Cell Biology
| Researchers have deciphered the structure of part of the ribosome found in mitochondria, the power plants of the cell. The scientists were able to benefit from advancements in the field of electron microscopy and capture images of the mitochondrial ribosome at a level of resolution never achieved before. |
The ribosome can be thought of as a decryption device housed within the cell. It is able to decipher the genetic code, which is delivered in the form of messenger ribonucleic acid (mRNA), and translate it into a specific sequence of amino acids. The final assembly of amino acids into long protein chains also takes place in these enzyme complexes. Without ribosomes, a cell would be unable to produce any proteins. Due to their central function, these enzyme complexes have long been the focus of attention of biologists.
In order to obtain a better understanding of ribosomes, which are found in all cells, it is imperative to know their exact composition and structure.
Over the past 15 years, Nenad Ban, professor at ETH Zurich, has made a significant contribution to not only the elucidation of the ribosome structure of bacteria, but also of higher organisms, termed eukaryotes, which include fungi, plants and animals.
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In the case of mitochondrial ribosomes, RNA accounts for just under a third of the entire complex. One reason for this is that the RNA molecules have shortened significantly over the course of evolutionary history. Mitochondrial ribosomes in the cell are primarily localised at the inner membrane of mitochondria and are present within the cell in a far smaller number than the cytoplasmic ribosomes. This makes them more difficult to isolate, hampering progress of research in the field.
A team of researchers from the ETH research groups of Ban and Ruedi Aebersold have now succeeded in elucidating the structure of the large subunit of the mitochondrial ribosomes from mammalian cells to a resolution of 4.9 angstroms (less than 0.5 nanometres). Such a level of resolution allows, for example, the visualization of individual phosphate groups of the ribosomal RNA. The researchers’ findings were published in Nature as the cover story.
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| Image Source - Ban et al, Nature |
In order to interpret the calculated structure as precisely as possible and to determine the exact location of the RNA and protein molecules within the enzyme complex, the researchers used a method derived from Aebersold’s laboratory – a method called ‘chemical cross-linking combined with mass spectrometry.’ Here, the individual protein components of the ribosome are chemically cross-linked, fragmented into peptides for further analysis, and sequenced in the mass spectrometer.
From this data, it is then possible to determine the structure of a protein complex, such as the ribosome and its large subunit. A great deal of computer power is required, however, and so the research team used Brutus, ETH’s high-performance cluster.
The combination of these methods enabled the researchers to succeed in creating a high-resolution structural model of the large subunit of the mitochondrial ribosome with unprecedented precision.
Thanks to their new findings, the researchers can now explain why mitochondrial ribosomes are always located at the membrane of the mitochondrion. In the vicinity of the tunnel exit, through which freshly synthesised proteins leave the ribosome, the biologists were able to localise a protein with similarity to membrane anchor proteins. From this observation, they have been able to conclude that during the course of evolution an anchor protein of this kind was integrated in the ribosome in order to fix it to the mitochondrial membrane, thus allowing the freshly synthesised proteins to be targeted directly to their destination in the membrane.
On the basis of this ground-breaking work, the researchers also hope to gain new insights into the functioning and disorders of this important cellular organelle. Defects in the genetic material coding for the components of mitochondria can lead, for example, to muscle diseases and also play a role in cancer.
Cancer cells not only require high levels of nutrients in order to grow quickly, but also large amounts of energy. Their energy metabolism therefore is in an unusual state, to which the mitochondria probably also contribute. Ban makes clear, however, that no application-related questions are currently being addressed. “The structure of this ribosome provides an important foundation on which other researchers can build,” he says.
SOURCE ETH Zurich
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