One of the most powerful techniques for attributing functions to genes in uni-and multicellular organisms is comprehensive analysis of mutant traits. In this study, systematic and quantitative analyses of mutant traits are achieved in the budding yeast Saccharomyces cerevisiae by investigating morphological phenotypes. Analysis of fluorescent microscopic images of triple-stained cells makes it possible to treat morphological variations as quantitative traits. Deletion of nearly half of the yeast genes not essential for growth affects these morphological traits. Similar morphological phenotypes are caused by deletions of functionally related genes, enabling a functional assignment of a locus to a specific cellular pathway. The high-dimensional phenotypic analysis of defined yeast mutant strains provides another step toward attributing gene function to all of the genes in the yeast genome.cell morphology ͉ functional genomics ͉ high-dimensional phenotyping ͉ phenome O ne of the ultimate goals of genetics is to reveal relationships between gene function and phenotypic traits. Comprehensive analysis of mutant traits is a very powerful technique for attributing functions to genes in uni-and multicellular organisms. In the budding yeast Saccharomyces cerevisiae, a complete set of mutants, each of which carries a precise deletion of one yeast ORF, has been systematically constructed (1). By using these mutant strains combined with microarray and robot technology, genome-wide analyses of various mutant traits, including general growth rate, fitness under a particular condition, and sensitivity to drugs, has been reported (reviewed in ref. 2).Cell morphology becomes an attractive target for comprehensive analysis, because more powerful methods for fluorescent microscopic imaging analysis in biological research have been emerging after development of high-resolution microscopes and specific fluorescent dyes. Yeast cell morphology reflects various cellular events, including progression through the cell cycle, establishment of cell polarity, and regulation of cell size control. Previous genome-wide studies of yeast morphology were focused on a specific morphology, such as cell size, cell shape, or bud site pattern (3-6), and therefore extracted limited information. Because morphological traits are often judged ''by eye,'' it has remained difficult to obtain quantitative and reproducible results.We recently developed an image-processing system that automatically processes digital cell images of each yeast cell (7,8) to obtain quantitative morphological data of yeast mutant cells. Mannoprotein (as a cell wall component marker), the actin cytoskeleton, and nuclear DNA are specifically stained simultaneously. Cells are then photographed, and fluorescence images are automatically processed. The obtained images of all yeast mutants and data-mining functions are available at our Saccharomyces cerevisiae Morphological Database (SCMD) web site (8,9).In this study, we employ high-dimensional and quantitative phenotyping of yeast muta...
Chaperone protein BiP binds to Ire1 and dissociates in response to endoplasmic reticulum (ER) stress. However, it remains unclear how the signal transducer Ire1 senses ER stress and is subsequently activated. The crystal structure of the core stress-sensing region (CSSR) of yeast Ire1 luminal domain led to the controversial suggestion that the molecule can bind to unfolded proteins. We demonstrate that, upon ER stress, Ire1 clusters and actually interacts with unfolded proteins. Ire1 mutations that affect these phenomena reveal that Ire1 is activated via two steps, both of which are ER stress regulated, albeit in different ways. In the first step, BiP dissociation from Ire1 leads to its cluster formation. In the second step, direct interaction of unfolded proteins with the CSSR orients the cytosolic effector domains of clustered Ire1 molecules.
