Zygocin,a secreted antifungal toxin of the yeast Zygosaccharomyces bailii,and its effect on sensitive fungal cells

Zygocin, a protein toxin produced and secreted by a killer virus-infected strain of the osmotolerant yeast Zygosaccharomyces bailii, kills a great variety of human and phytopathogenic yeasts and filamentous fungi. Toxicity of the viral toxin is envisaged in a two-step receptor-mediated process in which the toxin interacts with cell surface receptors at the level of the cell wall and the plasma membrane. Zygocin receptors were isolated and partially purified from the yeast cell wall mannoprotein fraction and could be successfully used as biospecific ligand for efficient one-step purification of the 10-kDa protein toxin by receptor-mediated affinity chromatography. Evidence is presented that zygocin-treated yeast cells are rapidly killed by the toxin, and intensive propidium iodide staining of zygocin-treated cells indicated that the toxin is affecting cytoplasmic membrane function, most probably by lethal ion channel formation. The presented findings suggest that zygocin has potential as a novel antimycotic in combating fungal infections.     

The yeast Zygosaccharomyces bailii: a new host for heterologous protein production, secretion and for metabolic engineering applications

Molecular tools for the production of heterologous proteins and metabolic engineering applications of the non-conventional yeast Zygosaccharomyces bailii were developed. The combination of Z. bailii's resistance to relatively high temperature, osmotic pressure and low pH values, with a high specific growth rate renders this yeast potentially interesting for exploitation for biotechnological purposes as well as for the understanding of the biological phenomena and mechanisms underlying the respective resistances. Looking forward to these potential applications, here we present the tools required for the production and the secretion of different heterologous proteins, and one example of a metabolic engineering application of this non-conventional yeast, employing the newly developed molecular tools.     

The glucose-dependent transport of l-malate in Zygosaccharomyces bailii

Zygosaccharomyces bailii possesses a constitutive malic enzyme, but only small amounts of malate are decomposed when the cells ferment fructose. Cells growing anaerobically on glucose (glucose cells) decompose malate, whereas fructose cells do not. Only glucose cells show an increase in the intracellular concentration of malate when suspended in a malate-containing solution. The transport system for malate is induced by glucose, but it is repressed by fructose. The synthesis of this transport system is inhibited by cycloheximide. Of the two enantiomers l-malate is transported preferentially. The transport of malate by induced cells is not only inhibited by addition of fructose but also inactivated. This inactivation is independent of the presence of cycloheximide. The transport of malate is inhibited by uranyl ions; various other inhibitors of transport and phosphorylation were of little influence. It is assumed that the inducible protein carrier for malate operates by facilitated diffusion. Fructose cells of Z. bailii and cells of Saccharomyces cerevisiae do not contain a transport system for malate.This research was supported in part by a grant from the Forschungsring des Deutschen Weinbaus.     

Zygosaccharomyces kombuchaensis: the physiology of a new species related to the spoilage yeasts Zygosaccharomyces lentus and Zygosaccharomyces bailii

Zygosaccharomyces kombuchaensis was recently discovered in the 'tea fungus' used to make fermented tea. Z. kombuchaensis was shown by ribosomal DNA sequencing to be a novel species, and a close relative of Zygosaccharomyces lentus, from which it could not be distinguished by conventional physiological tests. Z. lentus was originally established as a new taxon by growth at 4 degrees C, sensitivity for heat and oxidative stress, and lack of growth in aerobic shaken culture at temperatures above 25 degrees C. Subsequent analysis of Z. kombuchaensis reveals that this species shares these unusual characteristics, confirming its close genealogical relationship to Z. lentus. Detailed physiological data from a number of Z. kombuchaensis and Z. lentus strains clearly demonstrate that these two species can in fact be distinguished from one another based on their differing resistance/sensitivity to the food preservatives benzoic acid and sorbic acid. The spoilage yeasts Zygosaccharomyces bailii and Z. lentus are resistant to both acetic acid and sorbic acid, whereas Z. kombuchaensis is resistant to acetic acid but sensitive to sorbic acid. This would indicate that Z. kombuchaensis strains lack the mechanism for resistance to sorbic acid, but possess the means of resistance to acetic acid. This observation would therefore suggest that these two resistance mechanisms are different, and that in all probability acetic and sorbic acids inhibit yeast growth by different modes of action. Z. kombuchaensis strains were also sensitive to benzoic acid, again suggesting inhibition dissimilar from that to acetic acid.     

