Isabelle Sagot

Reversible cytoplasmic localization of the proteasome in quiescent yeast cells

The 26S proteasome is responsible for the controlled proteolysis of a vast number of proteins, including crucial cell cycle regulators. Accordingly, in Saccharomyces cerevisiae, 26S proteasome function is mandatory for cell cycle progression. In budding yeast, the 26S proteasome is assembled in the nucleus, where it is localized throughout the cell cycle. We report that upon cell entry into quiescence, proteasome subunits massively relocalize from the nucleus into motile cytoplasmic structures. We further demonstrate that these structures are proteasome cytoplasmic reservoirs that are rapidly mobilized upon exit from quiescence. Therefore, we have named these previously unknown structures proteasome storage granules (PSGs). Finally, we observe conserved formation and mobilization of these PSGs in the evolutionary distant yeast Schizosaccharomyces pombe. This conservation implies a broad significance for these proteasome reserves.

Yeast Cells Lacking the Mitochondrial Gene Encoding the ATP Synthase Subunit 6 Exhibit a Selective Loss of Complex IV and Unusual Mitochondrial Morphology

Atp6p is an essential subunit of the ATP synthase proton translocating domain, which is encoded by the mitochondrial DNA (mtDNA) in yeast. We have replaced the coding sequence of Atp6p gene with the non-respiratory genetic marker ARG8m. Due to the presence of ARG8m, accumulation of ρ–/ρ0 petites issued from large deletions in mtDNA could be restricted to 20–30% by growing the atp6 mutant in media lacking arginine. This moderate mtDNA instability created favorable conditions to investigate the consequences of a specific lack in Atp6p. Interestingly, in addition to the expected loss of ATP synthase activity, the cytochrome c oxidase respiratory enzyme steady-state level was found to be extremely low (<5%) in the atp6 mutant. We show that the cytochrome c oxidase-poor accumulation was caused by a failure in the synthesis of one of its mtDNA-encoded subunits, Cox1p, indicating that, in yeast mitochondria, Cox1p synthesis is a key target for cytochrome c oxidase abundance regulation in relation to the ATP synthase activity. We provide direct evidence showing that in the absence of Atp6p the remaining subunits of the ATP synthase can still assemble. Mitochondrial cristae were detected in the atp6 mutant, showing that neither Atp6p nor the ATP synthase activity is critical for their formation. However, the atp6 mutant exhibited unusual mitochondrial structure and distribution anomalies, presumably caused by a strong delay in inner membrane fusion.

Metabolic status rather than cell cycle signals control quiescence entry and exit

The use of new candidate markers for yeast quiescence reveals that quiescence entry and exit primarily rely on cellular metabolic status and can be uncoupled from the cell cycle.

Identification of genes affecting selenite toxicity and resistance in Saccharomyces cerevisiae

Recent studies associating dietary selenium with reduced cancer susceptibility have aroused interest in this substance. In the millimolar range, selenite is toxic and slightly mutagenic for yeast. We show that selenite‐treated yeast cells tend to arrest as large budded cells and that this arrest is abolished in a rad9 mutant that is significantly sensitive to selenite. Interestingly, a rev3 mutant affected in the error‐prone repair pathway is also sensitive to selenite, whereas mutations in the other DNA repair pathways do not strongly affect resistance to selenite. We propose that selenite treatment leads to DNA damage inducing the RAD9‐dependent cell cycle arrest. Selenite‐induced DNA damage could be converted to mutations by the Rev3p‐dependent lesion bypass system, thus allowing the cell cycle to progress. We have also investigated the selenite detoxification mechanisms and identified three genes involved in this process. In the present study, we show that lack of the cadmium glutathione‐conjugate vacuolar pump Ycf1p or overexpression of the sulphite resistance membrane protein Ssu1p enhance the capacity of yeast cells to resist selenite treatment. Finally, we show that overexpression of the glutathione reductase Glr1p increases resistance to selenite, suggesting that selenite toxicity in yeast is closely linked to its oxidative capacity.

In Vitro Phosphorylation of Annexin 2 Heterotetramer by Protein Kinase C COMPARATIVE PROPERTIES OF THE UNPHOSPHORYLATED AND PHOSPHORYLATED ANNEXIN 2 ON THE AGGREGATION AND FUSION OF CHROMAFFIN GRANULE MEMBRANES

