Structural insights into quinolone antibiotic resistance mediated by pentapeptide repeat proteins: conserved surface loops direct the activity of a Qnr protein from a gram-negative bacterium

Quinolones inhibit bacterial type II DNA topoisomerases (e.g. DNA gyrase) and are among the most important antibiotics in current use. However, their efficacy is now being threatened by various plasmid-mediated resistance determinants. Of these, the pentapeptide repeat-containing (PRP) Qnr proteins are believed to act as DNA mimics and are particularly prevalent in gram-negative bacteria. Predicted Qnr-like proteins are also present in numerous environmental bacteria. Here, we demonstrate that one such, Aeromonas hydrophila AhQnr, is soluble, stable, and relieves quinolone inhibition of Escherichia coli DNA gyrase, thus providing an appropriate model system for gram-negative Qnr proteins. The AhQnr crystal structure, the first for any gram-negative Qnr, reveals two prominent loops (1 and 2) that project from the PRP structure. Deletion mutagenesis demonstrates that both contribute to protection of E. coli DNA gyrase from quinolones. Sequence comparisons indicate that these are likely to be present across the full range of gram-negative Qnr proteins. On this basis we present a model for the AhQnr:DNA gyrase interaction where loop1 interacts with the gyrase A 'tower' and loop2 with the gyrase B TOPRIM domains. We propose this to be a general mechanism directing the interactions of Qnr proteins with DNA gyrase in gram-negative bacteria.     

Pentapeptide repeat protein QnrB1 requires ATP hydrolysis to rejuvenate poisoned gyrase complexes

DNA gyrase, a type II topoisomerase found predominantly in bacteria, is the target for a variety of ‘poisons’, namely natural product toxins (e.g. albicidin, microcin B17) and clinically important synthetic molecules (e.g. fluoroquinolones). Resistance to both groups can be mediated by pentapeptide repeat proteins (PRPs). Despite long-term studies, the mechanism of action of these protective PRPs is not known. We show that a PRP, QnrB1 provides specific protection against fluoroquinolones, which strictly requires ATP hydrolysis by gyrase. QnrB1 binds to the GyrB protein and stimulates ATPase activity of the isolated N-terminal ATPase domain of GyrB (GyrB43). We probed the QnrB1 binding site using site-specific incorporation of a photoreactive amino acid and mapped the crosslinks to the GyrB43 protein. We propose a model in which QnrB1 binding allosterically promotes dissociation of the fluoroquinolone molecule from the cleavage complex.     

Loop prediction for a GPCR homology model: Algorithms and results

We present loop structure prediction results of the intracellular and extracellular loops of four G‐protein‐coupled receptors (GPCRs): bovine rhodopsin (bRh), the turkey β1‐adrenergic (β1Ar), the human β2‐adrenergic (β2Ar) and the human A2a adenosine receptor (A2Ar) in perturbed environments. We used the protein local optimization program, which builds thousands of loop candidates by sampling rotamer states of the loops' constituent amino acids. The candidate loops are discriminated between with our physics‐based, all‐atom energy function, which is based on the OPLS force field with implicit solvent and several correction terms. For relevant cases, explicit membrane molecules are included to simulate the effect of the membrane on loop structure. We also discuss a new sampling algorithm that divides phase space into different regions, allowing more thorough sampling of long loops that greatly improves results. In the first half of the paper, loop prediction is done with the GPCRs' transmembrane domains fixed in their crystallographic positions, while the loops are built one‐by‐one. Side chains near the loops are also in non‐native conformations. The second half describes a full homology model of β2Ar using β1Ar as a template. No information about the crystal structure of β2Ar was used to build this homology model. We are able to capture the architecture of short loops and the very long second extracellular loop, which is key for ligand binding. We believe this the first successful example of an RMSD validated, physics‐based loop prediction in the context of a GPCR homology model. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Partial deletion of β9 loop in pancreatic lipase-related protein 2 reduces enzyme activity with a larger effect on long acyl chain substrates

