The role of GYP-3 in cellular morphogenesis of Neurospora crassa: Analyzing its relationship with the polarisome.

In fungal hyphae multiple protein complexes assemble at sites of apical growth to maintain cell polarity. The polarisome, which in Saccharomyces cerevisiae consists of Spa2, Pea2, Bud6 and Bni1 is described as a small network of functionally related proteins that regulate polarized growth. In yeast Msb3 and Msb4 are considered polarisome components since both proteins interact directly with Spa2 and are involved in Bni1-nucleated actin assembly in vivo. Additionally they regulate exocytosis through their GAP activity towards Sec4 and perhaps other Rab GTPases. In filamentous fungi the role of these proteins has not been investigated, and in the genome of Neurospora crassa only the gene gyp-3 (NCU04514) was found to correlate with MSB3 and MSB4 of S. cerevisiae. Therefore in this work the role of GYP-3 and its relationship with the polarisome in N. crassa was analyzed. The results show that GYP-3 is required for normal colony development and cell morphology since the Δgyp-3 strain displayed a substantial reduction in colony diameter and hyphae showed a distorted morphology expressed as a general pattern of bulging areas in the distal region and hyphae were thinner at the active growing zone. The lack of GYP-3 had no effects on the localization of the polarisome components SPA-2 and BNI-1. Likewise, GYP-3 was not necessary for the normal localization of the F-actin population, however the dynamics of the Spitzenkörper (Spk) and the actin population at the apical region seemed to be destabilized. Additionally, the lack of GYP-3 strongly affects the localization and dynamics of SEC-4; which no longer accumulates at the tip of hyphae. The results presented here strongly suggest that GYP-3 is not part of the polarisome; however it requires the scaffold protein SPA-2 for arriving at the tip of hyphae. Although GYP-3 is not essential for cell survival, it has an important role in maintaining normal cell growth and morphology in N. crassa.

Microtubules and associated molecular motors in Neurospora crassa.

The cytoskeleton provides structure, shape and movement to various cells. Microtubules (MTs) are tubular structures made of α and ß-tubulin heterodimers organized in 13 protofilaments, forming a hollow cylinder. A vast group of MT-associated proteins determines the function, behavior and interaction of the MTs with other cellular components. Among these proteins, molecular motors such as the dynein-dynactin complex and kinesin superfamily play roles in MT organization and organelle transport. This article focuses on the MT cytoskeleton and associated molecular motors in the filamentous fungus Neurospora crassa In addition to reviewing current available information for this fungus and contrasting it with knowledge of other fungal species, we present new experimental results that support the role of dynein, dynactin and conventional kinesin in MT organization, dynamics and transport of subcellular structures (nuclei and secretory vesicles). In wild type hyphae of N. crassa, cytoplasmic MTs are arranged longitudinally along hyphae and display a helical curvature. They interlace with one another to form a network throughout the cytoplasm. N. crassa dynein and dynactin mutants have a scant and disorganized MT cytoskeleton, an erratic and reduced Spitzenkörper (Spk) and distorted hyphal morphology. In contrast, hyphae of mutants with defective conventional kinesin exhibit only minor disruptions in MT and Spk organization. Although nuclear positioning is affected in all mutants, the MT-associated motor proteins are not major contributors to nuclear movement during hyphal growth. Cytoplasmic bulk flow is the vehicle for nuclear displacement in growing hyphal regions of N. crassa Motors are involved in nuclei saltatory movements in both retrograde or anterograde direction. In the dynein and kinesin mutants, micro and macrovesicles can reach the Spk, although growth is slightly impaired and the Spk displays an erratic path. Hyphal growth requires MTs, and their associated motors are required for their organization and dynamics and Spk integrity.

Protein interactors of Spindle Pole Body (SPB) components and septal proteins in fungus Neurospora crassa: A mass spectrometry-based dataset.

Microtubule Organizing Centers (MTOC) are subcellular structures in eukaryotic cells where nucleation of microtubules (MTs) takes place and represents the filament's minus end. Their localization depends on the species, cell type, and cell cycle stage. Along the fungal kingdom, the Spindle Pole Body (SPB) in the nucleus (an equivalent to Centrosomes in animal cells) is the principal MTOC. Other MTOCs have been identified in filamentous fungi, such as the Spitzenkörper in the hyphal tips of Schizosaccharomyces pombe or the septal pore of Aspergillus nidulans. However, in the fungal-model organism Neurospora crassa, these alternative MTOCs have not been recognized. Here, we present a Mass spectrometry-based dataset of proteins interacting with four MTOC components of N. crassa tagged with fluorescent proteins: γ-Tubulin-sGFP (main nucleator at the SPB), MZT-1-sGFP (structural SPB microprotein), APS-2-dRFP (septal protein and recognized SPB component), and SPA-10-sGFP (septal MTOC protein). A WT and a cytosolic GFP expressing strain were included as controls. The protein interactors were pulled down by Co-IP1, using GFP-Magnetic agarose that captures recombinant GFP proteins (including GFP-derivatives) in their native state. Bounded proteins were separated by SDS-PAGE and identified by nano LC-MS/MS2. The protein annotation was done using the N. crassa protein database.

The Adh1 gene of the fungus Metarhizium anisopliae is expressed during insect colonization and required for full virulence.

Zymography of alcohol dehydrogenase (ADH) activity in the entomopathogenic fungus Metarhizium anisopliae grown under various conditions revealed that micro-aerobic growth was associated with increased ADH activity. The major ADH protein, AdhIp, was purified to homogeneity by affinity chromatography and has an estimated molecular weight of 41kDa and an isoelectric point (pI) of 6.4. Peptide mass fingerprint analysis allowed the identification and cloning of the gene that encodes this protein, Adh1, as annotated in the M. anisopliae genome database. AdhIp is related to the medium-chain dehydrogenase/reductase (MDR)/zinc-dependent alcohol dehydrogenase-like family and contains conserved ADH sequence motifs, such as the zinc-containing ADH signature, the FAD/NAD binding domain and amino acid residues that are conserved in most microbial ADHs. Semi-quantitative RT-PCR analysis revealed that Adh1 gene expression occurs at low levels during early Plutella xylostella infection and that the Adh1 gene was primarily expressed at larval death and as mycelia emerge from the insect cuticle before conidiation. Antisense-RNA experiments indicated that NAD(+)-dependent ADH activity was diminished by 20-75% in the transformants, and the transformants that had lower ADH activity showed allyl alcohol resistance, which indicates that reduction in ADH activity also occurs in vivo. Bioassays performed using antisense adh1 transformants, which have lower ADH activity, showed that LC50 values were two to five times higher than the wild-type, indicating that AdhIp is required for full capability of the fungus to penetrate and/or colonize the insect.