Biochemists determine atomic structure of new ABC transporter

Proteins belonging to the large and important family of ABC transporters have been associated with metabolic diseases and can cause resistance to antibiotics. Biochemists from the University of Zurich and the NCCR Structural Biology have succeeded in determining the atomic structure of a new ABC transporter. The insights gained could give rise to new therapies to treat multi-resistant bacteria, cystic fibrosis or gout, for instance.

ABC transporters are membrane proteins that actively pump a wealth of molecules across the membrane. Over 40 different ABC transporters perform vital functions in humans. Genetic defects in ABC transporters can trigger metabolic diseases such as gout, neonatal diabetes or cystic fibrosis, and certain ABC transporters also cause resistance to a wide range of drugs. In tumor cells, increased amounts of ABC transporters that pump chemotherapeutic substances out of the cell are often produced, thus rendering anticancer drugs ineffective. Analogous mechanisms play a key role in many pathogenic bacteria: ABC transporters carry antibiotics out of the cell - multi-resistant bacteria are the result. 

Despite their major importance in biology and medicine, so far the atomic structure of only a few ABC transporters has been decoded. Now, under the supervision of Markus Seeger and Professor Markus Grütter, PhD student Michael Hohl and senior scientist Christophe Briand have succeeded in cracking the atomic structure of the new ABC transporter "TM287/288".

Illuminating asymmetry

The membrane protein originates from a thermophilic bacterium. Compared to structures already known, "TM287/288" has two different protein chains that assemble into a heterodimer. About half of the 40 human ABC transporters are heterodimers. "The asymmetries discovered enable us to consider the role of ABC transporters in a new light," explains Seeger. "In the longer term, our results could help develop new medication against multi-resistant bacteria or tumors that are difficult to treat. They also make new approaches to curing or alleviating hereditary diseases possible," concludes Grütter.