Biochemistry of dimorphism in the fungus Mucor

Alteration of Fermentative Metabolism Enhances Mucor circinelloides Virulence

The fungus Mucor circinelloides undergoes yeast-mold dimorphism, a developmental process associated with its capability as a human opportunistic pathogen. Dimorphism is strongly influenced by carbon metabolism, and hence the type of metabolism likely affects fungus virulence. We investigated the role of ethanol metabolism in M. circinelloides virulence. A mutant in the adh1 gene (M5 strain) exhibited higher virulence than the wild-type (R7B) and the complemented (M5/pEUKA-adh1 ⁺) strains, which were nonvirulent when tested in a mouse infection model. Cell-free culture supernatant (SS) from the M5 mutant showed increased toxic effect on nematodes compared to that from R7B and M5/pEUKA-adh1 ⁺ strains. The concentration of acetaldehyde excreted by strain M5 in the SS was higher than that from R7B, which correlated with the acute toxic effect on nematodes. Remarkably, strain M5 showed higher resistance to H₂O₂, resistance to phagocytosis, and invasiveness in mouse tissues and induced an enhanced systemic inflammatory response compared with R7B. The mice infected with strain M5 under disulfiram treatment exhibited only half the life expectancy of those infected with M5 alone, suggesting that acetaldehyde produced by M. circinelloides contributes to the toxic effect in mice. These results demonstrate that the failure in fermentative metabolism, in the step of the production of ethanol in M. circinelloides, contributes to its virulence, inducing a more severe tissue burden and inflammatory response in mice as a consequence of acetaldehyde overproduction.

Molecular analysis of an NAD-dependent alcohol dehydrogenase from the zygomycete Mucor circinelloides

NAD-dependent alcohol dehydrogenase (ADH) activity was detected mainly in the cytosol of aerobically cultured mycelium and in anaerobically grown yeast cells of Mucor circinelloides. ADH levels were about 2.5-fold higher in yeast cells than in mycelium; zymogram analysis suggested that the same ADH enzyme is produced in both developmental stages. The enzyme, named ADH1, was purified to homogeneity from yeast cells, using ion-exchange and affinity chromatography. The active ADH1 appears to be a homomeric tetramer of 37,500-kDa subunits. Km values obtained for acetaldehyde, ethanol, NADH and NAD+ indicated that in vivo the enzyme mainly serves to reduce acetaldehyde to ethanol. Amino acid sequences of internal peptides obtained from the purified ADH1 were used to design oligonucleotides that allowed the cloning of the corresponding cDNA by RT-PCR, and the characterization of the genomic DNA sequence. The adh1 ORF is interrupted by two small introns located towards the 5'-end. M. circinelloides adh1 encodes a protein of 348 amino acids, which display moderate to high overall identity to several hypothetical ADH enzymes from the related zygomycete Rhizopus oryzae. adh1 mRNA is expressed at similar levels in aerobic mycelium and anaerobic yeast cells. During exponential growth under aerobic conditions, the level of adh1 transcript was correlated with the glucose concentration in the growth medium.

Metabolic engineering of the morphology of Aspergillus

The morphology of filamentous organisms in submerged cultivation is a subject of considerable interest, notably due to the influence of morphology on process productivity. The relationship between process parameters and morphology is complex: the interactions between process variables, productivity, rheology, and macro- and micro-morphology create difficulties in defining and separating cause and effect. Additionally, organism physiology contributes a further level of complexity which means that the desired morphology (for optimum process performance and productivity) is likely to be process specific. However, a number of studies with increasingly powerful image analysis systems have yielded valuable information on what these desirable morphologies are likely to be. In parallel, studies on a variety of morphological mutants means that information on the genes involved in morphology is beginning to emerge. Indeed, we are now beginning to understand how morphology may be controlled at the molecular level. Coupling this knowledge with the tools of molecular biology means that it is now possible to design and engineer the morphology of organisms for specific bioprocesses. Tailor making strains with defined morphologies represents a clear advantage in optimization of submerged bioprocesses with filamentous organisms.

