Abstract
Membrane proteins are targeted not only to specific membranes in the cell architecture, but also to distinct lateral microdomains within individual membranes to properly execute their biological functions. Yeast tetraspan protein Nce102 has been shown to migrate between such microdomains within the plasma membrane in response to an acute drop in sphingolipid levels. Combining microscopy and biochemistry methods, we show that upon gradual ageing of a yeast culture, when sphingolipid demand increases, Nce102 migrates from the plasma membrane to the vacuole. Instead of being targeted for degradation it localizes to V-ATPase-poor, i.e., ergosterol-enriched, domains of the vacuolar membrane, analogous to its plasma membrane localization. We discovered that, together with its homologue Fhn1, Nce102 modulates vacuolar morphology, dynamics, and physiology. Specifically, the fusing of vacuoles, accompanying a switch of fermenting yeast culture to respiration, is retarded in the strain missing both proteins. Furthermore, the absence of either causes an enlargement of ergosterol-rich vacuolar membrane domains, while the vacuoles themselves become smaller. Our results clearly show decreased stability of the V-ATPase in the absence of either Nce102 or Fhn1, a possible result of the disruption of normal microdomain morphology of the vacuolar membrane. Therefore, the functionality of the vacuole as a whole might be compromised in these cells.
Highlights
Vital biochemical processes take place on membranes
Most of Nce102 localizations published to date were performed in exponentially growing cell cultures and the vast majority of the Nce102 protein was reported to distribute within the plasma membrane [1,10,14]
The marked increase of the intracellular fraction upon entering the stationary phase was specific to Nce102 and was not observed for other MCC or eisosomal proteins (Sur7, Pil1), which retained their plasma membrane localization (Figure S1A)
Summary
Vital biochemical processes take place on membranes. The lateral segmentation of biological membranes into distinct areas, namely microdomains, facilitates the spatio-temporal segregation of various cellular functions. This results in localization of activity of metabolic and signalling pathways, and provides an additional level for their effective regulation. Specific lipids and proteins preferentially accumulate in certain types of microdomains. Microdomain localization often determines protein activity and/or stability. Functional interplay between distinct microdomains is often mediated by the relocalization of a certain protein from one microdomain to another
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