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Epigenetic changes are not transferred via the germline to the next generation, whereas mutations in gametes are inherited."/>
Figure 4.20 Differences between genetic and epigenetic inheritance.
The nucleotide sequence of mRNA is translated using the genetic code into amino acid sequences. tRNA, with its specific anticodon, serves as a mediator between the mRNA and the protein. A central event in the progress in molecular biology was the discovery of the unit‐less, comma‐less, nonoverlapping code in all living organisms. In each case, three nucleotides code for a specific amino acid in each protein (Table 2.4). Using a triplet code with four bases, there are 43 = 64 available combinations. As there are only 20 amino acids that are used to synthesize proteins (Table 2.4), there are more codons than are actually necessary. This problem was solved by evolution in such a way that most of the amino acids are not be coded from only one, but from two to at the most six different synonymous codons (Table 2.4).
The widely universal triplet codehas a specific start signal. Since methionine (in eukaryotes) and N‐formylmethionine (in bacteria and chloroplasts) are the first amino acids to be built into polypeptides, the universal start codon is AUG (far more seldom, GUG is present). In most cases, however, methionine is removed by specific proteases following translation. When the start of the translation shifts only one or two nucleotides, resulting in a shift of the reading frame (frameshift) (Figure 4.13), a totally new protein results. This means that the start codon must be strictly preserved in order to produce reproducible proteins. In animal (but not in plant) mitochondria, there is a deviation from the universal genetic code (e.g. AUA is used for translation initiation and codes for methionine). However, in eukaryotic ribosomes this codon codes for isoleucine; AGG/A is used as a termination codon by vertebrate mitochondria, while it usually codes for arginine. UGA, which is usually a stop codon, codes for tryptophan in animal mtDNA.
Usually the codons that code for the same amino acid differ in the third codon position. Every codon is recognized by tRNA via the anticodon sequence. Within the so‐called degenerate codons that all code for the same amino acid, usually only one tRNA exists, one which tolerates a mismatching in the third codon position. Overall, about 31 tRNAs have been discovered in the eukaryotic system and 22 tRNAs in mitochondria.
4.3 Protein Biosynthesis (Translation)
Protein biosynthesis takes place in ribosomes – intricately constructed multienzyme complexes in which different rRNAs play an important role (Figure 4.22). rRNAs belong to the most prevalent macromolecules of the cell. The numerous copies of the rDNA cassettes in the genome (Figure 4.21) indicate that this gene must be transcribed very often in order to produce the large number of rRNA molecules that every cell requires. Just for E. coli alone, the number of rRNA molecules is estimated to be 38 000. In a mammalian cell more than 1 million rRNA copies exist. The rRNA genes for 18S, 5.8S, and 26S rRNA are transcribed by RNA polymerase I together, and the individual rRNAs are produced afterward by splicing. Nucleotides of the precursor RNA are chemically modified by snoRNAs before splicing (Figure 2.20).
Figure 4.21 Structure of RNA cassettes and synthesis of rRNA. ITSs, internal transcribed spacers; IGSs, intergenic spacers; 5S rRNA genes are transcribed separately.
Figure 4.22 shows the assembled building blocks of prokaryotic and eukaryotic ribosomes. As mitochondria and chloroplasts contain their own ribosomes, which originated from bacteria (see Section 3.1.3), the expected type of rRNAs corresponds to those of bacteria (note that in mitochondria a 12S rRNA is present instead of the 23S rRNA).
Figure 4.22 Structure of (a) prokaryotic and (b) eukaryotic ribosomes. For the structure of rRNA, see Figure 2.20.
16/18S rRNA and 23/28S rRNAs exhibit complex spatial structures, which are conserved over a wide range of organisms (Figure 2.20). Even though the RNAs consist of single strands, they form complementary double strands (so‐called stem structures) at many sites in aqueous environments. The nucleotide sequence of stem structures is very strongly preserved in evolution. The situation is different for the loops, in which the nucleotides have been modified posttranscriptionally. This phenomena of base modification is especially observed with tRNAs (but also in rRNAs), in which more than 50 modified nucleotides have been discovered. Substituted bases are thiouracil, 5‐methylcytosine, dihydrouracil, thiothymine, thiocytosine, N4‐acetylcytosine, 1‐methylhypoxanthine, 1‐methylguanine, and N6‐methyladenine. There are comparatively many substitutions, deletions, insertions, and inversions present in the loops. Before NGS, genetic trees of all organisms have been reconstructed from the nucleotide sequences of the conserved rRNAs, giving them a special role in molecular evolution. The tree of life and the classification of species were largely based on the analysis of conserved rDNA genes. Today, because of the wide availability of NGS, such trees are often reconstructed from partial genomes (see Chapter 1).
The ribosomal proteins are arranged around the rRNA, together constituting a complex nanomachine known as the ribosome (Figures 4.22 and 4.23). Both ribosomal subunits are assembled in the cell nucleolus and are transported individually into the cytosol through the nuclear pores. Free mRNA molecules are recognized by the small subunits, which are first loaded with methionine tRNA and guanosine triphosphate (GTP)‐activated initiation factors (eIF‐2). The small subunit slides along the mRNA until the first start codon AUG is reached, where methionine tRNA is bound via its anticodon UTC. Following the dissociation of the initiation factor eIF‐2, the large ribosomal subunit is able to bind, and the ribosome is positioned ready to begin translation. There are three formally distinguished binding sites: the arriving aminoacyl‐tRNAs bind to the A‐site, the tRNA with the peptide chain sits in the P‐site, and the E‐site releases the free tRNA after peptide