Biochemists Discover New Mechanism in Ribosome Formation

Figure: Ed Hurt

The figure shows the large subunit of the ribosome in its high-resolution 3D structure. The ribosomal RNA is depicted in grey, the myriad of ribosomal proteins in blue-grey. The r-protein Rpl5 is shown in yellow, the r-protein Rpl11 in green. The ruby-coloured area reveals the ribosomal RNA which binds Rpl5 and Rpl11.

A new mechanism in the formation of ribosomes has been discovered by researchers from the Heidelberg University Biochemistry Center. In an interdisciplinary approach, the Heidelberg scientists, along with colleagues from Switzerland and Japan, describe a heretofore uncharacterised protein that plays a specific role in ribosome assembly in eukaryotes, organisms whose cells contain a cell nucleus. This protein makes sure that specific factors required for ribosome synthesis are transported together, like hitchhikers, into the nucleus to the site of assembly. The results of this research were published in “Science”.

Ribosomes, the protein factories of the cell, are macromolecular complexes of ribonucleic acids (RNA) and ribosomal proteins (r-proteins) that are organised in a highly complicated three-dimensional nanostructure. Correct synthesis of ribosomes is critical for the division of all cells and is a process that follows strict rules. In eukaryotes, new ribosomes are formed predominantly in the cell nucleus. Therefore, the r-proteins needed for ribosome formation must travel from the cytoplasm of the cell to a site in the nucleus where the ribosomes are assembled. Until recently it was not clear whether r-proteins that have a similar function and form functional clusters on the ribosome structure are also co-transported into the nucleus.

The researchers have now found a protein that coordinates the co-transport of certain r-proteins in functional clusters into the cell nucleus. This factor is called Symportin1, for synchronised import. “Symportin1 synchronises the import of both the Rpl5 and Rpl11 r-proteins into the cell nucleus and supports their integration into the growing ribosome structure”, explains Prof. Dr. Irmgard Sinning of the Heidelberg University Biochemistry Center (BZH). “It employs a familiar logistical concept from every day life, like picking up a hitchhiker or sharing a taxi with someone headed for the same destination”, says Dr. Gert Bange of the BZH, lead author of the study together with Dr. Dieter Kressler (now of Fribourg University).

The researchers from Heidelberg University and the University of Fribourg (Switzerland) collaborated closely with colleagues from Osaka University in Japan on the research. “The combination of different methods ranging from traditional cell biology to new biophysical approaches was crucial in developing the detailed picture of this previously unknown biological mechanism”, emphasises Prof. Dr. Ed Hurt, also of the BZH. The study took advantage of the Biochemistry Center’s crystallisation platform and the research received support from the Cluster of Excellence “CellNetworks” of Heidelberg University.

Original publication:
D. Kressler, G. Bange, Y. Ogawa, G. Stjepanovic, B. Bradatsch, D. Pratte, S. Amlacher, D. Strauß, Y. Yoneda, J. Kata-hira, I. Sinning, E. Hurt: Synchronizing Nuclear Import of Ribosomal Proteins with Ribosome Assembly, Science (2 November 2012), Vol. 338 no. 6107, 666-671, doi: 10.1126/science.1226960

Contact:
Prof. Dr. Irmgard Sinning / Prof. Dr. Ed Hurt
Heidelberg University Biochemistry Center
Phone: +49 (0)6221 54-4781, -4173
Irmi.sinning@bzh.uni-heidelberg.de
ed.hurt@bzh.uni-heidelberg.de

Communications and Marketing
Press Office
phone: +49 6221 54-2311
presse@rektorat.uni-heidelberg.de