller anyiamgeorge19. Stuvia facilitates payment to the seller.

Will I be stuck with a subscription?

No, you only buy these notes for $11.99. You're not tied to anything after your purchase.

Can Stuvia be trusted?

4.6 stars on Google & Trustpilot (+1000 reviews)

67474 documents were sold in the last 30 days

Founded in 2010, the go-to place to buy study notes for 14 years now

Start selling
$11.99
  • (0)
  Add to cart