Aminoacyl-tRNA-synthetases

The regions of the tRNA molecule teferred to in Chapter 35 (and illustrated in Figure 35-11) now become important. The thymidine-pseudouridine-cyti-dine (T PC) arm is involved in binding of the amino-acyl-tRNA to the ribosomal surface at the site of protein synthesis. The D arm is one of the sites important for the proper recognition of a given tRNA species by its proper aminoacyl-tRNA synthetase. The acceptor arm, located at the 3 -hydroxyl adenosyl terminal, is the site of attachment of the specific amino acid. 

Figure 38-1. Formation of aminoacyl-tRNA. A two-step reaction, involving the enzyme aminoacyl-tRNA synthetase, results in the formation of aminoacyl-tRNA. The first reaction involves the formation of an AMP-amino acid-enzyme complex. This activated amino acid is next transferred to the corresponding tRNA molecule. The AMP and enzyme are released, and the latter can be reutilized. The charging reactions have an error rate of less than 10" and so are extremely accurate.

YAMAGUCHI M and suGiMOTO E (2000) Stimulatory effect of genistein and daidzein on protein synthesis in osteoblastic MC3T3-E1 cells Activation of aminoacyl-tRNA synthetase. Mol Cell Biochem 214, 97-102. 

In 1994, a conference with the title Aminoacyl-tRNA Synthetases and the Evolution of the Genetic Code was held in Berkeley, California its patron was the Institute of Advanced Studies in Biology. The conference dealt with the development of the synthetases and that of the genetic code (see Sect. 8.2), i.e., the assignment of the various amino acids to the corresponding base triplets of the nucleic acids. 

Fig. 5.1 Simplified model representation of the activation of an amino acid (ASY) at an amino acid-activating enzyme (i.e., an amino acid-specific aminoacyl-tRNA synthetase)...

It was earlier considered that all the amino acid-activating synthetases were derived from a single primeval synthetase , so that all synthetases would have similar structures. Surprisingly, however, this is not the case. When the primary sequences, and in part the secondary and tertiary structures, of all the synthetases had been determined, clear differences in their construction became obvious. The aminoacyl-tRNA synthetases consist either of one single polypeptide chain (a) or of two or four identical polypeptides (ot2 or 04). In addition, there are heterogeneously constructed species with two sets of two identical polypeptide chains (OC2P2). This nomenclature indicates that, for each synthetase, a or P refers to a primary structure. The number of amino acids can vary from 334 to more than 1,000. 

The close connection of this enzyme family with the transfer of genetic information has made it a popular object of study when dealing with questions regarding the formation and evolution of the genetic code (see Sect. 8.1). It is now agreed that the aminoacyl-tRNA synthetases are a very ancient enzyme species which do not, however, arise from one single primeval enzyme, but from at least two, corresponding to the synthetase classes. 

Cech s group was the first to have success in this direction (Piccirilli, 1992). Using a genetically modified Tetrahymena ribozyme, they were able to hydrolyse an ester bond between the amino acid A-formylmethionine and the corresponding tRNAf Met. The reaction was, however, very slow, only about 5 to 15 times faster than the uncatalysed reaction. The authors ventured to suggest that these ribozymes could have functioned as the first aminoacyl tRNA synthetases. 

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. 

An important factor in the evolution of the genetic code is certainly provided by the aminoacyl-tRNA synthetases (see Sect. 5.3.2). It is clear that the two synthetase classes are not randomly distributed across the matrix of the amino acid assignment of the genetic code. For example, with one exception, all XUX codons code for class 1 synthetases, while all XCX codons code for class 2 aminoacyl-tRNA synthetases. A possible explanation could be that the synthetases and the genetic code evolved simultaneously. However, it is more likely that these enzymes evolved when the genetic code had already been established (Wetzel, 1995). 

One important question is that of the order in which the basic mechanisms of evolution processes, leading eventually to the emergence of life, occurred. As far as the development of the genetic code is concerned, it is not clear whether the code evolved prior to the aminoacylation process, i.e., whether aminoacyl-tRNA synthetases evolved before or after the code. A tRNA species which is aminoacy-lated by two different synthetases was studied if this tRNA had important identity elements such as the discriminator base and the three anticodon bases for the two synthetases, this would be evidence that the aminoacyl-tRNA synthetases had developed after the genetic code. Dieter Soil s group, which is experienced in working with this family of enzymes, came to the conclusion that the universal genetic code must have developed before the evolution of the aminoacylation system (Hohn et al, 2006). 