The spoilage yeast Zygosaccharomyces bailii forms mitotic spores: a screening method for haploidization

Zygosaccharomyces bailii ISA 1307 and the type strain of this spoilage yeast show a diploid DNA content. Together with a rather peculiar life cycle in which mitotic but no meiotic spores appear to be formed, the diploid DNA content explains the observed difficulties in obtaining auxotrophic mutants. Mitotic chromosome loss induced by benomyl and selection on canavanine media resulted in three haploid strains of Z. bailii. This new set of Z. bailii strains allows the easy isolation of recessive mutants and is suitable for further molecular genetic studies.     

The Spoilage Yeast Zygosaccharomyces bailii Forms Mitotic Spores: a Screening Method for Haploidization

Zygosaccharomyces bailii ISA 1307 and the type strain of this spoilage yeast show a diploid DNA content. Together with a rather peculiar life cycle in which mitotic but no meiotic spores appear to be formed, the diploid DNA content explains the observed difficulties in obtaining auxotrophic mutants. Mitotic chromosome loss induced by benomyl and selection on canavanine media resulted in three haploid strains of Z. bailii. This new set of Z. bailii strains allows the easy isolation of recessive mutants and is suitable for further molecular genetic studies.     

Advances in cloning, functional analysis and heterologous expression of fungal polyketide synthase genes

Fungal polyketides comprise a diverse group of secondary metabolites that play an important role for drug discovery, as pigments, and as mycotoxins. Their biosynthesis is governed by multidomain enzymes, so-called fungal type I polyketide synthases (PKS). Investigating the molecular basis of polyketide biosynthesis in fungi is of great importance for ecological and pharmacological reasons. In addition, cloning, functional analysis and expression of fungal PKS genes also set the basis for engineering the yet largely untapped biosynthetic potential.     

Heterologous protein production in Zygosaccharomyces bailii: physiological effects and fermentative strategies

The optimisation and scale-up of a specific protein production process have to take into account cultivation conditions as well as cell physiology of growth and the influence of foreign protein expression on host cell metabolism. The ability of Zygosaccharomyces bailii to tolerate high sugar concentrations as well as high temperatures and acidic environments renders this "non-conventional" yeast suitable for the development of biotechnological processes like heterologous protein production. This work addresses the production of human interleukin-1beta by a recombinant Z. bailii strain. We found that the heterologous protein production causes some modifications of the Z. bailii carbon metabolism, leading to a reduced biomass yield. The other important factor is the dependence of the recombinant IL-1beta production/secretion on the growth rate. Among the cultivation strategies studied, the most appropriate in terms of production and productivity was the fed-batch mode.     

Streptomyces: a host for heterologous gene expression.

Streptomyces species offer many potential advantages as hosts for the expression and secretion of eukaryotic gene products. In this review we discuss the expression and localization signals that have been used to direct heterologous gene expression and the applications of these signals. Finally, we discuss future strategies aimed at increasing the capacity of this host for the high level production of biologically active eukaryotic gene products.     

Cyanobacterial sulfide-quinone reductase: cloning and heterologous expression

The gene encoding sulfide-quinone reductase (SQR; E.C.1.8.5.'), the enzyme catalyzing the first step of anoxygenic photosynthesis in the filamentous cyanobacterium Oscillatoria limnetica, was cloned by use of amino acid sequences of tryptic peptides as well as sequences conserved in the Rhodobacter capsulatus SQR and in an open reading frame found in the genome of Aquifex aeolicus. SQR activity was also detected in the unicellular cyanobacterium Aphanothece halophytica following sulfide induction, with a V(max) of 180 micromol of plastoquinone-1 (PQ-1) reduced/mg of chlorophyll/h and apparent K(m) values of 20 and 40 microM for sulfide and quinone, respectively. Based on the conserved sequences, the gene encoding A. halophytica SQR was also cloned. The SQR polypeptides deduced from the two cyanobacterial genes consist of 436 amino acids for O. limnetica SQR and 437 amino acids for A. halophytica SQR and show 58% identity and 74% similarity. The calculated molecular mass is about 48 kDa for both proteins; the theoretical isoelectric points are 7.7 and 5.6 and the net charges at a neutral pH are 0 and -14 for O. limnetica SQR and A. halophytica SQR, respectively. A search of databases showed SQR homologs in the genomes of the cyanobacterium Anabaena PCC7120 as well as the chemolithotrophic bacteria Shewanella putrefaciens and Thiobacillus ferrooxidans. All SQR enzymes contain characteristic flavin adenine dinucleotide binding fingerprints. The cyanobacterial proteins were expressed in Escherichia coli under the control of the T7 promoter. Membranes isolated from E. coli cells expressing A. halophytica SQR performed sulfide-dependent PQ-1 reduction that was sensitive to the quinone analog inhibitor 2n-nonyl-4-hydroxyquinoline-N-oxide. The wide distribution of SQR genes emphasizes the important role of SQR in the sulfur cycle in nature.     

