Uncoupling reproduction from metabolism extends chronological lifespan in yeast

Nagarajan, Saisubramanian; Kruckeberg, Arthur L.; Schmidt, Karen; Kroll, Evgueny; Hamilton, Morgan; McInnerney, Kate; Summers, Ryan M.; Taylor, Temis G.; Rosenzweig, Frank

doi:10.1073/pnas.1323918111

Cited by 43 publications

(53 citation statements)

References 103 publications

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“…Planktonic S. cerevisiae cultured in nutrient-limited retentostats retain 80% viability after 22 days,99 and alginate-encapsulated yeast continuously fed ad libitum exhibited >90% viability after almost 3 weeks continuous culture 42. The lower viability reported here may stem from cells being subjected to repeated cycles of feast and famine, each of which F I G U R E 4 Cell escape over time.…”

mentioning

confidence: 74%

“…42 Increased heat resistance displayed by encapsulated cells was once attributed to nutrient deficiency in cells close to the core of the bead, triggering a stress response similar to that observed for cells entering stationary phase. 115 Encapsulated cells are demonstrably heat-shock tolerant ( Figure 6) 42,116 ; others have shown that as much as 25% of this phenotype can be attributed to protection by the matrix itself. 115 Encapsulated cells are demonstrably heat-shock tolerant ( Figure 6) 42,116 ; others have shown that as much as 25% of this phenotype can be attributed to protection by the matrix itself.…”

Section: Cell Escape Increased Over Time Except In Pr Beadsmentioning

confidence: 94%

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Matrices (re)loaded: Durability, viability, and fermentative capacity of yeast encapsulated in beads of different composition during long‐term fed‐batch culture

Gulli

Yunker

Rosenzweig

2019

Biotechnology Progress

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Encapsulated microbes have been used for decades to produce commodities ranging from methyl ketone to beer. Encapsulated cells undergo limited replication, which enables them to more efficiently convert substrate to product than planktonic cells and which contributes to their stress resistance. To determine how encapsulated yeast supports long-term, repeated fed-batch ethanologenic fermentation, and whether different matrices influence that process, fermentation and indicators of matrix durability and cell viability were monitored in high-dextrose, fed-batch culture over 7 weeks. At most timepoints, ethanol yield (g/g) in encapsulated cultures exceeded that in planktonic cultures. And frequently, ethanol yield differed among the four matrices tested: sodium alginate crosslinked with Ca 2+ and chitosan, sodium alginate crosslinked with Ca 2+ , Protanal alginate crosslinked with Ca 2+ and chitosan, Protanal alginate crosslinked with Ca 2+ , with the last of these consistently demonstrating the highest values. Young's modulus and viscosity were higher for matrices crosslinked with chitosan over the first week; thereafter values for both parameters declined and were indistinguishable among treatments. Encapsulated cells exhibited greater heat shock tolerance at 50 C than planktonic cells in either stationary or exponential phase, with similar thermotolerance observed across all four matrix types. Altogether, these data demonstrate the feasibility of re-using encapsulated yeast to convert dextrose to ethanol over at least 7 weeks. K E Y W O R D Salginate, chitosan, fermentation, immobilization, yeast encapsulation

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mentioning

confidence: 74%

Section: Cell Escape Increased Over Time Except In Pr Beadsmentioning

confidence: 94%

Matrices (re)loaded: Durability, viability, and fermentative capacity of yeast encapsulated in beads of different composition during long‐term fed‐batch culture

Gulli

Yunker

Rosenzweig

2019

Biotechnology Progress

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“…Growth limitation by a nonenergy substrate can be explored, provided that overflow metabolism and reduced efficiency of energy source utilization under such energy excess conditions (90,91) can be prevented. Moreover, cell division can be uncoupled from metabolic activity under glucose excess by continuous cultivation of S. cerevisiae in alginate beads (92).…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

Physiological and Transcriptional Responses of Different Industrial Microbes at Near-Zero Specific Growth Rates

