Chapter 8: DNA Replication and Repair Back To Chapter

8.3: Lagging Strand Synthesis

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Lagging Strand Synthesis

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The complementary strands in double-stranded DNA replicate at different rates. On one strand, the replication process is continuous and fast; this newly formed daughter strand is called the leading strand.

On the other strand, the replication process is discontinuous, relatively slower, and starts slightly later; this daughter strand is known as the lagging strand.

DNA polymerase can only synthesize DNA in the 5' to 3' direction. Because of this, the leading strand is synthesized continuously.

However, DNA polymerase cannot synthesize DNA in a 3' to 5' direction on the lagging strand.

To deal with this problem, DNA synthesis is carried out discontinuously in a 5' to 3' direction.

The enzyme DNA primase, which is present close to the opening of the replication fork, will synthesize multiple RNA primers on the lagging strand as the DNA unwinds.

Then, DNA polymerase synthesizes DNA onto the end of the primer until it encounters the next primer.

This cycle of primer synthesis by primase and subsequent DNA elongation by polymerase continues along the lagging strand. The resultant short DNA fragments are known as Okazaki fragments.

The enzyme RNase H then removes the RNA primers interspersed between the Okazaki fragments.

Another DNA polymerase then fills the empty spaces left after the removal of the RNA primers.

However, the DNA polymerase cannot fill the nicks present between Okazaki fragments.

This final task is performed by the enzyme DNA ligase, which joins the 3’ end of one fragment with 5’ end of another in order to make the discontinuous lagging strand into a continuous one.

8.3: Lagging Strand Synthesis

During replication, the complementary strands in double-stranded DNA are synthesized at different rates. Replication first begins on the leading strand. Replication starts later, occurs more slowly, and proceeds discontinuously on the lagging strand.

There are several major differences between synthesis of the leading strand and synthesis of the lagging strand. 1) Leading strand synthesis happens in the direction of replication fork opening, whereas lagging strand synthesis happens in the opposite direction. 2) For leading strand synthesis, a single primer is needed, whereas multiple RNA primers are required for lagging strand synthesis. 3) After initial primer synthesis, the leading strand needs only DNA polymerase for replication to continue, whereas the lagging strand needs multiple enzymes, including DNA polymerase I, RNase H, and ligase. 4) The leading strand is synthesized as a continuous piece, whereas the lagging strand is synthesized as a series of shorter pieces called Okazaki fragments. Thus, lagging strand synthesis is a multistep process involving sophisticated coordination among different molecules.

Due to the different genome sizes of prokaryotes and eukaryotes, the process of lagging strand synthesis differs between them. The most prominent difference is the length of the Okazaki fragments. The average Okazaki fragment length is around 1000 to 2000 nucleotides in prokaryotes, but only 100 to 200 nucleotides in eukaryotes.

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Lagging Strand Synthesis Refers To The Process Of DNA Replication In Which The Lagging Strand Is Synthesized Discontinuously In Short Fragments Called Okazaki Fragments. This Process Occurs During The Replication Of The Non-template Strand Of DNA. The Lagging Strand Is Synthesized In The Opposite Direction To The Replication Fork Movement. As The Replication Fork Opens Up A RNA Primer Is Synthesized By The Enzyme Primase. This Primer Provides A Starting Point For DNA Polymerase III Which Then Extends The Primer By Adding Nucleotides In The 5' To 3' Direction. However Since DNA Synthesis Can Only Occur In One Direction The Lagging Strand Is Synthesized In Short Fragments. As The Replication Fork Progresses DNA Polymerase III Synthesizes These Fragments Each Initiated By A Separate RNA Primer. Once A Fragment Is Completed DNA Polymerase I Removes The RNA Primers And Replaces Them With DNA. Finally DNA Ligase Seals The Gaps Between The Okazaki Fragments By Catalyzing The Format

8.3: Lagging Strand Synthesis

Chapter 1: Cells, Genomes, and Evolution

Chapter 2: Biochemistry of the Cell

Chapter 3: Energy and Catalysis

Chapter 4: Introduction to Metabolism

Chapter 5: Protein Structure

Chapter 6: Protein Function

Chapter 7: Structure and Organization of DNA

Chapter 8: DNA Replication and Repair

Chapter 9: Transcription: DNA to RNA

Chapter 10: Translation: RNA to Protein

Chapter 11: Control of Gene Expression

Chapter 12: Membrane Structure and Components

Chapter 13: Membrane Transport and Active Transporters

Chapter 14: Channels and the Electrical Properties of Membranes

Chapter 15: Transmembrane Transport in Endoplasmic Reticulum and Peroxisomes

Chapter 16: Intracellular Compartments and Protein Sorting

Chapter 17: Intracellular Membrane Traffic

Chapter 18: Endocytosis and Exocytosis

Chapter 19: Mitochondria and Energy Production

Chapter 20: Chloroplasts and Photosynthesis

Chapter 21: Principles of Cell Signaling

Chapter 22: Signaling Networks of G Protein-coupled Receptors

Chapter 23: Signaling Networks of Kinase Receptors

Chapter 24: Alternative Signaling Routes in Gene Expression

Chapter 25: The Cytoskeleton I: Actin and Microfilaments

Chapter 26: The Cytoskeleton II: Microtubules and Intermediate Filaments

Chapter 27: Extracellular Matrix in Animals

Chapter 28: Cell-Matrix Interactions

Chapter 29: Cell-Cell Interactions

Chapter 30: Cell Polarization and Migration

Chapter 31: Plant Cell Structure and Organization

Chapter 32: Analyzing Cells and Proteins

Chapter 33: Visualizing Cells, Tissues, and Molecules

Chapter 34: Cell Proliferation

Chapter 35: Cell Division

Chapter 36: Meiosis

Chapter 37: Cell Death

Chapter 38: Cancer

Chapter 39: Stem Cell Biology And Renewal in Epithelial Tissue

Chapter 40: A Hierarchical Stem-Cell System: Blood Cell Formation

Chapter 41: Fibroblast Transformation and Muscle Stem Cells

Chapter 42: Regeneration and Repair

Chapter 43: Embryonic and Induced Pluripotent Stem Cells

8.3: Lagging Strand Synthesis

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