Oligomeric Dop1p is Part of the Endosomal Neo1p‐Ysl2p‐Arl1p Membrane Remodeling Complex

Yeast Dop1p is an essential protein that is highly conserved in evolution and whose function is largely unknown. Here, we provide evidence that Dop1p localizes to endosomes and exists in a complex with two other conserved proteins: Neo1p, a P₄‐ATPase and putative flippase, and the scaffolding protein Ysl2p/Mon2p. The latter operates during membrane budding at the tubular endosomal network/trans‐Golgi network (TEN/TGN) in a process that includes clathrin recruitment via adaptor proteins. Consistent with a role for Dop1p during this process, temperature‐sensitive dop1‐3 cells accumulate multivesicular, elongated tubular and ring‐like structures similar to those displayed by neo1 and ysl2 mutants. In further agreement with the concept of Dop1p‐Neo1p‐Ysl2p complex formation and co‐operation, we show that dop1‐3 cells exhibit reduced levels of Neo1p and Ysl2p at steady state. Conversely, mutations or deletions in NEO1 and YSL2 lead to a decrease in Dop1p levels. In addition to binding to Neo1p and Ysl2p, Dop1p can form dimers or multimers. A critical region for dimerization resides in the C‐terminus with leucine zipper‐like domains. Dop1p's membrane association is largely mediated by its internal region, but Ysl2p might not be crucial for membrane recruitment.     

Über Polyploidie in der GattungBeta und bei den Kulturpflanzen überhaupt

Ohne Zusammenfassung     

Bearbeitung der von Ignaz Dörfler im Jahre 1904 auf Kreta gesammelten Blüten- und Farnpflanzen

Ohne Zusammenfassung     

Immunochemistry of the Lewis-blood-group system: Proton nuclear magnetic resonance study of plasmatic Lewis-blood-group-active glycosphingolipids and related substances

The Le^a-, Le^b-, and H-type 1 (Le^dH)-blood-group-active glycosphingolipids, as well as H-I-type 2 glycolipid, lactotetraosyl ceramide, and neo-lactotetraosyl ceramide were examined by ¹H nuclear magnetic resonance at 360 MHz in dimethyl-d₆ sulfoxide as solvent. The resonances of almost all protons of the sugar rings were assigned with the aid of spin decoupling and nuclear Overhauser difference spectroscopy. The latter technique was also applied to establish the sequences and sites of glycosidic linkage. This information, combined with the chemical shift-structure correlations established in our previous work, led to an independent identification of those six glycolipids. Type 1 (Galβ1 → 3GlcNAc) and type 2 (Galβ1 → 4GlcNAc) saccharide chains can be distinguished by this approach. Some deviations from additivity in chemical shifts, calculated for oligosaccharides from the data on their constituent sugar residues, furnished information on the conformational changes in crowded glycolipid molecules.