Accomplishments
In order to achieve the central goal we focussed on a set of proteins: Kif3A, Kap3, APC and a specific mRNA: Tubb2b mRNA. It was reported that APC can be transported by the Kif3A-Kap3 complex in mouse neurons (14). In 2014 it was shown that APC binds mRNAs localised to axonal growth cones with Tubb2b-mRNA being one of its targets (15). Hence, we speculated that APC could be the adaptor needed to link some mRNAs to a kinesin-based transport complex. To test this hypothesis, I purified all needed proteins and in vitro transcribed the Tubb2b-mRNA 3’UTR, which harbours a G-rich APC-binding motif. We tested the functionality of purified APC-GFP by measuring its binding to Kap3 and Tubb2b-RNA by MST (Microscale Thermophoresis). APC-GFP binds to an in vitro transcribed Tubb2b-3’UTR-mRNA fragment with low nanomolar affinity which is close to the published value found by gel-shift assays (15). Kap3 binds APC-GFP with an affinity in the high nanomolar range. As it is not evident from existing literature whether Kif3A can homo-dimerise or hetero-trimerise with Kap3, we performed size-exclusion-coupled multi-angle-light scattering (SEC-MALS) experiments. Kap3 forms a monomer of 80kDA size while Kif3A dimerises to form a 160kDa complex. When combined, a new peak with a mass of 240kDa appears, which shows that the Kif3A-Kap3 complex assembles at a stoichiometric ratio of 2:1. We next tested whether the purified Kif3A-Kap3-GFP complex was active by using TIRF-M coupled in vitro motility assays on Taxol-stabilized, immobilised microtubules (MTs). Processive movement of Kif3A-Kap3-GFP complexes could be observed. Subsequently, we tested whether the APC-Kap3 interaction are strong enough to allow processive transport of APC-GFP in complex with the Tubb2b-RNA fragment. APC-GFP can complex its target mRNA and bind to Kif3A-Kap3 at the same time, allowing processive mRNA transport. The described experiments show the very first reconstitution of a microtubule based mRNA transport system (Fig. 1) and we anticipate that this pioneering work will open a new field allowing to dissect the core mechanisms driving cytoplasmic mRNA distribution.
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