Lecture Notes: Chapter 16 - The Molecular Basis of Inheritance PDF

Summary

These lecture notes cover Chapter 16 on the molecular basis of inheritance, providing an overview of DNA, RNA, replication, various experiments, and related concepts including errors and repair of DNA.

Full Transcript

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Chapter 16:
The Molecular Basis
of Inheritance
 Lecture Objectives

✓Know the various experiments that led to
the discovery of DNA & RNA
✓Know differences between DNA & RNA
✓Understand DNA replication
✓The editing process of DNA
✓Mistakes that can occur in DNA
✓Packaging of DNA
How does DNA replication transmit genetic info?

We just heard about mitosis &
meiosis and how
DNA needs to REPLICATE to pass the
genetic information down to offspring
How does DNA replication transmit genetic info?
 DNA is the genetic material

Early in the 20th century, the identification of the
molecules of inheritance posed a major challenge
to biologists
 The Search for the Genetic Material:

T. H. Morgan’s group showed that
genes are located on chromosomes,
1910-- Using fruit flies
DNA and protein—became candidates
for inheritable material

Frederick Griffith in 1928- discovery of
the genetic role of DNA
discovered through research on bacteria
& the viruses that infect them
worked with two strains of a bacterium,
one pathogenic and one harmless
 Can a genetic trait be transferred between
different bacterial strains?

Transformation= change in genotype and phenotype due to assimilation
of foreign DNA
Evidence That DNA Can Transform Bacteria

1944- Oswald Avery, Maclyn McCarty, and Colin
MacLeod
identified the transforming substance as DNA

Many biologists remained skeptical, mainly because
little was known about DNA
Further studies using:
bacteriophages (phages)= viruses that
infect bacteria
widely used as tools by researchers
in molecular genetics
viruses= DNA (sometimes RNA)
enclosed by a protective coat, often
simply protein
Phage T2 Reproductive Cycle
Evidence That Viral DNA Can Program Cells
In 1952,-- Alfred Hershey and Martha Chase showed
that DNA is the genetic material of a T2 phage
designed an experiment showing that only1 of 2
components of T2 (DNA or protein) enters an E. coli cell
during infection

They
concluded
that the
injected DNA
of the phage
provides the
genetic
information
More Evidence That DNA Is the Genetic Material

In 1950, Erwin Chargaff reported that DNA
composition varies from one species to the next
evidence of molecular diversity among organisms made
DNA a more credible candidate for the genetic material

Chargaff’s rules:
base composition of DNA varies
between species
In any species the # of A & T bases is =
and the # of G & C bases is equal
why was not understood until the discovery
of the double helix…
The structure of a DNA strand
 Building a Structural Model of DNA
Maurice Wilkins & Rosalind Franklin used a technique
called X-ray crystallography to study molecular
structure
Franklin produced a picture of the DNA molecule
using this technique
 Building a Structural Model of DNA
Franklin’s images of DNA allowed James Watson to
deduce that DNA was helical
also enabled Watson to deduce the width of the helix and
the spacing of the nitrogenous bases

The pattern in the photo suggested that the DNA
molecule was made up of two strands, forming a
double helix
 Building a Structural Model of DNA
Watson & Crick built models to
conform to the X-rays &
chemistry
Franklin concluded there were
2 outer sugar-phosphate
backbones,
with the nitrogenous bases
paired at the interior

Watson built a model in which
the backbones were
antiparallel (their subunits run in
opposite directions)
Stick Model DNA Double Helix
 Building a Structural Model of DNA
At first, Watson &Crick thought the bases paired A
with A, and so on, but such pairings did not result in
a uniform width across
Instead, pairing a purine (A or G) with a pyrimidine
(C or T) resulted in a uniform width consistent with
the X-ray data
 Building a Structural Model of DNA
Found pairing was more specific & dictated by the
base structures
Determined
adenine (A) paired only with thymine (T), &
guanine (G) paired only with cytosine (C)

Their model explains Chargaff’s rules: in any organism
the amount of A = T, and the amount of G = C
Proteins work together in DNA replication & repair

Inheritance relies on accurate replication of DNA
prior to meiosis & transmission to the next generation
Replication prior to mitosis
ensures the faithful transmission of genetic info

Watson & Crick’s base pairing suggested a possible
copying mechanism → DNA replication
Since the two strands are complementary, each acts as a
template for building a new one
yielding 2 exact replicas of the “parental” molecule
A model for DNA replication: the basic concept
 DNA replication: three alternative models
Competing models were
Semiconservative model
predicts each daughter
molecule will have one old
strand (derived or “conserved”
from the parent molecule) and
one newly made strand
Watson & Crick’s
Conservative model (the two
parent strands rejoin) &
Dispersive model (each strand
is a mix of old and new)
 How does DNA Replication

