Forming Aminoacyl-tRNA

NUCLEOSIDASES AND RELATED ENZYMES - LIGASES FORMING AMINOACYL-TRNA AND RELATED COMPOUNDS 

034333 Tyrosyl-tRNA synthetase [L-Tyrosine tRNATyr ligase 

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Ligases forming aminoacyl-tRNA and related compounds... 

The reactions that form aminoacyl-tRNAs and their significance in translation... 

The second key advance was made by Mahlon Hoagland and Zamecnik, when they found that amino acids were activated when incubated with ATP and the cytosolic fraction of liver cells. The amino acids became attached to a heat-stable soluble RNA of the type that had been discovered and characterized by Robert Holley and later called transfer RNA (tRNA), to form aminoacyl-tRNAs. The enzymes that catalyze this process are the aminoacyl-tRNA synthetases. 

In the second step, without leaving the enzyme, the aminoacyl group of aminoacyl-AMP is transferred to the 3 end of the tRNA molecule to form aminoacyl-tRNA ... 

Deoxyribonucleic acid is the genetic material such that the information to make all the functional macromolecules of the cell is preserved in DNA (Sinden, 1994). Ribonucleic acids occur in three functionally different classes messenger RNA (mRNA), ribosomal RNA (rRNA), and transfer RNA (tRNA) (Simons and Grun-berg-Manago, 1997). Messenger RNA serves to carry the information encoded from DNA to the sites of protein synthesis in the cell where this information is translated into a polypeptide sequence. Ribosomal RNA is the component of ribosome which serves as the site of protein synthesis. Transfer RNA (tRNA) serves as a carrier of amino acid residues for protein synthesis. Amino acids are attached as aminoacyl esters to the 3 -termini of the tRNA to form aminoacyl-tRNA, which is the substrate for protein biosynthesis. 

The percentage of tRNAs that will be laulty is 0.11%. For every 1000 aminoacyl-adenylates that are produced, 100 are faulty and 900 are correct. The 900 correct intermediates will be converted to correct aminoacyl tRNAs because the intermediates are tightly bound to the active site of the aminoacyl-tRNA synthetase. Of the 100 incorrect aminoacyl-adenylates, 99 will be hydrolyzed and will therefore not form aminoacyl tRNAs. Onfy one will survive to become an incorrect aminoacyl tRNA. The fraction of incorrect aminoacyl tRNAs is therefore 1/901, or 0.11%. 

Figure 38-8. Diagrammatic representation of the peptide elongation process of protein synthesis. The small circles labeled n - 1, n, n -I-1, etc, represent the amino acid residues of the newly formed protein molecule. EFIA and EF2 represent elongation factors 1 and 2, respectively. The peptidyl-tRNA and aminoacyl-tRNA sites on the ribosome are represented by P site and A site, respectively.

The charging of the tRNA molecule with the aminoacyl moiety requires the hydrolysis of an ATP to an AMP, equivalent to the hydrolysis of two ATPs to two ADPs and phosphates. The entry of the aminoacyl-tRNA into the A site results in the hydrolysis of one GTP to GDP. Translocation of the newly formed pep-tidyl-tRNA in the A site into the P site by EF2 similarly results in hydrolysis of GTP to GDP and phosphate. Thus, the energy requirements for the formation of one peptide bond include the equivalent of the hydrolysis of two ATP molecules to ADP and of two GTP molecules to GDP, or the hydrolysis of four high-energy phosphate bonds. A eukaryotic ribosome can incorporate as many as six amino acids per second prokaryotic ribosomes incorporate as many as 18 per second. Thus, the process of peptide synthesis occurs with great speed and accuracy until a termination codon is reached. 

Of the fonr possible optical isomers of chloramphenicol, only the o-threo form is active. This antibiotic selectively inhibits protein synthesis in bacterial ribosomes by binding to the 50S subunit in the region of the A site involving the 23 S rRNA. The normal binding of the aminoacyl-tRNA in the A site is affected by chloramphenicol in such a... 

The information contained in the DNA (i.e., the order of the nucleotides) is first transcribed into RNA. The messenger RNA thus formed interacts with the amino-acid-charged tRNA molecules at specific cell organelles, the ribosomes. The loading of the tRNA with the necessary amino acids is carried out with the help of aminoacyl-tRNA synthetases (see Sect. 5.3.2). Each separate amino acid has its own tRNA species, i.e., there must be at least 20 different tRNA molecules in the cells. The tRNAs contain a nucleotide triplet (the anticodon), which interacts with the codon of the mRNA in a Watson-Crick manner. It is clear from the genetic code that the different amino acids have different numbers of codons thus, serine, leucine and arginine each have 6 codewords, while methionine and tryptophan are defined by only one single nucleotide triplet. 

After formation of the initiation dipeptide, the first EF-G-dependent translocation allows binding of the third aminoacyl-tRNA in the A-site so that a tripeptide is formed. The apparent rate of this event may depend upon the nature of the initiation complex initially formed, being slower, for instance, with those containing mRNAs with an extended SD sequence than with those having either very short or no SD complementarity (C. O. G. and M. Rodnina, unpublished results). Furthermore, very powerful translocation inhibitors may block tripeptide formation to such an extent that they mimic translation initiation inhibitors. 

N-Hydroxy arylamines are also converted to N-acetoxy arylamines (V), but apparently by an acetyl coenzyme A-dependent enzymatic O-esterification (7, 8). Similarly, N-sulfonyloxy arylamines (VI) are thought to arise by a PAPS-dependent enzymatic O-sulfonylation of N-hydroxy arylamines (9,10) while 0-seryl or 0-prolyl esters (VII) are formed by their corresponding aminoacyl tRNA synthetases in a ATP-dependent reaction (11,12). 

Activation of individual amino acids occurs in the synthesis of aminoacyl tRNA. This process bums two ATP equivalents (forms pyrophosphate and AMP) and connects a specific amino acid to a specific tRNA. 

Several key concepts are worth remembering. GTP is used as an energy source for translation, but ATP is used to form the aminoacyl-tRNA. The ribosome effectively has two kinds of tRNA binding sites. Only tRNAMet can bind to the P (for peptide) site, and this only occurs during the initial formation of the functional ribosome (initiation). All other aminoacyl-tRNAs enter at the A (for amino acid) binding site. After formation of the peptide bond (this doesn t require GTP hydrolysis), the tRNA with the growing peptide attached is moved (translocated) to the other site (this does require GTP hydrolysis). 

Figure 5 Kinetic mechanism of aminoacyl-tRNA selection by the ribosome. The aminoacyl-tRNAs are delivered to the ribosome in the form of a ternary complex with EF-Tu-GTP. Incorrect aminoacyl-tRNAs can either dissociate as a ternary complex in the initial selection phase or later as free aminoacyl-tRNA in the proofreading phase. The two selection phases are separated through the irreversible GTP hydrolysis by EF-Tu. Discrimination against incorrect tRNAs is achieved by increased dissociation rate constants (/r 2 and kj) as well as decreased forward rate constants (ks and ks) compared to cognate tRNAs.

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