Declan A. Doyle

Structural Basis for Protein-Protein Interactions in the 14-3-3 Protein Family.

The seven members of the human 14-3-3 protein family regulate a diverse range of cell signaling pathways by formation of protein–protein complexes with signaling proteins that contain phosphorylated Ser/Thr residues within specific sequence motifs. Previously, crystal structures of three 14-3-3 isoforms (zeta, sigma, and tau) have been reported, with structural data for two isoforms deposited in the Protein Data Bank (zeta and sigma). In this study, we provide structural detail for five 14-3-3 isoforms bound to ligands, providing structural coverage for all isoforms of a human protein family. A comparative structural analysis of the seven 14-3-3 proteins revealed specificity determinants for binding of phosphopeptides in a specific orientation, target domain interaction surfaces and flexible adaptation of 14-3-3 proteins through domain movements. Specifically, the structures of the beta isoform in its apo and peptide bound forms showed that its binding site can exhibit structural flexibility to facilitate binding of its protein and peptide partners. In addition, the complex of 14-3-3 beta with the exoenzyme S peptide displayed a secondary structural element in the 14-3-3 peptide binding groove. These results show that the 14-3-3 proteins are adaptable structures in which internal flexibility is likely to facilitate recognition and binding of their interaction partners.

Crystal structure of the CorA Mg2+ transporter.

The magnesium ion, Mg2+, is essential for myriad biochemical processes and remains the only major biological ion whose transport mechanisms remain unknown. The CorA family of magnesium transporters is the primary Mg2+ uptake system of most prokaryotes and a functional homologue of the eukaryotic mitochondrial magnesium transporter. Here we determine crystal structures of the full-length Thermotoga maritima CorA in an apparent closed state and its isolated cytoplasmic domain at 3.9 Å and 1.85 Å resolution, respectively. The transporter is a funnel-shaped homopentamer with two transmembrane helices per monomer. The channel is formed by an inner group of five helices and putatively gated by bulky hydrophobic residues. The large cytoplasmic domain forms a funnel whose wide mouth points into the cell and whose walls are formed by five long helices that are extensions of the transmembrane helices. The cytoplasmic neck of the pore is surrounded, on the outside of the funnel, by a ring of highly conserved positively charged residues. Two negatively charged helices in the cytoplasmic domain extend back towards the membrane on the outside of the funnel and abut the ring of positive charge. An apparent Mg2+ ion was bound between monomers at a conserved site in the cytoplasmic domain, suggesting a mechanism to link gating of the pore to the intracellular concentration of Mg2+.

Structural diversity in the RGS domain and its interaction with heterotrimeric G protein alpha-subunits.

Regulator of G protein signaling (RGS) proteins accelerate GTP hydrolysis by Gα subunits and thus facilitate termination of signaling initiated by G protein-coupled receptors (GPCRs). RGS proteins hold great promise as disease intervention points, given their signature role as negative regulators of GPCRs—receptors to which the largest fraction of approved medications are currently directed. RGS proteins share a hallmark RGS domain that interacts most avidly with Gα when in its transition state for GTP hydrolysis; by binding and stabilizing switch regions I and II of Gα, RGS domain binding consequently accelerates Gα-mediated GTP hydrolysis. The human genome encodes more than three dozen RGS domain-containing proteins with varied Gα substrate specificities. To facilitate their exploitation as drug-discovery targets, we have taken a systematic structural biology approach toward cataloging the structural diversity present among RGS domains and identifying molecular determinants of their differential Gα selectivities. Here, we determined 14 structures derived from NMR and x-ray crystallography of members of the R4, R7, R12, and RZ subfamilies of RGS proteins, including 10 uncomplexed RGS domains and 4 RGS domain/Gα complexes. Heterogeneity observed in the structural architecture of the RGS domain, as well as in engagement of switch III and the all-helical domain of the Gα substrate, suggests that unique structural determinants specific to particular RGS protein/Gα pairings exist and could be used to achieve selective inhibition by small molecules.

