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.     

Above-ground space sequestration determines competitive success in juvenile beech and spruce trees

A 2-yr phytotron study was conducted to investigate the intra- and inter-specific competitive behaviour of juvenile beech (Fagus sylvatica) and spruce (Picea abies). Competitiveness was analysed by quantifying the resource budgets that occur along structures and within occupied space of relevance for competitive interaction. Ambient and elevated CO(2) and ozone (O(3)) regimes were applied throughout two growing seasons as stressors for provoking changes in resource budgets, growth and allocation to facilitate the competition analysis. The hypothesis tested was that the ability to sequester space at low structural cost will determine the competitive success. Spruce was a stronger competitor than beech, as displayed by its higher above-ground biomass increments in mixed culture compared with monoculture. A crucial factor in the competitive success of spruce was its ability to enlarge crown volume at low structural costs, supporting the hypothesis. Interspecific competition with spruce resulted in a size-independent readjustment of above-ground allocation in beech (reduced leaf : shoot biomass ratio). The efficient use of resources for above-ground space sequestration proved to be a parameter that quantitatively reflects competitiveness.     

Filaments of the Ure2p prion protein have a cross-beta core structure

Formation of filaments by the Ure2 protein constitutes the molecular mechanism of the [URE3] prion in yeast. According to the "amyloid backbone" model, the N-terminal asparagine-rich domains of Ure2p polymerize to form an amyloid core fibril that is surrounded by C-terminal domains in their native conformation. Protease resistance and Congo Red binding as well as beta-sheet content detected by spectroscopy-all markers for amyloid-have supported this model, as has the close resemblance between 40 A N-domain fibrils and the fibrillar core of intact Ure2p filaments visualized by cryo-electron microscopy and scanning transmission electron microscopy. Here, we present electron diffraction and X-ray diffraction data from filaments of Ure2p, of N-domains alone, of fragments thereof, and of an N-domain-containing fusion protein that demonstrate in each case the 4.7A reflection that is typical for cross-beta structure and highly indicative of amyloid. This reflection was observed for specimens prepared by air-drying with and without sucrose embedding. To confirm that the corresponding structure is not an artifact of air-drying, the reflection was also demonstrated for specimens preserved in vitreous ice. Local area electron diffraction and X-ray diffraction from partially aligned specimens showed that the 4.7A reflection is meridional and therefore the underlying structure is cross-beta.     

Riboswitches and the role of noncoding RNAs in bacterial metabolic control

Microorganisms use a plethora of genetic strategies to regulate expression of their genes. In recent years there has been an increase in the discovery and characterization of riboswitches, cis-acting regulatory RNAs that function as direct receptors for intracellular metabolites. Nine classes have been uncovered that together regulate many essential biochemical pathways. Two classes, responding to either glucosamine-6-phosphate (GlcN6P) or glycine, have been found to employ novel mechanisms of genetic control. Additionally, progress has been achieved in elucidating molecular details for regulation by the other riboswitches, via X-ray crystallography and biochemical analyses of riboswitch-metabolite interactions. The complete repertoire of metabolite-sensing RNAs and extent of their usage in modern organisms remains to be determined; however, these current data assist in establishing a foundation from which to build future expectations.     

New class of competitive inhibitor of bacterial histidine kinases

Bacterial histidine kinases have been proposed as targets for the discovery of new antibiotics, yet few specific inhibitors of bacterial histidine kinases have been reported. We report here a novel thienopyridine (TEP) compound that inhibits bacterial histidine kinases competitively with respect to ATP but does not comparably inhibit mammalian serine/threonine kinases. Although it partitions into membranes and does not inhibit the growth of bacterial or mammalian cells, TEP could serve as a starting compound for a new class of histidine kinase inhibitors with antibacterial activity.     

Electron tunneling in rhenium-modified Pseudomonas aeruginosa azurins

Laser flash-quench methods have been used to generate tyrosine and tryptophan radicals in structurally characterized rhenium-modified Pseudomonas aeruginosa azurins. Cu(I) to "Re(II)" electron tunneling in Re(H107) azurin occurs in the microsecond range. This reaction is much faster than that studied previously for Cu(I) to Ru(III) tunneling in Ru(H107) azurin, suggesting that a multistep ("hopping") mechanism might be involved. Although a Y108 radical can be generated by flash-quenching a Re(H107)M(II) (M=Cu, Zn) protein, the evidence suggests that it is not an active intermediate in the enhanced Cu(I) oxidation. Rather, the likely explanation is rapid conversion of Re(II)(H107) to deprotonated Re(I)(H107 radical), followed by electron tunneling from Cu(I) to the hole in the imidazole ligand.     

Cysteine-scanning mutagenesis and thiol modification of the Rickettsia prowazekii ATP/ADP translocase: evidence that transmembrane regions I and II, but not III, are structural components of the aqueous translocation channel

The contribution of transmembrane regions I, II, and III of the Rickettsia prowazekii ATP/ADP translocase to the structure of the putative water-filled ATP translocation channel was evaluated from the accessibility of hydrophilic, thiol-reactive, methanethiosulfonate reagents to a library of 68 independent cysteine-substitution mutants heterologously expressed in Escherichia coli. The MTS reagents used were MTSES (negatively charged) and MTSET and MTSEA (both positively charged). Mutants F036C, Y042C, and R046C (TM I), K066C and P072C (TM II), and F101C, F105C, F108C, Y113C, and P114C (TM III) had no assayable transport activity, indicating that cysteine substitution at these positions may not be tolerated. All three MTS reagents inhibit the transport of ATP in mutants of TM I (L039C, S043C, S047C, I048C) and TM II (S061C, S063C, T067C, I069C, V070C, A074C). Further, these residues appear to cluster along a single face of the transmembrane domain. Preexposure of MTS-reactive mutants S047C (TM I) and T067C (TM II) to high levels of ATP resulted in protection from MTS-mediated inhibition. This indicated that both TM I and TM II make major contributions to the structure of an aqueous ATP translocation pathway. Finally, on the basis of the lack of accessibility of charged MTS reagents to the thiol groups in mutants of TM III, it appears that TM III is not exposed to the ATP translocation channel. Cysteine substitution of residues constituting a highly conserved "phenylalanine face" in TM III resulted in ablation of ATP transport activity. Further, substituting these phenylalanine residues for either isoleucine or tyrosine also resulted in much lower transport activity, indicating that some property of phenylalanine at these positions that is not shared by cysteine, isoleucine, or tyrosine is critical to translocase activity.