Protein amino acid attachment base

The replacement of thymine by uracil has no significant effect on the hydrogen bonding, as RNA does not use base pairing to form complementary dimers it is of less importance than it would be for DNA, but the removal of the methyl group may have an influence on the tertiary structures that RNA can adopt. From this it is clear that DNA is a better method of storing information whereas RNA is more suited to turn that information into a protein sequence. This is done by the ribosome, composed of ribosomal RNA (rRNA), which translates the codons of the mRNA sequence into a protein by matching three base sequences to those of tRNA that have the appropriate amino acids attached. 

As shown in Figure 45.1, the bases appear in complementary pairs, A with T and G with C in this particular example, the sequence for one strand of DNA is A-T-C-G-T- while the other strand is -T-A-G-C-A-. The sequences of the bases attached to the sugar-phosphate backbone direct the production of proteins from amino acids. Along each strand, groups of three bases, called codons, correspond to individual amino acids. For example, in Figure 45.1, the triplet CGT, acting as a codon, would correspond to the amino acid serine. One codon, TAG, indicates where synthesis should begin in the DNA strand, and other codons, such as ATT, indicate where synthesis should stop. 

Figure 12.5 The structures for four tRNA molecules of yeast, (a) Alanyl-tRNA (b) phenylalanyl-tRNA (c) seryl-tRNA (d) tyrosyl-tRNA. The single letter designations identify the sequence of bases along the single chain. Note that several of these are unusual bases, most of which are methylated (Me). Note also the ACC sequence at the 3 terminus of each tRNA. This is the site to which amino acids are attached in the process of protein synthesis, as indicated. These tRNA molecules have a substantial amount of secondary structure created by formation of Watson-Crick base pairs. Finally, note that the anticoding triplet in the bottom loop is shown.

A tRNA molecule is specific for a particular amino acid, though there may be several different forms for each amino acid. Although relatively small, the polynucleotide chain may show several loops or arms because of base pairing along the chain. One arm always ends in the sequence cytosine-cytosine-adenosine. The 3 -hydroxyl of this terminal adenosine unit is used to attach the amino acid via an ester linkage. However, it is now a section of the nucleotide sequence that identifies the tRNA-amino acid combination, and not the amino acid itself. A loop in the RNA molecule contains a specific sequence of bases, termed an anticodon, and this sequence allows the tRNA to bind to a complementary sequence of bases, a codon, on mRNA. The synthesis of a protein from the message carried in mRNA is called translation, and a simplified representation of the process as characterized in the bacterium Escherichia coli is shown below. 

Transfer RNAs (tRNAs), the smallest of the three major species of RNA molecules (4S), have between 74 and 95 nucleotide residues. There is at least one specific type of tRNA molecule for each of the twenty amino acids commonly found in proteins. Together, tRNAs make up about fifteen percent of the total RNA in the cell. The tRNA molecules contain unusual bases (for example, pseudouracil, see Figure 22.2, p. 290) and have extensive intrachain base-pairing (Figure 30.3). Each tRNA serves as an "adaptor molecule that carries its specific amino acid—covalently attached to its 3-end—to the site of protein synthesis. There it recognizes the genetic code word on an mRNA, which specifies the addition of its amino acid to the growing peptide chain (see p. 429). 

Initiation of the polypeptide chain. mRNA bearing the code for the polypeptide is bound to the small sub-unit of RNA, followed by the initiating amino-acid, and is attached to its tRNA to form an initiation complex. The tRNA of the initiating amino-acid-base pairs with a specific nucleotide triplet or codon on the mRNA that signals the beginning of the polypeptide chain. This process requires GTP (ATP equivalent), plus three proteins called initiation factors. 

Ribonucleases are a widely distributed family of en-zymes that hydrolyze RNA by cutting the P—O ester bond attached to a ribose 5 carbon (fig. 8.12). A good representative of the family is the pancreatic enzyme ribonuclease A (RNase A), which is specific for a pyrimidine base (uracil or cytosine) on the 3 side of the phosphate bond that is cleaved. When the amino acid sequence of bovine RNase A was determined in 1960 by Stanford Moore and William Stein, it was the first enzyme and only the second protein to be sequenced. RNase A thus played an important role in the development of ideas about enzymatic catalysis. It was one of the first enzymes to have its three-dimensional structure elucidated by x-ray diffraction and was also the first to be synthesized completely from its amino acids. The synthetic protein proved to be enzymatically indistinguishable from the native enzyme. 

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