We recently isolated the AtBI-1 (Arabidopsis Bax Inhibitor-1) gene, the expression of which suppressed Bax-induced cell death in yeast. To determine whether the same is true in the plant system, transgenic Arabidopsis plants overexpressing Bax protein under a dexamethasone (DEX)-inducible promoter were generated. On DEX treatment, such transgenic plants exhibited marked cell death at the whole-plant level, cell shrinkage, membranous destruction, and other apoptotic phenotypes. Transgenic Bax plants were retransformed with a vector containing the AtBI-1 gene (tagged with green fluorescent protein) under the control of the cauliflower mosaic virus 35S promoter. Plants expressing both Bax and AtBI-1 were able to maintain growth on DEX-treatment by sustaining intracellular integrity. Thus, we present here direct genetic evidence that the plant antiapoptotic protein AtBI-1 is biologically active in suppressing the mammalian Bax action in planta.A lthough relatively little is known about the mechanistic details of cell death in plants, some aspects of the molecular machinery are conserved between plants and animals (1). It has been demonstrated that overexpression of Bax, which encodes a mammalian proapoptotic protein, is lethal in the budding yeast Saccharomyces cerevisiae (2-5), even though yeasts have neither Bcl-2-related proteins nor caspases. Lacomme and Santa Cruz (6) demonstrated that expression of Bax by using a tobacco mosaic virus (TMV) vector triggered cell death in tobacco leaf cells, which closely resembled the hypersensitive response (HR) induced by TMV in tobacco plants carrying the N gene. Conversely, overexpression of human Bcl-X L in transgenic tobacco suppressed HR and conferred stress tolerance (7). It was also reported that caspase-specific peptide inhibitors could abolish bacteria-induced plant programmed cell death (8). These observations clearly suggest some common features of animal and plant cell death processes.Xu and Reed (9) transformed yeast cells containing a galactose-inducible Bax plasmid by using a human cDNA library (in which cDNAs were fused to a constitutively active yeast promoter) and isolated cDNAs that prevented Bax-induced lethality in response to galactose. This resulted in the identification of a gene, termed BI-1 (Bax Inhibitor-1), which is identical to a previously isolated human gene of unknown function called TEGT (testis enhanced gene transcript; refs. 10 and 11). We have previously cloned plant BI-1 cDNAs (Arabidopsis AtBI-1, and rice OsBI-1) (12). Interestingly, Sanchez et al. (13) reported that AtBI-1, the same gene isolated by our group, was obtained by differential screening of genes from plants challenged with the phytopathogen Pseudomonas syringae. Expression of AtBI-1 was rapidly up-regulated in plants during wounding or pathogen challenge. Furthermore, accumulation of the AtBI-1 transcript is significantly delayed in coi1 plants, indicating that reduced AtBI-1 mRNA levels may contribute to the enhanced susceptibility exhibited by coi1 plants to infection by v...
Cysts of Azotobacter vinelandii are resting cells that are surrounded by a protective coat, conferring resistance to various chemical and physical agents. The major chemical components of the cyst coat are alkylresorcinols, which are amphiphilic molecules possessing an aromatic ring with a long aliphatic carbon chain. Although alkylresorcinols are widely distributed in bacteria, fungi, plants, and animals, no enzyme systems for their biosynthesis are known. We report here an ars operon in A. vinelandii that is responsible for the biosynthesis of the alkylresorcinols in the cysts. The ars operon consisted of four genes, two of which encoded a type III polyketide synthase, ArsB and ArsC. In vitro experiments revealed that ArsB and ArsC, sharing 71% amino acid sequence identity, were an alkylresorcinol synthase and an alkylpyrone synthase, respectively, indicating that ArsB and ArsC are not isozymes but enzymatically distinct polyketide synthases. In addition, ArsB and ArsC accepted several acyl-CoAs with various lengths of the side chain as a starter substrate and gave corresponding alkylresorcinols and alkylpyrones, respectively, which suggests that the mode of the ring folding is uninfluenced by the structure of the starter substrates. The importance of the alkylresorcinols for encystment was confirmed by gene inactivation experiments; the lack of alkylresorcinols synthesis caused by ars mutations resulted in the formation of severely impaired cysts, as observed by electron microscopy.
As an approach to understand the molecular mechanisms of endoplasmic reticulum (ER) protein sorting, we have isolated yeast rer mutants that mislocalize a Sec12-Mf␣1p fusion protein from the ER to later compartments of the secretory pathway (S. Nishikawa and A. Nakano, Proc. Natl. Acad. Sci. USA 90:8179-8183, 1993). The temperature-sensitive rer2 mutant mislocalizes different types of ER membrane proteins, suggesting that RER2 is involved in correct localization of ER proteins in general. The rer2 mutant shows several other characteristic phenotypes: slow growth, defects in N and O glycosylation, sensitivity to hygromycin B, and abnormal accumulation of membranes, including the ER and the Golgi membranes. RER2 and SRT1, a gene whose overexpression suppresses rer2, encode novel proteins similar to each other, and their double disruption is lethal. RER2 homologues are found not only in eukaryotes but also in many prokaryote species and thus constitute a large gene family which has been well conserved during evolution. Taking a hint from the phenotype of newly established mutants of the Rer2p homologue of Escherichia coli, we discovered that the rer2 mutant is deficient in the activity of cis-prenyltransferase, a key enzyme of dolichol synthesis. This and other lines of evidence let us conclude that members of the RER2 family of genes encode cis-prenyltransferase itself. The difference in phenotypes between the rer2 mutant and previously obtained glycosylation mutants suggests a novel, as-yetunknown role of dolichol.
