Genomic, transcriptomic and physiological analyses of silver‐resistant <scp><i>Saccharomyces cerevisiae</i></scp> obtained by evolutionary engineering

Terzioğlu, Ergi; Alkım, Ceren; Arslan, Mevlüt; Balaban, Berrak Gülçin; Holyavkin, Can; Kısakesen, Halil İbrahim; Topaloğlu, Alican; Şahin, Ülkü Yılmaz; Işık, Sema Gündüz; Akman, Süleyman; Çakar, Z. Petek

doi:10.1002/yea.3514

Cited by 23 publications

(24 citation statements)

References 39 publications

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“…It was previously described that exposure to AgNO 3 and Ag NPs resulted in the increased expression of CUP1-1 and CUP1-2 , proposing that the encoded MTs may also bind Ag + and decrease sensitivity [ 81 , 114 , 115 ]. Similar results were observed in AgNO 3 exposure, where yeast had increased expression of CUP1-1 and CUP1-2 (4.79-fold and 4.71-fold, respectively) in an extended study that resulted in an evolved yeast strain, confirming the potential role of copper MTs in silver resistance [ 116 ]. Other Ag + transporters, Pho84, Fet3, and Smf1, were not implicated in Ag + uptake; however, significant down regulation (68.56-fold) of PHO84 in silver evolved yeast has been observed, which may indicate that Pho84 plays a role in Ag + uptake, and may serve as a mechanism of Ag + resistance [ 81 , 116 ].…”

Section: Fungal–metal Interactionssupporting

confidence: 73%

“…Silver is a non-essential metal that has no designated cellular receptors or membrane channels for ion uptake. Much of the literature has focused on silver as an antimicrobial agent, but some studies have begun to clarify homeostatic mechanisms [ 81 , 114 , 116 , 298 ]. Silver has properties similar to copper, which has initiated the evaluation of copper homeostatic systems to investigate how they may contribute to silver uptake and transport [ 21 , 81 , 114 , 116 , 298 ].…”

Section: Fungal–metal Interactionsmentioning

confidence: 99%

“…The worldwide increase of silver usage makes studies on mechanisms of silver resistance important; presently, few studies have reported on this. CTR3 is implicated in Ag + resistance after an observed fold increase in its expression in a silver evolved strain of S. cerevisiae [ 116 ]. Insight into the expression of the Ctr3 transcription factor MAC1 in the presence of Ag + may clarify its role in resistance.…”

Section: Fungal–metal Interactionsmentioning

confidence: 99%

“…Other Ag + transporters, Pho84, Fet3, and Smf1, were not implicated in Ag + uptake; however, significant down regulation (68.56-fold) of PHO84 in silver evolved yeast has been observed, which may indicate that Pho84 plays a role in Ag + uptake, and may serve as a mechanism of Ag + resistance [ 81 , 116 ]. The effect of Ag + on genes involved in ergosterol biosynthesis was also investigated in a silver evolved yeast [ 116 ]. Results indicated down-regulation of those genes, suggesting that one mechanism of action of resistance against Ag + toxicity could be the ability to inhibit their down regulation [ 116 ].…”

Section: Fungal–metal Interactionsmentioning

confidence: 99%

“…The effect of Ag + on genes involved in ergosterol biosynthesis was also investigated in a silver evolved yeast [ 116 ]. Results indicated down-regulation of those genes, suggesting that one mechanism of action of resistance against Ag + toxicity could be the ability to inhibit their down regulation [ 116 ]. In the filamentous fungus A. nidulans , silver induced expression of copper exporter crpA, indicating that it may play a role in silver export and resistance [ 90 ].…”

