The kinetics of the active and de-energized transport of O-methyl glucose in Ustilago maydis

The kinetics of the uptake and efflux of 3-O-methyl-glucose in sporidia of Ustilago maydis were measured, both in active cells and in cells whose metabolic activity had been inhibited by azide and iodoacetate.The de-energized transport system proved to be carrier mediated with apparent affinity constants 13 ± 2 mM outside (K₀) and 18 ± 2 mM inside (K₁). The apparent maximum rate constants for the same system were 0.66 ± 0.05 mmol/l cell water per min for uptake (V₊ and 0.53 ± 0.04 mmol/l cell water per min for efflux (V_-. For the active system K₀ = 0.08 ± 0.01, K₁ > 40, V₊ = 9.7 ± 0.5 and V₋ 1.1 ± 0.9 (in equivalent units). These results are discussed in the context of the carrier mechanism as proposed by Regen and Morgan (Regen, D.M. and Morgan, H.E. (1964) Biochim. Biophys. Acta 79, 151–166).The antifungal compound carboxin had no effect on de-energized transport but was shown to decrease both K₀ and V₊ in the active system. Phloretin and phlorizin were also found to be without effect on de-energized cells but the former enhanced while the latter inhibited active uptake.     

Microtubule-dependent mRNA transport in the model microorganism Ustilago maydis

Microtubule-dependent trafficking is essential in moving mRNAs over long distances. This transport mechanism regulates important cellular events such as determining polarity and local protein secretion. Key examples are developmental and neuronal processes studied in Drosophila melanogaster, Xenopus laevis as well as in mammalian cells. A simple eukaryotic system to uncover basic mechanisms was missing. Fungal models are generally well suited for this purpose, since transgenic strains can be generated easily by homologous recombination allowing in vivo studies at native expression levels. Substantial advances in understanding Ustilago maydis showed that this fungus fulfils important criteria to serve as model for microtubule-dependent mRNA trafficking. Here, we summarize progress focusing on target mRNAs, RNA localization elements, RNA-binding proteins, mRNPs, molecular motors and microtubule organization. This serves as the basis to discuss the novel mechanism of mRNP hitchhiking on endosomes as well as an unexpected link to unconventional secretion with its implications for applied sciences.     

Ustilago maydis, the delightful blight.

Recent studies of the corn smut fungus life cycle and its regulation by two mating type loci and other genes provide a cornucopia of challenges in cell biology, genetics and protein structure. The fungus can exist in two states: nonpathogenic and pathogenic. The change from one state to the other is accompanied by a change in morphology (yeast-like to filamentous) and growth properties (saprophytic to parasitic).     

Gene mutation eliminating antimycin A-tolerant electron transport in Ustilago maydis

A class of mutants of Ustilago maydis selected on a fungitoxic oxathiin lack of antimycin A-tolerant respiratory system which is present in wild-type cells. This system provides, directly or indirectly, for considerable resistance to antimycin A because growth of mutant cells lacking the system is much more sensitive to the antibiotic than that of the wild type. Antimycin A-sensitive O(2) uptake and growth is found in half of the progeny from crosses of mutant to wild type. All antimycin A-sensitive segregants are somewhat more resistant to oxathiins than the antimycin A-resistant segregants. The respiration of the mutant is strongly inhibited by cyanide and azide at concentrations which stimulate respiration of the wild type. Respiration of both mutant and wild type is about equally inhibited by rotenone. It appears that the mutation alters some component of the respiratory system located between the rotenone inhibition site and the antimycin A inhibition site that permits shift of electron transport to an alternate terminal oxidase when the normal electron transport pathway is blocked.     

The a locus governs cytoduction in Ustilago maydis.

We have developed a cytoduction assay to measure cell fusion quantitatively in the basidiomycete corn smut fungus Ustilago maydis. This assay employs a mutation conferring resistance to oligomycin that exhibits non-Mendelian inheritance and presumably affects the mitochondrial genome. After auxotrophic olir cells are mixed with prototrophic olis cells, prototrophic olir cells can be detected at a significant frequency after several hours of incubation, reaching a maximum of 10% of the total prototrophs in the mixture after 18 h. We demonstrate that this cell fusion event occurs only if the mating partners have different alleles of the a mating-type locus and is not influenced by the b locus. These studies support the view that the a locus but not the b locus controls establishment of the filamentous, pathogenic state.     

