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Chapter 10: Problem 58

What are replication licensing factors? How did they get their name?

Short Answer

Expert verified
Replication licensing factors are proteins that ensure DNA is replicated only once per cell cycle, preventing re-replication. They got their name from their role in 'licensing' the initiation of DNA replication.

Step by step solution

01

- Define Replication Licensing Factors

Replication licensing factors (RLFs) are proteins that ensure DNA is replicated only once per cell cycle. They are crucial for maintaining the integrity of the genome by preventing re-replication of DNA within a single cell cycle.
02

- Explain Their Function

RLFs work by binding to origins of replication during the G1 phase of the cell cycle and rendering them competent for replication. This ensures that during the S phase, each origin of replication is activated only once.
03

- Describe How They Got Their Name

The term 'replication licensing factors' comes from their role of 'licensing' or permitting the initiation of DNA replication. Without this licensing, the origins of replication cannot function, ensuring controlled replication initiation.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Replication Licensing Factors
Replication licensing factors (RLFs) are essential proteins. They ensure that DNA is replicated only once per cell cycle. RLFs play a crucial role in maintaining genome integrity. Their function prevents re-replication of DNA, which can cause mutations or genomic instability.
These factors bind to origins of replication during the G1 phase. This prepares them for DNA synthesis in the S phase. Without RLFs, the replication process would be uncontrolled, leading to errors. The term 'licensing' refers to their role in 'permitting' DNA replication. Hence, origins of replication cannot initiate without this licensing.
DNA Replication
DNA replication is a fundamental process in cell division. It involves copying the entire DNA of a cell. This ensures that each daughter cell receives an identical set of genetic instructions. The process starts at specific sites called origins of replication and proceeds bi-directionally.
During replication, enzymes like DNA helicase unwind the double helix. DNA polymerase then synthesizes the new strand by adding nucleotides complementary to the template strand.
The accuracy of DNA replication is essential for genetic fidelity and proper cellular function. Errors in replication can lead to mutations, contributing to diseases like cancer.
Cell Cycle
The cell cycle is a series of stages cells undergo to divide and replicate. It is divided into four main phases: G1, S, G2, and M phase.
  • G1 Phase: Cell grows and prepares for DNA replication.
  • S Phase: DNA replication occurs.
  • G2 Phase: Cell checks for DNA errors and prepares for mitosis.
  • M Phase: Mitosis or cell division happens.
Regulation of the cell cycle is critical for growth and development. Proteins like cyclins and cyclin-dependent kinases (CDKs) help control the progression through each phase. Precise cell cycle regulation ensures proper cell function and prevents uncontrolled cell division, such as in cancer.
Genome Integrity
Genome integrity refers to the accuracy and stability of an organism's genetic information. Maintaining genome integrity is vital for normal cellular function and preventing diseases.
Several mechanisms work to ensure genome integrity:
  • DNA repair proteins fix errors during replication.
  • Checkpoints in the cell cycle halt division if DNA damage is detected.
  • RLFs prevent re-replication and avoid genomic instability.
Disruptions in these mechanisms can lead to mutations, chromosomal aberrations, and cancer. Therefore, maintaining genome integrity is essential for health and longevity.
G1 and S Phases
The G1 and S phases are crucial parts of the cell cycle.
G1 Phase: During G1, the cell grows and synthesizes proteins needed for DNA replication. This phase also includes a critical checkpoint to ensure the cell is ready for DNA synthesis.
S Phase: In the S phase, DNA replication takes place. Each chromosome is duplicated to ensure that both daughter cells receive identical genetic material. This phase is highly regulated to prevent errors and ensure complete replication.
Transition from G1 to S phase is controlled by various proteins, ensuring the integrity and accuracy of the replication process.

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Most popular questions from this chapter

Why is the replication of DNA referred to as a semiconservative process? What is the experimental evidence for the semiconservative nature of the process? What experimental results would you expect if replication of DNA were a conservative process?

In the Meselson-Stahl experiment that established the semiconservative nature of DNA replication, the extraction method produced short fragments of DNA. What sort of results might have been obtained with longer pieces of DNA?

Why is it reasonable that eukaryotes have a DNA polymerase (Pol \(\gamma\) ) that operates only in mitochondria?

What is a replication fork? Why is it important in replication?

How does DNA replication in eukaryotes differ from the Process in prokaryotes?
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