BMS 532 Cytogenetics Intro and Meiosis PDF

Summary

This document is a lecture slide presentation on cytogenetics and meiosis. It covers the principles of heredity, the history of cytogenetics, as well as the details required for the student to understand the processes involved with meiosis.

Full Transcript

Block 2:
Principles of
Heredity and
Cytogenetics
THIS BLOCK FOCUSES ON CHROMOSOMES AND
PATTERNS OF INHERITANCE
Human
Cytogenetics:
A VERY Brief History
Lesson
CY T O G E N E T I C S = T H E S T U DY O F I N H E R I TA N C E A S R E L AT E D T O
CHROMOSOME STRUCTURE AND FUNCTION
CHROMOSOMES CAN BE THOUGHT OF AS FUNCTIONAL UNITS OF
HEREDITY
T H I S I S V E RY M U C H BO T H A N O L D A N D A YO U N G F I E L D I F YO U
C O N S I D E R M O D E R N A N A LY S E S A S B E I N G B A S E D I N CY T O G E N E T I C S
 An important history:
Thomas Hunt Morgan
Experimentally demonstrated Chromosome
Theory of Inheritance using Drosophila
1st solid link between a specific gene on a
specific chromosome causing a trait
Also determined the role of biological sex in the
inheritance of a trait (sex-linked inheritance)
Why MORE Science is Beneficial…
For more than 30 years it was scientific consensus that humans have
48 chromosomes due to the first report on human chromosomes citing
48
Tijo and Levan using a modified technique that produced more clear
chromosome spreads concluded 46 was the absolute number; This
was confirmed by Ford and Hamerton
In science, relying on one finding can lead down false paths
Once a finding is confirmed and reproducible by others it can be
elevated to fact
This is particularly important in clinical analysis as sample sizes tend
to be very small and can sometimes be misleading
Meiosis: A
Chromosome
Perspective
BMS 532
BLOCK 2 LECTURE 1
 Objectives
1. Explain the following terms and their relationship to both genotype and phenotype: chromosome, homologous chromosome, sister
chromatid, autosome, bivalent, independent assortment, alignment, segregation, linkage, cis vs trans, and recombination

2. Describe the process of chromosome separation during meiosis by stage and explain how crossing-over contributes to chromosome
behavior and repulsion during prophase I
◦ Summarize the steps of meiosis with emphasis on chromosome behavior and content
◦ List the sequential sub-phases of prophase I of meiosis and describe the major events of each sub-phase

3. Explain the concept of regions of homology and how they contribute to chromosome behavior during alignment,
homologous recombination, and separation
◦ Define regions of homology and describe how they are generated
◦ Link regions of homology to the processes that enable two or more nonhomologous chromosomes to align

4. Evaluate the processes involved in generating genetic variation in offspring and explain how changes in the steps and stages
associated with meiosis affect outcomes
◦ Describe the two factors associated with increasing variation of offspring: 1) Crossing-over or Recombination vs. 2) alignment and segregation
◦ Explain the process of recombination and the corresponding consequences of different forms of crossing over
◦ Explain how alignment and segregation relate to independent assortment
◦ List the potential consequences of alignment and segregation for multiple chromosomes

5. Assess the consequences for genotype and phenotype with parental and recombinant chromosomes with consideration of cis and
trans arrangements

6
LO1, LO2

Meiosis

7
 Chromosomes Quick
LO1

Introduction
Chromosomes consist of
linear sequences of genes
◦genetic information which
specifies the physical
expression of a phenotypic
trait
 Genetic Linkage Introduction
Homologous pairs of chromosomes
contain genes whose information is
often non-identical = alleles
Different alleles of the same gene
segregate at Meiosis I
Alleles of different genes assort
independently in gametes
Genes on the same chromosome exhibit
linkage
◦ Inherited together
◦ Violates Mendel’s assortment law

LO1
 Homologs vs. Sister
Chromatids
Humans diploid cells contain 46 total chromosomes,
44 autosomes and 2 sex chromosomes.
Chromosomes are inherited in haploid sets with one
set from maternal lineage and one from paternal
lineage
The chromosomes of each set have a companion
chromosome in the other set = Homologous
Chromosomes or Homologs
Homologous chromosomes contain the same
sequence of genes which may vary in expression =
alleles
◦ NOTE: Sequence of genes does NOT equal
sequence of bases!

