Different tether proteins of the same membrane contact site affect the localization and mobility of each other.

Membrane contact sites enable the exchange of metabolites between subcellular compartments and regulate organelle dynamics and positioning. These structures often contain multiple proteins that tether the membranes, establishing the apposition and functionalizing the structure. In this work, we used drug-inducible tethers in vivo in Saccharomyces cerevisiae to address how different tethers influence each other. We found that the establishment of a region of membrane proximity can recruit tethers, influencing their distribution between different locations or protein complexes. In addition, restricting the localization of one tether to a subdomain of an organelle caused other tethers to be restricted there. Finally, we show that the mobility of contact site tethers can also be influenced by other tethers of the same interface. Overall, our results show that the presence of other tethers at contact sites is an important determinant of the behavior of tethering proteins. This suggests that contact sites with multiple tethers are controlled by the interplay between specific molecular interactions and the cross-influence of tethers of the same interface.

Multiple tethers of organelle contact sites are involved in α-synuclein toxicity in yeast.

The protein α-synuclein (α-syn) is one of the major factors linked to Parkinson's disease, yet how its misfolding and deposition contribute to the pathology remains largely elusive. Recently, contact sites among organelles were implicated in the development of this disease. Here, we used the budding yeast Saccharomyces cerevisiae, in which organelle contact sites have been characterized extensively, as a model to investigate their role in α-syn cytotoxicity. We observed that lack of specific tethers that anchor the endoplasmic reticulum to the plasma membrane resulted in cells with increased resistance to α-syn expression. Additionally, we found that strains lacking two dual-function proteins involved in contact sites, Mdm10 and Vps39, were resistant to the expression of α-syn. In the case of Mdm10, we found that this is related to its function in mitochondrial protein biogenesis and not to its role as a contact site tether. In contrast, both functions of Vps39, in vesicular transport and as a tether of the vacuole-mitochondria contact site, were required to support α-syn toxicity. Overall, our findings support that interorganelle communication through membrane contact sites is highly relevant for α-syn-mediated toxicity.