B. Janderová scite author profile

Under certain growth conditions unicellular organisms behave as highly organized multicellular structures. For example, the fruiting bodies of myxobacteria and of the slime mould Dictyostelium discoideum form structures composed of non-dividing motile cells. Although non-motile, yeasts can create organized structures, colonies in which cells communicate and act in a coordinated fashion. Colony morphologies are characteristic for different species and strains. Here we describe that, in addition to short-range intracolony cell-cell communication, yeasts exhibit long-distance signals between neighbouring colonies. The volatile alkaline compound ammonia, transmitted by yeast colonies in pulses, has been identified as a substance mediating the intercolony signal. The first alkaline pulse produced by neighbouring colonies is non-directed and is followed by acidification of the medium. The second pulse seems to be enhanced and is oriented towards the neighbour colony. Ammonia signalling results in growth inhibition of the facing parts of both colonies. This phenomenon is observed in different yeast genera. The presence of amino acids in the medium is required for ammonia production. Colonies derived from the yeast Saccharomyces cerevisiae shr3 mutant, defective in localization of amino-acid permeases, do not produce detectable amounts of ammonia and do not exhibit asymmetric growth inhibition.

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Role of distinct dimorphic transitions in territory colonizing and formation of yeast colony architecture

Vopálenská

Šťovíček

Janderová

et al. 2009

Environmental Microbiology

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Microbial populations in nature often form organized multicellular structures (biofilms, colonies) occupying different surfaces including host tissues and medical devices. How yeast cells within such populations cooperate and how their dimorphic switch to filamentous growth is regulated are therefore important questions. Studying population development, we discovered that Saccharomyces cerevisiae microcolonies early after their origination from one cell successfully occupy the territory via dimorphic transition, which is induced by ammonia and other volatile amines independently on cell ploidy and nutrients. It results in oriented pseudohyphal cell expansion in the direction of ammonia source, which consequently leads to unification of adjacent microcolonies to one more numerous entity. The further population development is accompanied by another dimorphic switch, which is strictly dependent on Flo11p adhesin and is indispensable for proper formation of biofilm-like aerial 3-D colony architecture. In this, Flo11p is required for both elongation of cells organized to radial clusters (formed earlier within the colony) and their subsequent pseudohyphal expansion. Just before this expansion, Flo11p relocalizes from the bud-neck of radial cell clusters also to the tip of elongated cells.

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The morphology of Saccharomyces cerevisiae colonies is affected by cell adhesion and the budding pattern

Vopálenská

Hůlková

Janderová

et al. 2005

Research in Microbiology

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Effect of high-voltage electric pulses on yeast cells: factors influencing the killing efficiency

Gášková

Sigler

Janderová

et al. 1996

Bioelectrochemistry and Bioenergetics

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B. Janderová

Domestication of wild Saccharomyces cerevisiae is accompanied by changes in gene expression and colony morphology

Ammonia mediates communication between yeast colonies

Role of distinct dimorphic transitions in territory colonizing and formation of yeast colony architecture

The morphology of Saccharomyces cerevisiae colonies is affected by cell adhesion and the budding pattern

Effect of high-voltage electric pulses on yeast cells: factors influencing the killing efficiency

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