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PubMed Central

Toxicity Mechanisms of the Food Contaminant Citrinin: Application of a Quantitative Yeast Model

Author: Amparo Pascual-Ahuir
Donmez-Altuntas
Elena Vanacloig-Pedros
Flajs
Garay-Arroyo
Heider
Markus Proft
Proft
Singh
Publication venue: 'MDPI AG'
Publication date: 01/05/2014
Field of study

Mycotoxins are important food contaminants and a serious threat for human nutrition. However, in many cases the mechanisms of toxicity for this diverse group of metabolites are poorly understood. Here we apply live cell gene expression reporters in yeast as a quantitative model to unravel the cellular defense mechanisms in response to the mycotoxin citrinin. We find that citrinin triggers a fast and dose dependent activation of stress responsive promoters such as GRE2 or SOD2. More specifically, oxidative stress responsive pathways via the transcription factors Yap1 and Skn7 are critically implied in the response to citrinin. Additionally, genes in various multidrug resistance transport systems are functionally involved in the resistance to citrinin. Our study identifies the antioxidant defense as a major physiological response in the case of citrinin. In general, our results show that the use of live cell gene expression reporters in yeast are a powerful tool to identify toxicity targets and detoxification mechanisms of a broad range of food contaminants relevant for human nutrition.This work was supported by Ministerio de Economia y Competitividad grant BFU2011-23326. We thank the Fond for Open Access Publication from Consejo Superior de Investigaciones Cientificas for supporting publication costs of this article.Pascual-Ahuir Giner, MD.; Vanacloig Pedrós, ME.; Proft, MH. (2014). Toxicity Mechanisms of the Food Contaminant Citrinin: Application of a Quantitative Yeast Model. Nutrients. 6(5):2077-2087. https://doi.org/10.3390/nu6052077S2077208765Moretti, A., Susca, A., Mulé, G., Logrieco, A. F., & Proctor, R. H. (2013). Molecular biodiversity of mycotoxigenic fungi that threaten food safety. International Journal of Food Microbiology, 167(1), 57-66. doi:10.1016/j.ijfoodmicro.2013.06.033Wu, F., Groopman, J. D., & Pestka, J. J. 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D., Dhawan, A., Das, M., & Ansari, K. M. (2011). Citrinin-Generated Reactive Oxygen Species Cause Cell Cycle Arrest Leading to Apoptosis via the Intrinsic Mitochondrial Pathway in Mouse Skin. Toxicological Sciences, 122(2), 557-566. doi:10.1093/toxsci/kfr143Ribeiro, S. M. R., Chagas, G. M., Campello, A. P., & Kluppel, M. L. W. (1997). Mechanism of citrinin-induced dysfunction of mitochondria. V. Effect on the homeostasis of the reactive oxygen species. Cell Biochemistry and Function, 15(3), 203-209. doi:10.1002/(sici)1099-0844(199709)15:33.0.co;2-jChen, C.-C., & Chan, W.-H. (2009). Inhibition of Citrinin-Induced Apoptotic Biochemical Signaling in Human Hepatoma G2 Cells by Resveratrol. International Journal of Molecular Sciences, 10(8), 3338-3357. doi:10.3390/ijms10083338Hsu, L.-C., Hsu, Y.-W., Liang, Y.-H., Lin, Z.-H., Kuo, Y.-H., & Pan, T.-M. (2012). Protective Effect of Deferricoprogen Isolated from Monascus purpureus NTU 568 on Citrinin-Induced Apoptosis in HEK-293 Cells. 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PubMed Central

Coordinated gene regulation in the initial phase of salt stress adaptation

Author: Alberti
Albertyn
Amparo Pascual-Ahuir
Ansell
Aparicio
Ariño
Babazadeh
Berry
Bouwman
Carolina Bets-Plasencia
Cook
Czeko
de Nadal
de Nadal
de Nadal
Dihazi
Dolz-Edo
Elena Vanacloig-Pedros
Esberg
Gasch
Gasch
Guan
Hamilton
Hohmann
Hohmann
Hohmann
Kellermayer
Klipp
Li
Li
Markus Proft
Martínez-Montañés
Miermont
Nadal-Ribelles
Norbeck
Ostergaard
Petelenz-Kurdziel
Proft
Proft
Proft
Rep
Rep
Rienzo
Rios
Ruiz-Roig
Saito
Somesh
Tamás
Van Wuytswinkel
Westfall
Wilson
Winzeler
Woudstra
Publication venue: 'American Society for Biochemistry & Molecular Biology (ASBMB)'
Publication date: 17/04/2015
Field of study