Structural changes during ion channel gating

Ion channels are generally multi-subunit complexes, with the ion conduction pathway formed at the subunit interface. In moving between the closed and open states, three structurally distinct channels, represented by the recently determined structures of a mechanosensitive, ligand-gated and K(+) selective channel, all move transmembrane helices away from the central ion conduction pathway. In all three cases, this results in the displacement of a hydrophobic gate from the ion conduction pathway, freeing ion movement. The channels achieve this by moving the transmembrane helices as rigid bodies using three major types of motion: MscL tilts its helices, the nicotinic ACh receptor rotates its helices, and KirBac1.1 bends its helices. In all cases, the gating motions are likely to take place rapidly. These large and fast movements provide a possible explanation for why the conduction pathways of a wide range of different ion channels are formed at the interface between subunits.

Structure of PICK1 and other PDZ domains obtained with the help of self-binding C-terminal extensions.

PDZ domains are protein–protein interaction modules that generally bind to the C termini of their target proteins. The C‐terminal four amino acids of a prospective binding partner of a PDZ domain are typically the determinants of binding specificity. In an effort to determine the structures of a number of PDZ domains we have included appropriate four residue extensions on the C termini of PDZ domain truncation mutants, designed for self‐binding. Multiple truncations of each PDZ domain were generated. The four residue extensions, which represent known specificity sequences of the target PDZ domains and cover both class I and II motifs, form intermolecular contacts in the expected manner for the interactions of PDZ domains with protein C termini for both classes. We present the structures of eight unique PDZ domains crystallized using this approach and focus on four which provide information on selectivity (PICK1 and the third PDZ domain of DLG2), binding site flexibility (the third PDZ domain of MPDZ), and peptide–domain interactions (MPDZ 12th PDZ domain). Analysis of our results shows a clear improvement in the chances of obtaining PDZ domain crystals by using this approach compared to similar truncations of the PDZ domains without the C‐terminal four residue extensions.

Direct and Specific Activation of Human Inward Rectifier K+ Channels by Membrane Phosphatidylinositol 4,5-Bisphosphate

Many ion channels are modulated by phosphatidylinositol 4,5-bisphosphate (PIP2), but studies examining the PIP2 dependence of channel activity have been limited to cell expression systems, which present difficulties for controlling membrane composition. We have characterized the PIP2 dependence of purified human Kir2.1 and Kir2.2 activity using 86Rb+ flux and patch clamp assays in liposomes of defined composition. We definitively show that these channels are directly activated by PIP2 and that PIP2 is absolutely required in the membrane for channel activity. The results provide the first quantitative description of the dependence of eukaryotic Kir channel function on PIP2 levels in the membrane; Kir2.1 shows measureable activity in as little as 0.01% PIP2, and open probability increases to ∼0.4 at 1% PIP2. Activation of Kir2.1 by phosphatidylinositol phosphates is also highly selective for PIP2; PI, PI(4)P, and PI(5)P do not activate channels, and PI(3,4,5)P3 causes minimal activity. The PIP2 dependence of eukaryotic Kir activity is almost exactly opposite that of KirBac1.1, which shows marked inhibition by PIP2. This raises the interesting hypothesis that PIP2 activation of eukaryotic channels reflects an evolutionary adaptation of the channel to the appearance of PIP2 in the eukaryotic cell membrane.