Sister chromatids = duplicated versions of the
LO1chromosomes connected at a constriction point 10
 MITOSIS

LO1, LO2
 MEIOSIS I

LO1, LO2
 MEIOSIS II

LO1, LO2
 Meiosis: Prophase I
Multiple Distinct Stages for
Chromosome Condensation

Leptoten
e
Zygotene
Pachyten
e
Diplotene
Diakinesi
s
LO1, LO2
 Leptotene to Zygotene
Leptotene = First phase of prophase I when the chromosome become
visible under the light microscope.
Nucleus remains intact and process appears similar to prophase of
mitosis.
Condensation of the chromosomes continues

LO1, LO2
15
 Zygotene to Pachytene
Zygotene = Second phase of prophase I
Continued chromosome condensation and
homolog pairing
The homologs will synapse initiating crossing over
(crossing-over begins during zygotene)

Synapse represents a very tight association between
the sister chromatids of each homolog.
The two homologs when synapsed form what is
called a bivalent
Different numbers of chromosomes involved in
synapse are given different names
Solo chromosome = univalent
3 chromosomes = trivalent

Pachytene = continued chromosome condensation
and Chiasmata present but difficult to visualize
LO1, LO2
16
 Pachytene to Diplotene
Diplotene begins homolog “repulsion”
Forces to drive exchange and separation
begin
Chiasmata are more clear as chromosomes
have condensed further
Each chiasma is formed by a breakage and
rejoining event between nonsister
chromatids (HOMOLOGOUS
RECOMBINATION)
Synaptonemal complex breaks down and the
arms of the bivalent separate.

LO1, LO2
17
 A Bivalent of a Pair of Homologous
Chromosomes

LO1, LO2
 Diplotene to Diakinesis
Chromosome condensation continues.
Diakinesis = maximum forces to drive chromosomes apart (maximum contraction)
Concludes with breakdown of nuclear membrane and weaker association between homologs

LO1, LO2

19
 Meiosis: Metaphase I
Metaphase I – the bivalents positioned with
the centromeres of the two homologs on
opposite sides of the metaphase plate
As each bivalent moves onto the metaphase
plate, its centromeres are oriented randomly
with respect to the poles of the spindle
Genes on different chromosomes undergo
independent assortment because
nonhomologous chromosomes align at
random in metaphase I

LO1, LO2
 Meiosis Summary

LO1, LO2
 Meiosis and Genetic
Variation
There are two mechanisms that
generate genetic variation during
meiosis.
Random separation of homologs
(alignment and segregation)
Crossing over during prophase I
LO1, LO3,
LO4
22
 Alignment and Segregation

Each homologous pair is
independent.

Random segregation can
produce >8.3 million unique
combinations of human
chromosomes.

Premature separation of
chromosomes is a major
mechanism of aneuploidy

Multiply this by the amount of
variation that comes from
recombination (unknown large
LO1, LO3,
LO4
number).
2
LO1, LO3,
LO4
 Crossing Over During
Prophase I
Crossing over creates
novel combinations of
alleles on the
chromosomes.
While it is highly
probable that every
pair will undergo at
least one
recombination event,
many will actually
undergo multiple
events dramatically
increasing genetic
variation in the
daughter cells

25
LO1, LO3,
LO4, LO5

Recombination
Recombination between linked genes located on the same chromosome involves
homologous crossing-over
◦ allelic exchange between them

Recombination changes the allelic arrangement on homologous chromosomes =
recombinant
 Recombination

Recombination between linked genes occurs at the same frequency
whether alleles are in cis or trans configuration
Recombination frequency is specific for a particular pair of genes
Recombination frequency increases with increasing distances between
genes
No matter how far apart two genes may be, the maximum frequency
of recombination between any two genes is 50 percent.
LO1, LO3,
LO4, LO5
 Cis, Trans, Parental, and
Recombinants
In double heterozyote:
Cis configuration = mutant
alleles of both genes are on the
same chromosome = ab/AB
Trans configuration = mutant
alleles are on different
homologues of the same
chromosome = Ab/aB

LO1, LO3,
LO4, LO5
LO1, LO3,
LO4, LO5
LO1, LO3,

Making Connections to Past and
LO4, LO5

Future
Homologous recombination repair utilizes many of the mechanisms we
associate with traditional homologous recombination
◦ Regions of homology enabling strand crossover and exchange is very similar to
homology search and strand invasion

Recombination when done correctly as intended should not produce error
Inappropriate alignment can result in duplications and deletions similar to our
strand slippage during replication
◦ Repetitive regions do not always align perfectly
◦ If crossing over occurs after inappropriate alignment, one copy will have too much
info (duplications) and one will have too little (deletion)
◦ Chromosome deletions are among the most common genetic abnormality observed
clinically
Questions
At which point would you expect to be able to observe chiasmata and
bivalent chromosomes clearly? (LO2)
What does it mean for two genes to be linked and arranged in cis? In trans?
(LO1)
What do you expect for chromosome content for two genes that are unlinked
if the original parent is a heterozygote? (LO4)
What factors ensure that two chromosomes will line up and exchange
information? (LO3)