An alpha-specific gene, SAG1 is required for sexual agglutination in Saccharomyces cerevisiae

Defining Functions of Mannoproteins in Saccharomyces cerevisiae by High-Dimensional Morphological Phenotyping

Mannoproteins are non-filamentous glycoproteins localized to the outermost layer of the yeast cell wall. The physiological roles of these structural components have not been completely elucidated due to the limited availability of appropriate tools. As the perturbation of mannoproteins may affect cell morphology, we investigated mannoprotein mutants in Saccharomyces cerevisiae via high-dimensional morphological phenotyping. The mannoprotein mutants were morphologically classified into seven groups using clustering analysis with Gaussian mixture modeling. The pleiotropic phenotypes of cluster I mutant cells (ccw12Δ) indicated that CCW12 plays major roles in cell wall organization. Cluster II (ccw14Δ, flo11Δ, srl1Δ, and tir3Δ) mutants exhibited altered mother cell size and shape. Mutants of cluster III and IV exhibited no or very small morphological defects. Cluster V (dse2Δ, egt2Δ, and sun4Δ) consisted of endoglucanase mutants with cell separation defects due to incomplete septum digestion. The cluster VI mutant cells (ecm33Δ) exhibited perturbation of apical bud growth. Cluster VII mutant cells (sag1Δ) exhibited differences in cell size and actin organization. Biochemical assays further confirmed the observed morphological defects. Further investigations based on various omics data indicated that morphological phenotyping is a complementary tool that can help with gaining a deeper understanding of the functions of mannoproteins.

Mapping of endoglucanases displayed on yeast cell surface using atomic force microscopy

The surface of yeast cells has been an attractive interface for the effective use of cellulose. Surface enzymes, however, are difficult to visualize and evaluate. In this study, two kinds of unique anchoring regions were used to display the cellulase, endoglucanase (EG), on a yeast cell surface. Differences in the display level and the localization of EG were observed by atomic force microscopy. By surveying the yeast cell surface with a chemically modified cantilever, the interactive force between the cellulose and EG was measured. Force curve mapping revealed differences in the display levels and the localization of EG according to anchoring regions. The proposed methodology enables visualization of displayed enzymes such as EG on the yeast cell surface.

Roles of sexual cell agglutination in yeast mass mating

The agalpha1 mutant MAT alpha cells specifically lack the cell surface alpha-type sexual agglutination substance, which is also called alpha-agglutinin. Because the mutant cells (MATalpha agalpha1) can not form aggregates with MATa cells, MATalpha agalpha1 cells are unable to mate with MATa cells when they are co-inoculated in a liquid medium, and the mating is attenuated on solid medium. The attenuated mating ability shown in the previous studies gave us a vague idea about a physiological function of the sexual agglutinability. In order to solve the question, mating behavior of MATalpha agalpha1 cells was investigated here under conditions where the contact between MATa and MAT alpha cells is assisted by physical methods. A synthetic mutation agalpha1::URA3 was constructed and used as well as agalpha1-1 for this study to ensure the genetic defect. When a mixture of MATa and MAT alpha cells was kept on filter membrane placed on relatively dry agar medium, even agalpha1::URA3 mutant cells mated as efficiently as the wild type (AGalpha1) cells did. On filter membrane placed on moist agar medium, agalpha1 mutants mated 10-fold less efficiently than wild type cells did. The mutant cells mated 10000-time less efficiently than the wild type cells in a pellet formed by brief low speed centrifugation. In contrast, the wild type MATalpha cells mated well under all conditions tested. Under the pellet condition, a mixture of MATa and MATalpha AG alpha1 cells formed an extended and cotton-like pellet while a mixture of MATa and MATalpha agalpha1 cells formed a compact and tight pellet. These results suggest that sexual cell agglutination contributes not only to cell contact between MATa and MAT alpha cells thereby stabilizing a-alpha cell pairs, but also to construction of a uniquely organized ultra structure favorable for zygote formation and subsequent growth of diploid cells. The mating specific extended pellet formation was observed also in 4 pairs of a and alpha strains in ascosporogenous yeast genera Hansenula and Pichia.

Sexual agglutination in budding yeasts: structure, function, and regulation of adhesion glycoproteins

The sexual agglutinins of the budding yeasts are cell adhesion proteins that promote aggregation of cells during mating. In each yeast species, complementary agglutinins are expressed by cells of opposite mating type that interact to mediate aggregation. Saccharomyces cerevisiae alpha-agglutinin and its analogs from other yeasts are single-subunit glycoproteins that contain N-linked and O-linked oligosaccharides. The N-glycosidase-sensitive carbohydrate is not necessary for activity. The proposed binding domain of alpha-agglutinin has features characteristic of the immunoglobulin fold structures of cell adhesion proteins of higher eukaryotes. The C-terminal region of alpha-agglutinin plays a role in anchoring the glycoprotein to the cell surface. The S. cerevisiae alpha-agglutinin and its analogs from other species contain multiple subunits; one or more binding subunits, which interact with the opposite agglutinin, are disulfide bonded to a core subunit, which mediates cell wall anchorage. The core subunits are composed of 80 to 95% O-linked carbohydrate. The binding subunits have less carbohydrate, and both carbohydrate and peptide play roles in binding. The alpha-agglutinin and alpha-agglutinin genes from S. cerevisiae have been cloned and shown to be regulated by the mating-type locus, MAT, and by pheromone induction. The agglutinins are necessary for mating under conditions that do not promote cell-cell contact. The role of the agglutinins therefore is to promote close interactions between cells of opposite mating type and possibly to facilitate the response to phermone, thus increasing the efficiency of mating. We speculate that they mediate enhanced response to sex pheromones by providing a synapse at the point of cell-cell contact, at which both pheromone secretion and cell fusion occur.