Nucleotide Binding States of Subunit A of the A-ATP Synthase and the Implication of P-Loop Switch in Evolution

The crystal structures of the nucleotide-empty (A_E), 5′-adenylyl-β,γ-imidodiphosphate (A_PNP)-bound, and ADP (A_DP)-bound forms of the catalytic A subunit of the energy producer A₁A_O ATP synthase from Pyrococcus horikoshii OT3 have been solved at 2.47 Å and 2.4 Å resolutions. The structures provide novel features of nucleotide binding and depict the residues involved in the catalysis of the A subunit. In the A_E form, the phosphate analog SO₄²⁻ binds, via a water molecule, to the phosphate binding loop (P-loop) residue Ser238, which is also involved in the phosphate binding of ADP and 5′-adenylyl-β,γ-imidodiphosphate. Together with amino acids Gly234 and Phe236, the serine residue stabilizes the arched P-loop conformation of subunit A, as shown by the 2.4-Å structure of the mutant protein S238A in which the P-loop flips into a relaxed state, comparable to the one in catalytic β subunits of F₁F_O ATP synthases. Superposition of the existing P-loop structures of ATPases emphasizes the unique P-loop in subunit A, which is also discussed in the light of an evolutionary P-loop switch in related A₁A_O ATP synthases, F₁F_O ATP synthases, and vacuolar ATPases and implicates diverse catalytic mechanisms inside these biological motors.     

Crystallographic and enzymatic insights into the mechanisms of Mg-ADP inhibition in the A1 complex of the A1AO ATP synthase

F-ATP synthases are described to have mechanisms which regulate the unnecessary depletion of ATP pool during an energy limited state of the cell. Mg-ADP inhibition is one of the regulatory features where Mg-ADP gets entrapped in the catalytic site, preventing the binding of ATP and further inhibiting ATP hydrolysis. Knowledge about the existence and regulation of the related archaeal-type A₁A_O ATP synthases (A₃B₃CDE₂FG₂ac) is limited. We demonstrate MgADP inhibition of the enzymatically active A₃B₃D- and A₃B₃DF complexes of Methanosarcina mazei Gö1 A-ATP synthase and reveal the importance of the amino acids P235 and S238 inside the P-loop (GPFGSGKTV) of the catalytic A subunit. Substituting these two residues by the respective P-loop residues alanine and cysteine (GAFGCGKTV) of the related eukaryotic V-ATPase increases significantly the ATPase activity of the enzyme variant and abolishes MgADP inhibition. The atomic structure of the P235A, S238C double mutant of subunit A of the Pyrococcus horikoshii OT3 A-ATP synthase provides details of how these critical residues affect nucleotide-binding and ATP hydrolysis in this molecular engine. The qualitative data are confirmed by quantitative results derived from fluorescence correlation spectroscopy experiments.     

The transition-like state and Pi entrance into the catalytic a subunit of the biological engine A-ATP synthase

Archaeal A-ATP synthases catalyze the formation of the energy currency ATP. The chemical mechanisms of ATP synthesis in A-ATP synthases are unknown. We have determined the crystal structure of a transition-like state of the vanadate-bound form of catalytic subunit A (A_Vi) of the A-ATP synthase from Pyrococcus horikoshii OT3. Two orthovanadate molecules were observed in the A_Vi structure, one of which interacts with the phosphate binding loop through residue S238. The second vanadate is positioned in the transient binding site, implicating for the first time the pathway for phosphate entry to the catalytic site. Moreover, since residues K240 and T241 are proposed to be essential for catalysis, the mutant structures of K240A and T241A were also determined. The results demonstrate the importance of these two residues for transition-state stabilization. The structures presented shed light on the diversity of catalytic mechanisms used by the biological motors A- and F-ATP synthases and eukaryotic V-ATPases.     