Developing Aspergillus as a host for heterologous expression

Filamentous fungi have long been used for production of a range of valuable products; with the advent of molecular biology, it became apparent that these fungi possess considerable potential as expression hosts for the production of heterologous proteins and small molecules. Aspergillus is an important genus, including well known species of economically significant molds, and widely used for basic genetic research. The development of a genetic engineering "toolkit" for Aspergillus, such as those existing for the simpler yeasts and bacteria, was delayed due to the added complexity of the filamentous fungi, and also to the lesser resources devoted to their study. History of the development of Aspergillus as an expression host, current state of the art and future directions are reviewed, touching on related research in other fungi when discussing the areas of greatest potential for future biotechnological applications, focusing on the large and diverse families of fungal secondary metabolites.     

How hexoses and inhibitors influence the malate transport system in Zygosaccharomyces bailii

When grown in fructose or glucose the cells of Zygosaccharomyces bailii were physiologically different. Only the glucose grown cells (glucose cells) possessed an additional transport system for glucose and malate. Experiments with transport mutants had lead to the assumption that malate and glucose were transported by one carrier, but further experiments proved the existence of two separate carrier systems. Glucose was taken up by carriers with high and low affinity. Malate was only transported by an uptake system and it was not liberated by starved malate-loaded cells, probably due to the low affinity of the intracellular anion to the carrier. The uptake of malate was inhibited by fructose, glucose, mannose, and 2-DOG but not by non metabolisable analogues of glucose. The interference of malate transport by glucose, mannose or 2-DOG was prevented by 2,4-dinitrophenol, probably by inhibiting the sugar phosphorylation by hexokinase. Preincubation of glucose-cells with metabolisable hexoses promoted the subsequent malate transport in a sugar free environment. Preincubation of glucose-cells with 2-DOG, but not with 2-DOG/2,4-DNP, decreased the subsequent malate transport. The existence of two separate transport systems for glucose and malate was demonstrated with specific inhibitors: malate transport was inhibited by sodium fluoride and glucose transport by uranylnitrate. A model has been discussed that might explain the interference of hexoses with malate uptake in Z. bailii.Abbreviations 2,4-DNP 2,4-dinitrophenol - 2-DOG 2-deoxyglucose - 6-DOG 6-deoxyglucose - pCMB para-hydroxymercuribenzoate     

cDNA cloning and heterologous expression of functional cysteine-rich antifungal protein Psd1 in the yeast Pichia pastoris.

In the present work, we describe the cDNA cloning, expression in Pichia pastoris, purification, and characterization of the recombinant Pisum sativum defensin 1 (rPsd1), a novel Cys-rich protein presenting four disulfide bridges and high antifungal activity. Several parameters that affect the level of protein expression were assayed. The best condition yielded 13.8 mg/L (1.50 microg/10(8) cells) of active rPsd1. The recombinant rPsd1 was purified to homogeneity by cation exchange, followed by reversed-phase HPLC, and subjected to automated amino acid sequencing, which revealed four additional amino acids (EAEA) at the N-terminal region. Circular dichroism, intrinsic fluorescence, and nuclear magnetic resonance spectroscopy analysis indicated that the recombinant protein has a very similar folding and a correct disulfide-bonding pattern when compared to native Psd1. Nevertheless, the rPsd1 presented a more species-specific antifungal activity. The importance of the N- and C-termini for Psd1 activity is pointed out.     

