Genetics I - Mendelian Genetics & Chromosomal Disorders PDF

Summary

This document details Mendelian genetics and chromosomal disorders. It includes topics such as inheritance, meiosis, and nondisjunction. The content is suitable for secondary school biology students.

Full Transcript

Genetics I =
Mendelian Genetics &
Chromosomal Disorders
6a: Construct an argument based on evidence to support the claim that heritable genetic
variations may result from various process such as crossing over during mitosis
6a1: Develop and use models to investigate how genetic variations arise during meiosis
(crossing over; nondisjunction)
7b: ask questions and define problems that explain the relationship between Mendel’s laws
and role (segregation & independent assortment) & the role of meiosis in reproductive
variability.
7c: Construct an explanation regarding how errors in meiosis (non-disjunction) may contribute
to certain human genetic disorders resulting from monosomy & trisomy.
Genetics: The Science
of Gregor Mendel
What is genetics?
the science of heredity

What is heredity?
passing of traits from parents to offspring.
From Mom & Dad to Child

Gregor Mendel (Born in 1822) – Austrian monk
who laid important groundwork for understanding
biological inheritance. He observed 7 inherited
traits in pea plants.
 “ The Father of Modern Genetics”

Studied offspring from different “matings,” or crosses, of pea plants.

He began his research with pea plants that were considered true-breeding.
Plants that have the ability to produce offspring identical to themselves,
through the use of their own gametes = “Self-Pollination” = true
breeding
 Most plants reproduce via
cross-pollination, the
combining of gametes from
two separate plants.

Mendel DID NOT want to
have this extra variable in his
research, so he prevented
his plants from
“self-pollinating” by crossing
the pea plants himself.

He cross-pollinated plants
with different forms of the
same trait (i.e. purple x
white) to examine offspring.
Conclusions…
Inheritance is
determined by genes.

Some alleles
(different forms of a
gene) are considered
Dominant and some
are Recessive
The Principle of
Dominance.
 From Mendel’s Research we have
2 Important Laws:
1. Law of Segregation
= Offspring inherit
two copies of each
gene, one from each
parent. Two alleles
for a trait segregate
(separate) when
Gametes are formed
 From Mendel’s Research we have
2 Important Laws:
Law of Independent Assortment = alleles for different
genes separate independently of each other during
gamete formation, Meiosis.
Applying Content I: Laws of Mendel
Christian’s hair is brown, but his eye color is
blue. Construct an argument using Mendel’s
law to explain why Christian’s hair does not
match his eye color.

Construct an argument that supports why a
little girl named Allison would only inherit one
set of information on hair color from her
mother, rather than 2 sets.
 Applying Content I: Laws of Mendel (ANSWERS)

Christian’s hair is brown, but his eye color is blue. Construct an
argument using Mendel’s law to explain why Christian’s hair does not
match his eye color.
According to the Law of Independent Assortment, alleles for different
genes are separate independently during meiosis. Therefore, hair
color does not affect ones eye color, because they are on separate
genes. Thus, Christians hair color can be different from his eye color
– they are independent of each other.

Construct an argument that supports why a little girl named Allison will
only inherit one set of information on hair color from her mother, rather
than 2 sets.
Based on the Law of Segregation, during meiosis each parent has a 50%
chance of passing on one of their traits to their offspring. Therefore, Allison
will only inherit one set/ half of the info on hair color from her mom (and she
will get the other half/ set from her dad). If Allison had 2 sets, she would a
mutation that could result in a genetic disorder.
So what happens when meiosis
goes wrong?
The most common error in meiosis occurs
when homologous chromosomes fail to
separate.
This is known as nondisjunction (not coming
apart).

If nondisjunction occurs, abnormal numbers
of chromosomes may find their way into
gametes, and a disorder of chromosome
numbers may result.
Nondisjunction
Nondisjunction causes gametes to have abnormal numbers of
chromosomes.
Applying Content II: Nondisjunction

Complete the
models showing
what would
happen if
Nondisjunction
nondisjunction
took place.

Nondisjunction
Applying Content II: Nondisjunction
(ANSWERS)
Complete the
models showing
what would
happen if
Nondisjunction
nondisjunction
took place.

Nondisjunction
How can we view our chromosomes?
To analyze chromosomes, cell biologists
photograph cells in mitosis (because the
chromosomes are fully condensed and easy
to see)
Biologists then cut out the chromosomes from
the photographs and group them together in
pairs
A picture of chromosomes arranged in this
way is known as a karyotype
 The Human Karyotype
The chromosomes in
this figure are from a
typical human body
cell, which contains 23
pairs (46 total)
chromosomes.
Is this a karyotype for
a male or female?
How do you know?
HINT: look at the
23rd pair of
chromosomes…
 An example of Nondisjunction…
If two copies of an autosomal chromosome fail
to separate during meiosis, an individual may
be born with three copies of a chromosome.
This type of nondisjunction is known as trisomy
(three bodies).
The most common form of trisomy involves 3
copies of chromosome 21 and is called Down
syndrome (trisomy 21).
Down syndrome produces mild to severe mental
retardation, increased susceptibility to many
diseases, and a high frequency of birth defects.
 Trisomy 21 – Down Syndrome

Karyotype showing trisomy 21 – individual has three #21
chromosomes. Child will exhibit facial characteristics of Down
syndrome, as well as difficulty processing some information in
the brain.
 Applying Content II: Chromosomal Disorders A

Kayrotype XYY – not characterized by a particular syndrome, but
usually are males who are somewhat taller than average; additional amounts
of testosterone.
 Applying Content II: Chromosomal Disorders B

Trisomy 16 – Major Cause of Miscarriage in 1st Trimester Pregnancy
 Applying Content II: Chromosomal Disorders C

Monosomy X (also known as XO) - individuals are phenotypically
female, but their sex organs do not mature at adolescence, and they are
sterile. Most have normal intelligence.
 Turner’s Syndrome (XO)
Symp/Charac Missing or
incomplete chromosome of
girls; Short, "webbed" neck
with folds of skin; Low
hairline in the back; Low-set
ears; Swollen hands and
feet ; infertility
Sex-linked
Chromosomal
Treatments Specific
to symptoms
 Applying Content II: Chromosomal Disorders D

Klinefelter Syndrome – XXY – have male sex organs, but testes
are abnormally small and the man is sterile. Often includes breast
enlargement and other feminine body characteristics.
 Klinefelter’s Syndrome (XXY)
⚫ Symp/Charac XXY male;
Abnormal body proportions
(long legs, short trunk,
shoulder equal to hip size) ;
Enlarged breasts; Less
than normal amount of
pubic, armpit, and facial
hair; Small, firm testicles
;Tall height
⚫ Sex-linked Chromosomal
⚫ Treatment Educational
services; Physical, speech
and occupational therapy;
Medical treatments
including testosterone
replacement