Synthetic genome engineering forging new frontiers for wine yeast

Pretorius, Isak S.

doi:10.1080/07388551.2016.1214945

Cited by 51 publications

(50 citation statements)

References 91 publications

(116 reference statements)

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“…Resveratrol is a polyketide derivative with potent antioxidant properties and it has been recently brought to market as a bio-product [72]. Earlier reports on the production of resveratrol were based on bioconversion of aromatic precursors such as p-coumaric acid and tyrosine by engineered S. cerevisiae strains [73,74].…”

Section: Representative Studies and Their Strain Improvement Strategymentioning

confidence: 99%

Advances in Metabolic Engineering of Saccharomyces cerevisiae for the Production of Industrially and Clinically Important Chemicals

Turanlı-Yıldız¹,

Hacısalihoğlu²,

Çakar³

2017

Old Yeasts - New Questions

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Sustainable production of chemicals is of increasing importance, due to depletion of petroleum and environmental concerns. In addition to its importance in basic research as a simple, eukaryotic model organism, Saccharomyces cerevisiae has long been exploited in industry because of its physiological properties. And today, the development in genetic engineering toolbox and genome-scale metabolic models of S. cerevisiae has extended its application range to new products and bioprocesses. In addition, evolutionary engineering strategies have been useful in improving cellular properties of S. cerevisiae, such as tolerance to product toxicity and inhibitors. In this chapter, recent metabolic and evolutionary engineering studies that involve S. cerevisiae for the production of bulk chemicals and ine chemicals including lavours and pharmaceuticals are reviewed. It was shown that metabolic engineering particularly allowed the improvement of pharmaceuticals production, which will enable economic and large-scale production of many valuable pharmaceuticals. It is clear that S. cerevisiae will continue to be an important host for future metabolic engineering and metabolic pathway engineering applications to produce a variety of industrially and clinically important chemicals.

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Section: Representative Studies and Their Strain Improvement Strategymentioning

confidence: 99%

Advances in Metabolic Engineering of Saccharomyces cerevisiae for the Production of Industrially and Clinically Important Chemicals

Turanlı-Yıldız¹,

Hacısalihoğlu²,

Çakar³

2017

Old Yeasts - New Questions

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“…The goals of this large international project -the Synthetic Yeast Genome Project (referred to as the Yeast 2.0 or Sc2.0 project) include answering a broad spectrum of "profound questions about fundamental properties of chromosomes, genome organisation, gene content, function of RNA splicing, the extent to which small RNAs play a role in yeast biology, the distinction between prokaryotes and eukaryotes, and questions relating to genome structure and evolution" while recognising that "the eventual 'synthetic yeast' being designed and refined could ultimately play an important practical role" (www.syntheticyeast.org). The early learnings from the Yeast 2.0 project are already starting to forge new frontiers for wine yeast development (Pretorius, 2016).…”

Section: Orchestrating Future Music In the Research Laboratorymentioning

confidence: 99%

“…Those who research in the emerging field of synthetic genomics have to work relentlessly to engage all stakeholders, including fellow scientists, industry practitioners, policymakers, regulators, commentators and consumers [23]. It is important for researchers to explain that the development of 'synthetic' yeast models in the laboratory would help yeast researchers to further expand their understanding of the biological fundamentals, limitations and potential of existing wine yeastsmuch like what the physicist Richard Feynman meant when he famously said "What I cannot create, I do not understand".…”

Section: Orchestrating Future Music In the Research Laboratorymentioning

confidence: 99%

“…Once the best candidate strains have been identified, yeast researchers employ hybridisation, mutagenesis, genetic engineering or genome engineering techniques to genetically improve the oenological properties of selected strains (Figure 14). Improved mutants and hybrids are routinely used in commercial winemaking whereas genetically modified (GM) strains generated through genetic and genome engineering are largely reserved for research purposes at this stage [13,[17][18][19][20][21][22][23]. Researchers are investigating non-GM strategies, including hybridisation, mutagenesis and adaptive laboratory evolution, to circumvent the current anti-GM constraints from consumers facing comestible food products generated through bioengineering strategies [24].…”