Conserved glycine residues in the P-loop of ATP synthases form a doorframe for nucleotide entrance

The phosphate binding loop (GXXXXGKT(S)) is conserved in several mononucleotide-binding proteins with similar three-dimensional structures. Although variations in other amino acids have been noted, the first glycine and glycine-lysine residues are highly conserved in all enzymes, whose role is yet to be understood. Alanine substitutions for critically positioned glycines—G234, G237, and G239—were generated for the catalytic A-subunit of A-ATP synthase from Pyrococcus horikoshii OT3, and their crystal structures were determined. They showed altered conformation for the phosphate binding loop, with G234A and G237A becoming flat and with G239A taking an intermediate conformation, resulting in the active-site region being closed to nucleotide entry. Furthermore, the essential amino acids S238 and K240, which normally interact with the nucleotide, become inaccessible. These mutant structures demonstrate the role of the strictly conserved glycine residues in guarding the active-site region for nucleotide entrance in archaea-type ATP synthases.     

The structure of genetically modified iron-sulfur cluster Fx in photosystem I as determined by X-ray absorption spectroscopy

Photosystem I (PS I) mediates light-induced electron transfer from P700 through a chlorophyll a, a quinone and a [4Fe-4S] iron-sulfur cluster F_X, located on the core subunits PsaA/B to iron-sulfur clusters F_A/B on subunit PsaC. Structure function relations in the native and in the mutant (psaB-C565S/D566E) of the cysteine ligand of F_X cluster were studied by X-ray absorption spectroscopy (EXAFS) and transient spectroscopy. The structure of F_X was determined in PS I lacking clusters F_A/B by interruption of the psaC2 gene of PS I in the cyanobacterium Synechocystis sp PCC 6803. PsaC-deficient mutant cells assembled the core subunits of PS I which mediated electron transfer mostly to the phylloquinone. EXAFS analysis of the iron resolved a [4Fe-4S] cluster in the native PsaC-deficient PS I. Each iron had 4 sulfur and 3 iron atoms in the first and second shells with average Fe-S and Fe-Fe distances of 2.27 Å and 2.69 Å, respectively. In the C565S/D566E serine mutant, one of the irons of the cluster was ligated to three oxygen atoms with Fe-O distance of 1.81 Å. The possibility that the structural changes induced an increase in the reorganization energy that consequently decreased the rate of electron transfer from the phylloquinone to F_X is discussed.     

Structural Insights into ribosome recycling factor interactions with the 70S ribosome

At the end of translation in bacteria, ribosome recycling factor (RRF) is used together with elongation factor G to recycle the 30S and 50S ribosomal subunits for the next round of translation. In x-ray crystal structures of RRF with the Escherichia coli 70S ribosome, RRF binds to the large ribosomal subunit in the cleft that contains the peptidyl transferase center. Upon binding of either E. coli or Thermus thermophilus RRF to the E. coli ribosome, the tip of ribosomal RNA helix 69 in the large subunit moves away from the small subunit toward RRF by 8 Å, thereby disrupting a key contact between the small and large ribosomal subunits termed bridge B2a. In the ribosome crystals, the ability of RRF to destabilize bridge B2a is influenced by crystal packing forces. Movement of helix 69 involves an ordered-to-disordered transition upon binding of RRF to the ribosome. The disruption of bridge B2a upon RRF binding to the ribosome seen in the present structures reveals one of the key roles that RRF plays in ribosome recycling, the dissociation of 70S ribosomes into subunits. The structures also reveal contacts between domain II of RRF and protein S12 in the 30S subunit that may also play a role in ribosome recycling.     