Structural studies on pancreatic lipase have revealed a complex architecture of surface loops surrounding the enzyme active site and potentially involved in interactions with lipids. Two of them, the lid and β9 loop, expose a large hydrophobic surface and are considered as acyl chain binding sites based on their interaction with an alkyl phosphonate inhibitor. While the role of the lid in substrate recognition and selectivity has been extensively studied, the implication of β9 loop in acyl chain stabilization remained hypothetical. The characterization of an enzyme with a natural deletion of the lid, guinea pig pancreatic lipase-related protein 2 (GPLRP2), suggests however an essential contribution of the β9 loop in the stabilization of the acyl enzyme intermediate formed during the lipolysis reaction. A GPLRP2 mutant with a seven-residue deletion of β9 loop (GPLRP2-Δβ9) was produced and its enzyme activity was measured using various substrates (triglycerides, monoglycerides, galactolipids, phospholipids, vinyl esters) with short, medium and long acyl chains. Whatever the substrate tested, GPLRP2-Δβ9 activity is drastically reduced compared to that of wild-type GPLRP2 and this effect is more pronounced as the length of substrate acyl chain increases. Changes in relative substrate selectivity and stereoselectivity remained however weak. The deletion within β9 loop has also a negative effect on the rate of enzyme inhibition by alkyl phosphonates. All these findings indicate that the reduced enzyme turnover observed with GPLRP2-Δβ9 results from a weaker stabilization of the acyl enzyme intermediate due to a loss of hydrophobic interactions.     

Cutting off functional loops from homodimeric enzyme superoxide dismutase 1 (SOD1) leaves monomeric β-barrels

Demetallation of the homodimeric enzyme Cu/Zn-superoxide dismutase (SOD1) is known to unleash pronounced dynamic motions in the long active-site loops that comprise almost a third of the folded structure. The resulting apo species, which shows increased propensity to aggregate, stands out as the prime disease precursor in amyotrophic lateral sclerosis (ALS). Even so, the detailed structural properties of the apoSOD1 framework have remained elusive and controversial. In this study, we examine the structural interplay between the central apoSOD1 barrel and the active-site loops by simply cutting them off; loops IV and VII were substituted with short Gly-Ala-Gly linkers. The results show that loop removal breaks the dimer interface and leads to soluble, monomeric β-barrels with high structural integrity. NMR-detected nuclear Overhauser effects are found between all of the constituent β-strands, confirming ordered interactions across the whole barrel. Moreover, the breathing motions of the SOD1 barrel are overall insensitive to loop removal and yield hydrogen/deuterium protection factors typical for cooperatively folded proteins (i.e. the active-site loops act as a "bolt-on" domain with little dynamic influence on its structural foundation). The sole exceptions are the relatively low protection factors in β-strand 5 and the turn around Gly-93, a hot spot for ALS-provoking mutations, which decrease even further upon loop removal. Taken together, these data suggest that the cytotoxic function of apoSOD1 does not emerge from its folded ground state but from a high energy intermediate or even from the denatured ensemble.     

Crystal structure and mutational analysis of Ca2+-independent type II antifreeze protein from longsnout poacher, Brachyopsis rostratus

We recently found that longsnout poacher (Brachyosis rostratus) produces a Ca²⁺-independent type II antifreeze protein (lpAFP) and succeeded in expressing recombinant lpAFP using Phichia pastoris. Here, we report, for the first time, the X-ray crystal structure of lpAFP at 1.34 Å resolution. The lpAFP structure displayed a relatively planar surface, which encompasses two loop regions (Cys86-Lys89 and Asn91-Cys97) and a short β-strand (Trp109-Leu112) with three unstructured segments (Gly57-Ile58, Ala103-Ala104, and Pro113-His118). Electrostatic calculation of the protein surface showed that the relatively planar surface was divided roughly into a hydrophobic area (composed of the three unstructured segments lacking secondary structure) and a hydrophilic area (composed of the loops and β-strand). Site-directed mutation of Ile58 with Phe at the center of the hydrophobic area decreased activity significantly, whereas mutation of Leu112 with Phe at an intermediate area between the hydrophobic and hydrophilic areas retained complete activity. In the hydrophilic area, a peptide-swap mutant in the loops retained 60% activity despite simultaneous mutations of eight residues. We conclude that the epicenter of the ice-binding site of lpAFP is the hydrophobic region, which is centered by Ile58, in the relatively planar surface. We built an ice-binding model for lpAFP on the basis of a lattice match of ice and constrained water oxygen atoms surrounding the hydrophobic area in the lpAFP structure. The model in which lpAFP has been docked to a secondary prism (2-1-10) plane, which is different from the one determined for Ca²⁺-independent type II AFP from sea raven (11-21), appears to explain the results of the mutagenesis analysis.     

