Acetic acid inhibits nutrient uptake in Saccharomyces cerevisiae: auxotrophy confounds the use of yeast deletion libraries for strain improvement

Ding, Jun; Bierma, Jan C.; Smith, Mark R.; Poliner, Eric; Wolfe, Carole; Hadduck, Alex N.; Zara, Severino; Jirikovic, Mallori; Zee, Kari van; Penner, Michael H.; Patton‐Vogt, Jana; Bakalinsky, Alan T.

doi:10.1007/s00253-013-5071-y

Cited by 53 publications

(50 citation statements)

References 36 publications

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“…Once in the near-neutral environment, acetic acid dissociates causing a decrease in internal pH which, like in bacteria, leads to a dissipation of the electrochemical gradient maintained across the plasma membrane and inhibits the activity of metabolic enzymes (Booth and Statford 2003;Holyoak et al 1996;Pampulha and Loureiro-Dias 1990). Accumulation of acetate has been found to increase turgor pressure of yeast cells, to induce oxidative stress, to inhibit cell wall glucans' synthesis, and to deplete cells of ATP and amino acids, among other deleterious effects (Almeida et al 2009;Ding et al 2013;Semchyshyn et al 2011;Ullah et al 2013). Yeast cells counteract the internal acidification imposed by acetic acid stress essentially by up-regulating the activity of two proton pumps, one located in the plasma membrane (the PM-H + -ATPase) and the other in the vacuolar membrane (the V-ATPase), which excrete the exceeding protons to the exterior or to the vacuole lumen, respectively (Carmelo et al 1997;Kawahata et al 2006;Mira et al 2010b).…”

Section: Toxic Effect Of Acetic Acid In Yeast Cells and Underlying Admentioning

confidence: 97%

“…The large-scale phenotypic screenings carried out in the presence of stressful concentrations of acetic acid have expanded the range of biological functions required for maximal yeast tolerance to acetic acid being demonstrated, in some cases for the first time, such as for the crucial role of genes involved in intracellular trafficking and in the uptake of amino acids and K + (Ding et al 2013;Kawahata et al 2006;Mira et al 2010b). The identification of acetic acid resistance genes and/or of the biological functions maximizing tolerance to this acid provides a valuable asset for the rational design of acetic acid-tolerant yeast strains.…”

Section: Toxic Effect Of Acetic Acid In Yeast Cells and Underlying Admentioning

confidence: 99%

“…These studies have been boosted by the availability of an experimental system for this yeast, which allowed the development of a huge panoply of resources and tools that are not available for less genetically accessible systems. In particular, phenotypic screenings of large collections of mutants devoid of all non-essential yeast genes had been conducted using different experimental setups and exploring different genetic backgrounds to identify acetic acid resistance genes in yeast (Ding et al 2013;Kawahata et al 2006;Mira et al 2010b). Putting together the results obtained in these chemogenomic screenings with those resulting from other studies performed at a genomic scale or on a gene-by-gene basis, comprehensive models on the adaptive responses of Saccharomyces cerevisiae to acetic acid toxicity have been established, and these are well described in previous reviews (Mira et al 2010c;Mollapour et al 2008;Piper et al 2001).…”

Section: Toxic Effect Of Acetic Acid In Yeast Cells and Underlying Admentioning

confidence: 99%

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Adaptation and tolerance of bacteria against acetic acid

Trček

Mira

Jarboe

2015

Appl Microbiol Biotechnol

181

100

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Acetic acid is a weak organic acid exerting a toxic effect to most microorganisms at concentrations as low as 0.5 wt%. This toxic effect results mostly from acetic acid dissociation inside microbial cells, causing a decrease of intracellular pH and metabolic disturbance by the anion, among other deleterious effects. These microbial inhibition mechanisms enable acetic acid to be used as a preservative, although its usefulness is limited by the emergence of highly tolerant spoilage strains. Several biotechnological processes are also inhibited by the accumulation of acetic acid in the growth medium including production of bioethanol from lignocellulosics, wine making, and microbe-based production of acetic acid itself. To design better preservation strategies based on acetic acid and to improve the robustness of industrial biotechnological processes limited by this acid's toxicity, it is essential to deepen the understanding of the underlying toxicity mechanisms. In this sense, adaptive responses that improve tolerance to acetic acid have been well studied in Escherichia coli and Saccharomyces cerevisiae. Strains highly tolerant to acetic acid, either isolated from natural environments or specifically engineered for this effect, represent a unique reservoir of information that could increase our understanding of acetic acid tolerance and contribute to the design of additional tolerance mechanisms. In this article, the mechanisms underlying the acetic acid tolerance exhibited by several bacterial strains are reviewed, with emphasis on the knowledge gathered in acetic acid bacteria and E. coli. A comparison of how these bacterial adaptive responses to acetic acid stress fit to those described in the yeast Saccharomyces cerevisiae is also performed. A systematic comparison of the similarities and dissimilarities of the ways by which different microbial systems surpass the deleterious effects of acetic acid toxicity has not been performed so far, although such exchange of knowledge can open the door to the design of novel approaches aiming the development of acetic acid-tolerant strains with increased industrial robustness in a synthetic biology perspective.

