Crystal Structure of the α-Actinin Rod Reveals an Extensive Torsional Twist

AbstractBackground: α-Actinin is a ubiquitously expressed protein found in numerous actin structures. It consists of an N-terminal actin binding domain, a central rod domain, and a C-terminal domain and functions as a homodimer to cross-link actin filaments. The rod domain determines the distance between cross-linked actin filaments and also serves as an interaction site for several cytoskeletal and signaling proteins.Results: We report here the crystal structure of the α-actinin rod. The structure is a twisted antiparallel dimer that contains a conserved acidic surface.Conclusions: The novel features revealed by the structure allow prediction of the orientation of parallel and antiparallel cross-linked actin filaments in relation to α-actinin. The conserved acidic surface is a possible interaction site for several cytoplasmic tails of transmembrane proteins involved in the recruitment of α-actinin to the plasma membrane

Human Lsg1 defines a family of essential GTPases that correlates with the evolution of compartmentalization

BACKGROUND: Compartmentalization is a key feature of eukaryotic cells, but its evolution remains poorly understood. GTPases are the oldest enzymes that use nucleotides as substrates and they participate in a wide range of cellular processes. Therefore, they are ideal tools for comparative genomic studies aimed at understanding how aspects of biological complexity such as cellular compartmentalization evolved. RESULTS: We describe the identification and characterization of a unique family of circularly permuted GTPases represented by the human orthologue of yeast Lsg1p. We placed the members of this family in the phylogenetic context of the YlqF Related GTPase (YRG) family, which are present in Eukarya, Bacteria and Archea and include the stem cell regulator Nucleostemin. To extend the computational analysis, we showed that hLsg1 is an essential GTPase predominantly located in the endoplasmic reticulum and, in some cells, in Cajal bodies in the nucleus. Comparison of localization and siRNA datasets suggests that all members of the family are essential GTPases that have increased in number as the compartmentalization of the eukaryotic cell and the ribosome biogenesis pathway have evolved. CONCLUSION: We propose a scenario, consistent with our data, for the evolution of this family: cytoplasmic components were first acquired, followed by nuclear components, and finally the mitochondrial and chloroplast elements were derived from different bacterial species, in parallel with the formation of the nucleolus and the specialization of nuclear components

Crystal Structure of the Complex of UMP/CMP Kinase from Dictyostelium discoideum and the Bisubstrate Inhibitor P1−(5'−Adenosyl) P5−(5'−Uridyl) Pentaphosphate (UP5A) and Mg2+ at 2.2 Å: Implications for Water−Mediated Specificity

The three−dimensional structure of the UMP/CMP kinase (UK) from the slime mold Dictyostelium discoideum complexed with the specific and asymmetric bisubstrate inhibitor P1−(5'−adenosyl) P5−(5'−uridyl) pentaphosphate (UP5A) has been determined at a resolution of 2.2 A. The structure of the enzyme, which has up to 41% sequence homology with known adenylate kinases (AK), represents a closed conformation with the flexible monophosphate binding domain (NMP site) being closed over the uridyl moiety of the dinucleotide. Two water molecules were found within hydrogen−bonding distance to the uracil base. The key residue for the positioning and stabilization of those water molecules appears to be asparagine 97, a residue that is highly specific for AK−homologous UMP kinases, but is almost invariably a glutamine in adenylate kinases. Other residues in this region are highly conserved among AK−related NMP kinases. The catalytic Mg2+ ion is coordinated with octahedral geometry to four water molecules and two oxygens of the phosphate chain of UP5A but has no direct interactions with the protein. The comparison of the geometry of the UKdicty.UP5A.Mg2+ complex with the previously reported structure of the UKyeast.ADP.ADP complex [Muller−Dieckmann & Schulz (1994) J. Mol. Biol. 236, 361−367] suggests that UP5A in our structure mimics an ADP.Mg.UDP biproduct inhibitor rather than an ATP. MG.UMP bisubstrate inhibito

The Role of the Metal Ion in the p21rasCatalysed GTP−hydrolysis: Mn2+ versus Mg2+

