+IBDP Biology post, we will see how the DNA replicated, and what enzymes are involved with DNA replication.

DNA Replication 

DNA is kept in a double helix by:

• phospo-diester bonds of the sugar-phosphate backbone
• hydrogen bonds between the complementary bases

DNA Replication in Prokaryotes can only be initiated at one point

DNA Replication in Eukaryotes can be initiated at many points

Standard Level

1. DNA Helicase unwinds the and unzips DNA

The two strands are seperated by breaking Hydrogen bonds between complementary base pairs. The two separated strands become Template strands

2. DNA Polymerase creates complementary strands

DNA Polymerase always moves in a 5' to 3' direction. It catalyses the phopodisester bonds between sugar and phosphate molecules. 

HIGHER LEVEL

RNA Primers provide an attachment and initiation point for DNA Polymerase iii

RNA Primers: Short sequence of RNA nucleotides

DNA Replication moves in a 5' to 3' direction. The 5' is the end to which a new nucleotide attaches

Leading Strand: DNA is being replicated continously in a 5' to 3' direction

Lagging Strand: DNA is being replicated discontinously in small fragments in the 5' to 3' direction away from the replication fork

DNA Polymerase iii adds free nucleotides to C3. The strand grows from the 3' end

New strand: 5' to 3' direction 

Template strand 3' to 5' direction

Two new strands which are identical to the Template strand

Semi-Conservative: New strand contains one new and one template strand 

Enzymes involved in DNA Replication  

1. DNA Gyrase: Relieves strain and prevents supercoiling of DNA double helix

2. DNA Helicase: Unwinds and seperates double stranded DNA by breaking Hydrogen bonds between Complementary bases

3. RNA Primase: Synthesizes a short RNA Primer on each template strand to provide an attachment and initiation point for DNA Polymerase iii

4. DNA Polymerase iii: Adds nucleotides to the 3' end of the polynucleotide chain, synthesizing in a 5' to 3' direction

5. DNA Polymerase i: Removes the RNA Primers and replaces them with DNA

6. DNA Ligase: Joins the Okazaki fragments together to create a continuous strand  

That's the end ! Well done!

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References:

• https://www.google.com/url?sa=i&url=https%3A%2F%2Fbyjus.com%2Fbiology%2Fdna-replication-machinery-enzymes%2F&psig=AOvVaw2FeASQjuDWAJbjXXCkAcCg&ust=1626194915570000&source=images&cd=vfe&ved=0CAoQjRxqFwoTCPDBuaX-3fECFQAAAAAdAAAAABAD
• https://www.google.com/url?sa=i&url=https%3A%2F%2Fjackwestin.com%2Fresources%2Fmcat-content%2Fdna-replication%2Fspecific-enzymes-involved-in-replication&psig=AOvVaw2FeASQjuDWAJbjXXCkAcCg&ust=1626194915570000&source=images&cd=vfe&ved=0CAoQjRxqFwoTCPDBuaX-3fECFQAAAAAdAAAAABAJ

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