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TPLATE Protein Complex’s Molecular Architecture Revealed

TPLATE Protein Complex’s Molecular Architecture Revealed

TPLATE Protein Complex’s Molecular Architecture Revealed

TPLATE Protein Complex’s Molecular Architecture Revealed

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The molecular architecture of TPLATE

Complex life has complex cells, also known as eukaryotic cells. Unlike bacteria, for example, the cells of complex life have many distinct internal compartments known as organelles. These organelles exchange material among themselves. To do so, the organelles have a few tricks. One of those tricks is vesicle trafficking. This means that they use a part of their own membrane as a bag for the goods to be exchanged.

A recent discovery showed that plants heavily rely on a protein complex named the TPLATE complex to do so. This complex is not only present in plants, but also in a wide range of other eukaryotes, which suggests it is evolutionary very old and part of a protein complex family of which all other members are intensively studied. However, because this particular complex is not present in the most-studied model organisms (animals and yeasts), its existence and function remained under the radar for a very long time. 

In this study, VIB teams (the groups of Bert De Rybel, Geert De Jaeger, and Daniël Van Damme from the VIB-UGent Center for Plant Systems Biology, Remy Loris from the VIB-VIB Center for Structural Biology, and Savvas Savvides from the VIB-UGent Center for Inflammation Research) reveal TPLATE's molecular architecture for the very first time. They achieved this by crosslinking mass spectrometry and computer simulations. These new insights revealed the orientation of this complex towards the membrane as well as the delicate relationship between the different domains of its subunits.

These findings are important to increase our knowledge of crucial eukaryotic processes. Indeed, the structure of this complex now allows us to compare it with known structures of its close relatives that are present in all eukaryotes including animals and yeasts and this allows us to visualize the evolution of these trafficking complexes.

Collaborating for success

To obtain both structural and functional insight into this enigmatic complex an integrative, collaborative approach was needed. Five VIB research groups and one group from the Czech Republic contributed within their specific expertise to perform experiments ranging from lipid-binding studies to structural biology approaches.

The novel structural insight was mostly generated based on crosslinking mass spectrometry, performed with the help of the VIB Proteomics core facility.

‘A major benefit of working at VIB is that it greatly encourages and facilitates access to knowledge and expertise that allows research groups to successfully embark on joint projects that lie far beyond their comfort zone.’ – Prof. Daniel Van Damme

This study will form the foundation of further scientific work and will open doors for the generation of novel and safer herbicides or modulation of stress responses in plants.

Reference: Yperman K, Wang J, Eeckhout D, et al. Molecular architecture of the endocytic TPLATE complex. Sci Adv. 2021;7(9):eabe7999. doi:10.1126/sciadv.abe7999.

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