This research was originally published in Journal of Biological Chemistry, 2015 - 16 : 10175- 10163 © the American Society for Biochemistry and Molecular Biology[EN] Stress triggers complex transcriptional responses, which include both gene activation and repression. We used time-resolved reporter assays in living yeast cells to gain insights into the coordination of positive and negative control of gene expression upon salt stress. We found that the repression of housekeeping genes coincides with the transient activation of defense genes and that the timing of this expression pattern depends on the severity of the stress. Moreover, we identified mutants that caused an alteration in the kinetics of this transcriptional control. Loss of function of the vacuolar H+-ATPase (vma1) or a defect in the biosynthesis of the osmolyte glycerol (gpd1) caused a prolonged repression of housekeeping genes and a delay in gene activation at inducible loci. Both mutants have a defect in the relocation of RNA polymerase II complexes at stress defense genes. Accordingly salt-activated transcription is delayed and less efficient upon partially respiratory growth conditions in which glycerol production is significantly reduced. Furthermore, the loss of Hog1 MAP kinase function aggravates the loss of RNA polymerase II from housekeeping loci, which apparently do not accumulate at inducible genes. Additionally the Def1 RNA polymerase II degradation factor, but not a high pool of nuclear polymerase II complexes, is needed for efficient stress-induced gene activation. The data presented here indicate that the finely tuned transcriptional control upon salt stress is dependent on physiological functions of the cell, such as the intracellular ion balance, the protective accumulation of osmolyte molecules, and the RNA polymerase II turnover.This work was supported by Ministerio de Economia y Competitividad Grant BFU2011-23326 (to M. P.).Vanacloig Pedros, ME.; Bets Plasencia, C.; Pascual-Ahuir Giner, MD.; Proft, MH. (2015). Coordinated gene regulation in the initial phase of salt stress adaptation. Journal of Biological Chemistry. 16(290):10163-10175. https://doi.org/10.1074/jbc.M115.637264S101631017516290De Nadal, E., Ammerer, G., & Posas, F. (2011). Controlling gene expression in response to stress. Nature Reviews Genetics, 12(12), 833-845. doi:10.1038/nrg3055Gasch, A. P., Spellman, P. T., Kao, C. M., Carmel-Harel, O., Eisen, M. B., Storz, G., … Brown, P. O. (2000). Genomic Expression Programs in the Response of Yeast Cells to Environmental Changes. Molecular Biology of the Cell, 11(12), 4241-4257. doi:10.1091/mbc.11.12.4241Gasch, A. P., & Werner-Washburne, M. (2002). The genomics of yeast responses to environmental stress and starvation. Functional & Integrative Genomics, 2(4-5), 181-192. doi:10.1007/s10142-002-0058-2Saito, H., & Posas, F. (2012). Response to Hyperosmotic Stress. 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Differential regulation of mitochondrial pyruvate carrier genes modulates respiratory capacity and stress tolerance in yeast

Author: Alba Timón-Gómez
Amparo Pascual-Ahuir
AS Divakaruni
B Westermann
C Ruiz-Roig
DK Bricker
E Poteet
EA Winzeler
F Martinez-Montanes
GG Perrone
H Saito
HJ Schuller
HY Hong
JR Broach
K Hedbacker
L Galdieri
L Palmieri
M Martinez-Pastor
M Proft
Markus Proft
MM Pastor
MP Murphy
Nai Sum Wong
RA Smith
S Alberti
S Boubekeur
S Ghaemmaghami
S Herzig
T Nakai
T Soga
Y Pan
Publication venue: 'Public Library of Science (PLoS)'
Publication date: 01/01/2013
Field of study

