The sequences preceding the initiation codons in eukaryotic messengers do not contain significant regions of complementarity to the 18S RNA from the smaller ribosomal subunit. Additionally, translation almost always begins on these RNAs at the first AUG codon. In bacteria, a number of AUG triplets can precede the actual initiation codon. Translation of most eukaryotic messengers begins with the binding of a cap-recognizing protein to the 5’ end of the mRNA. The translation efficiency of most, but not all, messengers in eukaryotic systems is much higher when the messenger contains the cap structure discussed in Chapter 5. Additional proteins bind followed by the 40S ribosomal subunit. With the consumption of ATP, the complex moves down the RNA to the first AUG, at which point another protein binds to the complex and finally the 60S ribosomal subunit binds (Fig. 1). Translation begins from this point. The preinitiation complex can open and slide right through moderately stable regions of base paired RNA to reach the first AUG of the messenger. This is unlike the prokaryotic translation machinery, which has difficulty reaching an initiation codon that is buried in extraneous secondary structure of the mRNA.

Fig1. The initiation process in eukaryotes in which the smaller subunit slides from the 5’ end of the mRNA to the first AUG, associates with the larger subunit and translation begins.

In special situations when only a low level of protein is required, translation begins not at the first AUG, but at a later one. Similarly, an AUG codon immediately followed by a termination signal and then another AUG codon, also produces a low translation efficiency.

The need for a mechanism that can deposit the translation machinery at the initiation codon despite the existence of secondary structure in the mRNA arises from the eukaryotic translation pathway. In eukaryotes, the RNA is synthesized, spliced, transported to the cytoplasm and then translated. Undoubtedly, regions of secondary structure obscuring a potential ribosome-binding site would exist on many species of messengers. To circumvent this problem, the translation apparatus recognizes the capped 5’ end, which cannot be involved in base pairing. After binding, the apparatus slides down the mRNA until it reaches a starting AUG. In contrast, prokaryotes lack a need for binding and sliding since ribosomes attach to a ribosome recognition sequence on mRNA as soon as it protrudes from the RNA polymerase. Thus, prokaryotic mRNA has little opportunity to fold and hide the start region of a protein.

مواضيع ذات صلة

Experimental Support for the Shine-Dalgarno Hypothesis

تشكيل فُقَاعات التنسخ Replication Bubbles

ابتداء تخليق الدنا وتطويله Initiation & Elongation

تشكيل شعبة التنسخ Replication Fork

مناشئ التنسخ (Ori)

Regulation of RNA Stability by 5 and 3 UTR Sequences and Structures

Base Pairing between Ribosomal RNA and Messenger

Decoding the Message

How Synthetases Identify the Correct tRNA Molecule

متطلبات التنسخ

المتواليات المتكررة الساتلة الدقيقة Microsatellites

المجين جينات وفائض