RESUMEN
Designer cellulosomes (DCs) are engineered multi-enzyme complexes, comprising carbohydrate-active enzymes attached to a common backbone, the scaffoldin, via high-affinity cohesin-dockerin interactions. The use of DCs in the degradation of renewable biomass polymers is a promising approach for biorefineries. Indeed, DCs have shown significant hydrolytic activities due to the enhanced enzyme-substrate proximity and inter-enzyme synergies, but technical hurdles in DC engineering have hindered further progress towards industrial application. The challenge in DC engineering lies in the large diversity of possible building blocks and architectures, resulting in a multivariate and immense design space. Simultaneously, the precise DC composition affects many relevant parameters such as activity, stability, and manufacturability. Since protein engineers face a lack of high-throughput approaches to explore this vast design space, DC engineering may result in an unsatisfying outcome. This review provides a roadmap to guide researchers through the process of DC engineering. Each step, starting from concept to evaluation, is described and provided with its challenges, along with possible solutions, both for DCs that are assembled in vitro or are displayed on the yeast cell surface. KEY POINTS: ⢠Construction of designer cellulosomes is a multi-step process. ⢠Designer cellulosome research deals with multivariate construction challenges. ⢠Boosting designer cellulosome efficiency requires exploring a vast design space.
Asunto(s)
Celulosomas , Celulosomas/metabolismo , Celulosa/metabolismo , Membrana Celular/metabolismo , Proteínas de Ciclo Celular/metabolismo , Complejos Multienzimáticos/metabolismo , Proteínas Bacterianas/metabolismoRESUMEN
Cellulosomes are multi-enzyme complexes produced by specialised micro-organisms. The spatial proximity of synergistically acting enzymes incorporated in these naturally occurring complexes supports the efficient hydrolysis of lignocellulosic biomass. Several functional designer cellulosomes, incorporating naturally non-cellulosomal cellulases, have been constructed and can be used for cellulose saccharification. However, in lignocellulosic biomass, cellulose is tightly intertwined with several hemicelluloses and lignin. One of the most abundant hemicelluloses interacting with cellulose microfibrils is xyloglucan, and degradation of these polymers is crucial for complete saccharification. Yet, designer cellulosome studies focusing on the incorporation of hemicellulases have been limited. Here, we report the conversion of the free Cellvibrio japonicus xyloglucan degradation system to the cellulosomal mode. Therefore, we constructed multiple docking enzyme variants of C. japonicus endoxyloglucanase, ß-1,2-galactosidase, α-1,6 xylosidase and ß-1,4-glucosidase, using the combinatorial VersaTile technique dedicated to the design and optimisation of modular proteins. We individually optimised the docking enzymes to degrade the xyloglucan backbone and side chains. Finally, we show that a purified designer xyloglucanosome comprising these docking enzymes was able to release xyloglucan oligosaccharides, galactose, xylose and glucose from tamarind xyloglucan. KEY POINTS: ⢠Construction of xyloglucan-degrading designer cellulosome. ⢠Conversion of free Cellvibrio japonicus enzymes to cellulosomal mode. ⢠Type of linker inserted between dockerin and enzyme module affects docking enzyme activity.
Asunto(s)
Celulosomas , Proteínas Bacterianas , Celulosa , Cellvibrio , Glucanos , XilanosRESUMEN
BACKGROUND: Designer cellulosomes are self-assembled chimeric enzyme complexes that can be used to improve lignocellulosic biomass degradation. They are composed of a synthetic multimodular backbone protein, termed the scaffoldin, and a range of different chimeric docking enzymes that degrade polysaccharides. Over the years, several functional designer cellulosomes have been constructed. Since many parameters influence the efficiency of these multi-enzyme complexes, there is a need to optimise designer cellulosome architecture by testing combinatorial arrangements of docking enzyme and scaffoldin variants. However, the modular cloning procedures are tedious and cumbersome. RESULTS: VersaTile is a combinatorial DNA assembly method, allowing the rapid construction and thus comparison of a range of modular proteins. Here, we present the extension of the VersaTile platform to facilitate the construction of designer cellulosomes. We have constructed a tile repository, composed of dockerins, cohesins, linkers, tags and enzymatically active modules. The developed toolbox allows us to efficiently create and optimise designer cellulosomes at an unprecedented speed. As a proof of concept, a trivalent designer cellulosome able to degrade the specific hemicellulose substrate, galactomannan, was constructed and optimised. The main factors influencing cellulosome efficiency were found to be the selected dockerins and linkers and the docking enzyme ratio on the scaffoldin. The optimised designer cellulosome was able to hydrolyse the galactomannan polysaccharide and release mannose and galactose monomers. CONCLUSION: We have eliminated one of the main technical hurdles in the designer cellulosome field and anticipate the VersaTile platform to be a starting point in the development of more elaborate multi-enzyme complexes.
RESUMEN
Nature relies on complexes of colocated enzymes to efficiently perform multiple catalytic steps. Such enzyme colocalisation promotes substrate channelling, enhances the activity of multiple synergistically acting enzymes and avoids the loss of potentially toxic intermediates. The industrial biotechnology field develops sophisticated methods to mimic natural colocalisation mechanisms to produce increasingly complex bio-based chemicals. Synthetic protein scaffolds are an advanced way to achieve colocalisation of multiple enzymes in one protein complex. The backbone scaffold is composed of multiple domains that are either separated by linkers or fused to self-assembling proteins. Enzymes are recruited to this scaffold by fusing them to domains that bind to orthogonal domains in the scaffold. A particular feature of synthetic protein scaffolds is the control over spatial organisation and enzyme stoichiometry. Several successful examples of synthetic protein scaffolds have been reported, yet the optimisation of such multi-enzyme complexes is a multiparametric, and therefore often empirical process. This review focusses on pioneering scaffolding examples and elaborates on each parameter influencing the activity of these multi-enzyme complexes. Advances in this field are expected to result in a growing catalogue of chemicals that can be produced starting from cheap and widely available renewable materials.