Gene expression inMucordimorphism

An ongoing dialectic has concerned the relative importance of differential gene expression versus the pattern of new wall deposition in Mucor dimorphism. Numerous physiological processes and enzyme activities have been observed in flux during morphogenesis, but a causal link to dimorphism has been infrequently demonstrated. Very few of the proteins that are conspicuous in two-dimensional polyacrylamide gel electrophoresis are specific to cell morphology or significantly change in amount during morphogenesis. Cyclic AMP, putrescine, S-adenosylmethionine, and enzymes governing their intracellular concentrations show patterns of change that consistently correlate with morphogenesis. The expression of RAS proteins and translation elongation factor-1α activity during morphogenesis are regulated at the level of transcription and post-translational methylation, respectively. Wall chemistry is very similar in both morphologies, but wall deposition is isodiametric in yeasts and vectorial in hyphae. Electron microscopy shows patterns of apparent exocytosis that are generalized in the former and apical in the latter. Research on other dimorphic fungi, including Saccharomyces cerevisiae, suggests an involvement of cytoskeletal proteins and a family of GTP-linked protein kinases in directing polar growth. Some of these elements, which may be controlled quite distal from the genes encoding them, have been demonstrated in Mucor spp., while others are the subject of ongoing investigations. Key words: Mucor, dimorphism, morphogenesis, gene expression, yeasts, hyphae.

Genetic evidence for independence between fermentative metabolism (ethanol accumulation) and yeast-cell development in the dimorphic fungus Mucor rouxii

Three allyl-alcohol-resistant mutants were isolated in the dimorphic fungus Mucor rouxii and characterized with regard to their alcohol dehydrogenase (ADH) activity in vitro and in vivo as well as their ability to execute the morphological alternatives of dimorphism under different environmental stimuli, either in the absence or in the presence of oxygen. These studies indicated that fermentation and yeast-cell development are independent events and that ADH activity is essential for growth of the fungus in the absence of oxygen. Heterokaryon construction and analysis indicated that in the three mutant strains the corresponding genetic alterations are recessive nuclear mutations which behave as allelic in complementation tests.

Purification and characterization of a developmentally regulated carboxypeptidase from Mucor racemosus

A developmentally regulated carboxypeptidase was purified from hyphae of the dimorphic fungus Mucor racemosus. The enzyme, designated carboxypeptidase 3 (CP3), has been purified greater than 900-fold to homogeneity and characterized. The carboxypeptidase migrated as a single electrophoretic band in isoelectric focusing polyacrylamide gel electrophoresis (PAGE), with an isoelectric point of pH 4.4. The apparent molecular mass of the native enzyme was estimated by gel filtration to be 52 kDa. Sodium dodecyl sulfate (SDS)-PAGE under nonreducing conditions revealed the presence of a single polypeptide of 51 kDa. SDS-PAGE of CP3 reacted with 2-mercaptoethanol revealed the presence of two polypeptides of 31 and 18 kDa, indicating a dimer structure (alpha 1 beta 1) of the enzyme with disulfide-linked subunits. By using [1,3-3H]diisopropylfluorophosphate as an active-site labeling reagent, it was determined that the catalytic site resides on the small subunit of the carboxypeptidase. With N-carboben zoxy-L-phenylalanyl-L-leucine (N-CBZ-Phe-Leu) as the substrate, the Km, kcat, and Vmax values were 1.7 x 10(-4) M, 490 s-1, and 588 mumol of Leu released per min per mg of protein, respectively. CP3 was determined to be a serine protease, since its catalytic activity was blocked by the serine protease inhibitors diisopropylfluorophosphate, phenylmethylsulfonyl fluoride, and 3,4-dichloroi Socoumarin (DCI). The enzyme was strongly inhibited by the mercurial compound p-chloromercuribenzoate. The carboxypeptidase readily hydrolyzed peptides with aliphatic or aromatic side chains, whereas most of the peptides which contained glycine in the penultimate position did not serve as substrates for the enzyme. Although CP3 activity was undetectable in Mucor yeast cells, antisera revealed the presence of the enzyme in the yeast form of the fungus. The partial amino acid sequence of the carboxypeptidase was determined.

