The sensitive period for light and temperature regulation of sporangiophore development inPhycomyces

Light and temperature markedly influence sporangiophore development inPhycomyces blakesleeanus. Under normal conditions in the dark, low temperature drastically stimulates the production of dwarf sporangiophores (microphorogenesis) and inhibits that of giant sporangiophores (macrophorogenesis). These effects of low temperature could still be observed if applied only for a short period before sporangiophore initiation. Continuous white illumination strongly inhibits microphorogenesis and slightly stimulates macrophorogenesis. Short exposures to white light noticeably inhibit microphorogenesis and stimulate macrophorogenesis when given to mycelia grown for between 90 and 160 h at 14° C or 150 h or more at 10° C. These results indicate the existence in the mycelium of developmental stages for the regulation of sporangiophorogenesis by environmental signals.     

Transformation of Mucor circinelloides with Autoreplicative Vectors Containing Homologous and Heterologous ARS Elements and the Dominant Cbx r Carboxine-Resistance Gene

Mucor circinelloides transformants prototrophic to leucine and resistant to carboxine (Leu⁺ Cbx^r) have been obtained by treatment of protoplasts with plasmid constructs containing homologous leuA gene and adjacent autonomously replicating sequences (ARS) element combined with the Cbx^r(carboxine-resistance) gene of Ustilago maydis and ARS sequences from this basidiomycete (plasmid pGG37) or from the 2 μ plasmid of Saccharomyces cerevisiae (plasmid pGG43). The presence in the same plasmid molecule of the M. circinelloides leuA gene and adjacent ARS element together with heterologous ARS elements produced an increase in the transformation frequency of about 65–120%. The presence of autoreplicating plasmid molecules in the transformants was demonstrated by mitotic stability experiments, by Southern analysis, and by the rescue of plasmids from transformed bacterial cells.     

Nikkomycin-resistant mutants ofMucor rouxii: physiological and biochemical properties

We isolated three nikkomycin-resistant mutants of the dimorphic fungusM. rouxii which were physiologically characterized regarding their response to yeast-phase inducing conditions and their sensitivity to bacilysin. Mutant strains G21 and G23, showed a qualitatively normal, though delayed, dimorphic transition and partial cross-resistance to bacilysin. Mutant strain G27 showed an altered dimorphism, producing a high proportion (50%) of hyphal cells, and a wild-type sensitivity to bacilysin. Cell-free extracts from this mutant exhibited an activity of both basal and protease-activated chitin synthetase which was overexpressed as compared with the parental strain and mutants G21 and G23. Results are discussed in terms of the different genetic background of the mutants.Abbreviations NTG N-methyl-N-nitro-N-nitrosoguanidine - UDP-GlcNAc uridine 5-diphospho-N-acetylglucosamine - GlcNAc N-acetylglucosamine     

Chitin synthetase activity in a developmental mutant of Phycomyces blakesleeanus

Chitin synthetase activity was analyzed in vitro and in vivo in two morphogenetic stages, namely, dormant spore cells and germlings of the wild type strain and the developmental mutant S356 of Phycomyces blakesleeanus. In vitro experiments showed a much higher specific activity in dormant spores of the mutant strain than in those of the wild-type. This difference was restricted to the dormant spore phase since germlings exhibited comparable levels of activity to those detected in the wild-type strain. Although no correlation was observed between chitin synthesis in vitro and in vivo in mutant spores, germination of these cells was accompanied by an earlier expression of chitin synthetase in vivo. Germination of mutant spores in liquid medium produced morphologically aberrant germlings. Contrary to the extended mycelial growth of the wild-type strain in solid medium, the mutant grew with a typical colonial morphology. Results are discussed in relation to the possible basis of the mutant phenotype.     

Altered expression of chitin synthetase activity and biochemical changes in the cell wall in a developmental mutant ofPhycomyces

The Phycomyces developmental mutant S356 elaborates spores which show a much poorer viability and a higher affinity for Calcofluor White than the wild-type spores. Protease-activated extracts of the mutant spores showed higher levels of chitin synthetase activity than the parental strain-derived spores. High levels of enzyme activity in the mutant extracts, but not in the corresponding wild-type extracts, could be detected in the absence of an exogenous protease. The high basal active chitin synthetase is not the result of activation by endogeneous proteases during cell breakage since protease inhibitors did not reduce, but rather increased, the activity levels. The analysis of cell wall composition in the mutant spores revealed significant changes in the proportion of uronic acids and protein but not in chitin. The mutant phenotype is discussed in relation to the developmental stage at which the alterations connected with cell wall metabolism occurred.     

Copper resistance mechanisms in bacteria and fungi

Abstract: Copper is both an essential micronutrient and a toxic heavy metal for most living cells. The presence of high concentrations of cupric ions in the environment promotes the selection of microorganisms possessing genetic determinants for copper resistance. Several examples of chromosomal and plasmid copper-resistance systems in bacteria have been reported, and the mechanisms of resistance have started to be understood at the molecular level. Bacterial mechanisms of copper resistance are related to reduced copper transport, enhanced effiux of cupric ions, or copper complexation by cell components. Copper tolerance in fungi has also been ascribed to diverse mechanisms involving trapping of the metal by cell-wall components, altered uptake of copper, extracellular chelation or precipitation by secreted metabolites, and intracellular complexing by metallothioneins and phytochelatins; only the metallothionein chelation mechanism has been approached with molecular detail.