5 Must Know Facts For Your Next Test

1. During the extension phase, the temperature is typically set to around 72°C, which is optimal for most DNA polymerases to function effectively.
2. The duration of the extension step can vary depending on the length of the target DNA; longer sequences require longer extension times.
3. Taq polymerase, a commonly used enzyme in PCR, can add approximately 1000 nucleotides per minute during the extension phase.
4. Proper extension is vital for generating accurate copies of the target DNA, as errors during this process can lead to mutations in the amplified product.
5. Extension is often followed by additional cycles of denaturation, annealing, and extension, exponentially increasing the amount of target DNA.

Review Questions

• How does the extension step contribute to the overall effectiveness of PCR in amplifying specific DNA sequences?
  • The extension step is essential because it is when new DNA strands are synthesized by DNA polymerase. This process directly impacts the efficiency and accuracy of amplifying specific DNA sequences. If extension occurs correctly, it ensures that enough copies of the target sequence are produced while maintaining fidelity. Therefore, any issues during this phase could compromise the PCR results.
• Compare and contrast the roles of extension and annealing in PCR. How do they work together to ensure successful amplification?
  • Extension and annealing are two critical steps in PCR that work together to facilitate successful amplification. During annealing, primers attach to specific regions on the template DNA, setting up a starting point for replication. Following this, extension occurs where DNA polymerase synthesizes new strands by adding nucleotides. The success of extension relies heavily on proper annealing, as misaligned primers can lead to ineffective or incomplete amplification.
• Evaluate the impact of temperature adjustments during the extension step on PCR outcomes and discuss potential consequences if not optimized.
  • Temperature adjustments during the extension step significantly impact PCR outcomes because each DNA polymerase has an optimal temperature range for activity. If the temperature is too low, the enzyme may not function effectively, resulting in incomplete or slow synthesis of DNA. Conversely, if it is too high, it can lead to enzyme denaturation and loss of activity. Such errors can lead to low yield or poor-quality amplification, affecting downstream applications like sequencing or cloning.

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