5 Must Know Facts For Your Next Test

1. During DNA replication, elongation occurs after the primer has been laid down, with DNA polymerase adding nucleotides in a 5' to 3' direction.
2. In transcription, elongation involves RNA polymerase moving along the DNA template strand, unwinding the double helix and synthesizing mRNA.
3. During translation, elongation consists of the addition of amino acids to the growing polypeptide chain, facilitated by transfer RNA (tRNA) molecules bringing specific amino acids to the ribosome.
4. Elongation factors are proteins that assist in the efficient and accurate addition of nucleotides during transcription and translation.
5. The speed and fidelity of elongation are critical for ensuring that genetic information is accurately copied and expressed in cells.

Review Questions

• How does elongation differ between DNA replication and transcription?
  • In DNA replication, elongation involves DNA polymerase adding nucleotides to a growing DNA strand, while in transcription, elongation involves RNA polymerase synthesizing an RNA strand from a DNA template. Both processes add nucleotides in a specific direction (5' to 3'), but they utilize different enzymes and substrates. Additionally, during replication, both strands of DNA are synthesized simultaneously at different locations, whereas in transcription, only one strand serves as a template for RNA synthesis.
• Discuss the role of elongation factors during protein synthesis and their impact on translation efficiency.
  • Elongation factors play a crucial role during translation by facilitating the process of amino acid addition to the growing polypeptide chain. They help stabilize the interaction between tRNA molecules and the ribosome while also promoting the movement of the ribosome along the mRNA. By enhancing the accuracy and speed of elongation, these factors ensure that proteins are synthesized efficiently and correctly, which is essential for proper cellular function.
• Evaluate how errors during elongation can affect cellular functions and lead to disease.
  • Errors during elongation in either DNA replication or protein synthesis can have significant consequences for cellular functions. For example, if DNA polymerase incorporates incorrect nucleotides during replication, it can lead to mutations that may disrupt gene function or contribute to cancer development. Similarly, mistakes during translation can result in misfolded proteins or dysfunctional enzymes, potentially leading to diseases such as cystic fibrosis or neurodegenerative disorders. Understanding these processes is vital for developing targeted therapies that address such errors at their source.

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