Proteins in the Rho family are small monomeric GTPases primarily involved in polarization, control of cell division, and reorganization of cytoskeletal elements. Phylogenetic analysis of predicted fungal Rho proteins suggests that a new Rho-type GTPase family, whose founding member is Rho4 from the archiascomycete Schizosaccharomyces pombe, is involved in septation. S. pombe rho4⌬ mutants have multiple, abnormal septa. In contrast to S. pombe rho4⌬ mutants, we show that strains containing rho-4 loss-of-function mutations in the filamentous fungus Neurospora crassa lead to a loss of septation. Epitope-tagged RHO-4 localized to septa and to the plasma membrane. In other fungi, the steps required for septation include formin, septin, and actin localization followed by cell wall synthesis and the completion of septation. rho-4 mutants were unable to form actin rings, showing that RHO-4 is required for actin ring formation. Characterization of strains containing activated alleles of rho-4 showed that RHO-4-GTP is likely to initiate new septum formation in N. crassa.In many organisms, the purpose of cytokinesis is to couple the process of making a new cell with the replication of the nucleus. In eukaryotes, this can be accomplished by positioning the division plane according to the location of the spindle or by moving mitotic machinery to an already determined division plane (15). Most eukaryotes tightly couple cell division with replication of the nucleus, making cell division essential for viability. For example, Saccharomyces cerevisiae moves the mitotic machinery to the division plane specified by "landmark proteins," which remain at the bud scar (10). In contrast, the division plane in animal cells is determined by the position of either the spindle midzone (56) or astral microtubules (38). In filamentous fungi, which grow by apical tip extension to form highly polarized multinucleate cells called hyphae, cytokinesis occurs by the formation of crosswalls or septa. These septa serve to define the boundary between hyphal compartments. However, septal pores maintain cytoplasmic continuity in a colony and allow nuclei and organelles to travel between cells (23). Three observations suggest that filamentous fungi have partially uncoupled septation from mitosis: (i) hyphal compartments are multinucleate, (ii) septation is observed in anucleate compartments of Neurospora crassa ropy mutants (29), and (iii) Ashbya gossypii Agcky1 mutants lack septa but grow at a wildtype rate (53). Thus, the partial uncoupling of cell division from mitosis allows isolation of viable aseptate mutants in filamentous fungi. Septation in filamentous fungi is required for certain developmental processes, such as conidiation (asexual spore production) and protoperithecial (female sexual structure) development (20,37). In addition, septa may serve a structural role in maintaining the tubular shape of hyphae.Septa also act as a scaffold for the Woronin body, a septal plug that stops cytoplasmic leaking after hyphal injury (23,24,48).The process o...