Mpc proteins are highly conserved from yeast to humans and are necessary for the uptake of pyruvate at the inner mitochondrial membrane, which is used for leucine and valine biosynthesis and as a fuel for respiration. Our analysis of the yeast MPC gene family suggests that amino acid biosynthesis, respiration rate and oxidative stress tolerance are regulated by changes in the Mpc protein composition of the mitochondria. Mpc2 and Mpc3 are highly similar but functionally different: Mpc2 is most abundant under fermentative non stress conditions and important for amino acid biosynthesis, while Mpc3 is the most abundant family member upon salt stress or when high respiration rates are required. Accordingly, expression of the MPC3 gene is highly activated upon NaCl stress or during the transition from fermentation to respiration, both types of regulation depend on the Hog1 MAP kinase. Overexpression experiments show that gain of Mpc2 function leads to a severe respiration defect and ROS accumulation, while Mpc3 stimulates respiration and enhances tolerance to oxidative stress. Our results identify the regulated mitochondrial pyruvate uptake as an important determinant of respiration rate and stress resistance.This work was supported by Ministerio de Economia y Competitividad grant BFU2011-23326 to M.P.; A.T.-G. was supported by a JAE predoctoral grant from Consejo Superior de Investigaciones Cientificas. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.Timón Gómez, A.; Proft ., MH.; Pascual-Ahuir Giner, MD. (2013). Differential regulation of mitochondrial pyruvate carrier genes modulates respiratory capacity and stress tolerance in yeast. PLoS ONE. 8(11):1-9. doi:10.1371/journal.pone.0079405S19811Murphy, M. P. (2008). How mitochondria produce reactive oxygen species. 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Adaptive Changes of the Yeast Mitochondrial Proteome in Response to Salt Stress. OMICS: A Journal of Integrative Biology, 14(5), 541-552. doi:10.1089/omi.2010.0020Pastor, M. M., Proft, M., & Pascual-Ahuir, A. (2009). Mitochondrial Function Is an Inducible Determinant of Osmotic Stress Adaptation in Yeast. Journal of Biological Chemistry, 284(44), 30307-30317. doi:10.1074/jbc.m109.050682Saito, H., & Posas, F. (2012). Response to Hyperosmotic Stress. Genetics, 192(2), 289-318. doi:10.1534/genetics.112.140863Ruiz-Roig, C., Noriega, N., Duch, A., Posas, F., & de Nadal, E. (2012). The Hog1 SAPK controls the Rtg1/Rtg3 transcriptional complex activity by multiple regulatory mechanisms. Molecular Biology of the Cell, 23(21), 4286-4296. doi:10.1091/mbc.e12-04-0289Bricker, D. K., Taylor, E. B., Schell, J. C., Orsak, T., Boutron, A., Chen, Y.-C., … Rutter, J. (2012). A Mitochondrial Pyruvate Carrier Required for Pyruvate Uptake in Yeast, Drosophila, and Humans. 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CiteSeerX

PubMed Central

Ask yeast how to burn your fats: lessons learned from the metabolic adaptation to salt stress

Author: A Duch
A Duch
A Rienzo
A Roy
A Timon-Gomez
A Yoshida
Alba Timón-Gómez
Amparo Pascual-Ahuir
C Ferreira
C Molin
C Ruiz-Roig
C Sole
CJ Wei
DB Berry
E Bilsland-Marchesan
E Nadal de
E Nadal de
E Nadal de
E Nadal de
E Petelenz-Kurdziel
E Vanacloig-Pedros
F Martinez-Montanes
F Posas
G Mas
H Saito
J Aguilera
J Albertyn
J Clotet
J Clotet
J Warringer
JL Brewster
JT Mettetal
K Maeta
K Mao
KE Cook
L Romero-Santacreu
M Martinez-Pastor
M Nadal-Ribelles
M Proft
M Proft
M Proft
M Proft
M Rep
M Rep
M Teige
Markus Proft
MJ Tamas
MM Pastor
PJ Westfall
PM Alepuz
PM Alepuz
R Ansell
R Babazadeh
R Gonzalez
RD Silva
S Hohmann
S Hohmann
S Manzanares-Estreder
S Ratnakumar
S Regot
Sara Manzanares-Estreder
SC Li
SP Hong
T Bender
T Sekito
T Ye
X Escote
YH Ho
Publication venue: 'Springer Science and Business Media LLC'
Publication date: 01/01/2017
Field of study

