5 Must Know Facts For Your Next Test

1. Helicase moves along the DNA strand in a 5' to 3' direction, unwinding the DNA ahead of the replication fork or transcription bubble.
2. The activity of helicase requires energy, which it derives from the hydrolysis of ATP to ADP.
3. Different types of helicases exist, including those specific to DNA replication and others that function during RNA transcription.
4. In eukaryotic cells, helicase is part of larger protein complexes, which help regulate its function and coordination with other enzymes.
5. Mutations in helicase can lead to serious genetic disorders and are associated with diseases like cancer and progeria due to their role in maintaining genomic stability.

Review Questions

• How does helicase facilitate the process of DNA replication and what happens if helicase is not functioning properly?
  • Helicase facilitates DNA replication by unwinding the double-stranded DNA helix, allowing each strand to serve as a template for new strand synthesis. If helicase is not functioning properly, the DNA strands remain coiled together, preventing replication from occurring. This can lead to stalled replication forks, accumulation of genetic errors, and ultimately compromise cell division and genomic integrity.
• Discuss the relationship between helicase and other enzymes involved in DNA replication, such as DNA polymerase.
  • Helicase works closely with DNA polymerase during replication. As helicase unwinds the DNA strands, it creates single-stranded templates that DNA polymerase needs to synthesize new complementary strands. Without helicase's activity, DNA polymerase cannot effectively access the template strands, leading to inefficient or incomplete replication. This highlights how helicase plays a crucial role in ensuring that DNA polymerase can perform its function efficiently.
• Evaluate the implications of dysfunctional helicase on cellular processes and human health, citing specific examples.
  • Dysfunctional helicase can have severe implications for cellular processes, particularly in maintaining genomic stability. For instance, mutations in helicases like WRN (associated with Werner syndrome) lead to premature aging and increased cancer risk due to genomic instability. Similarly, defects in other helicases can result in diseases like Bloom syndrome, characterized by growth defects and increased cancer susceptibility. These examples illustrate how critical helicases are for proper cellular function and overall human health.

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