Role and dynamics of an agmatinase-like protein (AGM-1) in Neurospora crassa

Agmatinase is known as a metalloenzyme which hydrolyzes agmatine to produce urea and putrescine, being crucial in the alternative pathway to produce polyamines. In this study, an agmatinase-like protein (AGM-1) (NCU 01348) in the filamentous fungus Neurospora crassa is reported. Purified AGM-1 from N. crassa displays enzymatic activity hydrolyzing agmatine; therefore, it can be considered as an agmatinase-like protein. However, its role in the alternative pathway to produce polyamines apparently is not its main function since only a slight reduction of polyamines concentration was detected in the Δagm-1 het strain. Moreover, the null mutant Δagm-1 (homokaryon strain) was unable to grow and the deficiency of agm-1 in the heterokaryon strain provoked a decrease in elongation rate, conidia and biomass production, despite of having de constitutive pathway via the ornithine decarboxylase (ODC). Additionally, mature hyphae of the Δagm-1 het strain presented unusual apical branching and a disorganized Spitzenkörper (Spk). Trying to reveal the role of AGM-1in N. crassa, the protein was tagged with GFP and interestingly the dynamics and intracellular localization of AGM-1 closely resembles the F-actin population. This finding was further examined in order to elucidate if AGM-1is in a close association with F-actin. Since polyamines, among them agmatine, have been reported to act as stabilizers of actin filaments, we evaluated in vitro G-actin polymerization in the presence of agmatine and the effect of purified AGM-1 from N. crassa on these polymerized actin filaments. It was found that polymerization of actin filaments increases in the presence of agmatine and the addition of purified AGM-1 from N. crassa depolymerizes these actin filaments. Also, it was determined that an intact substrate binding site of the enzyme is necessary for the localization pattern of the native AGM-1. These results suggest that in N. crassa AGM-1 has a close association with the F-actin population via its substrate agmatine, playing an essential role during cell development.

iTRAQ-based quantitative proteomic analysis of conidia and mycelium in the filamentous fungus Metarhizium robertsii

Metarhizium robertsii is widely applied in biological control via conidia application. To clarify the proteomic differences between conidia and mycelia and explore the underlying mechanisms of conidia as a unit responsible for dispersal and environmental stress, we carried out an iTRAQ (isobaric tags for relative and absolute quantitation)-based quantitative proteomic analysis for two developmental stages from M. robertsii. A total of 2052 proteins were detected, and 90 showed differential protein abundance between the conidia and mycelia. These 90 proteins were primarily associated with stress resistance, amino acid and protein metabolism, and energy metabolism. Further bioinformatics analysis showed that these proteins could be mapped to 52 pathways, five of which were significantly enriched after mapping to KEGG pathways. Interestingly, many proteins involved in the significantly enriched pathway of peroxisome, biosynthesis of secondary metabolites and glyoxylate and dicarboxylate metabolism, including catalase, peroxisomal membrane anchor protein, formate dehydrogenase and isocitrate lyase, were identified with higher abundance in conidia. The results deepened our understanding of the conidia proteome in M. robertsii and provide a basis for further exploration for improving the efficiency of the fungi as biocontrol agents.