A mutational analysis and molecular dynamics simulation of quinolone resistance proteins QnrA1 and QnrC from <Emphasis Type="Italic">Proteus mirabilis</Emphasis>

Background  

The first report on the transferable, plasmid-mediated quinolone-resistance determinant qnrA1 was in 1998. Since then, qnr alleles have been discovered worldwide in clinical strains of Gram-negative bacilli. Qnr proteins confer quinolone resistance, and belong to the pentapeptide repeat protein (PRP) family. Several PRP crystal structures have been solved, but little is known about the functional significance of their structural arrangement.     

The Pentapeptide Repeat Proteins MfpAMt and QnrB4 Exhibit Opposite Effects on DNA Gyrase Catalytic Reactions and on the Ternary Gyrase-DNA-Quinolone Complex

MfpA_Mt and QnrB4 are two newly characterized pentapeptide repeat proteins (PRPs) that interact with DNA gyrase. The mfpA_Mt gene is chromosome borne in Mycobacterium tuberculosis, while qnrB4 is plasmid borne in enterobacteria. We expressed and purified the two PRPs and compared their effects on DNA gyrase, taking into account host specificity, i.e., the effect of MfpA_Mt on M. tuberculosis gyrase and the effect of QnrB4 on Escherichia coli gyrase. Whereas QnrB4 inhibited E. coli gyrase activity only at concentrations higher than 30 μM, MfpA_Mt inhibited all catalytic reactions of the M. tuberculosis gyrase described for this enzyme (supercoiling, cleavage, relaxation, and decatenation) with a 50% inhibitory concentration of 2 μM. We showed that the D87 residue in GyrA has a major role in the MfpA_Mt-gyrase interaction, as D87H and D87G substitutions abolished MfpA_Mt inhibition of M. tuberculosis gyrase catalytic reactions, while A83S modification did not. Since MfpA_Mt and QnrB4 have been involved in resistance to fluoroquinolones, we measured the inhibition of the quinolone effect in the presence of each PRP. QnrB4 reversed quinolone inhibition of E. coli gyrase at 0.1 μM as described for other Qnr proteins, but MfpA_Mt did not modify M. tuberculosis gyrase inhibition by fluoroquinolones. Crossover experiments showed that MfpA_Mt also inhibited E. coli gyrase function, while QnrB4 did not reverse quinolone inhibition of M. tuberculosis gyrase. In conclusion, our in vitro experiments showed that MfpA_Mt and QnrB4 exhibit opposite effects on DNA gyrase and that these effects are protein and species specific.The pentapeptide repeat protein (PRP) family includes more than 500 proteins in the prokaryotic and eukaryotic kingdoms (45). PRPs are characterized by the repetition of the pentapeptide repeat motif [S,T,A,V][D,N][L,F][S,T,R][G] (6), which results in a right-handed β-helical structure (8, 17). The functions of the majority of the members of this large and heterogeneous family remain unknown, but three PRPs, McbG (from Escherichia coli), MfpA_Mt (from Mycobacterium tuberculosis), and Qnr (from Klebsiella pneumoniae and other enterobacteria) were reported to interact with DNA gyrase, at least with the E. coli enzyme (17, 33, 35, 44). McbG was shown to protect E. coli DNA gyrase from the toxic action of microcin B17 (33). Qnr and MfpA_Mt were involved in resistance to fluoroquinolones, which are synthetic antibacterial agents prescribed worldwide for the treatment of various infectious diseases, including tuberculosis (7).DNA gyrase is an essential ATP-dependent enzyme that transiently cleaves a segment of double-stranded DNA, passes another piece of DNA through the break, and reseals it (12). DNA gyrase is unique in catalyzing the negative supercoiling of DNA in order to facilitate the progression of RNA polymerase. Most eubacteria, such as E. coli, have two type II DNA topoisomerases, i.e., DNA gyrase and topoisomerase IV, but a few, such as M. tuberculosis, harbor only DNA gyrase (11).Quinolones target type II topoisomerases, and their activity is measured by the inhibition of supercoiling by gyrase or decatenation by topoisomerase IV and stabilization of complexes composed of topoisomerase covalently linked to cleaved DNA (16). The DNA gyrase active enzyme is a GyrA₂GyrB₂ heterotetramer. The quinolone-gyrase interaction site in gyrase is thought to be located at the so-called quinolone resistance-determining regions (QRDR) in the A subunit (amino acids 57 to 196 in GyrA) and the B subunit (amino acids 426 to 466 in GyrB), which contain the majority of mutations conferring quinolone resistance (19). The GyrB QRDR is thought to interact with the GyrA QRDR to form a drug-binding pocket (18). Resistance to quinolones is usually due to chromosomal mutations either in the structural genes encoding type II topoisomerases (QRDR) (19, 22) or in regulatory genes producing decreased cell wall permeability or enhancement of efflux pumps (36). The recent emergence of plasmid-borne resistance genes, such as qnr (9, 13, 31, 38, 46), aac(6′)-Ib-cr (32, 39) and qepA (34, 47), renewed interest in quinolone resistance, and especially interest in the new Qnr-based mechanism. Three qnr determinants have been identified so far: qnrA (variants A1 to A6), qnrB (variants B1 to B19), and qnrS (variants S1 and S2) (15, 21, 23, 27). Qnr confers a new mechanism of quinolone resistance by mediating DNA gyrase protection (42): in vitro, QnrA1 and QnrB1 protect E. coli DNA gyrase and topoisomerase IV from the inhibitory effect of fluoroquinolones in a concentration-dependent manner (23, 42-44). Although Qnr was shown to bind GyrA and GyrB and compete with DNA binding, the consequences of Qnr binding for enzyme performance are not yet clear.mfpA, a chromosomal gene that encodes a 192-amino-acid PRP, is an intrinsic quinolone resistance determinant of Mycobacterium smegmatis (29). A similar gene, mfpA_Mt, was found in the M. tuberculosis genome, and MfpA_Mt shows 67% identity with MfpA. Recent crystallography analysis of MfpA_Mt showed that its atomic structure displays size, shape, and electrostatic similarity to B-form DNA, and MfpA_Mt has been suggested to interact with DNA gyrase via DNA mimicry (17). The effect of MfpA_Mt was studied by testing E. coli DNA gyrase, and MfpA_Mt showed catalytic inhibition (17, 37), but whether it protects gyrase from quinolones was not assessed. Because the structure and functions of the M. tuberculosis gyrase, as well as its interaction with quinolones, differ from those of the E. coli gyrase (2, 3, 20, 26, 28), we suspected that the PRP-topoisomerase interaction exhibits species specificity, i.e., depends on the proteins issued from the same host.Our objective was to compare the effects of MfpA_Mt and Qnr on their respective targets, i.e., the effect of MfpA_Mt on the M. tuberculosis gyrase and the effect of Qnr on the E. coli gyrase, by assessing (i) the catalytic reactions of the enzyme and (ii) the interaction with the DNA gyrase-DNA-fluoroquinolone ternary complex. Among the Qnr proteins, we selected the QnrB4 protein, which is a frequent variant of QnrB and has not yet been purified and studied. We cloned, expressed, and purified the two PRPs, MfpA_Mt and QnrB4, as recombinant His tag fusion proteins and assessed their functions under the same experimental conditions.     

