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Chapter 16: Problem 15

The regulation of mRNA decay relies heavily upon deadenylases and decapping enzymes. Explain how these classes of enzymes are critical to initiating mRNA decay.

Short Answer

Expert verified
Answer: Deadenylases and decapping enzymes are important in initiating mRNA decay because they play crucial roles in destabilizing the mRNA molecule, leading to its eventual degradation. Deadenylases remove the poly(A) tail, which reduces translation efficiency and stability, while decapping enzymes remove the 5' cap, allowing exonucleases to further degrade the mRNA. These processes help regulate gene expression and maintain mRNA quality control within the cell.

Step by step solution

01

Definition of Deadenylases

Deadenylases are enzymes responsible for the removal of the poly(A) tail from the mRNA molecule. The poly(A) tail is a stretch of adenine nucleotides added post-transcriptionally to the 3' end of the mRNA. It plays a role in mRNA stability and translation efficiency. During mRNA decay, deadenylases shorten the mRNA's poly(A) tail.
02

Definition of Decapping Enzymes

Decapping enzymes are another class of enzymes that participate in mRNA decay. They remove the 5' cap structure from the mRNA molecule. The 5' cap is a 7-methylguanosine (7mG) modification on the mRNA's 5' end, required for stability and efficient translation initiation. Decapping enzymes expose the 5' end of mRNA to exonucleases for further decay.
03

Deadenylase Role in Initiating mRNA Decay

As deadenylases shorten the poly(A) tail of mRNA, the association of proteins involved in translation is affected. When the poly(A) tail is sufficiently shortened, translation is no longer efficient, and the mRNA molecule is destabilized and targeted for decay. The removal of the poly(A) tail by deadenylases is one of the first steps in mRNA decay and serves as an important checkpoint for mRNA quality control.
04

Decapping Enzyme Role in Initiating mRNA Decay

After the removal of the poly(A) tail, decapping enzymes come into action and remove the 5' cap structure from the mRNA. The removal of the cap structure exposes the 5' end of the mRNA to exonucleases like 5' exonuclease Xrn1, allowing them to degrade the mRNA molecule. Decapping, and the subsequent degradation by exonucleases, is a critical step in controlling the stability and ultimately destruction of the mRNA molecule.
05

Conclusion

In summary, both deadenylases and decapping enzymes are critical to initiating mRNA decay. Deadenylases remove the poly(A) tail, leading to the destabilization of the mRNA and inefficient translation, while decapping enzymes remove the 5' cap, exposing the mRNA to further degradation by exonucleases. These processes allow the cell to regulate gene expression and maintain mRNA quality control.

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