玉米瘤黑粉菌的遗传交配型

玉米瘤黑粉病是玉米的一种重要病害,普遍分布于世界各玉米产区,我国各地也有不同程度的发生,主要症状是在玉米的茎、叶、雄花、雌穗等部位形成肿瘤［１］。其病原菌为玉米瘤黑粉菌（Ｕｓｔｉｌａｌｇｏ　ｍａｙｄｉｓ）,属于担子菌亚门,异宗配合。在玉米瘤黑粉菌的生活史中,有两种不同形态的细胞,即单倍体细胞（担孢子）和双核菌丝体。单倍体细胞没有致病性,在特定培养基上芽殖产生“酵母”状菌落。不同遗传型的单倍体细胞融合形成双核菌丝,双核菌丝能在寄主植物体内迅速发育,刺激寄主组织形成肿瘤,并继而经过细胞核融合,产生双…     

The secretome of the maize pathogen Ustilago maydis

Ustilago maydis establishes a biotrophic relationship with its host plant, i.e. plant cells stay alive despite massive fungal growth in infected tissue. The genome sequence has revealed that U. maydis is poorly equipped with plant cell wall degrading enzymes and uses novel secreted protein effectors as crucial determinants for biotrophic development. Many of these effector genes are clustered and differentially regulated during plant colonization. In this review, we analyze the secretome of U. maydis by differentiating between secreted enzymes, likely structural proteins of the fungal cell wall (excluding GPI-anchored proteins) as well as likely effectors with either apoplastic or cytoplasmic function. This classification is based on the presence of functional domains, general domain structure and cysteine pattern. In addition, we discuss possible functions of selected protein classes with a special focus on disease development.     

Cloning and disruption of Ustilago maydis genes.

We have demonstrated that genes from Ustilago maydis can be cloned by direct complementation of mutants through the use of genomic libraries made in a high-frequency transformation vector. We isolated a gene involved in amino acid biosynthesis as an illustrative example and showed that integrative and one-step disruption methods can be used to create null mutations in the chromosomal copy of the gene by homologous recombination. The results of this investigation make it clear that one-step gene disruption will be of general utility in investigations of U. maydis, since simple, precise replacement of the sequence under study was readily achieved.     

Pheromones trigger filamentous growth in Ustilago maydis.

Cell recognition and mating in the smut fungus Ustilago maydis have been proposed to involve specific pheromones and pheromone receptors. The respective structural genes are located in the a mating type locus that exists in the alleles a1 and a2. We demonstrate that binding of pheromone to the receptor can induce a morphological switch from yeast-like to filamentous growth in certain strains. Using this as biological assay we were able to purify both the a1 and a2 pheromone. The structure of the secreted pheromones was determined to be 13 amino acids for a1 and nine amino acids for a2. Both pheromones are post-translationally modified by farnesylation and carboxyl methyl esterification of the C-terminal cysteine. An unmodified a1 peptide exhibits dramatically reduced activity. The pheromone alone is able to induce characteristic conjugation tubes in cells of opposite mating type and confers mating competence; even cells of the same mating type undergo fusion. We discuss the role of pheromones in initiating filamentous growth and pathogenic development.     

The homologous recombination system of Ustilago maydis

Homologous recombination is a high fidelity, template-dependent process that is used in repair of damaged DNA, recovery of broken replication forks, and disjunction of homologous chromosomes in meiosis. Much of what is known about recombination genes and mechanisms comes from studies on baker's yeast. Ustilago maydis, a basidiomycete fungus, is distant evolutionarily from baker's yeast and so offers the possibility of gaining insight into recombination from an alternative perspective. Here we have surveyed the genome of U. maydis to determine the composition of its homologous recombination system. Compared to baker's yeast, there are fundamental differences in the function as well as in the repertoire of dedicated components. These include the use of a BRCA2 homolog and its modifier Dss1 rather than Rad52 as a mediator of Rad51, the presence of only a single Rad51 paralog, and the absence of Dmc1 and auxiliary meiotic proteins.     

Endocytosis in the plant-pathogenic fungus Ustilago maydis

Summary. Filamentous fungi are an important group of tip-growing organisms, which include numerous plant pathogens such as Magnaporthe grisea and Ustilago maydis. Despite their ecological and economical relevance, we are just beginning to unravel the importance of endocytosis in filamentous fungi. Most evidence for endocytosis in filamentous fungi is based on the use of endocytic tracer dyes that are taken up into the cell and delivered to the vacuole. Moreover, genomewide screening for candidate genes in Neurospora crassa and U. maydis confirmed the presence of most components of the endocytic machinery, indicating that endocytosis participates in filamentous growth. Indeed, it was shown that in U. maydis early endosomes cluster at sites of growth, where they support morphogenesis and polar growth, most likely via endosome-based membrane recycling. In humans, such recycling processes to the plasma membrane involve small GTPases such as Rab4. A homologue of this protein is encoded in the genome of U. maydis but is absent from the yeast Saccharomyces cerevisiae, suggesting that Rab4-mediated recycling is important for filamentous growth. Furthermore, human Rab4 regulates traffic of early endosomes along microtubules, and a similar microtubule-based transport is described for U. maydis. These observations suggest that Rab4-like GTPases might regulate endosome- and microtubule-based recycling during tip growth of filamentous fungi. Correspondence and reprints: MPI für terrestrische Mikrobiologie, Karl-von-Frisch-Strasse, 35043 Marburg, Federal Republic of Germany.     