GTP and ATP hydrolysing proteins have an absolute requirement for a divalent cation, which is usually Mg2+, as a cofactor in the enzymatic reaction. Other phosphoryl transfer enzymes employ more than one divalent ion for the enzymatic reaction. It is shown here for p21ras, a well studied example of GTP hydrolysing proteins, that the GTP−hydrolysis rate is significantly faster if Mg2+ is replaced by Mn2+, both in the presence or absence of its GTPase−activating protein Ras−GAP. This effect is not due to a different stoichiometry of metal ion binding, since one metal ion is sufficient for full enzymatic activity. To determine the role of the metal ion, the crystal structure of p21(G12P)·GppCp complexed with Mn2+ was determined and shown to be very similar to the corresponding p21(G12P)·GppCp·Mg2+ structure. Especially the coordination sphere around the metal ions is very similar, and no second metal ion binding site could be detected, consistent with the assumption that one metal ion is sufficient for GTP hydrolysis. In order to explain the biochemical differences, we analysed the GTPase reaction mechanism with a linear free energy relationships approach. The result suggests that the reaction mechanism is not changed with Mn2+ but that the transition metal ion Mn2+ shifts the pKa of the γ−phosphate by almost half a unit and increases the reaction rate due to an increase in the basicity of GTP acting as the general base. This suggests that the intrinsic GTPase reaction could be an attractive target for anti−cancer drug design. By using Rap1A and Ran, we show that the acceleration of the GTPase by Mn2+ appears to be a general phenomenon of GTP−binding protein

Structural fingerprints of the Ras-GTPase activating proteins neurofibromin and p120GAP

Ras specific GTPase activating proteins (GAPs), neurofibromin and p120GAP, bind GTP bound Ras and efficiently complement its active site. Here we present comparative data from mutations and fluorescence-based assays of the catalytic domains of both RasGAPs and interpret them using the crystal structures. Three prominent regions in RasGAPs, the arginine-finger loop, the phenylalanine-leucine-arginine (FLR) region and alpha7/variable loop contain structural fingerprints governing the GAP function. The finger loop is crucial for the stabilization of the transition state of the GTPase reaction. This function is controlled by residues proximal to the catalytic arginine, which are strikingly different between the two RasGAPs. These residues specifically determine the orientation and therefore the positioning of the arginine finger in the Ras active site. The invariant FLR region, a hallmark for RasGAPs, indirectly contributes to GTPase stimulation by forming a scaffold, which stabilizes Ras switch regions. We show that a long hydrophobic side-chain in the FLR region is crucial for this function. The alpha7/variable loop uses several conserved residues including two lysine residues, which are involved in numerous interactions with the switch I region of Ras. This region determines the specificity of the Ras-RasGAP interaction

Confirmation of the arginine-finger hypothesis for the GAP-stimulated GTP-hydrolysis reaction of Ras

RasGAPs supply a catalytic residue, termed the arginine finger, into the active site of Ras thereby stabilizing the transition state of the GTPase reaction and increasing the reaction rate by more than one thousand−fold, in good agreement with the structure of the Ras*RasGAP comple

Thioredoxin as a fusion tag for carrier-driven crystallization

Structural investigations are frequently hindered by difficulties in obtaining diffracting crystals of the target protein. Here, we report the crystallization and structure solution of the U2AF homology motif (UHM) domain of splicing factor Puf60 fused to Escherichia coli thioredoxin A. Both modules make extensive crystallographic contacts, contributing to a well-defined crystal lattice with clear electron density for both the thioredoxin and the Puf60-UHM module. We compare two short linker sequences between the two fusion domains, GSAM and GSPPM, for which only the GSAM-linked fusion protein yielded diffracting crystals. While specific interdomain contacts are not observed for both fusion proteins, NMR relaxation data in solution indicate reduced interdomain mobility between the Trx and Puf60-UHM modules. The GSPPM-linked fusion protein is significantly more flexible, albeit both linker sequences have the same number of degrees of torsional freedom. Our analysis provides a rationale for the crystallization of the GSAM-linked fusion protein and indicates that in this case, a four-residue linker between thioredoxin A and the fused target may represent the maximal length for crystallization purposes. Our data provide an experimental basis for the rational design of linker sequences in carrier-driven crystallization and identify thioredoxin A as a powerful fusion partner that can aid crystallization of difficult targets