Development of synthetic biology tools applied to fungi of medical and industrial importance

As new technologies and methodologies are surfacing, and researchers are now eager for fast, enhanced and easy-to-use molecular tools, mastering the principles and technologies of vector design and standardization of biological parts have become fundamental challenges. This is making room for the rise of an entirely novel discipline called Synthetic Biology. This innovative field of study combines biological parts and modules to create more reliable and robust systems. Fungal strains are commonly the target of these studies, not only because several fundamental findings regarding molecular cloning arose from lessons given by them, but also due to an immense and much unexplored potential of those organisms in a wide range of applications - ranging from biofuels and fine chemicals production to biomedical therapies. In this context, the present dissertation is divided in two parts: the first one concerns the design and construction of a modular and versatile tool to be applied in several fungal strains. This tool is a plasmid binary vector for Agrobacterium tumefaciens-mediated transformation, which was built in four different versions containing either GFP or mCherry as reporter proteins and a synthetic hygromycin resistance gene as selection marker. The vector was validated in Paracoccidioides lutzii, a dimorphic human opportunist pathogen that is very important for health care but was still lacking efficient genetic tools. The second part consists in the creation of a promoter library for the oleaginous yeast Rhodosporidium toruloides, a promising host for the production of bioproducts from biomass since it can efficiently consume C5 and C6 sugars and lignin-derived aromatics. Twenty-nine promoters were tested with a dual-reporter cassette - comprising both GFP and mRuby fluorescent proteins - using flow cytometer for single-cell analysis. The assortment of promoters presented in this work is the largest set available for R. toruloides until now and was an imperative advancement to overcome the scarcity of tools for this organism. Remarkably, we also presented the first bidirectional promoters described for this yeast and optimized the transformation protocol. Thus, we efficiently applied Synthetic Biology to expand the collection of standard biological parts and to12 optimize vectors for fungal transformation and genetic manipulation. These tools are of immediate value and are applicable for very distinct but equally important challenges: the pursuit of new solutions for human health and for a sustainable biobased economy (AU)