Mucor dimorphism

Mucor dimorphism has interested microbiologists since the time of Pasteur. When deprived of oxygen, these fungi grow as spherical, multipolar budding yeasts. In the presence of oxygen, they propagate as branching coenocytic hyphae. The ease with which these morphologies can be manipulated in the laboratory, the diverse array of morphopoietic agents available, and the alternative developmental fates that can be elicited from a single cell type (the sporangiospore) make Mucor spp. a highly propitious system in which to study eukaryotic cellular morphogenesis. The composition and organization of the cell wall differ greatly in Mucor yeasts and hyphae. The deposition of new wall polymers is isodiametric in yeasts and apically polarized in hyphae. Current research has focused on the identity and control of enzymes participating in wall synthesis. An understanding of how the chitosome interacts with appropriate effectors, specific enzymes, and the plasma membrane to assemble chitin-chitosan microfibrils and to deposit them at the proper sites on the cell exterior will be critical to elucidating dimorphism. Several biochemical and physiological parameters have been reported to fluctuate in a manner that correlates with Mucor morphogenesis. The literature describing these has been reviewed critically with the intent of distinguishing between causal and casual connections. The advancement of molecular genetics has afforded powerful new tools that researchers have begun to exploit in the study of Mucor dimorphism. Several genes, some encoding products known to correlate with development in Mucor spp. or other fungi, have been cloned, sequenced, and examined for transcriptional activity during morphogenesis. Most have appeared in multiple copies displaying independent transcriptional control. Selective translation of stored mRNA molecules occurs during sporangiospore germination. Many other correlates of Mucor morphogenesis, presently described but not yet explained, should prove amenable to analysis by the emerging molecular technology.

Dimorphism of Benjaminiella poitrasii: isolation and biochemical studies of morphological mutants

The yeast-mycelium dimorphism of the genus Benjaminiella poitrasii has been investigated. To understand the mechanism of dimorphism two stable yeast-phase mutants (Y-1 & Y-2) and one slow growing mycelial mutant (M-1) of B. poitrasii were isolated after NTG treatment of parent strain spores and studied for their biochemical characteristics. Effects of (i) kind and concentration of carbon source, (ii) presence of complex organic nitrogen and (iii) C:N ratio in the growth medium on the morphology of parent and mutant strains were carried out at 28 degrees C under shaking conditions. Ethanol induced morphological change and its reversal were studied in all the strains in order to elucidate the possible mechanism of morphogenesis.

DNA methylation and polyamines in regulation of development of the fungus Mucor rouxii

DNA from intact or spherically growing spores of Mucor rouxii is highly methylated, whereas DNA from germlings has low levels of methylation. DNA from spores incubated with hydroxyurea or 1,4-diaminobutanone is also highly methylated. The reversal of the effect of 1,4-diaminobutanone by azacytidine correlated with DNA hypomethylation. These data suggest that the change in growth pattern from spherical to polarized correlates with the degree of DNA methylation and that this, in turn, may be controlled by polyamine levels.

Effect of L-amino acids on Mucor rouxii dimorphism

Mucor rouxii organisms growing aerobically and exponentially on a well-defined minimal medium are able to differentiate as yeasts or as mycelia, depending on the amino acid as the nitrogen source. When certain amino acids were used as the nitrogen source, spores differentiated only as hyphae, whereas other amino acids gave rise to other morphological forms having different ratios of yeasts to hyphae. In both hyphal and yeast cultures, an aerobic metabolism was predominant, as shown by determining several metabolic parameters such as oxygen tension, glucose consumption, ethanol production, and CO2 release. A complete conversion of yeasts to hyphae was obtained by the appropriate change in the amino acid used as nitrogen source. By preparing spheroplasts from mycelial cultures and transferring them to media with amino acids that induce yeast formation, a 50% yield in the reverse transformation was achieved. A correlation between the change in pH of the medium and cell morphology was observed in different growth conditions. Decrease in the pH of the medium preceded the appearance of hyphae. Also, when the initial pH of the medium was increased, aspartate-containing cultures developed mainly as mycelia, instead of yeasts, with a corresponding decrease in the final pH.