Inquiry: Does DNA
replication follow the
conservative,
semiconservative, or
dispersive model?
Experiments by
Matthew Meselson
& Franklin Stahl
supported the
semiconservative
model
 DNA Replication: A Closer Look
is remarkable in its speed & accuracy
more than a dozen enzymes and other proteins
participate!
Replication in bacteria is best understood, but evidence
suggests that the replication process in eukaryotes and
prokaryotes is fundamentally similar
 Getting Started
DNA Replication
begins at particular sites
origins of replication- where two DNA strands are
separated, opening up a replication “bubble”
proceeds in both directions from each origin, until the entire
molecule is copied

eukaryotic
chromosomes
have hundreds or
even thousands
of origins of
replication!
Animation: Origins of Replication
 Getting Started
At the end of each bubble is a
replication fork: Y-shaped region where parental DNA
strands are being unwound

Players involved:
Helicases untwist the double helix at the replication forks
Single-strand binding proteins bind to and stabilize single-
stranded DNA
Topoisomerase relieves the strain of twisting of the double
helix by breaking, swiveling, and rejoining DNA strands
It’s complicated!
 Synthesizing a New DNA Strand

DNA polymerases catalyze the
elongation of new DNA at a
replication fork
can only add nucleotides to the 3’ end of
a growing DNA strand

Most DNA polymerases require a
primer (5-10 bp) to which they can
add nucleotides
Synthesized by primase
 Synthesizing a New DNA Strand
nucleoside triphosphate- added to growing DNA
strand
dATP supplies adenine to DNA and is similar to the ATP of
energy metabolism

each joins the DNA
strand, via a
dehydration
reaction, losing
two phosphate
groups
(pyrophosphate)
 Antiparallel Elongation: Leading Strand
D N A polymerases add
nucleotides only to the
free 3′ end of a growing
strand; therefore, it can
elongate only in the
5′ → 3′ direction
along one strand the
DNA polymerase
synthesizes a leading
strand continuously,
moving toward the
replication fork
 Antiparallel Elongation: Lagging Strand

To elongate the
lagging strand, DNA
polymerase must
work away from
the replication fork
The lagging strand
is synthesized as a
series of Okazaki
fragments, which
are joined together
by DNA ligase
 DNA Replication

https://www.youtube.com/watch?v=s3nDTGg73AU
Bacterial DNA replication
Bacterial DNA replication proteins and their functions
The “trombone” model: DNA replication complex

--The proteins that participate in DNA replication form a large complex
that is hypothesized to stay stationary as the DNA winds through
 Proofreading & Repairing DNA
DNA polymerases proofread
newly made DNA, replacing
any incorrect nucleotides
In mismatch repair enzymes
replace incorrectly paired
nucleotides that have evaded
the proofreading process
In nucleotide excision repair,
a nuclease cuts out and
replaces damaged stretches
of DNA
Evolutionary Significance of Altered DNA Nucleotides

Error rate after proofreading and repair is low but not zero
sequence changes may become permanent and can be passed
on to the next generation
changes (mutations) are the source of the genetic variation upon
which natural selection operates & are responsible for the
appearance of new species!!
 Replicating the Ends of DNA Molecules
For linear DNA, the usual
machinery cannot
complete the 5′ ends of
daughter DNA strands
There is no 3′ end of a
preexisting polynucleotide for
DNA polymerase to add on to
After each round it would
produce shorter DNA
molecules with uneven ends
This is not a problem for
prokaryotes, most of which have
circular chromosomes!
 Replicating the Ends of DNA Molecules

A telomere= is repetitive DNA at the end of a
eukaryotic chromosome’s DNA molecule
postpones the erosion of genes near the ends of DNA molecules
possibly connected to aging

Telomerase catalyzes the lengthening of
telomeres in germ cells
Not present in somatic cells
 Chromosomes
A chromosome consists of a DNA molecule packed
together with proteins

bacterial chromosome: double- Eukaryotic chromosomes have
stranded, circular molecule with a linear DNA molecules associated
small amount of protein with a large amount of protein
DNA is “supercoiled” in a region
of the cell called the nucleoid
 Eukaryotic Chromosome

DNA is precisely combined with proteins in a
complex called chromatin
Chromosomes fit into the nucleus through an
elaborate, multilevel system of packing
Proteins called histones are responsible for the main
level of DNA packing in interphase chromatin
 Chromatin packing in a eukaryotic chromosome

In a 10-nm chromatin fiber, the unfolded
chromatin resembles beads on a string,
with each “bead” being a nucleosome
composed of DNA wound twice around a core of
eight histones, two each of the four main histone
types (H2A, H2B, H3, H4)

amino end of each, the histone tail extends
outward from the nucleosome and is
involved in regulation of gene expression
 DNA Packing

https://www.youtube.com/watch?v=9kQpYdCnU14
 Chromatin Packing
Most chromatin is loosely packed
during interphase & condenses prior to mitosis

Euchromatin= loosely packed chromatin
Heterochromatin= highly condensed chromatin
a few regions (centromeres and telomeres) are packed as
heterochromatin which makes it difficult for the cell to
express genetic information coded in these regions
 Lecture Objectives

✓Know the various experiments that led to
the discovery of DNA & RNA
✓Know differences between DNA & RNA
✓Understand DNA replication
✓The editing process of DNA
✓Mistakes that can occur in DNA
✓Packaging of DNA