Domesticating a food spoilage yeast into an organic acid‐tolerant metabolic engineering host: Lactic acid production by engineered Zygosaccharomyces bailii

Lactic acid represents an important class of commodity chemicals, which can be produced by microbial cell factories. However, due to the toxicity of lactic acid at lower pH, microbial production requires the usage of neutralizing agents to maintain neutral pH. Zygosaccharomyces bailii, a food spoilage yeast, can grow under the presence of organic acids used as food preservatives. This unique trait of the yeast might be useful for producing lactic acid. With the goal of domesticating the organic acid‐tolerant yeast as a metabolic engineering host, seven Z. bailii strains were screened in a minimal medium with 10 g/L of acetic, or 60 g/L of lactic acid at pH 3. The Z. bailii NRRL Y7239 strain was selected as the most robust strain to be engineered for lactic acid production. By applying a PAN‐ARS‐based CRISPR‐Cas9 system consisting of a transfer RNA promoter and NAT selection, we demonstrated the targeted deletion of ADE2 and site‐specific integration of Rhizopus oryzae ldhA coding for lactate dehydrogenase into the PDC1 locus. The resulting pdc1::ldhA strain produced 35 g/L of lactic acid without ethanol production. This study demonstrates the feasibility of the CRISPR‐Cas9 system in Z. bailii, which can be applied for a fundamental study of the species.     

Acetic acid induces a programmed cell death process in the food spoilage yeast Zygosaccharomyces bailii

Here we show that 320-800 mM acetic acid induces in Zygosaccharomyces bailii a programmed cell death (PCD) process that is inhibited by cycloheximide, is accompanied by structural and biochemical alterations typical of apoptosis, and occurs in cells with preserved mitochondrial and plasma membrane integrity (as revealed by rhodamine 123 (Rh123) and propidium iodide (PI) staining, respectively). Mitochondrial ultrastructural changes, namely decrease of the cristae number, formation of myelinic bodies and swelling were also seen. Exposure to acetic acid above 800 mM resulted in killing by necrosis. The occurrence of an acetic acid-induced active cell death process in Z. bailii reinforces the concept of a physiological role of the PCD in the normal yeast life cycle.     

Advances in molecular tools for the use of Zygosaccharomyces bailii as host for biotechnological productions and construction of the first auxotrophic mutant

The nonconventional yeast Zygosaccharomyces bailii has been proposed as a new host for biotechnological processes due to convenient properties such as its resistance to high sugar concentrations, relatively high temperatures and especially to acidic environments. We describe a series of new expression vectors specific for Z. bailii and the resulting improvements in production levels. By exploiting the sequences of the endogenous plasmid pSB2, 2microm-like multicopy vectors were obtained, giving a fivefold increase in production. A specific integrative vector was developed which led to 100% stability in the absence of selective pressure; a multiple-integration vector was constructed, based on an rRNA gene unit portion cloned and sequenced for this purpose, driving the insertion of up to 80 copies of the foreign construct. Moreover, we show the construction of the first stable auxotrophic mutant of Z. bailii, obtained by targeted gene deletion applied to ZbLEU2. The development of molecular tools for the Z. bailii manipulation has now reached a level that may be compatible with its industrial exploitation; the production of organic acids is a prominent field of application.     

Oxygen Requirements of the Food Spoilage Yeast Zygosaccharomyces bailii in Synthetic and Complex Media

Most yeast species can ferment sugars to ethanol, but only a few can grow in the complete absence of oxygen. Oxygen availability might, therefore, be a key parameter in spoilage of food caused by fermentative yeasts. In this study, the oxygen requirement and regulation of alcoholic fermentation were studied in batch cultures of the spoilage yeast Zygosaccharomyces bailii at a constant pH, pH 3.0. In aerobic, glucose-grown cultures, Z. bailii exhibited aerobic alcoholic fermentation similar to that of Saccharomyces cerevisiae and other Crabtree-positive yeasts. In anaerobic fermentor cultures grown on a synthetic medium supplemented with glucose, Tween 80, and ergosterol, S. cerevisiae exhibited rapid exponential growth. Growth of Z. bailii under these conditions was extremely slow and linear. These linear growth kinetics indicate that cell proliferation of Z. bailii in the anaerobic fermentors was limited by a constant, low rate of oxygen leakage into the system. Similar results were obtained with the facultatively fermentative yeast Candida utilis. When the same experimental setup was used for anaerobic cultivation, in complex YPD medium, Z. bailii exhibited exponential growth and vigorous fermentation, indicating that a nutritional requirement for anaerobic growth was met by complex-medium components. Our results demonstrate that restriction of oxygen entry into foods and beverages, which are rich in nutrients, is not a promising strategy for preventing growth and gas formation by Z. bailii. In contrast to the growth of Z. bailii, anaerobic growth of S. cerevisiae on complex YPD medium was much slower than growth in synthetic medium, which probably reflected the superior tolerance of the former yeast to organic acids at low pH.     

