Genetics Lesson 3-4 PDF

Summary

This document provides notes on genetics, covering topics such as Mendel vs. Darwin, modern evolution, the link between Mendelian and Darwinian theories, chromosomes and heredity, the cell cycle, mitosis, meiosis, chromosome structure, and more.

Full Transcript

Biomedical Sciences &
Therapeutics: Genetics
(MSOP-1002)
 Lectures 3-4 contents
Mendel vs Darwin
‘Modern’ evolution
The link between Mendelian and Darwinian
theories
Link between chromosomes and heredity
Cell cycle and cell division
Mitosis and meiosis (and the difference)
Chromosome structure and function
 Mendel vs Darwin
There is no evidence that Darwin knew about
Mendel’s experiments, and he certainly didn’t cite his
work in his own publications
However Mendel did know of Darwin’s studies and
was critical of some ideas
For example, Darwin wrote a ‘provisional hypothesis
for Pangenesis’ in which each organ or tissue had
‘gemmules’ which had trait information
These gemmules travelled via the circulatory
system to the reproductive organs and parental
gemmules combined at fertilization
 ‘Modern’ natural selection
During the industrial revolution, pollution changed
the city environment rapidly and significantly
Prior to 1848, all examples of the Peppered Moth
collected were grey/white with black mottling. In 1848
a black variant (carbonaria) found in Manchester
By 1900, 90% city peppered moths were carbonaria
Thus moths that had the beneficial colour trait had a
greater probability of surviving to reproduce, thus
leading to a population density increase in that trait -
natural selection!
 ‘Modern’ natural selection
In the 1950’s, Bernhard Kettlewell conducted ‘mark/
release/ recapture’ experiments, showing higher bird
predation of moths in non-camoflaged environments
(city and country)
Remember such new variants occur by RANDOM
mutation
‘Modern’ natural selection

Individuals of one extreme
phenotype are favoured
Numbers of phenotype vary
in population
 Paleontology
Paleontology is the study of of the history and
development of life on earth
This is primarily based on the fossil record. Fossils are
generally the mineralised remains (e.g. skeletal) or traces
(e.g. footprints) of living organisms in rock or sediments
The geological position of fossils enables dating and the
examination of remains enables evolutionary relationships to
be determined, and phylogenetic trees drawn (phylon – tribe
or race, genesis – birth)
As new fossil finds are discovered, continued clarification of
how species have evolved (or died out)
 Evidence for Evolution: Fossils
Fossil records show
– Extinctions
– Change in species
17
 Common ancestry
Natural Selection envisages the origins of species currently
living on earth form a ‘tree’
Thus different modern species have common ancestors

The common ancestor of man and apes is known as
the ‘missing link’: this would be neither human nor ape
Natural selection and genetic transmission
Despite the robustness of Darwin’s theory, it was
not based on Mendel’s ideas of genetic transmission
Indeed, seven years after (1866) the Origin of
Species was published, Mendel stated ‘the laws of
inheritance are for the most part unknown’
On the surface, Darwin believed in ‘continuous
variation’ and Mendel in ‘discontinuous variation’
Natural selection and genetic transmission
Darwin died in 1882, and Mendel in 1884. Around
this time, several scientists noted so-called ‘coloured
bodies’ or ‘chromosomes’ in nuclei of stained cells
The German anatomist Walther Flemming described
the segregation of chromosomes into daughter cells
during cell division. He called the process ‘mitosis’
(Greek for thread)
 Linking Mendel and Darwin
In 1900, the Englishman William Bateson became
pre-eminent in ‘rediscovering’ and popularising
Mendel and invented the term ‘genetics’

After confirming Mendel’s data, the botanist Hugo
DeVries postulated a ‘mutation theory’ to explain
evolution. He also coined the term ‘pangene’ for the
unit of inheritance, from Darwin’s - pangenesis
(‘whole’ ‘origin’) – theory of heredity
 Linking Mendel and Darwin
With Mendel’s work in higher profile, Boveri & Sutton
were first to link chromosome behaviour in cell division
to Mendelian segregation in 1902
In 1911, American Thomas Hunt Morgan linked
Mendelian inheritance to (sex) chromosomes in
studies with fruit flies displaying mutant traits
He also proposed the idea of ‘genetic linkage’ where
he observed some traits were often inherited together
 Linking Mendel and Darwin

