Reviews

pH homeostasis links the nutrient sensing PKA/TORC1/Sch9 ménage-à-trois to stress tolerance and longevity

Marie-Anne Deprez1,°, Elja Eskes1,°, Tobias Wilms1, Paula Ludovico2, Joris Winderickx1

In this article, Deprez et al. discuss accumulating evidence indicates that pH homeostasis plays a prominent role in the determination of ageing and longevity, thereby providing new perspectives and avenues to explore the underlying molecular mechanisms.

Guidelines and recommendations on yeast cell death nomenclature

Didac Carmona-Gutierrez1,‡,*, Maria Anna Bauer1,‡, Andreas Zimmermann1, Andrés Aguilera2, Nicanor Austriaco3, Kathryn Ayscough4, Rena Balzan5, Shoshana Bar-Nun6, Antonio Barrientos7,8, Peter Belenky9, Marc Blondel10, Ralf J. Braun11, Michael Breitenbach12, William C. Burhans13, Sabrina Büttner1,14, Duccio Cavalieri15, Michael Chang16, Katrina F. Cooper17, Manuela Côrte-Real18, Vítor Costa19–21, Christophe Cullin22, Ian Dawes23, Jörn Dengjel24, Martin B. Dickman25, Tobias Eisenberg1,26, Birthe Fahrenkrog27, Nicolas Fasel28, Kai-Uwe Fröhlich1, Ali Gargouri29, Sergio Giannattasio30, Paola Goffrini31, Campbell W. Gourlay32, Chris M. Grant33, Michael T. Greenwood34, Nicoletta Guaragnella30, Thomas Heger35, Jürgen Heinisch36, Eva Herker37, Johannes M. Herrmann38, Sebastian Hofer1, Antonio Jiménez-Ruiz39, Helmut Jungwirth1, Katharina Kainz1, Dimitrios P. Kontoyiannis40, Paula Ludovico41,42, Stéphen Manon43, Enzo Martegani44, Cristina Mazzoni45, Lynn A. Megeney46–48, Chris Meisinger49, Jens Nielsen50–52, Thomas Nyström53, Heinz D. Osiewacz54, Tiago F. Outeiro55–58, Hay-Oak Park59, Tobias Pendl1, Dina Petranovic50,51, Stephane Picot60,61, Peter Polčic62, Ted Powers63, Mark Ramsdale64, Mark Rinnerthaler65, Patrick Rockenfeller1,32, Christoph Ruckenstuhl1, Raffael Schaffrath66, Maria Segovia67, Fedor F. Severin68, Amir Sharon69, Stephan J. Sigrist70, Cornelia Sommer-Ruck1, Maria João Sousa18, Johan M. Thevelein71,72, Karin Thevissen73, Vladimir Titorenko74, Michel B. Toledano75, Mick Tuite32, F.-Nora Vögtle49, Benedikt Westermann11, Joris Winderickx76, Silke Wissing77, Stefan Wölfl78, Zhaojie J. Zhang79, Richard Y. Zhao80, Bing Zhou81, Lorenzo Galluzzi82–84,*, Guido Kroemer84–90,*, Frank Madeo1,26,*

In this review, we propose unified criteria for the definition of accidental, regulated, and programmed forms of cell death in yeast based on a series of morphological and biochemical criteria. Specifically, we provide consensus guidelines on the differential definition of terms including apoptosis, regulated necrosis, and autophagic cell death, as we refer to additional cell death routines that are relevant for the biology of yeast.

Ras signalling in pathogenic yeasts

Daniel R. Pentland1, Elliot Piper-Brown1, Fritz A. Mühlschlegel1,2 and Campbell W. Gourlay1

In this article Pentland et al. review the roles of Ras protein function and signalling in the major human yeast pathogens Candida albicans and Cryptococcus neoformans and discuss the potential for targeting Ras as a novel approach to anti-fungal therapy.

The integrated stress response in budding yeast lifespan extension

Spike D.L. Postnikoff1, Jay E. Johnson2 and Jessica K. Tyler1

 

This article summarizes how the budding yeast Saccharomyces cerevisiae has been instrumental in unraveling the molecular and cellular determinants of aging, and how the induction of cellular stress responses has been associated with experimental lifespan extension, thus underscoring the value of yeast as a model for developing potential aging therapies for humans.

Yeast for virus research

Richard Yuqi Zhao

This article summarizes the use of budding yeast (Saccharomyces cerevisiae) and fission yeast (Schizosaccharomyces pombe) in virus research, highlighting their advantages for studying viral replication, interaction with host cells, and fundamental cellular processes affected by viruses, while discussing their potential in analyzing small viral genomes and facilitating the discovery of antiviral drugs.

Exacerbating and reversing lysosomal storage diseases: from yeast to humans

Tamayanthi Rajakumar1, Andrew B. Munkacsi1,2 and Stephen L. Sturley3

This article summarizes the use of yeast models in advancing our understanding of lysosomal storage diseases (LSDs), where they have been instrumental in researching LSD mechanisms, screening for therapeutic compounds, and exploring genetic and gene-environment interactions relevant to diseases like Batten disease, cystinosis, and Niemann-Pick type C disease, as well as their connection to broader health issues such as viral infections and obesity.

