Neosartorya udagawae (Aspergillus udagawae), an emerging agent of aspergillosis: how different is it from Aspergillus fumigatus?

A recent report on several cases of invasive aspergillosis caused by Neosartorya udagawae suggested distinctive patterns of disease progression between N. udagawae and Aspergillus fumigatus. This prompted us to characterize N. udagawae in comparison to A. fumigatus. Our findings showed that both species exist in two mating types at similar ratios and produce gliotoxin. However, the thermotolerance of the two species differs: while A. fumigatus is able to grow at 55 degrees C but not at 10 degrees C, N. udagawae is able to grow at 10 degrees C but fails to grow at >42 degrees C. Furthermore, compared to A. fumigatus, the conidia of N. udagawae require longer incubation periods to germinate at 37 degrees C and are more susceptible to neutrophil attack as well as hydrogen peroxide; N. udagawae is also less virulent in gp91(phox-/-) mice. These findings suggest that growth and susceptibility to the host response might account for the reduced virulence of N. udagawae and the subtle distinction in the progression of the disease caused by the two species.

Plasma Membrane Sterols Are Essential for Sensing Osmotic Changes in the Halotolerant Alga Dunaliella.

The halotolerant alga Dunaliella responds to hyperosmotic stress by synthesis of massive amounts of glycerol. The trigger for this osmotic response is the change in cell volume, but the mechanism that senses volume changes is not known. Preincubation of Dunaliella salina with tridemorph, a specific inhibitor of sterol biosynthesis, inhibits glycerol synthesis and volume recovery. The inhibition is associated with suppression of [14C]bicarbonate incorporation into sterols and is correlated with pronounced depletion of plasma membrane sterols. Incubation of sterol-depleted cells with cholesterol hemisuccinate restores the capacity for volume regulation in response to hyperosmotic stress. Tridemorph as well as lovastatin also inhibit volume changes that are induced by high light in Dunaliella bardawil, a species that responds to high light intensity by synthesis of large amounts of [beta]-carotene. These volume changes result from accumulation of glycerol and are associated with de novo synthesis of sterols. The major plasma membrane sterol in D. salina and the high-light-induced sterol in D. bardawil co-migrate with ergosterol on thin-layer chromatography and on reversed-phase high-performance liquid chromatography. These results suggest that the osmosensory mechanism in Dunaliella resides in the plasma membrane, and that sterols have an important role in sensing osmotic changes.

Capillary and mitochondrial support of neural plasticity in adult rat visual cortex.

Young adult rats (60 days old) were placed in complex environments (EC) or kept in individual cages (IC) for 10, 30, or 60 days. Previously reported findings in these same animals of synaptogenesis, decreased neuronal density, and increased cortical thickness in the EC animals demonstrated that cortical volume substantially expanded after 30 days. Such expansion would have spread apart existing capillaries and mitochondria, thereby diluting metabolic support. However, capillary spacing and mitochondrial volume fraction were maintained in these EC animals after 30 days, suggesting that new capillaries and mitochondria had infiltrated the tissue. Furthermore, many small vessels appeared after 10 days of complex experience, followed by expansion in vessel size until vessels from rats in EC for 60 days were larger than those from rats in IC for 60 days. The findings of constant vessel spacing in the face of expanding tissue volume, along with a set of small vessels that subsequently increased in size, suggest that small-sized new vessels were introduced in EC cortex by 10 days but had not matured in size until after 30 days. The results indicate that young adult rats can generate new capillaries and mitochondria in response to increased metabolic demands, but in a less vigorous fashion than in previously described weanling animals.