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12. Implementation of Synthetic Pathways to Foster Microbe-Based Production of Non-Naturally Occurring Carboxylic Acids and Derivatives

Author

Vila-Santa, Ana, Mendes, Fernão C., Ferreira, Frederico C., Prather, Kristala L. J., Mira, Nuno P., Vila-Santa, Ana, Mendes, Fernão C., Ferreira, Frederico C., Prather, Kristala L. J., and Mira, Nuno P.

Abstract

Microbially produced carboxylic acids (CAs) are considered key players in the implementation of more sustainable industrial processes due to their potential to replace a set of oil-derived commodity chemicals. Most CAs are intermediates of microbial central carbon metabolism, and therefore, a biochemical production pathway is described and can be transferred to a host of choice to enable/improve production at an industrial scale. However, for some CAs, the implementation of this approach is difficult, either because they do not occur naturally (as is the case for levulinic acid) or because the described production pathway cannot be easily ported (as it is the case for adipic, muconic or glucaric acids). Synthetic biology has been reshaping the range of molecules that can be produced by microbial cells by setting new-to-nature pathways that leverage on enzyme arrangements not observed in vivo, often in association with the use of substrates that are not enzymes’ natural ones. In this review, we provide an overview of how the establishment of synthetic pathways, assisted by computational tools for metabolic retrobiosynthesis, has been applied to the field of CA production. The translation of these efforts in bridging the gap between the synthesis of CAs and of their more interesting derivatives, often themselves non-naturally occurring molecules, is also reviewed using as case studies the production of methacrylic, methylmethacrylic and poly-lactic acids.

Published
2022

14. Disclosing azole resistance mechanisms in resistant Candida glabrata strains encoding wild-type or gain-of-function CgPDR1 alleles through comparative genomics and transcriptomics

Author

Salazar, Sara B, primary, Pinheiro, Maria Joana F, additional, Sotti-Novais, Danielle, additional, Soares, Ana R, additional, Lopes, Maria M, additional, Ferreira, Teresa, additional, Rodrigues, Vitória, additional, Fernandes, Fábio, additional, and Mira, Nuno P, additional

Published
2022
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17. Unveiling azole resistance mechanisms in Candida glabrata clinical isolates encoding wild-type or gain-of-function CgPdr1 alleles

Author

Salazar, Sara B., primary, Valez, Noémi, additional, Sotti-Novais, Danielle, additional, Simões, Rita, additional, Souza, José António, additional, Faustino, Maria Joana, additional, Mendonça, Catarina, additional, Lopes, Maria Manuel, additional, Rodrigues, Vitória, additional, and Mira, Nuno P., additional

Published
2021
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19. A Genome-Wide Phenotypic Analysis of Saccharomyces cerevisiae 's Adaptive Response and Tolerance to Chitosan in Conditions Relevant for Winemaking.

Author

Lage, Patrícia, Coelho, Bárbara B., Mira, Nuno P., and Mendes-Ferreira, Ana

Subjects
SACCHAROMYCES cerevisiae, POLYSACCHARIDES, MEMBRANE transport proteins, PROTEIN structure, BLOOD lipids, CHITOSAN, RIBOSOMES
Abstract