Surface loops of extracellular phospholipase A(1) determine both substrate specificity and preference for lysophospholipids

Members of the pancreatic lipase family exhibit both lipase activity toward triacylglycerol and/or phospholipase A(1) (PLA(1)) activity toward certain phospholipids. Some members of the pancreatic lipase family exhibit lysophospholipase activity in addition to their lipase and PLA(1) activities. Two such enzymes, phosphatidylserine (PS)-specific PLA(1) (PS-PLA(1)) and phosphatidic acid (PA)-selective PLA(1)α (PA-PLA(1)α, also known as LIPH) specifically hydrolyze PS and PA, respectively. However, little is known about the mechanisms that determine their substrate specificities. Crystal structures of lipases and mutagenesis studies have suggested that three surface loops, namely, β5, β9, and lid, have roles in determining substrate specificity. To determine roles of these loop structures in the substrate recognition of these PLA(1) enzymes, we constructed a number of PS-PLA(1) mutants in which the three surface loops are replaced with those of PA-PLA(1)α. The results indicate that the surface loops, especially the β5 loop, of PA-PLA(1)α play important roles in the recognition of PA, whereas other structure(s) in PS-PLA(1) is responsible for PS preference. In addition, β5 loop of PS-PLA(1) has a crucial role in lysophospholipase activity toward lysophosphatidylserine. The present study revealed the critical role of lipase surface loops, especially the β5 loop, in determining substrate specificities of PLA(1) enzymes.     