Thus the process of heredity involves both the
orderly transmission of Mendel’s ‘particulate
factors’ (i.e. genes/chromosomes)
and
‘natural selection’ based on smaller genetic
changes (e.g. mutations) producing slight
variations in the population, which may confer
survival or reproductive advantage
 Genes Are on Chromosomes
Mendel was unaware of chromosomes
– “Genes” were inheritable units
– Their physical structure was unknown
Chromosomes seen to segregate during
mitosis (Flemming)
‘Chromosome theory of inheritance’
(Boveri & Sutton)
– Inherited units (genes) are on the chromosomes
Essential Cell Biology (© Garland Science 2010)
 How Are Chromosomes, DNA,
and Genes Related?
Homologous chromosomes
– Chromosomes that pair up during meiosis
– Contain the same genes
– One comes from each parent
Each is one long DNA molecule
– A gene is a short region of the molecule
– Each chromosome can have > 1,000 genes
Somatic Cells are Diploid
 Karyotype
Chromosomes are
visible during mitosis
Humans have 46
chromosomes
Sex chromosomes
Females have 2 X chromosomes (XX)
Males have X and Y (XY)
Autosomes
The other 22 pairs of chromosomes are
homologous
 Homologous Chromosomes
46 chromosomes are arranged in 23
pairs
– One came from each parent
22 pairs are autosomes
– Both chromosomes are homologues
1 pair are sex chromosomes
– Can be homologous; XX for females
– Can be different; XY for males

© 2009 W.W. Norton & 22
Company, Inc.
Homologous
Chromosomes
 Cell Division
When eukaryotic (e.g. human), somatic cells divide, the whole
process is called Mitosis
When ‘germ’ cells divide (producing gametes) it is known as
Meiosis
Cell division (confusingly also known as mitosis) is only one
part of the ‘cell cycle’
Most of the cell cycle is called Interphase – this is where cell
prepares for cell division (DNA replication → sister chromatids)
In mitosis chromatids spilt at centromere → identical
chromosomes → each migrates in a new ‘daughter cell’
The Cell Cycle
Interphase: The Longest Stage
The period between divisions
– Longest phase of the cell cycle
– The cell prepares to divide
Divided into 3 stages:
– G1: growth after mitosis (M phase)
– S: synthesis of DNA
– G2: growth before mitosis (M)
 G1 and G2 phases

G stands for “gap”
– Early biologists saw a gap
Between S phase and cell division
– Important for two reasons
periods of growth
– size of cell and protein content increase
preparation for next phase
– checkpoint that ensures conditions are suitable
 G0 Phase

Most cells are not actively dividing
These cells are in G0 phase
– Can last days to years
– Some cells will divide again; e.g. liver cells
– Some cells stay in G0; e.g. nerve cells
 Mitosis
Consists of five phases
– Prophase
– (Prometaphase)
– Metaphase
– Anaphase
– Telophase
Cytokinesis: division of the cytoplasm
Mitosis
 Prophase

Cell enters mitosis
– Chromosomes condense
– Centrosomes move apart
Go to the poles of the cell
– Mitotic spindle begins to
form
 Prometaphase
Mitosis proceeds
– Chromosome condensation completed
– Nuclear envelope breaks down
– Mitotic spindle extends from centrosomes
Attaches to centromeres of chromosomes
Kinetochore: site of attachment
Chromatids linked to opposite poles
 Metaphase

Chromosomes line up
– Metaphase plate
– Align sister chromatids
Equal and balanced
segregation
 Anaphase
Chromatids separate
– Break free and dragged
to opposite sides
Microtubules shorten
Result:
– Equal segregation of
chromosomes in two
daughter cells
 Telophase and Cytokinesis

