Retrograde transport of CDMPR depends on several machineries as analyzed by sulfatable nanobodies

Retrograde protein transport from the cell surface and endosomes to the TGN is essential for membrane homeostasis in general and for the recycling of mannose-6-phosphate receptors (MPRs) for sorting of lysosomal hydrolases in particular. We used a nanobody-based sulfation tool to more directly determine transport kinetics from the plasma membrane to the TGN for the cation-dependent MPR (CDMPR) with and without rapid or gradual inactivation of candidate machinery proteins. Although knockdown of retromer (Vps26), epsinR, or Rab9a reduced CDMPR arrival to the TGN, no effect was observed upon silencing of TIP47. Strikingly, when retrograde transport was analyzed by rapamycin-induced rapid depletion (knocksideways) or long-term depletion by knockdown of the clathrin adaptor AP-1 or of the GGA machinery, distinct phenotypes in sulfation kinetics were observed, suggesting a potential role of GGA adaptors in retrograde and anterograde transport. Our study illustrates the usefulness of derivatized, sulfation-competent nanobodies, reveals novel insights into CDMPR trafficking biology, and further outlines that the selection of machinery inactivation is critical for phenotype analysis.

Automated summary

Retrograde protein transport plays a crucial role in maintaining membrane homeostasis and recycling of mannose-6-phosphate receptors (MPRs) for sorting of lysosomal hydrolases. Using a sulfation tool based on nanobodies, we directly determined the transport kinetics of cation-dependent MPR (CDMPR) from the plasma membrane to the trans-Golgi network (TGN). Our study suggests a potential role of GGA adaptors in retrograde and anterograde transport.