A detailed treatment of the evolution of the genetic code requires modelling physical components of the translational process this includes the dynamic processes of the tRNAs and the aminoacyl-tRNA synthetases (Vetsigian et al., 2006). Thus, in spite of considerable advances in the search for the roots of the genetic code, there is still much to do ... 

Thompson, Damien Plateau, Pierre Simonson, Thomas, Free-energy simulations and experiments reveal long-range electrostatic interactions and substrate-assisted specificity in an aminoacyl-tRNA synthetase., ChemBioChem Feb 2006, 7, 337-344. 

Protocol The test for the identification of aminoacyl-tRNA synthetase inhibitors requires the availability of precharged fMet-tRNA, Phe-tRNA, Thr-tRNA, and Ile-tRNA, which correspond to the amino acids present in the 027 peptide. The preparation of fMet-tRNA is described in the accompanying chapter by Milon et al., (2007), while the preparation of the other aminoacyl-tRNAs has been described previously. 

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). 

The formation of 0-seryl or 0-prolyl esters (Figure 1) of certain N-hydroxy arylamines has been inferred from the observations that highly reactive intermediates can be generated in vitro by incubation with ATP, serine or proline, and the corresponding aminoacyl tRNA synthetases (11,12,119). For example, activation of N-hydroxy-4-aminoquinoline-l-oxide (119,120), N-hydroxy-4-aminoazobenzene (11) and N-hydroxy-Trp-P-2 (121) to nucleic acid-bound products was demonstrated using seryl-tRNA synthetase from yeast or rat ascites hepatoma cells. More recently, hepatic cytosolic prolyl-, but not seryl-, tRNA synthetase was shown to activate N-hydroxy-Trp-P-2 (12) however, no activation was detectable for the N-hydroxy metabolites of AF, 3,2 -dimethyl-4-aminobiphenyl, or N -acetylbenzidine (122). 

Although aminoacyl-tRNA synthetases are necessary for protein synthesis in all tissues, their importance in chemical carcinogenesis is difficult to assess. Mutation induction by this pathway has been studied extensively (123), yet metabolic activation in a carcinogen-target tissue has not been demonstrated. The only exception is hepatic prolyl-tRNA synthetase activation of N-hydroxy-Trp-P-2 however, hepatic O-acetylation of this substrate also occurs to an appreciable extent (12). Further investigations involving the use of specific enzyme inhibitors would be helpful in addressing this problem. 

The tRNA synthetases may provide a check to make sure that the correct amino acid has been attached to the correct tRNA. If an incorrect amino acid is attached to the tRNA, it will be incorporated into the protein at the position specified by the identity of the tRNA. At least some of the aminoacyl tRNA synthetases have a proofreading function that hydrolyzes any incorrect aminoacyl tRNAs (for example, a Val residue attached to an lie tRNA). 

How, in turn, does the synthetase recognize its specific tRNA From extensive mutagenesis studies, it appears that the aminoacyl-tRNA synthetases recognize particular regions of the tRNA molecule, most often in their anticodon loops and/or in their acceptor stems. 

Aminoacyl-tRNA synthetases Degradation of proteins, peptides, and glycopeptides Nucleoproteins Protein modification... 

Aside from these relatively direct applications of site-directed mutagenesis, combination of recombinant DNA techniques with other experimental strategies will no doubt prove to be of increasing importance. If the gene of interest can be expressed with sufficient efficiency in auxotrophs, then proteins in which selected amino acids are isotopically enriched [12] may be produced to increase the sensitivity and selectivity of magnetic resonance techniques. Alternatively, amino acid analogues that are recognized as substrates by aminoacyl tRNA synthetases may be incorporated randomly in place of the true substrate amino... 

CoRTi, O., et al.. The p38 subunit of the aminoacyl-tRNA synthetase complex is a Parkin substrate linking protein biosynthesis and neurodegeneration. Hum Mol Genet, 2003, 12(12), 1427-37. 

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