proposed by Crick ( ) which states that tRNA anticodon has the ability to wobble at its ’ end by pairing with even non-complementary base of mRNA codon. According to this hypothesis, in codon-anticodon pairing the third base may not be complementary. The third base of the codon is called wobble base and this position is called wobble position. The actual base pairing occurs at first two positions only.
The importance of Wobbling hypothesis is that it reduces the number of tRNAs required for polypeptide synthesis and it overcomes the effect of code degeneracy. In the above example though the codon and the anti codon do not match perfectly, yet the required amino acid is brought perfectly. This enables the economy of tRNA, GUU, GUC, GUA and GUG code for the amino acid - Valine. XII Std Biology-Zoology Chapter- XII Std Biology-Zoology Chapter- Molecular Genetics variable loop or extra arm.
The amino acid is attached to one end (amino acid acceptor end) and the other end consists of three anticodon nucleotides. The anticodon pairs with a codon in mRNA ensuring that the correct amino acid is incorporated into the growing polypeptide chain. Four different regions of double-stranded RNA are formed during the folding process. Modified bases are especially common in tRNA.
Wobbling between anticodon and codon allows some tRNA molecules to read more than one codon. The process of addition of amino acid to tRNA is known as aminoacylation or charging and the resultant product is called aminoacyl- tRNA (charged tRNA). Without aminoacylation tRNA is known as uncharged tRNA (Fig. .
). If two such tRNAs are brought together peptide bond formation is favoured energetically. Numbers of amino acids are joined by peptide bonds to form a polypeptide chain. This aminoacylation is catalyzed by an enzyme aminoacyl – tRNA synthetase .
This is an endothermic reaction and is associated with ATP hydrolysis. $ $ * $ $ $ $ $ $ $ $ $ $ < $ $ $ & & * & & & & * & & &