Lecture 5 - DNA Replication Flashcards
Explain Meselson and Stahl’s experiment
- They used density labelling to distinguish parent DNA strands from new DNA strands
- DNA was labelled with 15N, making it more dense
- Bacteria was grown in this ‘heavy’ medium then transferred to a normal ‘light’ medium (14N)
- At t=0 all DNA was heavy
- After two generations DNA was half ‘light’ and half ‘intermediate’ proving the semiconservative replication
Primase
Synthesizes short RNA sequences called primers that serve as a starting point for DNA synthesis.
In eukaryotes they are about 10 nucleotides long and made at intervals of 100-200 nucleotides on the lagging strand.
DNA polymerase I
- Removes RNA primers in lagging strand and fills in the nucleotides which are necessary for the formation of DNA in the direction 5’ to 3’.
- Helps in proof reading to see if there are any mistakes done while replicating and matching base pairs
- ONLY ADDS NUCLEOTIDES, DOESN’T JOIN THEM
DNA Polymerase III
Essential for the replication of the leading and lagging strands
- Alpha subunit: responsible for the DNA polymerase activity
- Epsilon subunit: proof reading exonuclease activity
- Theta subunit: smallest of all and helps in enhancing proof reading properties of epsilon
Ligase
Facilitates the joining of DNA strands together by catalyzing the formation of a phosphodiester bond.
On the lagging strand it joins the 3’ end of the new DNA to the 5’ end of the previous one.
Helicase
Uses hydrolysis of ATP to “unzip” or unwind the DNA helix at the replication fork to allow the resulting single strands to be copied.
1000 nucleotide pairs/second
Has 6 subunits
Telomerase
Made of protein and RNA subunits that elongates chromosomes by adding TTAGGG sequences to the end of existing chromosomes at the 3’ end.
Nuclease
Catalyses the cleavage of phosphodiester bonds
Topoisomerase
Regulates the over winding or under winding of DNA. Separates two chromosomes in prokaryotic DNA
Single-strand binding proteins
-Helix-destabilizing protein
Binds tightly and cooperatively to exposed single-strand DNA without covering bases, which therefore remain available as templates
Sliding clamp
Keeps the polymerase firmly on the DNA when it is moving, but releases it as soon as the polymerase runs into a double-strand region of DNA
- First discovered in dividing cells therefore called proliferating cell nuclear antigen (PCNA)
- Helps to orient the polymerase for substrate binding
- Removes the pre-replication complex from ori
Direction of synthesis for DNA replication
Synthesis of DNA replication is done from the 3’ to 5’ so that the new strand is in a 5’ to 3’ direction
Synthesis of leading strand
Made by continuous synthesis from a single primer
Synthesis of lagging strand
Made by synthesis of short Okazaki fragments from multiple primers.
Fragments nearest to the fork are the most recent.
Direction of nucleotide polymerization is opposite to the overall direction of DNA chain growth
Pre-replication complex
Large protein complex that interacts with the template strands. Bind to a DNA sequence in the ori