In the wine industry, the use of chitosan, a non-toxic biodegradable polysaccharide with antimicrobial properties, has been gaining interest with respect to envisaging the reduction in the use of sulfur dioxide (SO2). Although the mechanisms of toxicity of chitosan against fungal cells have been addressed before, most of the studies undertaken used other sources of chitosan and/or used conditions to solubilize the polymer that were not compatible with winemaking. Herein, the effect of a commercial formulation of chitosan approved for use in winemaking over the growth of the spoilage yeast species Dekkera anomala, Saccharomycodes ludwigii, Zygosaccharomyces bailii, and Pichia anomala was assessed. At the legally allowed concentration of 0.1 g/L, chitosan inhibited the growth of all spoilage yeasts, except for the tested Pichia anomala strains. Interestingly, the highly SO2-tolerant yeasts S. ludwigii and Z. bailii were highly susceptible to chitosan. The growth of commercial Saccharomyces cerevisiae was also impacted by chitosan, in a strain-dependent manner, albeit at higher concentrations. To dissect this differential inhibitory potential and gain further insight into the interaction of chitosan over fungal cells, we explored a chemogenomic analysis to identify all of the S. cerevisiae genes conferring protection against or increasing susceptibility to the commercial formulation of chitosan. Among the genes found to confer protection against chitosan, a high proportion was found to encode proteins required for the assembly and structuring of the cell wall, enzymes involved in the synthesis of plasma membrane lipids, and components of signaling pathways that respond to damages in the plasma membrane (e.g., the Rim101 pathway). The data obtained also suggest that the fungal ribosome and the vacuolar V-ATPase could be directly targeted by chitosan, since the deletion of genes encoding proteins required for the structure and function of these organelles was found to increase tolerance to chitosan. We also demonstrated, for the first time, that the deletion of ITR1, AGP2 and FPS1, encoding plasma membrane transporters, prominently increased the tolerance of S. cerevisiae to chitosan, suggesting that they can serve as carriers for chitosan. Besides providing new insights into the mode of action of chitosan against wine yeasts, this study adds relevant information for its rational use as a substitute/complementary preservative to SO2. [ABSTRACT FROM AUTHOR]

Published
2023
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20. Insights into the transcriptional regulation of poorly characterized alcohol acetyltransferase-encoding genes (HgAATs) shed light into the production of acetate esters in the wine yeast Hanseniaspora guilliermondii.

Author

Seixas, Isabel, Santos, Diogo, Vasconcelos, Isabel, Mira, Nuno P, and Mendes-Ferreira, Ana

Subjects
GENETIC transcription regulation, ESTERS, ACETATES, WINES, YEAST, AMINO acids, ALCOHOL
Abstract

Hanseniaspora guilliermondii is a well-recognized producer of acetate esters associated with fruity and floral aromas. The molecular mechanisms underneath this production or the environmental factors modulating it remain unknown. Herein, we found that, unlike Saccharomyces cerevisiae, H. guilliermondii over-produces acetate esters and higher alcohols at low carbon-to-assimilable nitrogen (C:N) ratios, with the highest titers being obtained in the amino acid-enriched medium YPD. The evidences gathered support a model in which the strict preference of H. guilliermondii for amino acids as nitrogen sources results in a channeling of keto-acids obtained after transamination to higher alcohols and acetate esters. This higher production was accompanied by higher expression of the four HgAATs, genes, recently proposed to encode alcohol acetyl transferases. In silico analyses of these HgAat's reveal that they harbor conserved AATs motifs, albeit radical substitutions were identified that might result in different kinetic properties. Close homologues of HgAat2, HgAat3, and HgAat4 were only found in members of Hanseniaspora genus and phylogenetic reconstruction shows that these constitute a distinct family of Aat's. These results advance the exploration of H. guilliermondii as a bio-flavoring agent providing important insights to guide future strategies for strain engineering and media manipulation that can enhance production of aromatic volatiles. Acetate esters production by the wine yeastHanseniaspora guilliermondi. [ABSTRACT FROM AUTHOR]

Published
2023
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24. Additional file 1 of Genome sequencing, annotation and exploration of the SO2-tolerant non-conventional yeast Saccharomycodes ludwigii

Author

Tavares, Maria J., Güldener, Ulrich, Mendes-Ferreira, Ana, and Mira, Nuno P.

