Strategies for Efficient Expression of Heterologous Monosaccharide Transporters in Saccharomyces cerevisiae.

Marilia M Knychala,Fernanda Gelsleichter,Angela A Dos Santos,Leonardo G Kretzer,Boris U Stambuk,César Fonseca,Maria José Leandro

doi:10.3390/jof8010084

Abstract

In previous work, we developed a Saccharomyces cerevisiae strain (DLG-K1) lacking the main monosaccharide transporters (hxt-null) and displaying high xylose reductase, xylitol dehydrogenase and xylulokinase activities. This strain proved to be a useful chassis strain to study new glucose/xylose transporters, as SsXUT1 from Scheffersomyces stipitis. Proteins with high amino acid sequence similarity (78–80%) to SsXUT1 were identified from Spathaspora passalidarum and Spathaspora arborariae genomes. The characterization of these putative transporter genes (SpXUT1 and SaXUT1, respectively) was performed in the same chassis strain. Surprisingly, the cloned genes could not restore the ability to grow in several monosaccharides tested (including glucose and xylose), but after being grown in maltose, the uptake of 14C-glucose and 14C-xylose was detected. While SsXUT1 lacks lysine residues with high ubiquitinylation potential in its N-terminal domain and displays only one in its C-terminal domain, both SpXUT1 and SaXUT1 transporters have several such residues in their C-terminal domains. A truncated version of SpXUT1 gene, deprived of the respective 3′-end, was cloned in DLG-K1 and allowed growth and fermentation in glucose or xylose. In another approach, two arrestins known to be involved in the ubiquitinylation and endocytosis of sugar transporters (ROD1 and ROG3) were knocked out, but only the rog3 mutant allowed a significant improvement of growth and fermentation in glucose when either of the XUT permeases were expressed. Therefore, for the efficient heterologous expression of monosaccharide (e.g., glucose/xylose) transporters in S. cerevisiae, we propose either the removal of lysines involved in ubiquitinylation and endocytosis or the use of chassis strains hampered in the specific mechanism of membrane protein turnover.

Highlights

We show that the cloned genes (SsXUT1 and SpXUT1) could not restore the ability of the yeast strain to grow in several monosaccharides tested, after growth on maltose, 14 C-glucose and 14 C-xylose uptake was observed
DLG-K1 strain was constructed by transforming the hxt-null strain KY73 [41] with an integrative plasmid at the AUR1 loci that has the three genes required for efficient xylose utilization (XYL1 and XYL2 from Sc. stipitis, and XKS1 from S. cerevisiae) under control of the PGK promoter and terminator, allowing high xylose reductase, xylitol dehydrogenase and xylulokinase activities [21,27]
We knocked out two α–arrestin genes, the ROD1 and/or ROG3, known to be involved in sugar transporter endocytosis, in the strain DLG-K1 using the PCR-based gene replacement procedure [49]

Summary

Introduction

While first generation (1G) biofuels rely on food-based plant materials (e.g., sugarcane and corn), second generation (2G) biofuels use lignocellulosic biomasses [5]. Lignocellulosic plant materials, obtained from agricultural and forestry residues, exist in large quantities and are prevalent on earth [4,6]. The most recent technologies developed for the biochemical conversion of lignocellulosic biomass typically involve several steps, including pre-treatment, enzymatic hydrolysis and fermentation, effi- 4.0/). J. Fungi 2022, 8, 84 involve several steps, including pre-treatment, enzymatic hydrolysis and fermentation, efficient conversion of all the sugars available being a major requirement for an economically feasible 2G bioethanol process [7,8]

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Discussion

Conclusion