The generic position of Ustilago maydis, Ustilago scitaminea, and Ustilago esculenta (Ustilaginales)

Three species of smut fungi (Ustilaginales, Basidiomycota) of economic importance, Ustilago maydis on corn, U. scitaminea on sugar cane, and U. esculenta on Zizania latifolia, were investigated in order to define their systematic position using morphological characteristics of the sori, ultrastructure of teliospore walls, and molecular data of the LSU rDNA. LSU rDNA suggests that U. maydis and U. scitaminea belong to the genus Sporisorium. This has already been proposed for U. scitaminea, which develops sori with whip-shaped axes corresponding to columellae. U. maydis and U. scitaminea, like typical species of Sporisorium, present peridia and columellae in their sori. Therefore, U. scitaminea is called Sporisorium scitamineum. U. maydis, however, is not placed in the genus Sporisorium here, because ongoing investigation of molecular data from the ITS rDNA region yields contradictory results and because the name Sporisorium maydis is occupied by an imperfect fungus. U. esculenta is recognized as Yenia esculenta. This placement in a separate genus is based on molecular data and on unique teliospore ultrastructure, i.e. apically enlarged, partly confluent warts developing on a strongly folded plasmalemma, and the exosporium and endosporium forming part of the ornamentation. Part 193 in the series „Studies in Heterobasidiomycetes“ from the Botanical Institute, University of Tübingen.     

The isolation and properties of a DNA-unwinding protein from Ustilago maydis.

The direction of DNA chain growth in thymine-depleted bacteria was determined by comparing the rate of release of radioactive label by Escherichia coli exonuclease I from pulse-labeled DNA chains to that of uniformly labeled DNA of the same size. Radioactive label was found to be distributed throughout the length of the pulse-labeled DNA, indicating that longer chains arise through the joining of many extremely small polynucleotide chains.     

The physiologic role of alternative oxidase in Ustilago maydis

Alternative oxidase (AOX) is a ubiquitous respiratory enzyme found in plants, fungi, protists and some bacterial species. One of the major questions about this enzyme is related to its metabolic role(s) in cellular physiology, due to its capacity to bypass the proton-pumping cytochrome pathway, and as a consequence it has great energy-wasting potential. In this study, the physiological role and regulatory mechanisms of AOX in the fungal phytopathogen Ustilago maydis were studied. We found evidence for at least two metabolic functions for AOX in this organism, as a major part of the oxidative stress-handling machinery, a well-described issue, and as part of the mechanisms that increase the metabolic plasticity of the cell, a role that might be valuable for organisms exposed to variations in temperature, nutrient source and availability, and biotic or abiotic factors that limit the activity of the cytochrome pathway. Experiments under different culture conditions of ecological significance for this organism revealed that AOX activity is modified by the growth stage of the culture, amino acid availability and growth temperature. In addition, nucleotide content, stimulation of AOX by AMP and respiratory rates obtained after inhibition of the cytochrome pathway showed that fungal/protist AOX is activated under low-energy conditions, in contrast to plant AOX, which is activated under high-energy conditions. An estimation of the contribution of AOX to cell respiration was performed by comparing the steady-state concentration of adenine nucleotides, the mitochondrial membrane potential, and the respiratory rate.     

Initiation of Meiotic Recombination in Ustilago maydis

A central feature of meiosis is the pairing and recombination of homologous chromosomes. Ustilago maydis, a biotrophic fungus that parasitizes maize, has long been utilized as an experimental system for studying recombination, but it has not been clear when in the life cycle meiotic recombination initiates. U. maydis forms dormant diploid teliospores as the end product of the infection process. Upon germination, teliospores complete meiosis to produce four haploid basidiospores. Here we asked whether the meiotic process begins when teliospores germinate or at an earlier stage in development. When teliospores homozygous for a cdc45 mutation temperature sensitive for DNA synthesis were germinated at the restrictive temperature, four nuclei became visible. This implies that teliospores have already undergone premeiotic DNA synthesis and suggests that meiotic recombination initiates at a stage of infection before teliospores mature. Determination of homologous recombination in plant tissue infected with U. maydis strains heteroallelic for the nar1 gene revealed that Nar⁺ recombinants were produced at a stage before teliospore maturation. Teliospores obtained from a spo11Δ cross were still able to germinate but the process was highly disturbed and the meiotic products were imbalanced in chromosomal complement. These results show that in U. maydis, homologous recombination initiates during the infection process and that meiosis can proceed even in the absence of Spo11, but with loss of genomic integrity.     

The pheromone response factor coordinates filamentous growth and pathogenicity in Ustilago maydis.

In Ustilago maydis, the a and b mating type loci regulate cell fusion, filamentous growth and pathogenicity. The a locus encodes a pheromone-based cell recognition system, and the b locus specifies two homeodomain proteins. The expression of all genes in the a and b loci is induced by pheromone. We have identified a HMG protein (Prf1) that binds sequence specifically to pheromone response elements present in the a and b loci. prf1 mutants do not express the a and b genes and are sterile. The disruption of prf1 in pathogenic haploid strains results in a loss of pathogenicity. The constitutive expression of the b genes restores pathogenicity and induces filamentous growth in the absence of the pheromone signal. These results provide evidence that pheromone signalling, filamentous growth and pathogenic development are linked through Prf1.