Functional characterization and cellular dynamics of the CDC-42 - RAC - CDC-24 module in Neurospora crassa.

Rho-type GTPases are key regulators that control eukaryotic cell polarity, but their role in fungal morphogenesis is only beginning to emerge. In this study, we investigate the role of the CDC-42 - RAC - CDC-24 module in Neurospora crassa. rac and cdc-42 deletion mutants are viable, but generate highly compact colonies with severe morphological defects. Double mutants carrying conditional and loss of function alleles of rac and cdc-42 are lethal, indicating that both GTPases share at least one common essential function. The defects of the GTPase mutants are phenocopied by deletion and conditional alleles of the guanine exchange factor (GEF) cdc-24, and in vitro GDP-GTP exchange assays identify CDC-24 as specific GEF for both CDC-42 and RAC. In vivo confocal microscopy shows that this module is organized as membrane-associated cap that covers the hyphal apex. However, the specific localization patterns of the three proteins are distinct, indicating different functions of RAC and CDC-42 within the hyphal tip. CDC-42 localized as confined apical membrane-associated crescent, while RAC labeled a membrane-associated ring excluding the region labeled by CDC42. The GEF CDC-24 occupied a strategic position, localizing as broad apical membrane-associated crescent and in the apical cytosol excluding the Spitzenkörper. RAC and CDC-42 also display distinct localization patterns during branch initiation and germ tube formation, with CDC-42 accumulating at the plasma membrane before RAC. Together with the distinct cellular defects of rac and cdc-42 mutants, these localizations suggest that CDC-42 is more important for polarity establishment, while the primary function of RAC may be maintaining polarity. In summary, this study identifies CDC-24 as essential regulator for RAC and CDC-42 that have common and distinct functions during polarity establishment and maintenance of cell polarity in N. crassa.

The polarisome component SPA-2 localizes at the apex of Neurospora crassa and partially colocalizes with the Spitzenkörper.

In fungal hyphae multiple protein complexes assemble at sites of apical growth to maintain cell polarity and promote nucleation of actin. Polarity allows the directional traffic of vesicles to the Spitzenkörper (Spk) prior to fusing with the plasma membrane to provide precursors and enzymes required for cell extension and nutrition. One of these complexes is the polarisome, which in Saccharomyces cerevisiae contains Spa2p, Pea2p, Bud6p/Aip3p and Bni1p. To investigate the localization and role of the polarisome during Spk establishment in Neurospora crassa we tagged SPA-2 with the green fluorescent protein (GFP) and examined growing cells by laser scanning confocal microscopy in elongating germ tubes and mature hyphae. SPA-2-GFP accumulated gradually at the apex of germ tubes, when a FM4-64 stained Spk was not still detectable. When the germlings reached about 40microm in length, a FM4-64 stained Spk started to be apparent and from this point on SPA-2-GFP was observed in the apical region of both germ tubes and mature hyphae, as a hand fan shape with a brighter spot at the base. Fusion of the N. crassa SPA-2-GFP strain with a N. crassa strain expressing chitin synthase 1 (CHS-1) labeled with mCherryFP indicated only partial colocalization of the polarisome and the Spk core. N. crassa SPA-2-GFP was also found at the apex of forming branches but not in septa, suggesting that it participates only in areas of tip growth. A Deltaspa-2 strain displayed hyphae with uneven constrictions, apices with an unstable Spk, reduced growth rate and higher number of branches than the wild type strain, indicating that SPA-2 is required for the stability, behavior and morphology of the Spk and maintenance of regular apical growth in hyphae of N. crassa, although not for polarity or Spk establishment.

Ontogeny of the Spitzenkörper in germlings of Neurospora crassa.

The Spitzenkörper (Spk) is a highly dynamic and pleomorphic complex located at the hyphal apex of filamentous fungi. Most studies revealing the structure and behavior of the Spk have been conducted on mature vegetative hyphae of filamentous fungi, including both main leading hyphae and branches. However, these reports do not address whether the observations can be extended to germ tubes. By enhanced phase-contrast video-microscopy and laser scanning confocal microscopy we have analyzed the intracellular changes prior to the appearance of a Spk in germlings of Neurospora crassa. Observations began at the early stages of spore germination and were carried out until a conspicuous Spk could be observed at the apex of germ tubes. Before a Spk could be observed, young germ tubes (<150 microm) displayed a uniform distribution of organelles such as nuclei, mitochondria, and cytoplasmic granules along the length of the cells. Once the germlings started reaching lengths of more than approximately 150 microm, visible organelles experienced a displacement towards the subapical region of the cell and a small exclusion zone free of organelles (0.6+/-0.3 microm) formed at the apex. The position of this exclusion zone within the apex seemed to determine the germling growth direction, which was highly erratic. Few minutes after it first appeared, upon growth of the germling, the exclusion zone started to become occupied by an accumulation of material that gradually concentrated into a light gray body that we describe as an immature Spk. During this phase the presence of a Spk in the apical dome was not constant. Approximately 30 min later, the immature Spk became more robust and gradually acquired its typical phase-dark appearance, while the growth direction of the germ tube became less wavering. The formation of a mature phase-dark Spk coincided with the stabilization of the growth direction of the germling, therefore suggesting that it is at this stage when the transition from germling to vegetative hypha occurs.