Growth and development are regulated using cyclic AMP (cAMP)-dependent and -independent pathways in Neurospora crassa. The cr-1 adenylyl cyclase mutant lacks detectable cAMP and exhibits numerous defects, including colonial growth habit, short aerial hyphae, premature conidiation on plates, inappropriate conidiation in submerged culture, and increased thermotolerance. Evidence suggests that the heterotrimeric G␣ protein GNA-1 is a direct positive regulator of adenylyl cyclase. ⌬gna-1 strains are female-sterile, and ⌬gna-1 strains have reduced apical extension rates on normal and hyperosmotic medium, greater resistance to oxidative and heat stress, and stunted aerial hyphae compared to the wild-type strain. In this study, a ⌬gna-1 cr-1 double mutant was analyzed to differentiate cAMP-dependent and -independent signaling pathways regulated by GNA-1. ⌬gna-1 cr-1 mutants have severely restricted colonial growth and do not produce aerial hyphae on plates or in standing liquid cultures. Addition of cAMP to plates or standing liquid cultures rescues cr-1, but not ⌬gna-1 cr-1, defects, which is consistent with previous results demonstrating that ⌬gna-1 mutants do not respond to exogenous cAMP. The females of all strains carrying the ⌬gna-1 mutation are sterile; however, unlike cr-1 and ⌬gna-1 strains, the ⌬gna-1 cr-1 mutant does not produce protoperithecia. The ⌬gna-1 and cr-1 mutations were synergistic with respect to inappropriate conidiation during growth in submerged culture. Thermotolerance followed the order wild type < ⌬gna-1 < cr-1 ؍ ⌬gna-1 cr-1, consistent with a cAMP-dependent process. Taken together, the results suggest that in general, GNA-1 and CR-1 regulate N. crassa growth and development using parallel pathways, while thermotolerance is largely dependent on cAMP.Development in fungal systems frequently occurs in response to specific environmental cues and stressors. In the presence of abundant nutrients, the filamentous fungus Neurospora crassa extends hyphae that elongate and fuse to form the multicellular mycelium (for a review, see reference 51). Desiccation or nutrient deprivation causes the mycelium to differentiate aerial hyphae that give rise to conidiophores and multinucleate asexual spores, macroconidia (referred to here as conidia). Elaboration of conidiophores and production of conidia require an air-water interface; however, submerged cultures can be induced to undergo conidiation by carbon or nitrogen starvation or exposure to high temperatures (7,18,43,55). Nitrogen limitation initiates the sexual cycle by stimulating production of female reproductive structures, or protoperithecia (reviewed in reference 44). Fertilization by a conidium or hypha of the opposite mating type results in formation of the fertilized structure (perithecium), within which sexual spores (ascospores) develop. Mature ascospores are subsequently ejected from the perithecium in the direction of blue light.Heterotrimeric GTP-binding proteins, consisting of ␣, , and ␥ subunits, transduce various environmental signals ...
