Isolation and characterization of microbodies and symphyomicrobodies with different buoyant densities from the fungus Blastocladiella emersonii

An electron microscopical study of the development of peroxisomes during formation and germination of ascospores in the methylotrophic yeast Hansenula polymorpha

Ascospore formation was studied in liquid cultures of the yeast Hansenula polymorpha, previously grown under conditions in which the synthesis of alcohol oxidase was repressed (glucose as growth substrate) or derepressed (methanol, glycerol and dihydroxyacetone as growth substrates and after growth on malt agar plates). In ascospores obtained from repressed cells, generally one small peroxisome was present. The organelle probably originated from the small peroxisome, originally present in the vegetative cells. They had no crystalline inclusions and cytochemical experiments indicated the presence of catalase, urate oxidase and amino acid oxidase activities in these organelles. In ascospores obtained from derepressed cells, generally 1--3 crystalline peroxisomes were observed. These organelles also originated from the peroxisomes originally present in the vegetative cells by means of fragmentation or division. They contained, in addition to the enzymes characteristic for peroxisomes in spores from repressed cells, also alcohol oxidase. The latter enzyme is probably responsible for the crystalline substructure of these peroxisomes. Peroxisomes had no apparent physiological function in the process of ascosporogenesis. A glyoxysomal function of the organelles during germination of the ascospores was also not observed. Germination of mature ascospores in media containing different sources of carbon and nitrogen showed that the function of the peroxisomes present in ascospores of Hansenula polymorpha is probably identical to that in vegetative haploid cells. They are involved in the oxidative metabolism of different carbon and nitrogen sources. Their enzyme profile is a reflection of that peroxisomes of vegetative cells and their presence may enable the formation of cells which are optimally adapted to environmental conditions extant during spore germination.

Phylogenetic implications of the microbody-lipid globule complex in zoosporic fungi

Chytridiomycetous fungal zoospores contain a unique and intricate association of organelles, the 'microbody-lipid globule complex' (MLC). The spatial arrangement of organelles in the MLC appears important in the utilization of lipid globules for energy, but in addition, the structural association of organelles in the MLC reveals phylogenetic trends within this diverse group of organisms. Variations in the structure of the MLC correlate well with current phylogenetic concepts of aquatic fungi, yet suggest new relationships among these posteriorly uniflagellate zoospores. Based upon the organization of organelles in the MLC, 4 basic patterns of MLCs can be recognized, and these correspond to the 4 orders of Chytridiomycetes. The MLC in its simplest form consists of a microbody appressed to the edge of a lipid globule. In more highly organized MLCs, mitochondria subtend the microbody and a cisterna surmounts one side of the lipid globule. The organization and structure is still more complex in other MLCs where ER is elaborated into a tubular network of membranes or where small microbodies or mitochondria fuse into 'giant' organelles. The structural organization of the MLC provides an additional criterion by which the phylogeny of awuatic fungi can be evaluated.

Isolation and characterization of lipid globules from the zoospores of Blastocladiella emersonii

Lipid globules were isolated and characterized both chemically and morphologically. They were composed mainly of triglyceride and free sterol, which accounted for over 90% of the total globule content. Smaller amounts of diglyceride, carotenoid, free fatty acid, phospholipid and protein were found. No sterol esters or monoglycerides were detected. Morphologically, the isolated lipid globules resembled the lipid globules in situ. They were spherical, 0.4-1.5 mum in diameter and lacked a trilaminar membrane.

Variation in levels of enzymes related to energy metabolism in alternative developmental pathways of Blastocladiella emersonii

The activities of phosphofructokinase (PFK), fructose diphosphatase (FDP), nicotinamide adenine dinucleotide (NAD) and NAD phosphate (NADP)-linked isocitrate dehydrogenases (IDHNAD, IDHNADP), two NAD-linked glutamate dehydrogenases (GDH1, GDH2), and isocitrate lyase were studied during the development of the two phenotypes, ordinary colorless and resistant sporangia (OC and RS plants), of water mold Blastocladiella emersonii in synchronized liquid cultures. The OC plants had a generation time of about 12 h, whereas the RS plants required 3.5 days to reach maturity. All the enzymes were present throughout the development of both phenotypes. In zoospores, PFK, FDP, and GDH2 were localized in the cytosol. The IDHNADP activity was distributed with two-thirds in the soluble and one-third in the particulate fraction. GDH1 and IDHNAD showed the same distribution and were predominantly present in the particulate fraction, presumably in the mitochondria. Isocitrate lyase was found in the particulate fraction. The enzyme levels changed considerably during development. FDP and IDHNADP varied in a parallel manner. Similarly, the three enzymes PFK, IDHNAD and GDH1 showed parallel variations. The activity patterns for all enzymes were different for the OC and RS pathways. Isocitrate lyase exhibited the largest changes in activity during development. Thus, during OC plant formation, its activity decreased by a factor of 20. GDH2 varied similarly to PFK and IDHNADP during OC plant development, whereas it behaved like isocitrate lyase during RS plant development. The ratios between anabolic and catabolic enzymes were higher in mature plants than in zoospores and higher in RS plants than in OC plants. The results indicate that the variations in the enzyme levels are secondary to the critical changes involved in the transition from one developmental pathway to the other.

Distribution of glyoxylate-cycle enzymes between microbodies and mitochondria in Aspergillus tamarii

The distribution of glyoxylate-cycle enzymes between microbodies and mitochondria was examined in ethanol-grown Aspergillus tamarii Kita. Particulate activities of catalase and the two glyoxylate by-pass enzymes, malate synthase and isocitrate lyase, were localized in the microbodies. The microbodies had a buoyant density of about 1.23 g cm(-3) after isopycnic centrifugation in linear sucrose gradients. Particulate activities of the other two glyoxycitrate synthase, together with that of succinate dehydrogenase were restricted to the mitochondria, which had a buoyant density of about 1.20 g cm(-3). Catalase also appeared to be localized in a second particle, perhaps the microbody inclusions or the Woronin bodies, having a buoyant density of about 1.26 g cm(-3).