Unusual role of a cysteine residue in substrate binding and activity of human AP-endonuclease 1

The mammalian AP-endonuclease (APE1) repairs apurinic/apyrimidinic (AP) sites and strand breaks with 3′ blocks in the genome that are formed both endogenously and as intermediates during base excision repair. APE1 has an unrelated activity as a redox activator (and named Ref-1) for several trans-acting factors. In order to identify whether any of the seven cysteine residues in human APE1 affects its enzymatic function, we substituted these singly or multiply with serine. The repair activity is not affected in any of the mutants except those with C99S mutation. The Ser99-containing mutant lost affinity for DNA and its activity was inhibited by 10 mM Mg²⁺. However, the Ser99 mutant has normal activity in 2 mM Mg²⁺. Using crystallographic data and molecular dynamics simulation, we have provided a mechanistic basis for the altered properties of the C99S mutant. We earlier predicted that Mg²⁺, with potential binding sites A and B, binds at the B site of wild-type APE1-substrate complex and moves to the A site after cleavage occurs, as observed in the crystal structure. The APE1-substrate complex is stabilized by a H bond between His309 and the AP site. We now show that this bond is broken to destabilize the complex in the absence of the Mg²⁺. This effect due to the mutation of Cys99, ∼ 16 Å from the active site, on the DNA binding and activity is surprising. Mg²⁺ at the B site promotes stabilization of the C99S mutant complex. At higher Mg²⁺ concentration the A site is also filled, causing the B-site Mg²⁺ to shift together with the AP site. At the same time, the H bond between His309 and the AP site shifts toward the 5′ site of DNA. These shifts could explain the lower activity of the C99S mutant at higher [Mg²⁺]. The unexpected involvement of Cys99 in APE1's substrate binding and catalysis provides an example of involvement of a residue far from the active site.     

Structural and Functional Analysis of SoPIP2;1 Mutants Adds Insight into Plant Aquaporin Gating

Plant plasma membrane aquaporins facilitate water flux into and out of plant cells, thus coupling their cellular function to basic aspects of plant physiology. Posttranslational modifications of conserved phosphorylation sites, changes in cytoplasmic pH and the binding of Ca²⁺ can regulate water transport activity by gating the plasma membrane aquaporins. A structural mechanism unifying these diverse biochemical signals has emerged for the spinach aquaporin SoPIP2;1, although several questions concerning the opening mechanism remain. Here, we describe the X-ray structures of the S115E and S274E single SoPIP2;1 mutants and the corresponding double mutant. Phosphorylation of these serines is believed to increase water transport activity of SoPIP2;1 by opening the channel. However, all mutants crystallised in a closed conformation, as confirmed by water transport assays, implying that neither substitution fully mimics the phosphorylated state. Nevertheless, a half-turn extension of transmembrane helix 1 occurs upon the substitution of Ser115, which draws the C^α atom of Glu31 10 Å away from its wild-type conformation, thereby disrupting the divalent cation binding site involved in the gating mechanism. Mutation of Ser274 disorders the C-terminus but no other significant conformational changes are observed. Inspection of the hydrogen-bond interactions within loop D suggested that the phosphorylation of Ser188 may also produce an open channel, and this was supported by an increased water transport activity for the S188E mutant and molecular dynamics simulations. These findings add additional insight into the general mechanism of plant aquaporin gating.     

A dominant-negative Galpha mutant that traps a stable rhodopsin-Galpha-GTP-betagamma complex

Residues comprising the guanine nucleotide-binding sites of the α subunits of heterotrimeric (large) G-proteins (Gα subunits), as well as the Ras-related (small) G-proteins, are highly conserved. This is especially the case for the phosphate-binding loop (P-loop) where both Gα subunits and Ras-related G-proteins have a conserved serine or threonine residue. Substitutions for this residue in Ras and related (small) G-proteins yield nucleotide-depleted, dominant-negative mutants. Here we have examined the consequences of changing the conserved serine residue in the P-loop to asparagine, within a chimeric Gα subunit (designated αT*) that is mainly comprised of the α subunit of the retinal G-protein transducin and a limited region from the α subunit of Gi1. The αT*(S43N) mutant exhibits a significantly higher rate of intrinsic GDP-GTP exchange compared with wild-type αT*, with light-activated rhodopsin (R*) causing only a moderate increase in the kinetics of nucleotide exchange on αT*(S43N). The αT*(S43N) mutant, when bound to either GDP or GTP, was able to significantly slow the rate of R*-catalyzed GDP-GTP exchange on wild-type αT*. Thus, GTP-bound αT*(S43N), as well as the GDP-bound mutant, is capable of forming a stable complex with R*. αT*(S43N) activated the cGMP phosphodiesterase (PDE) with a dose-response similar to wild-type αT*. Activation of the PDE by αT*(S43N) was unaffected if either R* or β1γ1 alone was present, whereas it was inhibited when R* and the β1γ1 subunit were added together. Overall, our studies suggest that the S43N substitution on αT* stabilizes an intermediate on the G-protein activation pathway consisting of an activated G-protein-coupled receptor, a GTP-bound Gα subunit, and the β1γ1 complex.     

