Cyanide-resistant respiration of a Neurospora crassa membrane mutant

Mitochondrial biogenesis during fungal spore germination: respiration and cytochrome c oxidase in Neurospora crassa

The germination of conidiospores of wild-type Neurospora crassa was found to be dependent upon the function of the cytochrome-mediated electron transport pathway. The cyanide-insensitive alternate oxidase did not contribute significantly to the respiration of these germinating spores. The dormant spores contained all of the cytochrome components and a catalytically active cytochrome c oxidase required for the activity of the standard respiratory pathway, and these preserved components were responsible for the accelerating rates of oxygen uptake which began immediately upon suspension of the spores in an incubation medium. Mitochondria of the dormant spores contained all of the subunit peptides of the functional cytochrome c oxidase; nevertheless, de novo synthesis of these subunits began at low rates in the first stages of germination. Reactivation of the respiratory system of germinating N. crassa spores seems not to be dependent initially upon the function of either the mitochondrial or cytoplasmic protein-synthesizing systems. The respiratory activity of spores of three mutant cytochrome c oxidase-deficient strains of N. crassa also was found to depend upon the function of the cytochrome electron transport pathway; the dormant and germinating spores of these strains contained a catalytically active cytochrome c oxidase. Cytochrome c oxidase may be present in the dormant and germinating spores of these strains as the result of a developmental-phase-specific synthesis of and requirement for the enzyme.

Nuclear mutants of Neurospora crassa temperature-sensitive for the synthesis of cytochrome aa3. Mitochondrial protein synthesis and analysis of the polypeptide composition of cytochrome c oxidase

Three previously isolated mutants of Neurospora crassa, temperature-sensitive for the production of cytochrome aa3, have been further analyzed. These mutants have a slightly reduced capacity for mitochondrial protein synthesis when grown at 41 degrees C, although this relative deficiency appeared to be no greater than the deficiency in other cytochrome-aa3-deficient mutants. Thermolability studies revealed that the cytochrome c oxidase purified from each of the mutants grown at 23 degrees C is no more sensitive to heat inactivation than the enzyme isolated from wild-type cells. Sodium dodecylsulfate gel electrophoresis of immunoprecipitates obtained from the mitochondria of each of the mutants grown at 23 degrees C, using antiserum directed against holocytochrome c oxidase, indicated that all the subunits of cytochrome c oxidase were present in relative amounts similar to those found in mitochondria from wild-type cultures. However, when the mitochondria from mutant cultures grown at 41 degrees C were examined in the above fashion, only subunits 5 and 6 of the oxidase were detected. Nonetheless, the mitochondrially synthesized subunit 1, 2 and 3 polypeptides could be immunoprecipitated from mitochondria isolated from mutant cells grown at 41 degrees C and labelled with [3H]leucine in medium containing cycloheximide. Although subunits 4 and 7 could not be detected, because a suitable antibody was not available, the fact that five of the seven subunits were present, but not associated with each other, suggested that the genetic defects in these mutants may affect the process of cytochrome c oxidase assembly.

The effect of phosphatidylcholine depletion on biochemical and physical properties of a Neurospora crassa membrane mutant

By using the choline starvation process it is possible to deplete the membranes of Neurospora crassa choline auxotroph chol-1 of phosphatidylcholine, without affecting the viability of germinated spores or whole mycelium. Spin label probes were used to examine the possible dependence of the physical state of cellular lipids on the presence of phosphatidylcholine in the membranes. Increased freedom of rotational motion of lipid soluble probes was regularly detected in choline-starved mycelium. The accumulation of neutral lipids (mostly triglycerides) in bulk form was also observed during the choline starvation process. The experiments with isolated and separated lipid classes indicated that the observed increase in fluidity of lipids in choline-starved mycelium is partly due to the difference in physical properties between bulk lipids and membrane lipids. Spin label probe 2N4 (2-propyl-2,5,5-trimethyloxazolidine-N-oxyl), which can partition at the membrane-water interface, exhibited easier partitioning among membrane lipids of choline-starved mycelium.

Spectral and metabolic characteristics of mitochondrial fractions from rotenone-induced tumours

Mitochondrial fractions isolated from tumours induced with the respiratory inhibitor rotenone lack respiratory control, oxidative phosphorylation, are partially or totally insensitive to cyanide and have a near-normal content of respiratory carriers. These characteristics are more similar to those of mitochondria from atrophic mammary gland than to those of mitochondria from spontaneous mammary adenomas. Thus, the characteristic structural and biochemical mitochondrial alteration of rotenone-induced tumours would represent a lack of mitochondrial differentiation as the tumour develops from the atrophic mammary gland. Slices of rotenone-induced tumours are insensitive to oligomycin and dinitrophenol, thus indicating that glycolysis would be their sole source of metabolic energy.

Lecithin requirement for the sporulation process in Neurospora crassa

Reversible inhibition of conidiogenesis occurred when lecithin was depleted from Neurospora membranes by choline starvation.