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Printable Handouts
Navigable Slide Index
- Introduction
- DNA replication
- Chemical composition of DNA
- Chargaff's rule
- DNA structure - Watson and Crick
- DNA double helix model
- DNA structure - base pairing
- Base pairing
- Semiconservative DNA replication
- DNA polymerase
- Mechanism of DNA replication
- Semidiscontinuous DNA replication
- Minimal requirements
- Cooperative action of proteins in DNA replication
- What we know
- DNA polymerase structure
- Structure of phage T7 DNA polymerase
- Chemical reaction catalyzed by DNA polymerases
- Metal ions play an essential role in DNA synthesis
- DNA synthesis has to be efficient and accurate
- Rates of correct and incorrect nucleotide addition
- Fidelity
- Correct nucleotide after an incorrect addition
- How are errors corrected?
- Fidelity: exonuclease activity
- Fidelity of DNA synthesis
- Processivity of the DNA polymerase
- Processivity factors
- DNA unwinding
- DNA unwinding: helicase protein
- Activities of the helicase protein
- Ring-shaped helicases
- Mechanism of dsDNA separation
- Mechanism of ATPase and DNA translocation
- Helicase functions in conjunction with DNA pol
- Synergy between proteins in DNA replication
- Primers for DNA replication
- Properties of the DNA primase
- DNA primase protein
- DNA replicase
- Many questions remain...
Topics Covered
- DNA structure
- Semiconservative DNA replication
- Mechanism of DNA replication
- DNA polymerase structure and function
- Metal ions in DNA synthesis
- Rates of correct and incorrect nucleotide addition
- Fidelity of DNA synthesis
- Helicase in DNA replication
- DNA primase protein
- DNA replicase
Talk Citation
Patel, S. (2022, April 27). DNA replication [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 22, 2024, from https://doi.org/10.69645/VHVL1896.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. Smita Patel has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
A selection of talks on Genetics & Epigenetics
Transcript
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0:00
DNA Replication.
0:03
DNA is the genetic
material of the cell that
carries all the information for
cell survival and
its propagation.
Every time a cell divides the
DNA needs to be duplicated.
During mitosis and meiosis,
a parental cell is divided
into two daughter cells.
During this process,
the DNA is efficiently and
faithfully replicated.
0:30
The chemical composition of DNA
has been known for some time.
DNA is a polymer and it is
made of repeating units
of phosphate, sugar and bases.
These units are arranged to give
the DNA polymer a polarity
or a directionality.
The DNA chain has a
3' end and a 5' end.
The DNA chain also has
four kinds of bases.
Two pyrimidines,
cytosine and thymine,
and two purines,
adenine and guanine.
1:06
Chargaff studied the base
composition of many genomes,
and an observation was made that
were an equal number
of As and Ts,
adenines and thymines,
in the genome,
as well as an equal number
of Gs and Cs in the genome.
This is known as the
Chargaff's Rule.
What remained a mystery
was how the DNA chain,
that we just saw in
the previous slide,
was duplicated or replicated
during each cell division.
1:38
The mystery was solved when
the work of four scientists
led to the discovery
of the DNA structure.
In a seminal paper published
in 1953 in the Nature journal,
Watson and Crick, using the data
from X-ray crystallography,
proposed a structure of the DNA.
This structure was
a double helix.