Heterotetrameric annexin 2 phosphorylated “in vitro” by rat brain protein kinase C is purified and obtained devoid of unphosphorylated protein; it contains 2 mol of phosphate/mol of heterotetramer. The aggregative and binding properties of the phosphorylated annexin 2 toward purified chromaffin granules are compared with those of the unphosphorylated annexin 2. Annexin 2 binds to chromaffin granules with high affinity. Phosphorylation of annexin 2 decreases the affinity of this binding without affecting the maximum binding capacity. The binding curves are strongly cooperative. It is suggested that a surface oligomerization of the proteins may take place upon binding. Besides, phosphorylation of annexin 2 is followed by a dissociation of the light chains from the heavy chains in the heterotetramer. Whereas annexin 2 induces the aggregation of chromaffin granules at μM calcium concentration, the phosphorylated annexin 2 does not induce aggregation at any concentration of calcium either at pH 6 or 7. The phosphorylation of annexin 2 by protein kinase C, MgATP, and 12-O-tetradecanoylphorbol-13-acetate on chromaffin granules induces a fusion of chromaffin granules membranes observed in electron microscopy. The fusion requires the activation of protein kinase C by 12-O-tetradecanoylphorbol-13-acetate. Given these results and since annexin 2 is phosphorylated by protein kinase C under stimulation of chromaffin cells, it is suggested that phosphorylated annexin 2 may be implicated in the fusion step during exocytosis of chromaffin granules.

Mechanism and cellular function of Bud6 as an actin nucleation–promoting factor

Bud6 functions as an actin nucleation–promoting factor (NPF) for Bni1; thus formins can depend on NPFs like the Arp2/3 complex. Unexpected parallels exist between Bud6 and WASp. Bud6 is the first nonmetazoan example of formins pairing with actin monomer–binding proteins to stimulate nucleation, akin to Spire-Capu and APC-mDia1

Mitochondrial F1F0-ATP synthase and organellar internal architecture

The mitochondrial F(1)F(0)-ATP synthase adopts supramolecular structures. The interaction domains between monomers involve components belonging to the F(0) domains. In Saccharomyces cerevisiae, alteration of these components destabilizes the oligomeric structures, leading concomitantly to the appearance of monomeric species of ATP synthase and anomalous mitochondrial morphologies in the form of onion-like structures. The mitochondrial ultrastructure at the cristae level is thus modified. Electron microscopy on cross-sections of wild type mitochondria display many short cristae with narrowed intra-cristae space, whereas yeast mutants defected in supramolecular ATP synthases assembly present a low number of large lamellar cristae of constant thickness and traversing the whole organelle. The growth of these internal structures leads finally to mitochondria with sphere-like structures with a mean diameter of 1 microm that are easily identified by epifluorescence microscopy. As a result, ATP synthase is an actor of the mitochondrial ultrastructure in yeast. This paper reviews the ATP synthase components whose modifications lead to anomalous mitochondrial morphology and also provides a schema showing the formation of the so-called onion-like structures.

Translocation of cytosolic annexin 2 to a Triton‐insoluble membrane subdomain upon nicotine stimulation of chromaffin cultured cells

To gain a better understanding of the function of annexin 2, we have investigated the subcellular distribution of the monomeric and heterotetrameric forms of annexin 2 and their relationship to the cytoskeleton upon stimulation of chromaffin cells. Quantitative immunoblotting has revealed that in resting cells a large amount of annexin 2 is monomeric and cytosolic. Upon nicotine stimulation 80% of total annexin 2 becomes associated with a Triton‐X100‐insoluble fraction where the monomeric and the heterotetrameric forms are found. The translocation of monomeric annexin 2 is Ca2+‐dependent and complete at 1 μM free Ca2+. We have shown that about 66% of the annexin 2 associated with the Triton‐X100‐insoluble fraction is soluble in octylglucoside while the remnants are insoluble in the detergent and remain likely associated with actin filaments and associated cytoskeleton proteins. The octylglucoside‐soluble fraction contains integral proteins from the plasma membrane and from granule membrane, but does not contain caveolin. Moreover, upon nicotine stimulation, a redistribution of proteins was detected in this fraction. These dynamic processes appear concomitantly with the phosphorylation of annexin 2 in this compartment and with catecholamine release. It is suggested that the soluble octylglucoside fraction may represent a special lipidic membrane compartment where the NSF attachment proteins and the cytosolic proteins like annexin 2 and rab3a may become concentrated upon stimulation of the cell. The presence of annexin 2 is consistent with its proposed function on granule and target membrane proteins required for the close apposition of two distinct membranes and supports its functional role in the regulated exocytosis/endocytosis process.

An array of nuclear microtubules reorganizes the budding yeast nucleus during quiescence

A stable monopolar array of nuclear microtubules displaces the nucleolus and kinetochores during quiescence and is required for both quiescence survival and exit.

Imaging fluorescence resonance energy transfer between two green fluorescent proteins in living yeast

We show that fluorescence resonance energy transfer between two mutants of the green fluorescent protein (GFP) can be monitored by imaging microscopy in living yeast. This work is based on the constitutive expression of a GFP‐containing fusion protein and the inducible expression of the tobacco etch virus (TEV) protease. In the fusion protein, the P4.3 GFP mutant is linked to the YS65T GFP mutant by a spacer bearing the TEV protease‐specific cleavage site.