Prospecting macroalgae (seaweeds) as feedstocks for bioconversion into biofuels and commodity chemical compounds is limited primarily by the availability of tractable microorganisms that can metabolize alginate polysaccharides. Here, we present the discovery of a 36-kilo-base pair DNA fragment from Vibrio splendidus encoding enzymes for alginate transport and metabolism. The genomic integration of this ensemble, together with an engineered system for extracellular alginate depolymerization, generated a microbial platform that can simultaneously degrade, uptake, and metabolize alginate. When further engineered for ethanol synthesis, this platform enables bioethanol production directly from macroalgae via a consolidated process, achieving a titer of 4.7% volume/volume and a yield of 0.281 weight ethanol/weight dry macroalgae (equivalent to ~80% of the maximum theoretical yield from the sugar composition in macroalgae).
It is generally believed that proteins with promiscuous functions divergently evolved to acquire higher specificity and activity, and that this process was highly dependent on the ability of proteins to alter their functions with a small number of amino acid substitutions (plasticity). The application of this theory of divergent molecular evolution to promiscuous enzymes may allow us to design enzymes with more specificity and higher activity. Many structural and biochemical analyses have identified the active or binding site residues important for functional plasticity (plasticity residues). To understand how these residues contribute to molecular evolution, and thereby formulate a design methodology, plasticity residues were probed in the active site of the promiscuous sesquiterpene synthase gamma-humulene synthase. Identified plasticity residues were systematically recombined based on a mathematical model in order to construct novel terpene synthases, each catalysing the synthesis of one or a few very different sesquiterpenes. Here we present the construction of seven specific and active synthases that use different reaction pathways to produce the specific and very different products. Creation of these enzymes demonstrates the feasibility of exploiting the underlying evolvability of this scaffold, and provides evidence that rational approaches based on these ideas are useful for enzyme design.
The increasing demands placed on natural resources for fuel and food production require that we explore the use of efficient, sustainable feedstocks such as brown macroalgae. The full potential of brown macroalgae as feedstocks for commercial-scale fuel ethanol production, however, requires extensive re-engineering of the alginate and mannitol catabolic pathways in the standard industrial microbe Saccharomyces cerevisiae. Here we present the discovery of an alginate monomer (4-deoxy-L-erythro-5-hexoseulose uronate, or DEHU) transporter from the alginolytic eukaryote Asteromyces cruciatus. The genomic integration and overexpression of the gene encoding this transporter, together with the necessary bacterial alginate and deregulated native mannitol catabolism genes, conferred the ability of an S. cerevisiae strain to efficiently metabolize DEHU and mannitol. When this platform was further adapted to grow on mannitol and DEHU under anaerobic conditions, it was capable of ethanol fermentation from mannitol and DEHU, achieving titres of 4.6% (v/v) (36.2 g l(-1)) and yields up to 83% of the maximum theoretical yield from consumed sugars. These results show that all major sugars in brown macroalgae can be used as feedstocks for biofuels and value-added renewable chemicals in a manner that is comparable to traditional arable-land-based feedstocks.
Computational protein design enables a novel one-carbon assimilation pathway
We describe a computationally designed enzyme, formolase (FLS), which catalyzes the carboligation of three one-carbon formaldehyde molecules into one three-carbon dihydroxyacetone molecule. The existence of FLS enables the design of a new carbon fixation pathway, the formolase pathway, consisting of a small number of thermodynamically favorable chemical transformations that convert formate into a three-carbon sugar in central metabolism. The formolase pathway is predicted to use carbon more efficiently and with less backward flux than any naturally occurring one-carbon assimilation pathway. When supplemented with enzymes carrying out the other steps in the pathway, FLS converts formate into dihydroxyacetone phosphate and other central metabolites in vitro. These results demonstrate how modern protein engineering and design tools can facilitate the construction of a completely new biosynthetic pathway.computational protein design | pathway engineering | carbon fixation N ovel strategies are needed to address current challenges in energy storage and carbon sequestration. One approach is to engineer biological systems to convert one-carbon compounds into multicarbon molecules such as fuels and other high value chemicals. Many synthetic pathways to produce value-added chemicals from common feedstocks, such as glucose, have been constructed in organisms that lack one-carbon anabolic pathways, such as Escherichia coli or Saccharomyces cerevisiae (1-3); however, despite considerable effort, it has been difficult to introduce heterologous one-carbon fixing pathways into these organisms (4). Likely problems include the inherent complexity, environmental sensitivity, inefficiency, or unfavorable chemical driving force of naturally occurring one-carbon metabolic pathways (5).An optimal pathway for one-carbon utilization in common synthetic biology platforms would be (i) composed of a minimal number of enzymes, (ii) linear and disconnected from other metabolic pathways, (iii) thermodynamically favorable with a significant driving force at most or all steps, and (iv) capable of functioning in a robust manner under both aerobic and anaerobic conditions (5). A pathway with these properties could enable the assimilation of one-carbon molecules as the sole carbon source for the production of fuels and chemicals. Although no such pathway is known in nature, the established electrochemical reduction of carbon dioxide to formate under ambient temperatures and pressures in neutral aqueous solutions provides an attractive starting point for a onecarbon fixation pathway (5-8).We describe the computational design of an enzyme that catalyzes the carboligation of three one-carbon molecules into a single three-carbon molecule. This enzyme enables the construction of a new pathway, the formolase pathway, in which formate is converted into the central metabolite dihydroxyacetone phosphate (DHAP; Fig. 1). The use of computational protein design to reengineer catalytic activities opens up the pathway design space beyond that available based o...
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