Telophase:
– Chromosomes reach the poles
– Mitotic spindle falls apart
– Chromosomes unfold
– Nuclear membrane reforms
Cytokinesis
– Cytoplasm is divided
– Two cells are formed
 Meiosis

Used to make gametes Meiosis

– Ovules/eggs and pollen/sperm
Chromosome number is halved
(haploid)
Zygote is diploid after fertilisation Fertilization

Mitosis
 Meiosis vs Mitosis
Meiosis is the process of cell division that occurs in ‘germ’
(from germinate) cells (gametes; eggs, sperm)
The process of meiosis is essentially the same as for mitosis,
except with a crucial, extra ‘reductional’ cell division producing
4 daughter cells from each parent cell
The resulting daughter cells
are thus haploid – only one
set of chromosomes,
from one parent only
In mitosis the daughter cells
are diploid – two sets of
chromosomes, one originating
from each parent
During fertilisation, gametes
combine to reconstitute diploid zygotes
 Meiosis I vs. Mitosis

Sister Chromatids
separate

Sister Chromatids
remain attached

Make notes to compare and contrast events in Mitosis vs Meiosis I
 Meiosis II

Metaphase Anaphase
 Meiosis vs Mitosis
In meiosis, homologous chromosomes (e.g. #3 – one
from each parent) pair up during prophase I on the
spindle – this pairing does not happen in mitosis
These pairs align along the length of the chromatids
and ‘zip’ together in ‘synapsis’
At this stage the pair exchange homologous parts in
a process called ‘crossing-over’ (first noted by Morgan
in 1916)
 Meiosis vs Mitosis
This is another system, like independent
assortment (of whole chromosomes) in gamete
production, that results in an increase in genetic
variation within a population
Thus genes that are closely positioned often result
in linked traits in individuals – genetic linkage
The new combination of traits may prove to be
advantageous (or not) to survival and reproduction
– a major contributor to Natural Selection
 Linkage and Crossing Over
Linkage: 2 genes on the same chromosome
– Not independently assorted
– Segregate together
Crossing over
– Linked genes should segregate together
– Crossing over causes them to separate
Crossing Over Reduces Genetic Linkage

Homologous chromosomes line up during metaphase
of meiosis
Parts of maternal and paternal chromosomes migrate
Linked Genes Are Inherited Together
◼ Test cross
◼ Independent assortment
predicts ¼ of each
phenotype
◼ Results are much
different
◼ These genes are linked

8
Impact of Crossing Over
Linked genes should
always assort together
Should have resulted in
two phenotypes
– Both recessive or both
dominant traits
– 50% of each
Crossing over changes
that result
– Result is less clear-cut

9
 Chromosomes Package DNA
DNA molecules are enormously long
– Double helix nearly 2 metres in length
DNA is tightly packaged with proteins
Chromatin
– DNA and proteins
Chromosome
– Tightly packed
 Chromosomes and DNA
The strand of DNA is wrapped round structures called
nucleosomes
Nucleosomes consist of proteins called histones, arranged
into ‘beads’
Each bead has a precise length of DNA wrapped round it
The string of nucleosomes is called chromatin
Mutiple chromatin strings fold into fibres
The chromatin fibres form loops which pack into the
chromatids (chromosome arms)

Electron microscope image
of chromatin (nucelosomes visible)
Levels of
Packaging
Metaphase—fully
condensed
Tightly packed loops
30 nm fibers
Histone spool
Double helix
 Managed Student Centred
Learning (MSCL)
Read relevant sections in Chapters 9,10, 12 and 13 in
‘Discover Biology’ (Cain et al) core module textbook
Try some of the ‘Self-Quiz’ questions (at end of chapters) for
topics we’ve covered
Some animations placed on Moodle
Remember to listen to BBC Sounds link:
‘In Our Time: mutation, evolution & disease’
on Moodle
Relevant weblinks on Moodle
(e.g. ‘What Darwin didn’t know’ article)