Abstract

Additional file 1 Supplementary figures – This file has included a set of 5 supplementary figures providing: a dendrogram comparing the ITS region of the yeast strains used for the comparative proteomic analysis performed (Figure S1), phographs obtained by microscopic imaging of S. ludwigii UTAD17 cells cultivated in minimal medium having glucose or GlcNAc as the sole carbon source (Figure S2), a functional distribution of the S. ludwigii UTAD17 ORFeome, as performed by the BLASTKoala Annotation tool (Figure S3), the alignment of the protein sequence of the transcription factors ScMsn2, ScCom2 and the S. ludwigii predicted regulator SCLUD3.g33 (Figure S4), the alignment of the protein sequence of the efflux pump ScSsu1 and of the four predicted S. ludwigii orthologues SCLUD1.g608, SCLUD1.g612, SCLUD1.g608b, SCLUD1.g612b (Figure S5).

Published
2021
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25. Implementation of Synthetic Pathways to Foster Microbe-Based Production of Non-Naturally Occurring Carboxylic Acids and Derivatives

Author

Vila-Santa, Ana, Mendes, Fernão C., Ferreira, Frederico C., Prather, Kristala L. J., Mira, Nuno P., Vila-Santa, Ana, Mendes, Fernão C., Ferreira, Frederico C., Prather, Kristala L. J., and Mira, Nuno P.

Abstract

Microbially produced carboxylic acids (CAs) are considered key players in the implementation of more sustainable industrial processes due to their potential to replace a set of oil-derived commodity chemicals. Most CAs are intermediates of microbial central carbon metabolism, and therefore, a biochemical production pathway is described and can be transferred to a host of choice to enable/improve production at an industrial scale. However, for some CAs, the implementation of this approach is difficult, either because they do not occur naturally (as is the case for levulinic acid) or because the described production pathway cannot be easily ported (as it is the case for adipic, muconic or glucaric acids). Synthetic biology has been reshaping the range of molecules that can be produced by microbial cells by setting new-to-nature pathways that leverage on enzyme arrangements not observed in vivo, often in association with the use of substrates that are not enzymes’ natural ones. In this review, we provide an overview of how the establishment of synthetic pathways, assisted by computational tools for metabolic retrobiosynthesis, has been applied to the field of CA production. The translation of these efforts in bridging the gap between the synthesis of CAs and of their more interesting derivatives, often themselves non-naturally occurring molecules, is also reviewed using as case studies the production of methacrylic, methylmethacrylic and poly-lactic acids.

Published
2021

36. Increased expression of the yeast multidrug resistance ABC transporter Pdr18 leads to increased ethanol tolerance and ethanol production in high gravity alcoholic fermentation

Author

Teixeira Miguel C, Godinho Cláudia P, Cabrito Tânia R, Mira Nuno P, and Sá-Correia Isabel

Subjects
Saccharomyces cerevisiae, Ethanol tolerance, ABC multidrug transporters, Membrane permeabilization, Bio-ethanol production, Microbiology, QR1-502
Abstract

Abstract Background The understanding of the molecular basis of yeast tolerance to ethanol may guide the design of rational strategies to increase process performance in industrial alcoholic fermentations. A set of 21 genes encoding multidrug transporters from the ATP-Binding Cassette (ABC) Superfamily and Major Facilitator Superfamily (MFS) in S. cerevisiae were scrutinized for a role in ethanol stress resistance. Results A yeast multidrug resistance ABC transporter encoded by the PDR18 gene, proposed to play a role in the incorporation of ergosterol in the yeast plasma membrane, was found to confer resistance to growth inhibitory concentrations of ethanol. PDR18 expression was seen to contribute to decreased 3 H-ethanol intracellular concentrations and decreased plasma membrane permeabilization of yeast cells challenged with inhibitory ethanol concentrations. Given the increased tolerance to ethanol of cells expressing PDR18, the final concentration of ethanol produced during high gravity alcoholic fermentation by yeast cells devoid of PDR18 was lower than the final ethanol concentration produced by the corresponding parental strain. Moreover, an engineered yeast strain in which the PDR18 promoter was replaced in the genome by the stronger PDR5 promoter, leading to increased PDR18 mRNA levels during alcoholic fermentation, was able to attain a 6 % higher ethanol concentration and a 17 % higher ethanol production yield than the parental strain. The improved fermentative performance of yeast cells over-expressing PDR18 was found to correlate with their increased ethanol tolerance and ability to restrain plasma membrane permeabilization induced throughout high gravity fermentation. Conclusions PDR18 gene over-expression increases yeast ethanol tolerance and fermentation performance leading to the production of highly inhibitory concentrations of ethanol. PDR18 overexpression in industrial yeast strains appears to be a promising approach to improve alcoholic fermentation performance for sustainable bio-ethanol production.

