Let it stick: Strategies and applications for intracellular plasma membrane targeting of proteins in Saccharomyces cerevisiae.

Lipid binding domains and protein lipidations are essential features to recruit proteins to intracellular membranes, enabling them to function at specific sites within the cell. Membrane association can also be exploited to answer fundamental and applied research questions, from obtaining insights into the understanding of lipid metabolism to employing them for metabolic engineering to redirect fluxes. This review presents a broad catalog of membrane binding strategies focusing on the plasma membrane of Saccharomyces cerevisiae. Both lipid binding domains (pleckstrin homology, discoidin-type C2, kinase associated-1, basic-rich and bacterial phosphoinositide-binding domains) and co- and post-translational lipidations (prenylation, myristoylation and palmitoylation) are introduced as tools to target the plasma membrane. To provide a toolset of membrane targeting modules, respective candidates that facilitate plasma membrane targeting are showcased including their in vitro and in vivo properties. The relevance and versatility of plasma membrane targeting modules are further highlighted by presenting a selected set of use cases.

Discovery of novel cellobiose lipid gene clusters from Basidiomycetes: How chemical variation is reflected in gene cluster architecture.

Cellobiose lipids are surface-active compounds or biological detergents produced by distinct Basidiomycetes yeasts, of which the most and best-described ones belong to the Ustilaginomycetes class. The molecules display slight variation in congener type, which is linked to the hydroxylation position of the long fatty acid, acetylation profile of the cellobiose unit, and presence or absence of the short fatty acid. In general, this variation is strain specific. Although cellobiose lipid biosynthesis has been described for about 11 yeast species, hitherto only two types of biosynthetic gene clusters are identified, and this for only three species. This work adds six more biosynthetic gene clusters and describes for the first time a novel type of cellobiose lipid biosynthetic cluster with a simplified architecture related to specific cellobiose lipids synthesized by Trichosporonaceae family members.

How do engineered Yarrowia lipolytica strains secrete free fatty acids: hints from comparative transcriptomics.

Yarrowia lipolytica has been considered one of the most promising platforms for the microbial production of fatty acids and derived products. The deletion of the faa1 gene coding for an acyl-CoA synthetase leads to the accumulation and secretion of free fatty acids (FFAs) into the extracellular space. The secretion of products is beneficial for the development of microbial cell factories to avoid intracellular inhibitory effects and reduce downstream processing costs. However, the mechanism behind the secretion of fatty acids is not well known. As a starting point, we compared the transcriptome of this mutant showing FFA secretion to a wildtype-like strain not showing this phenotype. The 12 most upregulated genes were evaluated for involvement in FFA secretion by the creation of deletion and overexpression mutants, among them MCH2, YMOH, three cell wall proteins CWP3, CWP4, and CWP11, M12B, and three proteins with unknown functions YUP1, YUP2, and YUP3. None of these proteins take a clear or isolated role in FFA export. As the transcriptomic data revealed an overrepresentation of cell wall-related proteins, some of them were further examined on a theoretical and experimental way. Surprisingly, overexpression of Ygpi led to the production of FFAs in the wildtype-like genetic background. Finally, some of the evaluated genes showed involvement in resistance to FFA toxicity.

The role of transport proteins in the production of microbial glycolipid biosurfactants.

Several microorganisms are currently being used as production platform for glycolipid biosurfactants, providing a greener alternative to chemical biosurfactants. One of the reasons why these processes are commercially competitive is the fact that microbial producers can efficiently export their product to the extracellular environment, reaching high product titers. Glycolipid biosynthetic genes are often found in a dedicated cluster, amidst which genes encoding a dedicated transporter committed to shuttle the glycolipid to the extracellular environment are often found, as is the case for many other secondary metabolites. Knowing this, one can rely on gene clustering features to screen for novel putative transporters, as described and performed in this review. The above strategy proves to be very powerful to identify glycolipid transporters in fungi but is less valid for bacterial systems. Indeed, the genetics of these export systems are currently largely unknown, but some hints are given. Apart from the direct export of the glycolipid, several other transport systems have an indirect effect on glycolipid production. Specific importers dictate which hydrophilic and hydrophobic substrates can be used for production and influence the final yields. In eukaryotes, cellular compartmentalization allows the assembly of glycolipid building blocks in a highly specialized and efficient way. Yet, this requires controlled transport across intracellular membranes. Next to the direct export of glycolipids, the current state of the art regarding this indirect involvement of transporter systems in microbial glycolipid synthesis is summarized in this review. KEY POINTS: • Transporters are directly and indirectly involved in microbial glycolipid synthesis. • Yeast glycolipid transporters are found in their biosynthetic gene cluster. • Hydrophilic and hydrophobic substrate uptake influence microbial glycolipid synthesis.

Just passing through: Deploying aquaporins in microbial cell factories.

As microbial membranes are naturally impermeable to even the smallest biomolecules, transporter proteins are physiologically essential for normal cell functioning. This makes transporters a key target area for engineering enhanced cell factories. As part of the wider cellular transportome, aquaporins (AQPs) are responsible for transporting small polar solutes, encompassing many compounds which are of great interest for industrial biotechnology, including cell feedstocks, numerous commercially relevant polyols and even weak organic acids. In this review, examples of cell factory engineering by targeting AQPs are presented. These AQP modifications aid in redirecting carbon fluxes and boosting bioconversions either by enhanced feedstock uptake, improved intermediate retention, increasing product export into the media or superior cell viability against stressors with applications in both bacterial and yeast production platforms. Additionally, the future potential for AQP deployment and targeting is discussed, showcasing hurdles and considerations of this strategy as well as recent advances and future directions in the field. By leveraging the natural diversity of AQPs and breakthroughs in channel protein engineering, these transporters are poised to be promising tools capable of enhancing a wide variety of biotechnological processes.