The Caenorhabditis elegans septin complex is nonpolar.

Septins are conserved GTPases that form heteromultimeric complexes and assemble into filaments that play a critical role in cell division and polarity. Results from budding and fission yeast indicate that septin complexes form around a tetrameric core. However, the molecular structure of the core and its influence on the polarity of septin complexes and filaments is poorly defined. The septin complex of the nematode Caenorhabditis elegans is formed entirely by the core septins UNC-59 and UNC-61. We show that UNC-59 and UNC-61 form a dimer of coiled-coil-mediated heterodimers. By electron microscopy, this heterotetramer appears as a linear arrangement of four densities representing the four septin subunits. Fusion of GFP to the N termini of UNC-59 and UNC-61 and subsequent electron microscopic visualization suggests that the sequence of septin subunits is UNC-59/UNC-61/UNC-61/UNC-59. Visualization of GFP extensions fused to the extremity of the C-terminal coiled coils indicates that these extend laterally from the heterotetrameric core. Together, our study establishes that the septin core complex is symmetric, and suggests that septins form nonpolar filaments.

Structural insights into the EB1-APC interaction.

EB1 proteins bind to microtubule ends where they act in concert with other components, including the adenomatous polyposis coli (APC) tumor suppressor, to regulate the microtubule filament system. We find that EB1 is a stable dimer with a parallel coiled coil and show that dimerization is essential for the formation of its C-terminal domain (EB1-C). The crystal structure of EB1-C reveals a highly conserved surface patch with a deep hydrophobic cavity at its center. EB1-C binds two copies of an APC-derived C-terminal peptide (C-APCp1) with equal 5 microM affinity. The conserved APC Ile2805-Pro2806 sequence motif serves as an anchor for the interaction of C-APCp1 with the hydrophobic cavity of EB1-C. Phosphorylation of the conserved Cdc2 site Ser2789-Lys2792 in C-APCp1 reduces binding four-fold, indicating that the interaction APC-EB1 is post-translationally regulated in cells. Our findings provide a basis for understanding the dynamic crosstalk of EB1 proteins with their molecular targets in eukaryotic organisms.

UUCAC- and vera-dependent localization of VegT RNA in Xenopus oocytes.

Localized mRNAs are directed to their destinations by "localization elements" (LEs) in their 3'UTRs. LEs harbor multiple, functionally redundant localization "signals." These signals are poorly defined, hence it is unclear whether the signals-and their cognate factors-are unique to each RNA or employed generally. Five "E2s" (UUCACs) in the 366 nt Vg1 LE (VgLE) direct this transcript to the vegetal pole of Xenopus oocytes via the binding of a protein-Vera/Vg1RBP/ZBP. Here we show that a different vegetal RNA, VegT, employs the same signal and factor. Five E2s within a 440 nt subregion (VegT440) of the VegT 3'UTR predict its LE and are both necessary and sufficient (in the context of antisense VegT440) for directing localization. The E2s in VegT440 and VgLE function similarly to recruit Vera protein: (1) in both contexts, E2 nt substitutions partially (UU to AC) or completely (CA to UG) inhibit localization in accordance with the sequence selectivity of Vera protein for E2s; (2) VegT440 and VgLE crosscompete, in an E2-dependent manner, for localization and Vera binding; (3) injection of anti-Vera antibody into oocytes inhibits localization of both injected transcripts. These findings imply that general localization signals traffic diverse RNAs.