Published
2012
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38. Identification of candidate genes for yeast engineering to improve bioethanol production in very high gravity and lignocellulosic biomass industrial fermentations

Author

Pereira Francisco B, Guimarães Pedro MR, Gomes Daniel G, Mira Nuno P, Teixeira Miguel C, Sá-Correia Isabel, and Domingues Lucília

Subjects
Fuel, TP315-360, Biotechnology, TP248.13-248.65
Abstract

Abstract Background The optimization of industrial bioethanol production will depend on the rational design and manipulation of industrial strains to improve their robustness against the many stress factors affecting their performance during very high gravity (VHG) or lignocellulosic fermentations. In this study, a set of Saccharomyces cerevisiae genes found, through genome-wide screenings, to confer resistance to the simultaneous presence of different relevant stresses were identified as required for maximal fermentation performance under industrial conditions. Results Chemogenomics data were used to identify eight genes whose expression confers simultaneous resistance to high concentrations of glucose, acetic acid and ethanol, chemical stresses relevant for VHG fermentations; and eleven genes conferring simultaneous resistance to stresses relevant during lignocellulosic fermentations. These eleven genes were identified based on two different sets: one with five genes granting simultaneous resistance to ethanol, acetic acid and furfural, and the other with six genes providing simultaneous resistance to ethanol, acetic acid and vanillin. The expression of Bud31 and Hpr1 was found to lead to the increase of both ethanol yield and fermentation rate, while Pho85, Vrp1 and Ygl024w expression is required for maximal ethanol production in VHG fermentations. Five genes, Erg2, Prs3, Rav1, Rpb4 and Vma8, were found to contribute to the maintenance of cell viability in wheat straw hydrolysate and/or the maximal fermentation rate of this substrate. Conclusions The identified genes stand as preferential targets for genetic engineering manipulation in order to generate more robust industrial strains, able to cope with the most significant fermentation stresses and, thus, to increase ethanol production rate and final ethanol titers.

Published
2011
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39. Genome-wide identification of Saccharomyces cerevisiae genes required for tolerance to acetic acid