Spectroscopy and a high-resolution crystal structure of Tyr263 mutants of cyanobacterial phytochrome Cph1

Phytochromes are biliprotein photoreceptors that can be photoswitched between red-light-absorbing state (Pr) and far-red-light-absorbing state (Pfr). Although three-dimensional structures of both states have been reported, the photoconversion and intramolecular signaling mechanisms are still unclear. Here, we report UV-Vis absorbance, fluorescence and CD spectroscopy along with various photochemical parameters of the wild type and Y263F, Y263H and Y263S mutants of the Cph1 photosensory module, as well as a 2.0-Å-resolution crystal structure of the Y263F mutant in its Pr ground state. Although Y263 is conserved, we show that the aromatic character but not the hydroxyl group of Y263 is important for Pfr formation. The crystal structure of the Y263F mutant (Protein Data Bank ID: 3ZQ5) reaffirms the ZZZssa chromophore configuration and provides a detailed picture of its binding pocket, particularly conformational heterogeneity around the chromophore. Comparison with other phytochrome structures reveals differences in the relative position of the PHY (phytochrome specific) domain and the interaction of the tongue with the extreme N-terminus. Our data support the notion that native phytochromes in their Pr state are structurally heterogeneous.     

Crystal Structures of Limulus SAP-Like Pentraxin Reveal Two Molecular Aggregations

The serum-amyloid-P-component-like pentraxin from Limulus polyphemus, a recently discovered pentraxin species and important effector protein of the hemolymph immune system, displays two distinct doubly stacked cyclic molecular aggregations, heptameric and octameric. The refined three-dimensional structures determined by X-ray crystallography, both based on the same cDNA sequence, show that each aggregate is constructed from a similar dimer of protomers, which is repeated to make up the ring structure. The native octameric form has been refined at a resolution of 3 Å, the native heptameric form at 2.3 Å, and the phosphoethanolamine (PE)-bound octameric form at 2.7 Å. The existence of the hitherto undescribed heptameric form was confirmed by single-particle analysis using cryo-electron microscopy. In the native structures, the calcium-binding site is similar to that in human pentraxins, with two calcium ions bound in each subunit. Upon binding PE, however, each subunit binds a third calcium ion, with all three calcium ions contributing to the binding and orientation of the bound phosphate group within the ligand-binding pocket. While the phosphate is well-defined in the electron density, the ethanolamine group is poorly defined, suggesting structural and binding variabilities of this group. Although sequence homology with human serum amyloid P component is relatively low, structural homology is high, with very similar overall folds and a common affinity for PE. This is due, in part, to a “topological” equivalence of side-chain position. Identical side chains that are important in both function and fold, from different regions of the sequence in human and Limulus structures, occupy similar space within the overall subunit fold. Sequence and structure alignment, based on the refined three-dimensional structures presented here and the known horseshoe crab pentraxin sequences, suggest that adaptation and refinement of C-reactive-protein-mediated immune responses in these ancient creatures lacking antibody-based immunity are based on adaptation by gene duplication.     