[EN] Here, we review and update the recent advances in the metabolic control during the adaptive response of budding yeast to hyperosmotic and salt stress, which is one of the best understood signaling events at the molecular level. This environmental stress can be easily applied and hence has been exploited in the past to generate an impressively detailed and comprehensive model of cellular adaptation. It is clear now that this stress modulates a great number of different physiological functions of the cell, which altogether contribute to cellular survival and adaptation. Primary defense mechanisms are the massive induction of stress tolerance genes in the nucleus, the activation of cation transport at the plasma membrane, or the production and intracellular accumulation of osmolytes. At the same time and in a coordinated manner, the cell shuts down the expression of housekeeping genes, delays the progression of the cell cycle, inhibits genomic replication, and modulates translation efficiency to optimize the response and to avoid cellular damage. To this fascinating interplay of cellular functions directly regulated by the stress, we have to add yet another layer of control, which is physiologically relevant for stress tolerance. Salt stress induces an immediate metabolic readjustment, which includes the up-regulation of peroxisomal biomass and activity in a coordinated manner with the reinforcement of mitochondrial respiratory metabolism. Our recent findings are consistent with a model, where salt stress triggers a metabolic shift from fermentation to respiration fueled by the enhanced peroxisomal oxidation of fatty acids. We discuss here the regulatory details of this stress-induced metabolic shift and its possible roles in the context of the previously known adaptive functions.The work of the authors was supported by grants from Ministerio de Economía y Competitividad (BFU2011- 23326 and BFU2016-75792-R).Pascual-Ahuir Giner, MD.; Manzanares-Estreder, S.; Timón Gómez, A.; Proft ., MH. (2017). Ask yeast how to burn your fats: lessons learned from the metabolic adaptation to salt stress. Current Genetics. 64(1):63-69. https://doi.org/10.1007/s00294-017-0724-5S6369641Aguilera J, Prieto JA (2001) The Saccharomyces cerevisiae aldose reductase is implied in the metabolism of methylglyoxal in response to stress conditions. Curr Genet 39:273–283Albertyn J, Hohmann S, Thevelein JM, Prior BA (1994) GPD1, which encodes glycerol-3-phosphate dehydrogenase, is essential for growth under osmotic stress in Saccharomyces cerevisiae, and its expression is regulated by the high-osmolarity glycerol response pathway. 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Multidisciplinary Digital Publishing Institute

Toxicity Mechanisms of the Food Contaminant Citrinin: Application of a Quantitative Yeast Model

Author: Amparo Pascual-Ahuir
Publication venue: 'MDPI AG'
Publication date: 22/05/2014
Field of study

The mission of AIMS Bioengineering, an open-access forum to bring together Biological and Engineering Sciences

Author: Pascual-Ahuir Amparo
Proft Markus
Publication venue: 'American Institute of Mathematical Sciences (AIMS)'
Publication date: 01/04/2020
Field of study

Editorial 2 páginasPeer reviewe

Genomic Instability and Epigenetic Changes during Aging

Author: Amparo Pascual-Ahuir
Lucía López-Gil
Markus Proft
Publication venue: MDPI AG
Publication date: 01/09/2023
Field of study

Aging is considered the deterioration of physiological functions along with an increased mortality rate. This scientific review focuses on the central importance of genomic instability during the aging process, encompassing a range of cellular and molecular changes that occur with advancing age. In particular, this revision addresses the genetic and epigenetic alterations that contribute to genomic instability, such as telomere shortening, DNA damage accumulation, and decreased DNA repair capacity. Furthermore, the review explores the epigenetic changes that occur with aging, including modifications to histones, DNA methylation patterns, and the role of non-coding RNAs. Finally, the review discusses the organization of chromatin and its contribution to genomic instability, including heterochromatin loss, chromatin remodeling, and changes in nucleosome and histone abundance. In conclusion, this review highlights the fundamental role that genomic instability plays in the aging process and underscores the need for continued research into these complex biological mechanisms

Fungal Drug Response and Antimicrobial Resistance

Author: Osset-Trénor Paloma
Pascual-Ahuir Amparo
Proft Markus
Publication venue: Multidisciplinary Digital Publishing Institute
Publication date: 04/06/2023
Field of study

Antifungal resistance is a growing concern as it poses a significant threat to public health. Fungal infections are a significant cause of morbidity and mortality, especially in immunocompromised individuals. The limited number of antifungal agents and the emergence of resistance have led to a critical need to understand the mechanisms of antifungal drug resistance. This review provides an overview of the importance of antifungal resistance, the classes of antifungal agents, and their mode of action. It highlights the molecular mechanisms of antifungal drug resistance, including alterations in drug modification, activation, and availability. In addition, the review discusses the response to drugs via the regulation of multidrug efflux systems and antifungal drug–target interactions. We emphasize the importance of understanding the molecular mechanisms of antifungal drug resistance to develop effective strategies to combat the emergence of resistance and highlight the need for continued research to identify new targets for antifungal drug development and explore alternative therapeutic options to overcome resistance. Overall, an understanding of antifungal drug resistance and its mechanisms will be indispensable for the field of antifungal drug development and clinical management of fungal infections