Nucleus-vacuole junctions in Saccharomyces cerevisiae are formed through the direct interaction of Vac8p with Nvj1p

Vac8p is a vacuolar membrane protein that is required for efficient vacuole inheritance and fusion, cytosol-to-vacuole targeting, and sporulation. By analogy to other armadillo domain proteins, including beta-catenin and importin alpha, we hypothesize that Vac8p docks various factors at the vacuole membrane. Two-hybrid and copurfication assays demonstrated that Vac8p does form complexes with multiple binding partners, including Apg13p, Vab2p, and Nvj1p. Here we describe the surprising role of Vac8p-Nvj1p complexes in the formation of nucleus-vacuole (NV) junctions. Nvj1p is an integral membrane protein of the nuclear envelope and interacts with Vac8p in the cytosol through its C-terminal 40-60 amino acids (aa). Nvj1p green fluorescent protein (GFP) concentrated in small patches or rafts at sites of close contact between the nucleus and one or more vacuoles. Previously, we showed that Vac8p-GFP concentrated in intervacuole rafts, where is it likely to facilitate vacuole-vacuole fusion, and in "orphan" rafts at the edges of vacuole clusters. Orphan rafts of Vac8p red-sifted GFP (YFP) colocalize at sites of NV junctions with Nvj1p blue-sifted GFP (CFP). GFP-tagged nuclear pore complexes (NPCs) were excluded from NV junctions. In vac8-Delta cells, Nvj1p-GFP generally failed to concentrate into rafts and, instead, encircled the nucleus. NV junctions were absent in both nvj1-Delta and vac8-Delta cells. Overexpression of Nvj1p caused the profound proliferation of NV junctions. We conclude that Vac8p and Nvj1p are necessary components of a novel interorganelle junction apparatus.

14-3-3 proteins: potential roles in vesicular transport and Ras signaling in Saccharomyces cerevisiae

Deletion of the clathrin heavy-chain gene, CHC1, in the budding yeast Saccharomyces cerevisiae results in growth, morphological, and membrane trafficking defects, and in some strains chc1-delta is lethal. A previous study identified five genes which, in multicopy, rescue inviable strains of Chc- yeast. Now we report that one of the suppressor loci, BMH2/SCD3, encodes a protein of the 14-3-3 family. The 14-3-3 proteins are abundant acidic proteins of approximately 30 kDa with numerous isoforms and a diverse array of reported functions. The Bmh2 protein is > 70% identical to the mammalian epsilon-isoform and > 90% identical to a previously reported yeast 14-3-3 protein encoded by BMH1. Single deletions of BMH1 or BMH2 have no discernable phenotypes, but deletion of both BMH1 and BMH2 is lethal. High-copy BMH1 also rescues inviable strains of Chc- yeast, although not as well as BMH2. In addition, the slow growth of viable strains of Chc- yeast is further impaired when combined with single bmh mutations, often resulting in lethality. Overexpression of BMH genes also partially suppresses the temperature sensitivity of the cdc25-1 mutant, and high-copy TPK1, encoding a cAMP-dependent protein kinase, restores Bmh- yeast to viability. High-copy TPK1 did not rescue Chc- yeast. These genetic interactions suggest that budding-yeast 14-3-3 proteins are multifunctional and may play a role in both vesicular transport and Ras signaling pathways.

The medium chains of the mammalian clathrin-associated proteins have a homolog in yeast

We have cloned and sequenced mouse brain AP47, the medium chain of the trans-Golgi network clathrin-associated protein complex AP-1. The predicted protein sequence of AP47 is closely related to rat and calf brain AP50, the corresponding medium chain of the plasma-membrane clathrin-associated protein complex AP-2. We have also identified in the yeast genome an open reading frame encoding a protein of previously unknown function. Referred to here as YAP54, its predicted protein sequence displays a striking homology to AP47. We therefore propose that Yap54 is the medium chain subunit of a putative AP-1 complex in yeast. From the analyses of the optimized sequence alignments of AP47, AP50 and Yap54p, we suggest a model for the domain organization of the medium chains.

Characterization of yeast clathrin and anticlathrin heavy-chain monoclonal antibodies

Clathrin-coated vesicles (CVs) were isolated from Saccharomyces cerevisiae by using procedures developed by Mueller and Branton [17]. Triskelions were purified from this material by extraction of CVs to release clathrin and by subsequent fractionation on Sepharose CL-4B. Triskelions were composed of approximately 180,000 Mr heavy chains and a single light-chain type of approximately 38,000 Mr and were able to undergo self-assembly into polyhedral cages. Trypsin digestion of such reassembled cages showed a peptide pattern very similar to that obtained for mammalian clathrin with two fragments of 125,000 and 110,000 Mr, which represent the major portion of the heavy-chain arm, and a polypeptide of approximately 43,000 Mr, which is the presumptive terminal domain. Eight monoclonal antibodies reacting with yeast clathrin heavy chains were produced. All eight bind to the major portion of the heavy-chain arm, and none bind to the terminal domain fragment. Peptide digestion experiments also indicated that at least three major regions on the arm are recognized by these antibodies. These will be useful in further structural and functional studies of clathrin from yeast.