Phosphorylation determines the calmodulin-mediated Ca2+ response and water permeability of AQP0

In Xenopus oocytes, the water permeability of AQP0 (P(f)) increases with removal of external calcium, an effect that is mediated by cytoplasmic calmodulin (CaM) bound to the C terminus of AQP0. To investigate the effects of serine phosphorylation on CaM-mediated Ca(2+) regulation of P(f), we tested the effects of kinase activation, CaM inhibition, and a series of mutations in the C terminus CaM binding site. Calcium regulation of AQP0 P(f) manifests four distinct phenotypes: Group 1, with high P(f) upon removal of external Ca(2+) (wild-type, S229N, R233A, S235A, S235K, K238A, and R241E); Group 2, with high P(f) in elevated (5 mm) external Ca(2+) (S235D and R241A); Group 3, with high P(f) and no Ca(2+) regulation (S229D, S231N, S231D, S235N, and S235N/I236S); and Group 4, with low P(f) and no Ca(2+) regulation (protein kinase A and protein kinase C activators, S229D/S235D and S235N/I236S). Within each group, we tested whether CaM binding mediates the phenotype, as shown previously for wild-type AQP0. In the presence of calmidazolium, a CaM inhibitor, S235D showed high P(f) and no Ca(2+) regulation, suggesting that S235D still binds CaM. Contrarily, S229D showed a decrease in recruitment of CaM, suggesting that S229D is unable to bind CaM. Taken together, our results suggest a model in which CaM acts as an inhibitor of AQP0 P(f). CaM binding is associated with a low P(f) state, and a lack of CaM binding is associated with a high P(f) state. Pathological conditions of inappropriate phosphorylation or calcium/CaM regulation could induce P(f) changes contributing to the development of a cataract.     

Functional consequences of the G235R mutation in liver arginase leading to hyperargininemia

Hyperargininemia is a rare autosomal disorder that results from a deficiency in hepatic type I arginase. This deficiency is the consequence of random point mutations that occur throughout the gene. The G235R patient mutation has been proposed to affect the catalytic activity and structural integrity of the protein [D. E. Ash, L. R. Scolnick, Z. F. Kanyo, J. G. Vockley, S. D. Cederbaum, and D. W. Christianson (1998) Mol. Genet. Metab. 64, 243-249]. The G235R (patient) and G235A (control) arginase mutants of rat liver arginase have been generated to probe the effects of these point mutations on the structure and function of hepatic type I arginase. Both mutant arginases were trimeric by gel filtration, but the control G235A mutant had 56% of wild-type activity and the G235R mutant had less than 0.03% activity compared to the wild-type enzyme. The G235R mutant contained undetectable levels of tightly bound manganese as determined by electron paramagnetic resonance, while the G235A mutant had a Mn(II) stoichiometry of 2 Mn/subunit. Molecular modeling indicates that the introduction of an arginine residue at position 235 results in a major rearrangement of the metal ligands that compromise Mn(II) binding.     

Human intestinal maltase-glucoamylase: crystal structure of the N-terminal catalytic subunit and basis of inhibition and substrate specificity

Human maltase-glucoamylase (MGAM) is one of the two enzymes responsible for catalyzing the last glucose-releasing step in starch digestion. MGAM is anchored to the small-intestinal brush-border epithelial cells and contains two homologous glycosyl hydrolase family 31 catalytic subunits: an N-terminal subunit (NtMGAM) found near the membrane-bound end and a C-terminal luminal subunit (CtMGAM). In this study, we report the crystal structure of the human NtMGAM subunit in its apo form (to 2.0 Å) and in complex with acarbose (to 1.9 Å). Structural analysis of the NtMGAM-acarbose complex reveals that acarbose is bound to the NtMGAM active site primarily through side-chain interactions with its acarvosine unit, and almost no interactions are made with its glycone rings. These observations, along with results from kinetic studies, suggest that the NtMGAM active site contains two primary sugar subsites and that NtMGAM and CtMGAM differ in their substrate specificities despite their structural relationship. Additional sequence analysis of the CtMGAM subunit suggests several features that could explain the higher affinity of the CtMGAM subunit for longer maltose oligosaccharides. The results provide a structural basis for the complementary roles of these glycosyl hydrolase family 31 subunits in the bioprocessing of complex starch structures into glucose.     