Formation of the forespore membrane, which becomes the plasma membrane of spores, is an intriguing step in the sporulation of the fission yeast Schizosaccharomyces pombe. Here we report two novel proteins that localize to the forespore membrane. spo3 ϩ encodes a potential membrane protein, which was expressed only during sporulation. Green fluorescent protein (GFP) fusion revealed that Spo3 localized to the forespore membrane. The spo3 disruptant was viable and executed meiotic nuclear divisions as efficiently as the wild type but did not form spores. One of the spo3 alleles, spo3-KC51, was dose-dependently suppressed by psy1 ϩ , which encodes a protein similar to mammalian syntaxin-1A, a component of the plasma membrane docking/fusion complex. psy1 ϩ was essential for vegetative growth, and its transcription was enhanced during sporulation. As expected, Psy1 localized to the plasma membrane during vegetative growth. Interestingly, Psy1 on the plasma membrane disappeared immediately after first meiotic division and relocalized to the forespore membrane as the second division initiated. In the spo3 null mutant, the forespore membrane was initiated but failed to develop a normal morphology. Electron microscopy revealed that membrane vesicles were accumulated in the cytoplasm of immature spo3⌬ asci. These results suggest that Spo3 is a key component of the forespore membrane and is essential for its assembly acting in collaboration with the syntaxin-like protein.
The VAM2/VPS41 and VAM6/VPS39 were shown to encode hydrophilic proteins of 113 and 123 kDa, respectively. Deletion of the VAM2 and VAM6 functions resulted in accumulation of numerous vacuole-related structures of 200-400 nm in diameter that were much smaller than the normal vacuoles. Loss of functions of Vam2p and Vam6p resulted in inefficient processings of a set of vacuolar proteins, including proteinase A, proteinase B, and carboxypeptidase Y (CPY), and in severely defective maturation of another vacuolar protein, alkaline phosphatase. A part of newly synthesized CPY was missorted to the cell surface in the mutants. Epitope-tagged versions of Vam2p and Vam6p retained their functions, and they were found mostly in sedimentable fractions. The epitope-tagged Vam2p and Vam6p remained in the sedimentable fractions in the presence of Triton X-100, but they were extracted by urea or NaCl. Vam2p and Vam6p were cross-linked by the treatment of a chemical cross-linker. These observations indicated that Vam2p and Vam6p physically interact with each other and exist as components of a large protein complex. Vam6p fused with a green fluorescent protein were highly accumulated in a few specific regions of the vacuolar membranes. Large portions of Vam2p and Vam6p were fractionated into a vacuolar enriched fraction, indicating that they were localized mainly in the vacuolar membranes. These results showed that Vam2p and Vam6p execute their function in the vacuolar assembly as the components of a protein complex reside on the vacuolar membranes.
Haematococcus pluvialis is a freshwater species of green algae and is well known for its accumulation of the strong antioxidant astaxanthin, which is used in aquaculture, various pharmaceuticals, and cosmetics. High levels of astaxanthin are present in cysts, which rapidly accumulate when the environmental conditions become unfavorable for normal cell growth. It is not understood, however, how accumulation of high levels of astaxanthin, which is soluble in oil, becomes possible during encystment. Here, we performed ultrastructural 3D reconstruction based on over 350 serial sections per cell to visualize the dynamics of astaxanthin accumulation and subcellular changes during the encystment of H. pluvialis. This study showcases the marked changes in subcellular elements, such as chloroplast degeneration, in the transition from green coccoid cells to red cyst cells during encystment. In green coccoid cells, chloroplasts accounted for 41.7% of the total cell volume, whereas the relative volume of astaxanthin was very low (0.2%). In contrast, oil droplets containing astaxanthin predominated in cyst cells (52.2%), in which the total chloroplast volume was markedly decreased (9.7%). Volumetric observations also demonstrated that the relative volumes of the cell wall, starch grains, pyrenoids, mitochondria, the Golgi apparatus, and the nucleus in a cyst cell are smaller than those in green coccid cells. Our data indicated that chloroplasts are degraded, resulting in a net-like morphology, but do not completely disappear, even at the red cyst stage.
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