Integrative metabolomics as emerging tool to study autophagy regulation

Sarah Stryeck1, Ruth Birner-Gruenberger2, Tobias Madl1,*

This review summarizes the advancements in metabolomics, particularly using NMR spectroscopy and mass spectrometry, and its increasing role in biological research, offering insights into autophagy regulation with a focus on key metabolites, recent studies, and future prospects in elucidating complex regulatory mechanisms of autophagy and related diseases.

The interplay between transcription and mRNA degradation in Saccharomyces cerevisiae

Subhadeep Das1, Debasish Sarkar2 and Biswadip Das1

This review summarizes how the integration of mRNA synthesis and degradation, mediated by specialized promoters and "coordinators," shapes the cellular transcriptome and plays a significant role in regulating gene expression profiles in various biological processes and potentially enhances evolutionary rates.

Impact of the host on Toxoplasma stage differentiation

Carsten G.K. Lüder1 and Taibur Rahman1

This review summarizes how Toxoplasma gondii transitions from an acute to a chronic infection in warm-blooded animals and humans through a developmental switch influenced by host cell physiology, which determines parasite persistence mainly in neural and muscular tissues.

Previous Next

Why are essential genes essential? – The essentiality of Saccharomyces genes

July 25, 2015

Essential genes are defined as required for the survival of an organism or a cell. This article reviews and analyzes the levels of essentiality of the Saccharomyces cerevisiae genes and groups the genes into four categories: (1) Conditional essential: essential only under certain circumstances or growth conditions; (2) Essential: required for survival under optimal growth conditions; (3) Redundant essential: synthetic lethal due to redundant pathways or gene duplication; and (4) Absolute essential: the minimal genes required for maintaining a cellular life under a stress-free environment. The essential and non-essential functions of the essential genes are further analyzed.

Membrane depolarization-triggered responsive diversification leads to antibiotic tolerance

July 24, 2015

In this article, the authors discuss the article "Obg and membrane depolarization are part of a microbial bet-hedging strategy that leads to antibiotic tolerance", Verstraeten et al., Mol. Cell 2015 Jul 2; 59 (1): 9-21.

Evolutionary rewiring of bacterial regulatory networks

July 6, 2015

Bacteria have evolved complex regulatory networks that enable integration of multiple intracellular and extracellular signals to coordinate responses to environmental changes. However, our knowledge of how regulatory systems function and evolve is still relatively limited. There is often extensive homology between components of different networks, due to past cycles of gene duplication, divergence, and horizontal gene transfer, raising the possibility of cross-talk or redundancy. Consequently, evolutionary resilience is built into gene networks – homology between regulators can potentially allow rapid rescue of lost regulatory function across distant regions of the genome. This article discusses Taylor, et al. Science (2015), 347(6225), reporting mutations that facilitate cross-talk between pathways can contribute to gene network evolution, but which come with severe pleiotropic costs. Arising from this work are a number of questions surrounding how this phenomenon occurs.

Wanted Plasmodium falciparum, dead or alive

June 23, 2015

In this article, mechanisms of cell death in unicellular parasites are discussed, focussing on “programmed cell death” in Plasmodium.

Yeast as a tool to explore cathepsin D function

June 11, 2015

Cathepsin D has garnered increased attention in recent years, mainly since it has been associated with several human pathologies. This review summarizes how cathepsin D can have both anti- and pro-survival functions depending on its proteolytic activity, cellular context and stress stimulus.

Coordinate responses to alkaline pH stress in budding yeast

May 22, 2015

This review summarizes the modulation of a substantial number of signaling pathways whose participate in the alkaline response in yeast. These regulatory inputs involve not only the conserved Rim101/PacC pathway, but also the calcium-activated phosphatase calcineurin, the Wsc1-Pkc1-Slt2 MAP kinase, the Snf1 and PKA kinases and oxidative stress-response pathways.

Handcuffs for bacteria – NDP52 orchestrates xenophagy of intracellular Salmonella

May 21, 2015

This microreview discusses the article "Autophagy Receptor NDP52 Regulates Pathogen-Containing Autophagosome Maturation" by Verlhac et al. (2015), Cell Host Microbe.

Struggling for breath in Sherbrooke: 1st Symposium on “One mitochondrion, many diseases” in Sherbrooke, Québec, Canada, March 11th, 2015

May 20, 2015

This meeting report summarizes discussions during the "1st symposium on “One mitochondrion, many diseases," which took place in Sherbrooke in southern Québec in 2015.

Understanding grapevine-microbiome interactions: implications for viticulture industry

May 4, 2015

This microreview discusses the article "The soil microbiome influences grapevine-associated microbiota" by Zarraonaindia et al. (2015), MBio, which reports that the grapevine-associated microbiota depends on the soil microbiome.

Cytokinins beyond plants: synthesis by Mycobacterium tuberculosis

May 4, 2015

This microreview discusses "Proteasomal Control of Cytokinin Synthesis Protects Mycobacterium tuberculosis against Nitric Oxide" by Samanovic et al. (2015), Mol Cell.

Previous Next