The central core region of yeast ribosomal protein L11 is important for subunit joining and translational fidelity

Yeast ribosomal protein L11 is positioned at the intersubunit cleft of the large subunit central protuberance, forming an intersubunit bridge with the small subunit protein S18. Mutants were engineered in the central core region of L11 which interacts with Helix 84 of the 25S rRNA. Numerous mutants in this region conferred 60S subunit biogenesis defects. Specifically, many mutations of F96 and the A66D mutant promoted formation of halfmers as assayed by sucrose density ultracentrifugation. Halfmer formation was not due to deficiency in 60S subunit production, suggesting that the mutants affected subunit-joining. Chemical modification analyses indicated that the A66D mutant, but not the F96 mutants, promoted changes in 25S rRNA structure, suggesting at least two modalities for subunit joining defects. 25S rRNA structural changes were located both adjacent to A66D (in H84), and more distant (in H96-7). While none of the mutants significantly affected ribosome/tRNA binding constants, they did have strong effects on cellular growth at both high and low temperatures, in the presence of translational inhibitors, and promoted changes in translational fidelity. Two distinct mechanisms are proposed by which L11 mutants may affect subunit joining, and identification of the amino acids associated with each of these processes are presented. These findings may have implications for our understanding of multifaceted diseases such as Diamond–Blackfan anemia which have been linked in part with mutations in L11.     

Dynamics and Stability in Maturation of a T = 4 Virus

Nudaurelia capensis ω virus is a T = 4, icosahedral virus with a bipartite, positive-sense RNA genome. Expression of the coat protein gene in a baculovirus system was previously shown to result in the formation of procapsids when purified at pH 7.6. Procapsids are round, porous particles (480 Å diameter) and have T = 4 quasi-symmetry. Reduction of pH from 7.6 to 5.0 resulted in virus-like particles (VLP_5.0) that are morphologically identical with authentic virions, with an icosahedral-shaped capsid and a maximum dimension of 410 Å. VLP_5.0 undergoes a maturation cleavage between residues N570 and F571, creating the covalently independent γ peptide (residues 571-641) that remains associated with the particle. This cleavage also occurs in authentic virions, and in each case, it renders the morphological change irreversible (i.e., capsids do not expand when the pH is raised back to 7.6). However, a non-cleavable mutant, N570T, undergoes the transition reversibly (NT_7.6 ↔ NT_5.0). We used electron cryo-microscopy and three-dimensional image reconstruction to study the icosahedral structures of NT_7.6, NT_5.0, and VLP_5.0 at about 8, 6, and 6 Å resolution, respectively. We employed the 2. 8-Å X-ray model of the mature virus, determined at pH 7.0 (XR_7.0), to establish (1) how and why procapsid and capsid structures differ, (2) why lowering pH drives the transition, and (3) why the non-cleaving NT_5.0 is reversible. We show that procapsid assembly minimizes the differences in quaternary interactions in the particle. The two classes of 2-fold contacts in the T = 4 surface lattice are virtually identical, both mediated by similarly positioned but dynamic γ peptides. Furthermore, quasi and icosahedral 3-fold interactions are indistinguishable. Maturation results from neutralizing the repulsive negative charge at subunit interfaces with significant differentiation of quaternary interactions (one 2-fold becomes flat, mediated by a γ peptide, while the other is bent with the γ peptide disordered) and dramatic stabilization of the particle. The γ peptide at the flat contact remains dynamic when cleavage cannot occur (NT_5.0) but becomes totally immobilized by noncovalent interactions after cleavage (VLP_5.0).     

