Anticodon

Among the 76 nucleotides of tRNA are two sets of three that are especially important The first is a group of three bases called the anticodon, which is comple mentary to the mRNA codon for the ammo acid being transferred Table 28 3 lists two mRNA codons for phenylalanine UUU and UUC (reading m the 5 3 direction) Because base pairing requires the mRNA and tRNA to be antiparallel the two anticodons are read m the 3 5 direction as AAA and AAG... 

As described in the preceding sections protein synthesis involves transcription of the DNA to rtiRNA followed by translation of the mRNA as an amino acid sequence In addition to outlining the mechanics of transcription we have described the relationship among mRNA codons tRNA anticodons and ammo acids... 

Anticodon (Section 27 28) Sequence of three bases in a mole cule of tRNA that is complementary to the codon of mRNA for a particular ammo acid... 

Cellular protein biosynthesis involves the following steps. One strand of double-stranded DNA serves as a template strand for the synthesis of a complementary single-stranded messenger ribonucleic acid (mRNA) in a process called transcription. This mRNA in turn serves as a template to direct the synthesis of the protein in a process called translation. The codons of the mRNA are read sequentially by transfer RNA (tRNA) molecules, which bind specifically to the mRNA via triplets of nucleotides that are complementary to the particular codon, called an anticodon. Protein synthesis occurs on a ribosome, a complex consisting of more than 50 different proteins and several stmctural RNA molecules, which moves along the mRNA and mediates the binding of the tRNA molecules and the formation of the nascent peptide chain. The tRNA molecule carries an activated form of the specific amino acid to the ribosome where it is added to the end of the growing peptide chain. There is at least one tRNA for each amino acid. 

It has been known for some time that tetracyclines are accumulated by bacteria and prevent bacterial protein synthesis (Fig. 4). Furthermore, inhibition of protein synthesis is responsible for the bacteriostatic effect (85). Inhibition of protein synthesis results primarily from dismption of codon-anticodon interaction between tRNA and mRNA so that binding of aminoacyl-tRNA to the ribosomal acceptor (A) site is prevented (85). The precise mechanism is not understood. However, inhibition is likely to result from interaction of the tetracyclines with the 30S ribosomal subunit because these antibiotics are known to bind strongly to a single site on the 30S subunit (85). 

Transfer RNAs normally contain some bases other than A, U, G, and C. Of the 76 bases in tRNA , for example, 13 are of the modified variety. One of these, marked G in Figure 28.11, is a modified guanosine in the anticodon. Many of the modified bases, including G, are methylated derivatives of the customary RNA bases. 

O Invariant pyrimidine, Y O Invariant T fC O Invariant purine, R O Anticodon... 

Figure 28.7 A representation of protein biosynthesis. The codon base sequences on mRNA are read by tRNAs containing complementary anticodon base sequences. Transfer RNAs assemble the proper amino acids into position for incorporation into the growing peptide.

List anticodon sequences on the tRNAs carrying the amino acids shown in I Problem 28.7. 

What anticodon sequences of tRNAs are coded for bv the codons in Problem 28.21 ... 

Anticodon (Section 28.5) A sequence of three bases on tRNA that reads the codons on mRNA and brings the correct amino acids into position for protein synthesis. 

Codon (Section 28.5) A three-base sequence on a messenger RNA chain that encodes the genetic information necessary to cause a specific amino acid to be incorporated into a protein. Codons on mRNA are read by complementary anticodons on tRNA. 

Figure 1 Schematic drawing of the morphology of the ribosome. The ribosomal subunits are labeled, as are the approximate locations of their respective functional centers. The drawing is a transparent view from the solvent side of the small subunit. Transfer RNAs are shown in different binding states with the arrow indicating their direction of movement through the ribosome. The tRNA anticodon ends are oriented towards the viewer, whereas the 3-ends of the tRNAs are oriented towards the peptidyl transferase region on the large subunit. The letters h and b denote the head and body regions on the 30S subunit, respectively.

Most of the aforementioned efforts are based on the nonsense suppression methodology as the method for peptide altering [100]. In this approach, a nonsense codon is introduced into the enzyme-coding mRNA in the site that has to be altered. Simultaneously, the tRNA-noncoded amino acid hybrids are prepared with nonsense anticodons. Finally, the translation of modified mRNA is performed in vivo [101] or in vitro [102]. 

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