5 Must Know Facts For Your Next Test

1. There are three stop codons in the genetic code: UAA, UAG, and UGA, which do not code for any amino acids.
2. When a ribosome encounters a stop codon, it does not add an amino acid but instead recruits release factors that facilitate the disassembly of the ribosome-mRNA complex.
3. Stop codons are critical for ensuring that proteins are synthesized correctly and that any unnecessary translation is avoided, preventing the production of non-functional or harmful proteins.
4. Mutations that introduce or alter stop codons can lead to diseases by causing premature termination of protein synthesis or by extending proteins beyond their functional limits.
5. The recognition of stop codons by the ribosome is part of the larger process of translation termination, which also includes the hydrolysis of the bond between the completed polypeptide and the tRNA in the P site.

Review Questions

• How do stop codons function in the process of translation termination?
  • Stop codons function by signaling the ribosome to halt protein synthesis. When a ribosome encounters one of the three stop codons (UAA, UAG, UGA) during translation, it does not bind any tRNA carrying an amino acid. Instead, release factors are recruited, which promote the release of the newly synthesized polypeptide chain from the ribosome, effectively concluding the translation process.
• Discuss the consequences of mutations that affect stop codons in mRNA.
  • Mutations that introduce or change stop codons can have serious implications for protein synthesis. A premature stop codon may lead to truncated proteins that lack essential functional domains, potentially resulting in loss-of-function disorders or diseases. Conversely, if a mutation results in a missing stop codon, it can lead to elongated proteins that may misfold and become toxic. Both scenarios highlight the importance of accurate stop codon signaling in maintaining cellular health.
• Evaluate the importance of stop codons in maintaining genetic integrity and preventing disease.
  • Stop codons are vital for maintaining genetic integrity as they ensure proteins are synthesized to their correct lengths and functional forms. Proper termination prevents aberrant protein products that can disrupt cellular processes or lead to disease states. When translation goes awry due to mutations affecting stop codons, it can trigger various diseases, emphasizing their role as essential checkpoints in gene expression and protein synthesis regulation. Understanding their function also aids in developing targeted therapies for genetic disorders related to translation errors.

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