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Section: Toxic Effect Of Acetic Acid In Yeast Cells and Underlying Admentioning

confidence: 97%

Section: Toxic Effect Of Acetic Acid In Yeast Cells and Underlying Admentioning

confidence: 99%

Section: Toxic Effect Of Acetic Acid In Yeast Cells and Underlying Admentioning

confidence: 99%

See 1 more Smart Citation

Adaptation and tolerance of bacteria against acetic acid

Trček

Mira

Jarboe

2015

Appl Microbiol Biotechnol

181

100

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“…Several previous reports have called for caution when using auxotrophic parent strains in genetic experiments (15,16,(57)(58)(59). We have now shown that in rich medium, the auxotrophic mutations do not seem to interfere with tolerance to any of the other stress factors tested, i.e., acetic acid at pH 5, hydrogen peroxide, and high temperature, except for osmotic stress caused by either high glucose or NaCl concentrations.…”

Section: Discussionmentioning

confidence: 78%

Auxotrophic Mutations Reduce Tolerance of Saccharomyces cerevisiae to Very High Levels of Ethanol Stress

et al. 2015

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Very high ethanol tolerance is a distinctive trait of the yeast Saccharomyces cerevisiae with notable ecological and industrial importance. Although many genes have been shown to be required for moderate ethanol tolerance (i.e., 6 to 12%) in laboratory strains, little is known of the much higher ethanol tolerance (i.e., 16 to 20%) in natural and industrial strains. We have analyzed the genetic basis of very high ethanol tolerance in a Brazilian bioethanol production strain by genetic mapping with laboratory strains containing artificially inserted oligonucleotide markers. The first locus contained the ura3⌬0 mutation of the laboratory strain as the causative mutation. Analysis of other auxotrophies also revealed significant linkage for LYS2, LEU2, HIS3, and MET15. Tolerance to only very high ethanol concentrations was reduced by auxotrophies, while the effect was reversed at lower concentrations. Evaluation of other stress conditions showed that the link with auxotrophy is dependent on the type of stress and the type of auxotrophy. When the concentration of the auxotrophic nutrient is close to that limiting growth, more stress factors can inhibit growth of an auxotrophic strain. We show that very high ethanol concentrations inhibit the uptake of leucine more than that of uracil, but the 500-fold-lower uracil uptake activity may explain the strong linkage between uracil auxotrophy and ethanol sensitivity compared to leucine auxotrophy. Since very high concentrations of ethanol inhibit the uptake of auxotrophic nutrients, the active uptake of scarce nutrients may be a major limiting factor for growth under conditions of ethanol stress.

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“…Because of limitations inherent in the widely used S. cerevisiae gene deletion libraries that restrict the extent of acetic acid resistance that can be obtained in the multiply auxotrophic library mutants (Ding et al 2013), we sought acetic acid-resistant mutants by screening a library of overexpressed yeast genes (Jones et al 2008). Here, we report that overexpression of PEP3 increases yeast tolerance for acetic acid by shortening lag phase.…”

Section: Introductionmentioning

confidence: 99%

PEP3 overexpression shortens lag phase but does not alter growth rate in Saccharomyces cerevisiae exposed to acetic acid stress

Ding

Holzwarth

Bradford

et al. 2015

Appl Microbiol Biotechnol

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In fungi, two recognized mechanisms contribute to pH homeostasis: the plasma membrane proton-pumping ATPase that exports excess protons and the vacuolar proton-pumping ATPase (V-ATPase) that mediates vacuolar proton uptake. Here, we report that overexpression of PEP3 which encodes a component of the HOPS and CORVET complexes involved in vacuolar biogenesis, shortened lag phase in Saccharomyces cerevisiae exposed to acetic acid stress. By confocal microscopy, PEP3-overexpressing cells stained with the vacuolar membrane-specific dye, FM4-64 had more fragmented vacuoles than the wild-type control. The stained overexpression mutant was also found to exhibit about 3.6-fold more FM4-64 fluorescence than the wild-type control as determined by flow cytometry. While the vacuolar pH of the wild-type strain grown in the presence of 80 mM acetic acid was significantly higher than in the absence of added acid, no significant difference was observed in vacuolar pH of the overexpression strain grown either in the presence or absence of 80 mM acetic acid. Based on an indirect growth assay, the PEP3-overexpression strain exhibited higher V-ATPase activity. We hypothesize that PEP3 overexpression provides protection from acid stress by increasing vacuolar surface area and V-ATPase activity and, hence, proton-sequestering capacity.

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Acetic acid inhibits nutrient uptake in Saccharomyces cerevisiae: auxotrophy confounds the use of yeast deletion libraries for strain improvement

Cited by 53 publications

References 36 publications

Adaptation and tolerance of bacteria against acetic acid

Adaptation and tolerance of bacteria against acetic acid

Auxotrophic Mutations Reduce Tolerance of Saccharomyces cerevisiae to Very High Levels of Ethanol Stress

PEP3 overexpression shortens lag phase but does not alter growth rate in Saccharomyces cerevisiae exposed to acetic acid stress

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