Saccharomyces cerevisiae is an increasingly attractive host for synthetic biology because of its long history in industrial fermentations. However, until recently, most synthetic biology systems have focused on bacteria. While there is a wealth of resources and literature about the biology of yeast, it can be daunting to navigate and extract the tools needed for engineering applications. Here we present a versatile engineering platform for yeast, which contains both a rapid, modular assembly method and a basic set of characterized parts. This platform provides a framework in which to create new designs, as well as data on promoters, terminators, degradation tags, and copy number to inform those designs. Additionally, we describe genome-editing tools for making modifications directly to the yeast chromosomes, which we find preferable to plasmids due to reduced variability in expression. With this toolkit, we strive to simplify the process of engineering yeast by standardizing the physical manipulations and...

A Highly Characterized Yeast Toolkit for Modular, Multipart Assembly

Opportunities and challenges in biological lignin valorization

The review compiles artificial cascades involving enzymes with a focus on the last 10 years. A cascade is defined as the combination of at least two reaction steps in a single reaction vessel without isolation of the intermediates, whereby at least one step is catalyzed by an enzyme. Additionally, cascades performed in vivo and in vitro are discussed separately, whereby in vivo cascades are defined here as cascades relying on cofactor recycling by the metabolism or on a metabolite from the living organism. The review introduces a systematic classification of the cascades according to the number of enzymes in the linear sequence and differentiates between cascades involving exclusively enzymes and combinations of enzymes with non-natural catalysts or chemical steps. Since the number of examples involving two enzymes is predominant, the two enzyme cascades are further subdivided according to the number, order, and type of redox steps. Furthermore, this classification differentiates between cascades where al...

Artificial Biocatalytic Linear Cascades for Preparation of Organic Molecules

/pdf/transformation-of-biomass-into-commodity-chemicals-using-2a93itd2a6.pdf

Transformation of biomass into commodity chemicals using enzymes or cells

Producing mass quantities of chemicals has its roots in the industrial revolution. But industrial synthesis leads to sizeable sustainability and socioeconomic challenges. The rapid advances in biotechnology suggest that biological manufacturing may soon be a feasible alternative, but can it produce chemicals at scale? Clomburg et al. review the progress made in industrial biomanufacturing, including the tradeoffs between highly tunable biocatalysts and units of scale. The biological conversion of single-carbon compounds such as methane, for example, has served as a testbed for more sustainable, decentralized production of desirable compounds.

Science , this issue p. [10.1126/science.aag0804][1]

 [1]: /lookup/doi/10.1126/science.aag0804

http://science.sciencemag.org/content/sci/355/6320/aag0804.full.pdf

Industrial biomanufacturing: The future of chemical production

Cell-free biology is the activation of biological processes without the use of intact living cells. It has been used for more than 50 years across the life sciences as a foundational research tool, but a recent technical renaissance has facilitated high-yielding (grams of protein per litre), cell-free gene expression systems from model bacteria, the development of cell-free platforms from non-model organisms and multiplexed strategies for rapidly assessing biological design. These advances provide exciting opportunities to profoundly transform synthetic biology by enabling new approaches to the model-driven design of synthetic gene networks, the fast and portable sensing of compounds, on-demand biomanufacturing, building cells from the bottom up, and next-generation educational kits. Cell-free gene expression systems have long been used to address fundamental research questions. Now, owing to technological advances, these systems are finding wider applications in the field of synthetic biology, including in biosensing, biomanufacturing, education and the design of gene networks.

Cell-free gene expression: an expanded repertoire of applications.

Metabolic engineering of muconic acid production in Saccharomyces cerevisiae.

Industrial biotechnology and microbial metabolic engineering are poised to help meet the growing demand for sustainable, low-cost commodity chemicals and natural products, yet the fraction of biochemicals amenable to commercial production remains limited. Common problems afflicting the current state-of-the-art include low volumetric productivities, build-up of toxic intermediates or products, and byproduct losses via competing pathways. To overcome these limitations, cell-free metabolic engineering (CFME) is expanding the scope of the traditional bioengineering model by using in vitro ensembles of catalytic proteins prepared from purified enzymes or crude lysates of cells for the production of target products. In recent years, the unprecedented level of control and freedom of design, relative to in vivo systems, has inspired the development of engineering foundations for cell-free systems. These efforts have led to activation of long enzymatic pathways (>8 enzymes), near theoretical conversion yields, productivities greater than 100 mg L(-1) h(-1) , reaction scales of >100 L, and new directions in protein purification, spatial organization, and enzyme stability. In the coming years, CFME will offer exciting opportunities to: (i) debug and optimize biosynthetic pathways; (ii) carry out design-build-test iterations without re-engineering organisms; and (iii) perform molecular transformations when bioconversion yields, productivities, or cellular toxicity limit commercial feasibility.

Cell-free metabolic engineering: biomanufacturing beyond the cell.

A cell-free framework for rapid biosynthetic pathway prototyping and enzyme discovery

Many metabolic engineering and genetic engineering applications in yeast rely on the use of plasmids. Despite their pervasive use and the diverse collections available, there is a fundamental lack of understanding of how commonly used DNA plasmids affect the cell’s ability to grow and how the choice of plasmid components can influence plasmid load and burden. In this study, we characterized the major attributes of the 2μ and centromeric plasmids typically used in yeast by examining the impact of choice of selection marker, promoter, origin of replication, and strain ploidy on conferred growth rates and plasmid copy number. We conclude that the “plasmid burden,” as demonstrated by a reduced growth rate, is primarily due to the choice of selection marker, especially when auxotrophic markers are utilized. The plasmid burden traditionally attributed to replication and maintenance of plasmid DNA plays only a minor role in haploid yeast yet is much more significant in diploid strains. The selection marker can also significantly change plasmid copy number. In fact, plasmid copy number can be influenced to some extent by all of the parameters tested. The information presented in this study will allow for more rational design and selection of plasmids for engineering applications.

Ashty S. Karim

Papers

Cell-free gene expression: an expanded repertoire of applications.

Metabolic engineering of muconic acid production in Saccharomyces cerevisiae.

Cell-free metabolic engineering: biomanufacturing beyond the cell.

A cell-free framework for rapid biosynthetic pathway prototyping and enzyme discovery

Characterization of plasmid burden and copy number in Saccharomyces cerevisiae for optimization of metabolic engineering applications