The tRNA molecules act as the adapters between the nucleic acid sequence carried on the messenger RNA (and originally the DNA), and the final protein. This ensures that the amino acids are lined up in the right order to create the proper protein. This is shown in Figure 11.2. When two amino acids are held next to each other at the ribosome, the rRNA can carry out a chemical reaction that attaches the end of one amino acid to the beginning of the next and thereby builds the protein chain.

Figure 11.2 As the messenger RNA moves through the ribosomes, transfer RNA molecules bring the appropriate amino acids to the correct position on the chain, using base pairing. The ribosomal RNA machinery joins up adjacent amino acids to create the protein chain.

Some of the triplets on the messenger RNA don’t have a match to any triplet on a tRNA. These triplets are known as stop signals. When the ribosome reads one of these, it can’t fit a tRNA in place and the ribosome falls off the messenger RNA and the protein stops growing. These are the roofing LEGO bricks we met in Chapter 7 (see page 85). The ribosome then finds another messenger RNA molecule to translate into protein, or could even go back to the start of the first one.

Even though the entire procedure relies on a giant complex of four types of ribosomal RNA and around 80 associated proteins, and is a very sophisticated task, the process of adding new amino acids into a growing protein chain is remarkably fast. It’s difficult to measure this accurately in human cells, but in bacteria each ribosome can add amino acids at the rate of about 200 a second. It’s probably not as fast as this in human cells, but it will still be about ten times faster than we could possibly stick two bricks together if we were making a LEGO tower. And don’t forget that the ribosome isn’t sticking together random LEGO bricks. It’s as if we had to choose just two out of 20 different types of LEGO bricks (there are 20 different amino acids) and stick them on top of each other in exactly the right order every fraction of a second. Quite a task.

Our cells need to produce millions of protein molecules every second, and so we need our ribosomes to work very efficiently. We also need a lot of ribosomes to meet the demand, up to 10 million robots in a single cell.^{216} In order to create enough ribosomes, our cells have accumulated lots of copies of rRNA genes. Instead of being dependent on creating rRNA from the classical situation of one gene inherited from each parent, we inherit about 400 rRNA genes, distributed across five different chromosomes.^{217}

One consequence of this vast number of rRNA genes is that we aren’t very prone to disorders caused by mutations in these genes. That’s because if one copy is mutated we have lots of redundancy. So the chances are that we can make up for the defect from all the normal versions encoding the same rRNA molecule. This isn’t true of mutations in the genes coding for the proteins that are also present in the ribosomes. We don’t know what many of these do in detail, and some don’t seem to be important at all in ribosome function. But there are others where mutations do result in human disorders.

The two best-known examples are called Diamond-Blackfan Anaemia and Treacher-Collins Syndrome. They are caused by inherited mutations in different protein-coding genes. The consequence in both cases is a decrease in the number of ribosomes. But there are clearly subtleties that we don’t understand in how this affects cell function, because if the only important factor was this reduced number, we would expect the clinical consequences to be identical. But they aren’t. The major symptom in Diamond-Blackfan Anaemia is a defect in the production of red blood cells. The major symptoms in Treacher-Collins Syndrome are malformations of the head and face, leading to problems with breathing, swallowing and hearing.^{218}

Because we need a lot of ribosomes and hence a lot of rRNA genes, it’s not unreasonable that we also need a lot of tRNA genes to ensure that there are plenty of tRNA molecules to transport the amino acids to the ribosomes. The human genome contains nearly 500 tRNA genes, distributed across almost every chromosome.^{219} This brings the same benefits as those described above for multiple copies of rRNA genes.

There’s also an odd and intriguing possible overlap between rRNA and imprinting. As described in Chapter 10, there are a small number of patients with Prader-Willi syndrome where the disorder has been localised to a junk DNA region that encodes a batch of non-coding RNAs (see page 140). These are called snoRNAs, for small nucleolar RNAs.[28] These non-coding RNAs migrate to a region of the nucleus called the nucleolus, which is very important in ribosome biology. The nucleolus is the place where the mature ribosomes are assembled, as shown in Figure 11.3.

In the nucleolus, the rRNAs and the proteins are modified and then assembled into mature intact ribosomes which are transported back into the cytoplasm, ready to carry out their functions as protein-creating robots. The snoRNAs are required to make sure that certain modifications take place properly on the rRNA molecules. Just as DNA and histone proteins can be modified by the addition of a methyl group, rRNA molecules can also be methylated. The snoRNAs probably facilitate this by finding regions on the rRNA with which they can form pairs. Once again this is possible because of bonding between complementary bases on the two nucleic acid molecules. Once they bind, the snoRNAs attract enzymes that can add methyl groups to the rRNAs. This be similar to the ways in which long non-coding RNAs attract enzymes that modify histones.[29] It’s not altogether clear why these modifications matter to the rRNA, but one suggestion is that they help to stabilise interactions between the rRNAs and the proteins in ribosomes.

Figure 11.3 Messenger RNA molecules for ribosomal proteins are created in the nucleus and then shipped out to existing ribosomes in the cytoplasm. The new ribosomal proteins are transported back into a specific region in the nucleus. Here they join up with ribosomal RNA molecules to create new ribosomes, which are moved out into the cytoplasm to act.

Although it’s tempting to speculate that the symptoms of Prader-Willi syndrome are caused by problems in the snoRNAs’ control of rRNA modifications, this remains just a theory at the moment. The problem is that we now recognise that the snoRNAs can also target lots of other types of RNA molecules, so we can’t be sure exactly which process is going wrong in the children with this disorder.

Ribosomes are extremely ancient structures, and can be detected in really primitive organisms. They are even found in bacteria, the tiny single-celled organisms which don’t have a nucleus in their cells to separate their DNA from their cytoplasm. Evolutionary biologists often use the DNA sequences of the genes that encode rRNAs to track how species have diverged over time.

Bacteria and higher organisms diverged about 2 billion years ago^{220} so although we can still recognise the rRNA genes in our uni-cellular (very) distant cousins they are really different from ours. This has turned out to be A Good Thing. Some of the most common and successful antibiotics work by inhibiting the bacterial ribosomes.^{221} These include tetracycline and erythromycin. These antibiotics disrupt the activity of the bacterial ribosomes, but not human ones. In the West we are so accustomed to antibiotics that we sometimes forget how important they have been, saving literally tens of millions of lives, at a conservative estimate, since they really hit the medical scene in the 1940s. It’s odd to think that many of these lives have been saved because of variation between species in what purists would consider junk DNA.