Ercan

Bisschops

Overkamp

et al. 2015

Appl Environ Microbiol

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The current knowledge of the physiology and gene expression of industrially relevant microorganisms is largely based on laboratory studies under conditions of rapid growth and high metabolic activity. However, in natural ecosystems and industrial processes, microbes frequently encounter severe calorie restriction. As a consequence, microbial growth rates in such settings can be extremely slow and even approach zero. Furthermore, uncoupling microbial growth from product formation, while cellular integrity and activity are maintained, offers perspectives that are economically highly interesting. Retentostat cultures have been employed to investigate microbial physiology at (near-)zero growth rates. This minireview compares information from recent physiological and gene expression studies on retentostat cultures of the industrially relevant microorganisms Lactobacillus plantarum, Lactococcus lactis, Bacillus subtilis, Saccharomyces cerevisiae, and Aspergillus niger. Shared responses of these organisms to (near-)zero growth rates include increased stress tolerance and a downregulation of genes involved in protein synthesis. Other adaptations, such as changes in morphology and (secondary) metabolite production, were species specific. This comparison underlines the industrial and scientific significance of further research on microbial (near-)zero growth physiology. Most research in microbial physiology focuses on growing cells, although under natural and industrial conditions, microbes frequently encounter a state in which neither growth nor deterioration of cells occurs. However, the experimental design to study microbes in this clearly relevant physiological state is far from trivial.In this minireview, we define zero growth as a nongrowing state in which the viability and metabolic activity of a microbial culture are maintained for prolonged periods. As such, zero growth differs from starvation, which is coupled to cellular deterioration, loss of activity, and ultimately, cell death (1, 2). Zero growth also differs from differentiated survival states, such as bacterial or fungal spores, in which metabolism comes to a standstill (3). Conversely, under zero-growth conditions, microbes exclusively use available substrates for processes that contribute to maintenance of cellular integrity and homeostasis (4-7). Such processes include homeostasis of transmembrane gradients of protons and solutes, defense and repair systems, osmoregulation, and protein turnover (8, 9).In classical food fermentation processes, (near-)zero growth occurs during prolonged periods of extremely restricted availability of energy substrates. Examples include cheese ripening by lactic acid bacteria (LAB) (10-12), wine fermentation by Saccharomyces cerevisiae (13,14), and natto fermentation by Bacillus subtilis (15). Despite the severely energy-limiting conditions, microbes manage to survive in these processes for many weeks, while continuing to produce aroma and flavor compounds in the product matrix (10,13,15,16). Another incentive for studying...

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“…Under these unrestricted nutrient conditions, yeast ceases to divide, remains metabolically active, and exhibits no decline in viability over 2 weeks of continuous culture, a condition that produces proliferation arrest in the presence of nutrients. This effect is totally lost in a rim15 ∆ yeast strain 21. Thus, it appears that when the cell cycle is arrested or compromised, for whatever the reason, CLS increases.…”

Section: The Yeast Cell Cyclementioning

confidence: 95%

Live fast, die soon: cell cycle progression and lifespan in yeast cells

Jiménez

Bru

Ribeiro

et al. 2015

MIC

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Our understanding of lifespan has benefited enormously from the study of a simple model, the yeast Saccharomyces cerevisiae. Although a unicellular organism, yeasts undergo many of the processes directly related with aging that to some extent are conserved in mammalian cells. Nutrient-limiting conditions have been involved in lifespan extension, especially in the case of caloric restriction, which also has a direct impact on cell cycle progression. In fact, other environmental stresses (osmotic, oxidative) that interfere with normal cell cycle progression also influence the lifespan of cells, indicating a relationship between lifespan and cell cycle control. In the present review we compile and discuss new findings related to how cell cycle progression is regulated by other nutrients. We centred this review on the analysis of phosphate, also give some attention to nitrogen, and the impact of these nutrients on lifespan.

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Uncoupling reproduction from metabolism extends chronological lifespan in yeast

Cited by 43 publications

References 103 publications

Matrices (re)loaded: Durability, viability, and fermentative capacity of yeast encapsulated in beads of different composition during long‐term fed‐batch culture

Matrices (re)loaded: Durability, viability, and fermentative capacity of yeast encapsulated in beads of different composition during long‐term fed‐batch culture

Physiological and Transcriptional Responses of Different Industrial Microbes at Near-Zero Specific Growth Rates

Live fast, die soon: cell cycle progression and lifespan in yeast cells

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