How a cell’s mitochondria make their own protein factories

A subunit of a yeast mitoribosome (pink) compared to that of a human mitoribosome (purple). Although different, the two developing subunits have an assembly factor (green) in common.
Credit: Sebastian Klinge

Ribosomes, the tiny protein-producing factories within cells, are ubiquitous and look largely identical across the tree of life. Those that keep bacteria chugging along are, structurally, not much different from the ribosomes churning out proteins in our own human cells.

But even two organisms with similar ribosomes may display significant structural differences in the RNA and protein components of their mitoribosomes. Specialized ribosomes within the mitochondria (the energy producing entities within our cells), mitoribosomes help the mitochondria produce proteins that manufacture ATP, the energy currency of the cell.

Scientists in the laboratory of Sebastian Klinge wondered how mitoribosomes evolved, how they assemble within the cell, and why their structures are so much less uniform across species. To answer these questions, they used cryo-electron microscopy to generate 3D snapshots of the small subunits of yeast and human mitoribosomes as they were being assembled. Their findings, published in Nature, shed light on the fundamentals of mitoribosome assembly, and may have implications for rare diseases linked to malfunctioning mitoribosomes.

“Three dimensional pictures can tell us a lot about what steps are required, what proteins are involved in the process, and how you might be able to regulate the assembly of these large and complex machines,” says Nathan Harper, a graduate student in Klinge’s lab. “Cryo-EM allowed us to identify and isolate individual stages of the assembly pathway from a heterogeneous population of purified complexes, and we are able to see how these complexes change over time during assembly,” adds Chloe Burnside, also a graduate student in Klinge’s lab.

By observing this process in two different species—yeast and humans—the team managed to directly observe many similarities and differences in mitoribosome assembly. One key distinction: different proteins often were involved in otherwise similar acts of RNA folding. That’s likely because “there are common hurdles for these ribosomes,” Harper explains. “You can think about it like manufacturing two different bikes—a road bike and a mountain bike. You might need additional parts or tools for each one, but some key stages in production will be similar.”

The results provide unique insights into how molecular complexity and diversity arises in macromolecular complexes, and how assembly systems evolve along with the complexes themselves. A better understanding of mitoribosomes may also have implications for a range of severe diseases linked to mitoribosome dysfunction, such as Perrault syndrome. “We were able to map various disease-causing mutations onto different assembly factors’ structures, so that we could see how these mutations could affect the ribosome assembly process.”

Journal: Nature
DOI: 10.1038/s41586-022-05621-0
Article Title: Principles of mitoribosomal small subunit assembly in eukaryotes
Article Publication Date: 8-Dec-2022

Media Contacts

Kelly McLees
Rockefeller University
kmclees@rockefeller.edu

Joshua Krisch
The Rockefeller University
press@rockefeller.edu
Office: 212-327-8982

www.rockefeller.edu

Media Contact

Kelly McLees
Rockefeller University

All latest news from the category: Life Sciences and Chemistry

Articles and reports from the Life Sciences and chemistry area deal with applied and basic research into modern biology, chemistry and human medicine.

Valuable information can be found on a range of life sciences fields including bacteriology, biochemistry, bionics, bioinformatics, biophysics, biotechnology, genetics, geobotany, human biology, marine biology, microbiology, molecular biology, cellular biology, zoology, bioinorganic chemistry, microchemistry and environmental chemistry.

Back to home

Comments (0)

Write a comment

Newest articles

Innovative 3D printed scaffolds offer new hope for bone healing

Researchers at the Institute for Bioengineering of Catalonia have developed novel 3D printed PLA-CaP scaffolds that promote blood vessel formation, ensuring better healing and regeneration of bone tissue. Bone is…

The surprising role of gut infection in Alzheimer’s disease

ASU- and Banner Alzheimer’s Institute-led study implicates link between a common virus and the disease, which travels from the gut to the brain and may be a target for antiviral…

Molecular gardening: New enzymes discovered for protein modification pruning

How deubiquitinases USP53 and USP54 cleave long polyubiquitin chains and how the former is linked to liver disease in children. Deubiquitinases (DUBs) are enzymes used by cells to trim protein…