Dual-Mode Phospholipid Regulation of Human Inward Rectifying Potassium Channels

The lipid bilayer is a critical determinant of ion channel activity; however, efforts to define the lipid dependence of channel function have generally been limited to cellular expression systems in which the membrane composition cannot be fully controlled. We reconstituted purified human Kir2.1 and Kir2.2 channels into liposomes of defined composition to study their phospholipid dependence of activity using (86)Rb(+) flux and patch-clamp assays. Our results demonstrate that Kir2.1 and Kir2.2 have two distinct lipid requirements for activity: a specific requirement for phosphatidylinositol 4,5-bisphosphate (PIP(2)) and a nonspecific requirement for anionic phospholipids. Whereas we previously showed that PIP(2) increases the channel open probability, in this work we find that activation by POPG increases both the open probability and unitary conductance. Oleoyl CoA potently inhibits Kir2.1 by antagonizing the specific requirement for PIP(2), and EPC appears to antagonize activation by the nonspecific anionic requirement. Phosphatidylinositol phosphates can act on both lipid requirements, yielding variable and even opposite effects on Kir2.1 activity depending on the lipid background. Mutagenesis experiments point to the role of intracellular residues in activation by both PIP(2) and anionic phospholipids. In conclusion, we utilized purified proteins in defined lipid membranes to quantitatively determine the phospholipid requirements for human Kir channel activity.

Regulator of G-protein signaling 14 (RGS14) is a selective H-Ras effector.

Background Regulator of G-protein signaling (RGS) proteins have been well-described as accelerators of Gα-mediated GTP hydrolysis (“GTPase-accelerating proteins” or GAPs). However, RGS proteins with complex domain architectures are now known to regulate much more than Gα GTPase activity. RGS14 contains tandem Ras-binding domains that have been reported to bind to Rap- but not Ras GTPases in vitro, leading to the suggestion that RGS14 is a Rap-specific effector. However, more recent data from mammals and Drosophila imply that, in vivo, RGS14 may instead be an effector of Ras. Methodology/Principal Findings Full-length and truncated forms of purified RGS14 protein were found to bind indiscriminately in vitro to both Rap- and Ras-family GTPases, consistent with prior literature reports. In stark contrast, however, we found that in a cellular context RGS14 selectively binds to activated H-Ras and not to Rap isoforms. Co-transfection / co-immunoprecipitation experiments demonstrated the ability of full-length RGS14 to assemble a multiprotein complex with components of the ERK MAPK pathway in a manner dependent on activated H-Ras. Small interfering RNA-mediated knockdown of RGS14 inhibited both nerve growth factor- and basic fibrobast growth factor-mediated neuronal differentiation of PC12 cells, a process which is known to be dependent on Ras-ERK signaling. Conclusions/Significance In cells, RGS14 facilitates the formation of a selective Ras·GTP-Raf-MEK-ERK multiprotein complex to promote sustained ERK activation and regulate H-Ras-dependent neuritogenesis. This cellular function for RGS14 is similar but distinct from that recently described for its closely-related paralogue, RGS12, which shares the tandem Ras-binding domain architecture with RGS14.

The Centaurin Gamma-1 Gtpase-Like Domain Functions as an Ntpase.

Centaurins are a family of proteins that contain GTPase-activating protein domains, with the gamma family members containing in addition a GTPase-like domain. Centaurins reside mainly in the nucleus and are known to activate phosphoinositide 3-kinase, a key regulator of cell proliferation, motility and vesicular trafficking. In the present study, using X-ray structural analysis, enzymatic assays and nucleotide-binding studies, we show that, for CENTG1 (centaurin gamma-1) the GTPase-like domain has broader trinucleotide specificity. Alterations within the G4 motif of CENTG1 from the highly conserved NKXD found in typical GTPases to TQDR result in the loss of specificity, a lower affinity for the nucleotides and higher turnover rates. These results indicate that the centaurins could be more accurately classified as NTPases and point to alternative mechanisms of cell signalling control.

Molecular insights into ion channel function (Review)

Water is probably the most important molecule in biology. It solvates molecules, all biochemical reactions occur in it and it is a major driving force in protein folding. Phospholipid membranes separate different water environments, but connections do exist between the different compartments. The integral membrane proteins (IMPs) form these connections. In the case of ions, IMPs form the passageways that regulate ion movement across the membrane. Structural information from three ion distinct channels are examined to see how these channels first select for and then control the movement of their target ions. This review focuses on how these channels select for target ions and control their movement while taking into account and using different properties of water. This includes the use of hydrophobic gates, mimicking the water environment, and controlling ions indirectly by controlling water.