Ani s 10, a new Anisakis simplex allergen: cloning and heterologous expression

Anisakiasis is a human disease caused by accidental ingestion of larval nematodes belonging to the Anisakidae family. Anisakiasis is often associated with a strong allergic response. Diagnosis of A. simplex allergy is currently carried out by test based on the IgE reactivity to a complete extract of L3 Anisakis larvae although the specificity of these diagnostic tests is poor. Improving the specificity of the diagnostic test is possible using purified recombinant allergens. A new Anisakis allergen, named Ani s 10, was detected by immunoscreening an expression cDNA library constructed from L3 Anisakis simplex larvae. The new allergen was overproduced in Escherichia coli; it is a protein of 212 amino acids and it was localized as a 22 kDa protein band in an ethanol fractionated extract from the parasite. Ani s 10 has no homology with any other described protein, and its sequence is composed by seven almost identical repetitions of 29 amino acids each. A total of 30 of 77 Anisakis allergic patients (39%) were positive both to rAni s 10 and natural Ani s 10 by immunoblotting. The new allergen could be useful in a component-resolved diagnosis system for Anisakis allergy.     

Killer toxin-secreting double-stranded RNA mycoviruses in the yeasts Hanseniaspora uvarum and Zygosaccharomyces bailii.

Killer toxin-secreting strains of the yeasts Hanseniaspora uvarum and Zygosaccharomyces bailii were shown to contain linear double-stranded RNAs (dsRNAs) that persist within the cytoplasm of the infected host cell as encapsidated virus-like particles. In both yeasts, L- and M-dsRNAs were associated with 85-kDa major capsid protein, whereas the additional Z-dsRNA (2.8 kb), present only in the wild-type Z. bailii killer strain, was capsid protein, whereas the additional Z-dsRNA (2.8 kb), present only in the wild-type Z. bailii killer strain, was shown to be encapsidated by a 35-kDa coat protein. Although Northern (RNA) blot hybridizations indicated that L-dsRNA from Z. bailii is a LA species, additional peptide maps of the purified 85-kDa capsid from Z. bailii and the 88- and 80-kDa major coat proteins from K1 and K28 killer viruses of Saccharomyces cerevisiae revealed distinctly different patterns of peptides. Electron microscopy of purified Z. bailii viruses (ZbV) identified icosahedral particles 40 nm in diameter which were undistinguishable from the S. cerevisiae killer viruses. We demonstrated that purified ZbVs are sufficient to confer the Z. bailii killer phenotype on transfected spheroplasts of a S. cerevisiae nonkiller strain and that the resulting transfectants secreted even more killer toxin that the original ZbV donor strain did. Curing experiments with ZbV-transfected S. cerevisiae strains indicated that the M-dsRNA satellite from Z. bailii contains the genetic information for toxin production, whereas expression of toxin immunity might be dependent on Z-dsRNA, which resembles a new dsRNA replicon in yeasts that is not dependent on an LA helper virus to be stably maintained and replicated within the cell.     

真菌天然产物异源生产研究进展

真菌天然产物是天然药物的重要来源之一,大规模真菌基因组序列测序的完成表明真菌具有产生丰富的次级代谢产物的潜能。然而,许多真菌或生长缓慢,或不适宜在实验室条件下培养,或难以进行遗传操作,或化合物产量极低等,这些因素导致大量有价值的真菌天然产物无法获得。利用异源表达系统对真菌天然产物进行生产是发现新天然产物及解析其生物合成途径的有效手段,并为定向的以合成生物学的手段去合成重要活性分子奠定基础。本文对目前用于真菌天然产物生产的各种异源表达系统进行了综述,并结合最新的DNA组装技术展望了异源表达系统在真菌天然产物研究中的应用价值和前景。