Effect of oxygen on morphogenesis and polypeptide expression by Mucor racemosus

The morphology of Mucor racemosus in cultures continuously sparged with nitrogen gas was investigated. When appropriate precautions were taken to prevent oxygen from entering the cultures, the morphology of the cells was uniformly yeastlike irrespective of the N2 flow rate. When small amounts of oxygen entered the cultures the resulting microaerobic conditions evoked mycelial development. Polypeptides synthesized by aerobic mycelia, microaerobic mycelia, anaerobic yeasts, and yeasts grown in a CO2 atmosphere were compared by two-dimensional gel electrophoresis. The results indicated that a large number of differences in polypeptide expression exist when microaerobic mycelia or anaerobic yeasts are compared with aerobic mycelia and that these alterations correlate with a change from an oxidative to a fermentative metabolic mode. Relatively few differences in polypeptide composition exist when microaerobic cells are compared with anaerobic cells, but these changes correlate with a change from the mycelial to the yeast morphology. We hypothesize that oxygen regulates the expression of polypeptides involved in both the metabolic mode and in morphogenesis.

Respiratory-competent conditional developmental mutant of Mucor racemosus

A conditional developmental mutant of Mucor racemosus which is capable of oxidative energy metabolism is described. Unlike the wild-type strain the mutant was highly fermentative and exhibited the yeast morphology when grown aerobically in glucose-containing media. The high fermentative activity and yeast morphology under these conditions correlated well with maximal expression of glycolytic enzymes and with expression of some polypeptides characteristic of anaerobic growth. Aerobic growth of the mutant on amino acids as the sole carbon source resulted in growth in the mycelial morphology. The mutant was fully capable of oxidative metabolism as judged by its ability to grow on amino acids, respiratory capacity, and complement of tricarboxylic acid cycle enzymes. The results support the hypothesis that oxygen controls both the expression of glycolytic enzymes and the expression of proteins involved in morphogenesis. Moreover, they suggest that there are common regulatory elements in the control of these two classes of gene products. Abnormally high levels of aconitase and isocitrate dehydrogenase in the mutant are consistent with the proposal that pool sizes of citrate may act as a regulator of genes responsive to environmental oxygen concentration.

Molecular and cellular events during the yeast to mycelium transition in Sporothrix schenckii

Unbudded singlets from exponentially growing yeast cells of Sporothrix schenckii were harvested, selected by filtration and allowed to form germ tubes in a basal medium with glucose at pH 4.0 and 25 degrees C. These conditions supported only the development of the mycelial form of S. schenckii in a reproducible manner which allowed further analysis of the early cellular events occurring during the yeast-to-mycelium transition. The relationship between macromolecular synthesis (DNA and RNA synthesis) and nuclear division, hyphal growth and septum formation were investigated during germ tube formation. RNA synthesis started 0 to 3 h after the induction of germ tube formation, followed by DNA synthesis and the first nuclear division, which took place between 3 and 6 h. Germ tube formation followed nuclear division and was first evidenced 6 h after the induction of germ tube formation, but was not completed until 12 h after inoculation. Septation was first observed in these germ tubes at the mother cell-germ tube junction 6 h after induction. Addition of hydroxyurea, an inhibitor of DNA synthesis, to the medium, also inhibited nuclear division and germ tube growth, suggesting that these processes in S. schenckii are dependent upon DNA synthesis.

Ca(II)-calmodulin regulation of fungal dimorphism in Ceratocystis ulmi

We have shown that Ca(II) ions, ethylene glycol-bis(beta-aminoethyl ether)-N,N-tetraacetic acid, LaCl3, and six known calmodulin inhibitors shift the yeast-mycelium dimorphic potential of Ceratocystis ulmi. Our data are consistent with the conclusions that Ca(II)-calmodulin interaction is necessary for mycelial growth in C. ulmi and that the absence of this interaction leads to the yeast phase.