Mitochondrial ATP synthase. Crystal structure of the catalytic F1 unit in a vanadate-induced transition-like state and implications for mechanism

ATP synthesis from ADP, P(i), and Mg2+ takes place in mitochondria on the catalytic F1 unit (alpha3beta3gammedeltaepsilon) of the ATP synthase complex (F0F1), a remarkable nanomachine that interconverts electrochemical and mechanical energy, producing the high energy terminal bond of ATP. In currently available structural models of F1, the P-loop (amino acid residues 156GGAGVGKT163) contributes to substrate binding at the subunit catalytic sites. Here, we report the first transition state-like structure of F1 (ADP.V(i).Mg.F1) from rat liver that was crystallized with the phosphate (P(i)) analog vanadate (VO(3-)4 or V(i)). Compared with earlier "ground state" structures, this new F1 structure reveals that the active site region has undergone significant remodeling. P-loop residue alanine 158 is located much closer to V(i) than it is to P(i) in a previous structural model. No significant movements of P-loop residues of the subunit were observed at its analogous but noncatalytic sites. Under physiological conditions, such active site remodeling involving the small hydrophobic alanine residue may promote ATP synthesis by lowering the local dielectric constant, thus facilitating the dehydration of ADP and P(i). This new crystallographic study provides strong support for the catalytic mechanism of ATP synthesis deduced from earlier biochemical studies of liver F1 conducted in the presence of V(i) (Ko, Y. H., Bianchet, M., Amzel, L. M., and Pedersen, P. L. (1997) J. Biol. Chem. 272, 18875-18881; Ko, Y. H., Hong, S., and Pedersen, P. L. (1999) J. Biol. Chem. 274, 28853-28856).     

Influence of the Cytoplasmic Domains of Aquaporin-4 on Water Conduction and Array Formation

Phosphorylation of Ser180 in cytoplasmic loop D has been shown to reduce the water permeability of aquaporin (AQP) 4, the predominant water channel in the brain. However, when the structure of the S180D mutant (AQP4M23S180D), which was generated to mimic phosphorylated Ser180, was determined to 2.8 Å resolution using electron diffraction patterns, it showed no significant differences from the structure of the wild-type channel. High-resolution density maps usually do not resolve protein regions that are only partially ordered, but these can sometimes be seen in lower-resolution density maps calculated from electron micrographs. We therefore used images of two-dimensional crystals and determined the structure of AQP4M23S180D at 10 Å resolution. The features of the 10-Å density map are consistent with those of the previously determined atomic model; in particular, there were no indications of any obstruction near the cytoplasmic pore entrance. In addition, water conductance measurements, both in vitro and in vivo, show the same water permeability for wild-type and mutant AQP4M23, suggesting that the S180D mutation neither reduces water conduction through a conformational change nor reduces water conduction by interacting with a protein that would obstruct the cytoplasmic channel entrance. Finally, the 10-Å map shows a cytoplasmic density in between four adjacent tetramers that most likely represents the association of four N termini. This finding supports the critical role of the N terminus of AQP4 in the stabilization of orthogonal arrays, as well as their interference through lipid modification of cysteine residues in the longer N-terminal isoform.     

Partially folded bovine pancreatic trypsin inhibitor analogues attain fully native structures when co-crystallized with S195A rat trypsin

Crystal structures, at 1.7 Å resolution, were solved for complexes between each of two chemically synthesized partially folded analogues of bovine pancreatic trypsin inhibitor (BPTI) with the proteolytically inactive rat trypsin mutant S195A. The BPTI analogue termed [14-38]_Abu retains only the disulfide bond between Cys14 and Cys38, while Cys5, Cys30, Cys51, and Cys55 are replaced by isosteric α-amino-n-butyric acid residues. The analogue K26P,A27D[14-38]_Abu contains two further replacements, by statistically favored residues, in the type I β-turn that has been suggested to be a main site for initiation of BPTI folding. As a control, the structure of the complex between S195A trypsin and wild-type BPTI was also solved. Despite significant differences in the degree of structure detected among these three BPTIs in solution by several biophysical techniques, their tertiary folds once bound to S195A trypsin in a crystalline lattice are essentially superimposable.