Author

Sá-Correia Isabel, Guerreiro Joana F, Palma Margarida, and Mira Nuno P

Subjects
Microbiology, QR1-502
Abstract

Abstract Background Acetic acid is a byproduct of Saccharomyces cerevisiae alcoholic fermentation. Together with high concentrations of ethanol and other toxic metabolites, acetic acid may contribute to fermentation arrest and reduced ethanol productivity. This weak acid is also a present in lignocellulosic hydrolysates, a highly interesting non-feedstock substrate in industrial biotechnology. Therefore, the better understanding of the molecular mechanisms underlying S. cerevisiae tolerance to acetic acid is essential for the rational selection of optimal fermentation conditions and the engineering of more robust industrial strains to be used in processes in which yeast is explored as cell factory. Results The yeast genes conferring protection against acetic acid were identified in this study at a genome-wide scale, based on the screening of the EUROSCARF haploid mutant collection for susceptibility phenotypes to this weak acid (concentrations in the range 70-110 mM, at pH 4.5). Approximately 650 determinants of tolerance to acetic acid were identified. Clustering of these acetic acid-resistance genes based on their biological function indicated an enrichment of genes involved in transcription, internal pH homeostasis, carbohydrate metabolism, cell wall assembly, biogenesis of mitochondria, ribosome and vacuole, and in the sensing, signalling and uptake of various nutrients in particular iron, potassium, glucose and amino acids. A correlation between increased resistance to acetic acid and the level of potassium in the growth medium was found. The activation of the Snf1p signalling pathway, involved in yeast response to glucose starvation, is demonstrated to occur in response to acetic acid stress but no evidence was obtained supporting the acetic acid-induced inhibition of glucose uptake. Conclusions Approximately 490 of the 650 determinants of tolerance to acetic acid identified in this work are implicated, for the first time, in tolerance to this weak acid. These are novel candidate genes for genetic engineering to obtain more robust yeast strains against acetic acid toxicity. Among these genes there are number of transcription factors that are documented regulators of a large percentage of the genes found to exert protection against acetic acid thus being considered interesting targets for subsequent genetic engineering. The increase of potassium concentration in the growth medium was found to improve the expression of maximal tolerance to acetic acid, consistent with the idea that the adequate manipulation of nutrient concentration of industrial growth medium can be an interesting strategy to surpass the deleterious effects of this weak acid in yeast cells.

Published
2010
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40. Genetic adaptive mechanisms mediating response and tolerance to acetic acid stress in the human pathogen Candida glabrata: role of the CgHaa1-dependent signaling pathway

Author

Salazar, Sara, Bernardes, Rúben, Cunha, Diana, Chibana, Hiroji, Azeredo, Joana, Butler, Geraldine, Mira, Nuno P., and Universidade do Minho

Subjects
Ecological balance, Engenharia e Tecnologia::Biotecnologia Industrial, Candida glabrata, Acetic acid, CgHAA1
Abstract

The increased resilience of Candida glabrata to azoles and the continuous emergence of strains resistant to other antifungals demands the development of new therapeutic approaches focused on non-conventional biological targets. Genes contributing to increase C. glabrata competitiveness in the different infection sites are an interesting and unexplored cohort of therapeutic targets. To thrive in the vaginal tract and avoid exclusion C. glabrata cells have evolved dedicated responses rendering them capable of tolerating multiple environmental challenges, including the presence of acetic and lactic acids produced by the commensal microbiota. In this work a cohort of vaginal clinical isolates were phenotyped for their tolerance to acetic acid stress at a low pH as well as for several traits that are known to influence sensitivity to this organic acid, including the structure of the cell envelope and the ability to consume the acid in the presence of glucose. The role played by the ORF CAGL0L09339g, an homologue of the ScHaa1, a critical regulator of acetic acid resistance in S. cerevisiae[1], in C. glabrata response and tolerance to acetic acid stress at pH 4 was also scrutinized using a transcriptomic analysis. The role of CgHaa1 as well as of several of its target genes in mediating virulence of C. glabrata against epithelial vaginal cells was also studied., Funding received by the Institute for Bioengineering and Biosciences from the Portuguese Foundation for Science and Technology (FCT) (UID/BIO/04565/2013) and from Programa Operacional Regional de Lisboa 2020 (project no. 007317) is acknowledged. FCT is also acknowledged for funding the Centre of Biological Engineering through contracts FCOMP-01-0124-FEDER- 020243 and PTDC/EBB-EBI/120495/2010, info:eu-repo/semantics/publishedVersion

Published
2017

41. A Transcriptomics Approach To Unveiling the Mechanisms of In Vitro Evolution towards Fluconazole Resistance of a Candida glabrata Clinical Isolate

Author

Cavalheiro, Mafalda, primary, Costa, Catarina, additional, Silva-Dias, Ana, additional, Miranda, Isabel M., additional, Wang, Can, additional, Pais, Pedro, additional, Pinto, Sandra N., additional, Mil-Homens, Dalila, additional, Sato-Okamoto, Michiyo, additional, Takahashi-Nakaguchi, Azusa, additional, Silva, Raquel M., additional, Mira, Nuno P., additional, Fialho, Arsénio M., additional, Chibana, Hiroji, additional, Rodrigues, Acácio G., additional, Butler, Geraldine, additional, and Teixeira, Miguel C., additional