The control of morphogenesis in Candida albicans

Morphogenesis (germ-tube formation) in Candida albicans was induced gratuitously by N-acetylhexosamine derivatives (N-acetyl-glucosamine covalently linked to agarose, N-acetylmannosamine, hyaluronic acid, colloidal chitin, and mucin). These compounds were not taken up by the yeast cells and did not support growth. 2-Deoxyglucose was a potent inhibitor of germ-tube formation (50 microM), but did not affect the yeast growth yield at a concentration of 2.5 mM. 2-Deoxyglucose covalently linked to agarose did not affect germ-tube formation, and the inhibition by free 2-deoxyglucose was overcome by the addition of glucose to the germ-tube-forming cells. Glucose competitively inhibited 2-deoxyglucose uptake (Ki = 0.14 mM), and these data indicate that 2-deoxyglucose acted intracellularly.

Isolation and biochemical analysis of Mucor bacilliformis monomorphic mutants

Fourteen stable mutants of Mucor bacilliformis which grew yeastlike under both aerobic and anaerobic conditions were isolated after treatment of growing mycelium with N-methyl-N'-nitro-N-nitrosoguanidine. Biochemical characterization of the mutants included determination of growth in different carbon and nitrogen sources, determination of sensitivity of respiration to cyanide and salicylhydroxamate, analysis of cytochrome spectra, determination of glutamate dehydrogenases, glutamine synthase, and ornithine decarboxylase activities, and measurement of cyclic AMP levels. Data showed that all mutants were defective in some aspect of oxidative metabolism and had low levels of ornithine decarboxylase, whereas other characters were variable. It was concluded that morphological transition in M. bacilliformis is probably associated with mitochondrial functions and expression of ornithine decarboxylase, but may be independent of cyclic AMP and glutamate dehydrogenase levels. The importance of genetic studies in the analysis of dimorphism is stressed.

Relationship of internal cyclic AMP levels, rates of protein synthesis and mucor dimorphism

Changes in the intracellular pools of cyclic AMP and specific rates of protein synthesis have been described as correlates of the yeast-to-hypha conversion in Mucor racemosis. A further examination of the relationship between these physiological parameters and the cellular morphogenesis was conducted in the present study. The levels of intracellular cyclic AMP consistently varied as a function of the cell morphology rather than the CO2 tension, oxygen tension or growth rate. The specific rate of protein synthesis failed to change during a N2-to-air-induced yeast-to-hypha transition. Previously reported changes in this parameter during CO2-to-air- and CO2-to-N2-induced yeast-to-hypha shifts may be a consequence of growth rate changes rather than development per se.

Differential synthesis of polypeptides during morphogenesis of Mucor

The extent of differential gene expression during morphogenesis of Mucor racemosus was investigated by two-dimensional polyacrylamide gel electrophoresis of neutral and acidic polypeptides. Cellular proteins were labeled with [35S]methionine in cells growing in either the yeast or hyphal form, or in yeast cells undergoing the transition of hyphae. The results showed that of the 400 to 500 polypeptides resolved by electrophoresis, relatively few were specific to one or the other morphological form. The major change in the patterns of proteins synthesized during morphogenesis was a change in rates of synthesis of individual polypeptides. Experiments in which morphogenesis was affected under aerobic or anaerobic conditions showed that the majority of changes in the protein patterns were associated with morphogenesis and were not a specific response to O2.

High-frequency heterokaryon formation by Mucor racemosus

Heterokaryons from Mucor racemosus were produced from two auxotrophic strains of the fungus. Germlings were converted to spheroplasts by using commercial chitinase and purified Myxobacter AL-1 chitosanase. Spheroplasts from the auxotrophic strains were mixed and fused in solutions of polyethylene glycol and CaCl2. Under optimal conditions, prototrophic heterokaryons were formed at a frequency of about 5%.