Section: Fungal–metal Interactionsmentioning

confidence: 99%

See 4 more Smart Citations

Fungal–Metal Interactions: A Review of Toxicity and Homeostasis

Robinson

Isikhuemhen

Anike

2021

JoF

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Metal nanoparticles used as antifungals have increased the occurrence of fungal–metal interactions. However, there is a lack of knowledge about how these interactions cause genomic and physiological changes, which can produce fungal superbugs. Despite interest in these interactions, there is limited understanding of resistance mechanisms in most fungi studied until now. We highlight the current knowledge of fungal homeostasis of zinc, copper, iron, manganese, and silver to comprehensively examine associated mechanisms of resistance. Such mechanisms have been widely studied in Saccharomyces cerevisiae, but limited reports exist in filamentous fungi, though they are frequently the subject of nanoparticle biosynthesis and targets of antifungal metals. In most cases, microarray analyses uncovered resistance mechanisms as a response to metal exposure. In yeast, metal resistance is mainly due to the down-regulation of metal ion importers, utilization of metallothionein and metallothionein-like structures, and ion sequestration to the vacuole. In contrast, metal resistance in filamentous fungi heavily relies upon cellular ion export. However, there are instances of resistance that utilized vacuole sequestration, ion metallothionein, and chelator binding, deleting a metal ion importer, and ion storage in hyphal cell walls. In general, resistance to zinc, copper, iron, and manganese is extensively reported in yeast and partially known in filamentous fungi; and silver resistance lacks comprehensive understanding in both.

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Section: Fungal–metal Interactionssupporting

confidence: 73%

Section: Fungal–metal Interactionsmentioning

confidence: 99%

Section: Fungal–metal Interactionsmentioning

confidence: 99%

Section: Fungal–metal Interactionsmentioning

confidence: 99%

Section: Fungal–metal Interactionsmentioning

confidence: 99%

See 3 more Smart Citations

Fungal–Metal Interactions: A Review of Toxicity and Homeostasis

Robinson

Isikhuemhen

Anike

2021

JoF

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Biotechnological potential of yeast cell wall: An overview

Jofre,

Queiroz,

Sanchez

et al. 2024

Biotechnology Progress

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The yeast cell wall is a complex structure whose main function is to protect the cell from physical and chemical damage, providing it with rigidity. It is composed of a matrix of covalently linked polysaccharides and proteins, including β‐glucans, mannoproteins, and chitin, whose proportion can vary according to the yeast species and environmental conditions. The main components of the yeast cell wall have relevant properties that expand the possibilities of use in different industrial sectors, such as pharmaceutical, food, medical, veterinary, and cosmetic. Some applications include bioremediation, enzyme immobilization, animal feed, wine production, and hydrogel production. In the literature it is the description of the cell wall composition of model species like Saccharomyces cerevisiae and Candida albicans, however, it is important to know that this composition can vary according to the species or the culture medium conditions. Thus, understanding the structural composition of different species holds promise as an alternative to expanding the utilization of residual yeast from different bioprocesses. In the context of a circular economy, the conversion of residual yeast into valuable products is an attractive prospect for researchers aiming to develop sustainable technologies. This review provides an overview of yeast cell wall composition and its significance in biotechnological applications, considering prospects to increase the diversification of these compounds in industry.

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Understanding the adaptive laboratory evolution of multiple stress‐resistant yeast strains by genome‐scale modeling

Çetin

Çakar

Ülgen

2022

Yeast

Self Cite

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Stress responses triggered by external exposures in adaptive laboratory evolution studies alter the ordinary behavior of cells, and the identification of the differences between the starting and the evolved strains would provide ideal strategies to obtain the desired strains. Metabolic networks are one of the most useful tools to analyze data for this purpose. This study integrates differential expression profiles of multiple Saccharomyces cerevisiae strains that have evolved in eight different stress conditions (ethanol, caffeine, coniferyl aldehyde, iron, nickel, phenylethanol, and silver) and enzyme kinetics into a genome-scale metabolic model of yeast, following a new enhanced method. Flux balance analysis, flux variability analysis, robustness, phenotype phase plane, minimization of metabolic adjustment, survivability, sensitivity analyses, and random sampling are conducted to identify the most common and divergent points within strains. Results were examined both individually and comparatively, and the target reactions, metabolites, and enzymes were identified. Our results showed that the models reconstructed by our methodology were able to simulate experimental conditions where efficient protein allocation was the main goal for survival under stressful conditions, and most of the metabolic changes in the adaptation process mainly arose from the differences in the metabolic reactions of energy maintenance (through coenzyme-A and FAD utilization), cell division (folate requirement of DNA synthesis), and cell wall formation (through sterol and ergosterol biosynthesis).

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Genomic, transcriptomic and physiological analyses of silver‐resistant Saccharomyces cerevisiae obtained by evolutionary engineering

Cited by 23 publications

References 39 publications

Fungal–Metal Interactions: A Review of Toxicity and Homeostasis

Fungal–Metal Interactions: A Review of Toxicity and Homeostasis

Biotechnological potential of yeast cell wall: An overview

Understanding the adaptive laboratory evolution of multiple stress‐resistant yeast strains by genome‐scale modeling

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