Significance
This study reveals that a dialogue-like communication mechanism, which mediates cell–cell fusion in filamentous fungi, is a conserved complex trait. It allows the communication and behavioral coordination of cells of distantly related species and mediates their mutual attraction and subsequent physical contact, although interspecies fusion does not occur. Through the activation of this signaling machinery, one species can reprogram the developmental program of the other fungus. These data promote our understanding of microbial communication, illustrate the mechanism of repurposing of existing building blocks in cellular evolution, revive the hypothesis of vegetative fusion as an avenue of horizontal gene transfer in fungi, and establish the idea of developmental reprogramming as a tool for controlling fungi.
An endophytic fungus Epichloë festucae systemically colonizes the intercellular spaces of aerial tissues of the host plants, including leaf primordia, sheaths, blades, and tillers to establish symbiotic associations with temperate grasses of the subfamily Pooideae (Scott, 2001; Schardl et al., 2004; Tanaka et al., 2012). Epichloë endophytes growing within the inflorescence tissues can colonize the embryo of plant seeds, which enables them to propagate with the host plant. Endophyte colonization confers various benefits on host plant including fitness to environmental stresses. In host plants, Epichloë endophytes produce distinct classes of biologically active metabolites, which improve plant resistance to a range of stresses such as drought, disease caused by microorganisms, and insect and mamma
Somatic cell fusion is widely studied in the filamentous fungus Neurospora crassa. The interaction of genetically identical germlings is mediated by a signaling mechanism in which the cells take turns in signal-sending and receiving. The switch between these physiological states is represented by the alternating membrane recruitment of the SO protein and the MAPK MAK-2. This dialog-like behavior is observed until the cells establish physical contact, when the cell-wall-integrity MAK-1 is recruited to the contact area to control the final steps of the cell fusion process. This work revealed, for the first-time, an additional MAK-1-function during the tropic growth phase. Specific inhibition of MAK-1 during tropic-growth resulted in disassembly of the actin-aster, and mislocalization of SO and MAK-2. Similar defects were observed after the inhibition of the Rho-GTPase RAC-1, suggesting a functional link between them, being MAK-1 upstream of RAC-1. In contrast, after inhibition of MAK-2, the actin-aster stayed intact, however, its subcellular localization became instable within the cell-membrane. Together these observations led to a new working model, in which MAK-1 promotes the formation and stability of the actin-aster, while MAK-2 controls its positionning and cell growth directionality.Summary statementThe CWI MAPK MAK-1 pathway controls actin cytoskeleton assembly at the cell tips through activation of the Rho-GTPase RAC-1 exclusively on somatic cell fusion.
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