Section: Fine-tuning Saccharomyces Cerevisiae Strains For Different Wmentioning

confidence: 99%

“…Figure 22. The construction of a 'synthetic' wine strain of Saccharomyces cerevisiae capable of producing raspberry aroma in Chardonnay (adapted from [23]). This is the first wine yeast containing a 'synthetic DNA circuit' coding for raspberry ketone formation.…”

Section: Orchestrating Future Music In the Research Laboratorymentioning

confidence: 99%

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Conducting Wine Symphonics with the Aid of Yeast Genomics

Pretorius

2016

Preprint

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A perfectly balanced wine can be said to create a symphony in the mouth. To achieve the sublime, both in wine and music, requires imagination and skilled orchestration of artistic craftmanship. For wine, inventiveness starts in the vineyard. Similar to a composer of music, the grapegrower produces grapes through a multitude of specifications to achieve a quality result. Different Vitis vinifera grape varieties allow the creation of wine of different genres. Akin to a conductor of music, the winemaker decides what genre to create and considers resources required to realise the grape's potential. A primary consideration is the yeast: inoculate the grape juice or leave it 'wild'; which specific or combined Saccharomyces strain(s) should be used; or proceed with a non-Saccharomyces species? Whilst the various Saccharomyces and non-Saccharomyces yeasts perform their role during fermentation, the performance is not over until the 'fat lady' (S. cerevisiae) has sung (i.e. the grape sugar has been fermented to specified dryness and alcoholic fermentation is complete). Is the wine harmonious or discordant? Will the consumer demand an encore and make a repeat purchase? Understanding consumer needs lets winemakers orchestrate different symphonies (i.e. wine styles) using single-or multi-species ferments. Some consumers will choose the sounds of a philharmonic orchestra comprising a great range of diverse instrumentalists (as is the case with wine created from spontaneous fermentation); some will prefer to listen to a smaller ensemble (analogous to wine produced by a selected group of non-Saccharomyces and Saccharomyces yeast); and others will favour the well-known and reliable superstar soprano (i.e. S. cerevisiae). But what if a digital music synthesiser -such as a synthetic yeast -becomes available that can produce any music genre with the purest of sounds by the touch of a few buttons? Will synthesisers spoil the character of the music and lead to the loss of the much-lauded romantic mystique? Or will music synthesisers support composers and conductors to create novel compositions and even higher quality performances that will thrill audiences? This article explores these and other relevant questions in the context of winemaking and the role that yeast and its genomics play in the betterment of wine quality.

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The potential of future foods for a sustainable future

Wang,

Zhang

2024

eFood

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Future foods have attracted widespread attention due to the view of a sustainable supply of food and nutritional health. At present, the food industry still faces high energy consumption and pollution, which have caused enormous pressure on the ecological environment, and raised new requirements for future foods. Food synthetic biology converts raw materials into important food ingredients, functional food additives, and nutritional chemicals through cell factories to solve the unsustainable problem in food processing. As an important component of the food industry, food 3D printing has many advantages including customized food design, personalized and digital nutrition customization, simplifying the food supply chain, and broadening the source of food ingredients, which will make up for the deficiency of traditional food processing technology. The promotion of the research and application of future foods will help to improve the natural environment, alleviate the resource and energy crisis, and achieve sustainable social development.

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Synthetic genome engineering forging new frontiers for wine yeast

Cited by 51 publications

References 91 publications

Advances in Metabolic Engineering of Saccharomyces cerevisiae for the Production of Industrially and Clinically Important Chemicals

Advances in Metabolic Engineering of Saccharomyces cerevisiae for the Production of Industrially and Clinically Important Chemicals

Conducting Wine Symphonics with the Aid of Yeast Genomics

The potential of future foods for a sustainable future

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