Published
2019
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45. Genome-wide identification of Saccharomyces cerevisiae genes required for maximal tolerance to ethanol

Author

Teixeira, Miguel C., Raposo, Luis R., Mira, Nuno P., Lourenco, Artur B., and Sa-Correia, Isabel

Subjects
Alcohol -- Environmental aspects, Alcohol, Denatured -- Environmental aspects, Fermentation -- Analysis, Gene expression -- Analysis, Brewer's yeast -- Genetic aspects, Brewer's yeast -- Identification and classification, Biological sciences
Abstract

The yeast disruptome is screened for mutants with differential susceptibility to stress induced by high ethanol concentrations in minimal growth medium. The increased expression of FPS1 has shown the important role of this gene in alcoholic fermentation, which has led to enhanced final ethanol concentration under conditions that has led to high ethanol production.

Published
2009

49. The CgHaa1-dependent pathway mediates Candida glabrata response and tolerance to acetic acid thereby enhancing colonization of vaginal epithelium

Author

Bernardo, Ruben, Silva, Sónia Carina, Cunha, Diana V., Pereira, Leonel, Wang, Can, Correia, Isabel Sá, Chibana, Hiroji, Butler, Geraldine, Azeredo, Joana, Mira, Nuno P., and Universidade do Minho

Abstract

To successfully colonize the vaginal tract Candida glabrata has to cope with various stresses including the presence of acetic acid at a low pH that is produced by the bacteria that co-colonize this niche. The genes/pathways involved in C. glabrata tolerance and response to acetic acid are largely unknown, although these are a highly interesting set of novel targets to control vaginal infections caused by this yeast. Saccharomyces cerevisae response and tolerance to acetic acid was found to be largely mediated by the ScHaa1 transcription factor [1,2,3]. In this work the involvement of CgHaa1 in C. glabrata tolerance and response to acetic acid is demonstrated. Elimination of CgHAA1 gene from C. glabrata genome dramatically increased susceptibility of this pathogenic yeast to acetic acid (30 mM at pH 4.0). Around 140 genes were found to be up-regulated, directly or indirectly, by CgHaa1 in response to acetic acid stress, based on results of a transcriptomic analysis. Functional clustering of the genes activated by CgHaa1 under acetic acid stress shows an enrichment of those involved in carbohydrate metabolism, transport, cell wall maintenance, regulation of internal pH and nucleic acid processing. At least five of the CgHaa1-regulated genes were found to increase C. glabrata tolerance to acetic acid including CgGAD1, encoding a glutamate decarboxylase; CgTPO2/3, encoding a drug efflux pump of the Major Facilitator Superfamily; CgYPS1, encoding a cell wall aspartyl protease; and CAGL0H04851 and CAGL0E03740, encoding two uncharacterized ORFs. Altogether our results are consistent with the concept that the CgHaa1- signalling pathway increases C. glabrata tolerance to acetic acid by reducing the internal accumulation of the acid and by up-regulating the activity of the plasma membrane proton pump H+-ATPase CgPma1, two essential features for a robust weak acid response. The role exerted by CgHaa1 in the ability of C. glabrata to colonize reconstituted vaginal human epithelium (RVHE) in the presence of acetic acid (30 mM at pH 4.0) was also investigated in this work. In the absence of acetic acid wild-type and DCgHaa1 mutant cells were able to colonize RVHE at a similar rate, however, in the presence of acetic acid colonization of the vaginal tissue was markedly reduced in the mutant background. The reduced colonizing capacity of DCgHaa1 mutant cells was correlated with a reduced expression of the adhesin-encoding genes EPA6, EPA7 and EPA1 and with a lower adhesiveness to the extracellular matrix proteins fibronectin and vitronectin.

Published
2014

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