Bidirectional and rolling circular dna replication
- 1. BIDIRECTIONAL AND ROLLING CIRCULAR DNA REPLICATION S. Gayathri MSFBI1506 MOLECULAR BIOLOGY BIOINFORMATICS
- 2. What is Bidirectional DNA?? • DNA is double stranded molecule only one strand codes for proteins at any given point in the molecule. • However, both strands are used during DNA replication. • Each of the four bases in DNA(A,T,G,C) binds to a unique complementary base on the other strand. • Therefore the base sequence on the strand determines the complementary sequence on the other strand.
- 3. BIDIRECTIONAL DNA REPLICATION • Each new DNA molecule is composed of one conservative strand from the original molecule and one new strand. • A single origin and proceeds on both directions. • This form of replication is called semi conservative.
- 5. REPLICATION FORK: • The leading strand is the strand of nascent DNA which is being synthesized in the same direction as the growing replication fork. • A polymerase "reads" the leading strand template and adds complementary nucleotides to the nascent leading strand on a continuous basis. • Unidirectional – One fork moving away from the other which remains fixed at the origin of replication. • Bidirectional – Two replicating forks moving in opposite directions away from the origin.
- 7. REPLICATION BUBBLE: • It is formed during replication in both eukaryotic and prokaryotic DNA. It is place where replication occurs actively know as replication bubble. • Formation of the replication eye provides theta(θ) like structure to the circular DNA during replication in prokaryotes. • Each replication bubble found to have two replication forks, each at the corner of an eye.
- 10. DNA REPLICATION • DNA replication is the process by which DNA makes a copy of itself during cell division. • In molecular biology, DNA replication is the biological process of producing two identical replicas of DNA from one original DNA molecule. This process occurs in all living organisms and is the basis for biological inheritance. • DNA is made up of a double helix of two complementary strands.
- 11. STEPS FOR DNA REPLICATION: STEP 1 :. In DNA replication, the first step is to ‘unzip’ the double helix structure of the DNA molecule. STEP 2: DNA gyrase, often referred to simply as gyrase, is an enzyme that relieves strain while double-strand DNA is being unwound by helicase. STEP 3:This is carried out by an enzyme called helicase which breaks the hydrogen bonds holding the complementary bases of DNA together (A with T, C with G).
- 13. • STEP 4:The separation of the two single strands of DNA creates a ‘Y’ shape called a replication ‘fork’. The two separated strands will act as templates for making the new strands of DNA. • STEP 5:One of the strands is oriented in the 3’ to 5’ direction (towards the replication fork), this is the leading strand. The other strand is oriented in the 5’ to 3’ direction (away from the replication fork), this is the lagging strand. • As a result of their different orientations, the two strands are replicated differently.
- 15. Leading Strand: • A short piece of RNA called a primer (produced by an enzyme called primase) comes along and binds to the end of the leading strand. The primer acts as the starting point for DNA synthesis. • DNA polymeraseIII binds to the leading strand and then ‘walks’ along it, adding new complementary Nucleotide bases (A, C, G and T) to the strand of DNA in the 5’ to 3’ direction. • This sort of replication is called continuous.
- 18. Lagging strand: • Numerous RNA primers are made by the primase enzyme and bind at various points along the lagging strand. • Chunks of DNA, called Okazaki fragments, are then added to the lagging strand also in the 5’ to 3’ direction. • This type of replication is called discontinuous as the Okazaki fragments will need to be joined up later.
- 20. Step 9: Once all of the bases are matched up (A with T, C with G), an enzyme called exonuclease (DNA Polymerase I) strips away the primer(s). The gaps where the primer(s) were are then filled by yet more complementary nucleotides. Step 10: The new strand is proofread to make sure there are no mistakes in the new DNA sequence. Step 11: Finally, an enzyme called DNA ligase seals up the sequence of DNA into two continuous double strands.
- 21. Step 12: The result of DNA replication is two DNA molecules consisting of one new and one old chain of nucleotides. This is why DNA replication is described as semi-conservative, half of the chain is part of the original DNA molecule, half is brand new. Step 13: Following replication the new DNA automatically winds up into a double helix.
- 24. Video for DNA replication
- 25. ROLLING CIRCULAR DNA REPLICATION • Rolling circle replication describes a process of unidirectional nucleic acid replication that can rapidly synthesize multiple copies of circular molecules of DNA or RNA, such as plasmids, the genomes of bacteriophages, and the circular RNA genome of viroids. • Some eukaryotic viruses also replicate their DNA via the rolling circle mechanism. Usually under the name rolling circle amplification, the mechanism is also widely used in the laboratory in molecular biology research and in nanotechnology.
- 27. Three basic steps: i) Initiation ii) Elongation iii) Termination
- 28. Initiation Initiates by the production of nick on one of the two strands producing free 3́-OH and 5́ phosphate ends, by the action of: a) Helicase b) Topoisomerases c) Single stranded binding proteins (SSBPs). Helicase Bacterial Plasmid SSBPs
- 29. Elongation For Elongation, the DNA polymerase III binds to the 3́- OH group of broken strand, using the unbroken strand as a template. The polymerase will start to move in a circle for elongation, due to which it is named as Rolling circle model. As the elongation proceeds, the 5́end will be displaced and will grow out like a waving thread. DNA Polymerase III Broken Strand Origin Point
- 30. Termination At the point of termination, the linear DNA molecule is cleaved from the circle, resulting in a double stranded circular DNA molecule and a single-stranded linear DNA molecule. The linear single stranded molecule is circularized by the action of ligase and then replication to double stranded circular plasmid molecule. Origin Point
- 32. Helicase Bacterial Plasmid SSBPs DNA Polymerase III Ligase Broken Strand
- 33. Replication