The 1.8-A crystal structure of alpha1-acid glycoprotein (Orosomucoid) solved by UV RIP reveals the broad drug-binding activity of this human plasma lipocalin

α₁-Acid glycoprotein (AGP) is an important drug-binding protein in human plasma and, as an acute-phase protein, it has a strong influence on pharmacokinetics and pharmacodynamics of many pharmaceuticals. We report the crystal structure of the recombinant unglycosylated human AGP at 1.8 Å resolution, which was solved using the new method of UV-radiation-damage-induced phasing (UV RIP). AGP reveals a typical lipocalin fold comprising an eight-stranded β-barrel. Of the four loops that form the entrance to the ligand-binding site, loop 1, which connects β-strands A and B, is among the longest observed so far and exhibits two full turns of an α-helix. Furthermore, it carries one of the five N-linked glycosylation sites, while a second one occurs underneath the tip of loop 2. The branched, partly hydrophobic, and partly acidic cavity, together with the presumably flexible loop 1 and the two sugar side chains at its entrance, explains the diverse ligand spectrum of AGP, which is known to vary with changes in glycosylation pattern.     

Structure of the Nidogen Binding LE Module of the Laminin γ1 Chain in Solution

The structure of the single LE module between residues 791 and 848 of the laminin γ1 chain, which contains the high affinity binding site for nidogen, has been probed using NMR methods. The module folds into an autonomous domain which has a stable and unique three-dimensional (3D) structure in solution. The 3D structure was determined on the basis of 362 interproton distance constraints derived from nuclear Overhauser enhancement measurements and 39 π angles, supplemented by 5 ψ and 22 χ₁angles. The main features of the NMR structures are two-stranded antiparallel β-sheets which are separated by loops and cross-connected by four disulfide bridges. The N-terminal segment which contains the first three disulfide bridges is similar to epidermal growth factor. The C-terminal segment has an S-like backbone profile with a crossover at the last disulfide bridge and comprises two three-residue long β-strands that form an antiparallel β-sheet. The LE module possesses an exposed nidogen binding loop that projects away from the main body of the protein. The side-chains of three amino acids which are crucial for binding (Asp, Asn, Val) are all exposed at the domain surface. An inactivating Asn-Ser mutation in this region showed the same 3D structure indicating that these three residues, and possibly an additional Tyr in an adjacent loop, provide direct contacts in the interaction with nidogen.     

Crystal structure of Lsm3 octamer from Saccharomyces cerevisiae: implications for Lsm ring organisation and recruitment

Sm and Sm-like (Lsm) proteins are core components of the ribonucleoprotein complexes essential to key nucleic acid processing events within the eukaryotic cell. They assemble as polyprotein ring scaffolds that have the capacity to bind RNA substrates and other necessary protein factors. The crystal structure of yeast Lsm3 reveals a new organisation of the L/Sm β-propeller ring, containing eight protein subunits. Little distortion of the characteristic L/Sm fold is required to form the octamer, indicating that the eukaryotic Lsm ring may be more pliable than previously thought. The homomeric Lsm3 octamer is found to successfully recruit Lsm6, Lsm2 and Lsm5 directly from yeast lysate. Our crystal structure shows the C-terminal tail of each Lsm3 subunit to be engaged in connections across rings through specific β-sheet interactions with elongated loops protruding from neighbouring octamers. While these loops are of distinct length for each Lsm protein and generally comprise low-complexity polar sequences, several Lsm C-termini comprise hydrophobic sequences suitable for β-sheet interactions. The Lsm3 structure thus provides evidence for protein-protein interactions likely utilised by the highly variable Lsm loops and termini in the recruitment of RNA processing factors to mixed Lsm ring scaffolds. Our coordinates also provide updated homology models for the active Lsm[1-7] and Lsm[2-8] heptameric rings.     

Fungal β-trefoil trypsin inhibitors cnispin and cospin demonstrate the plasticity of the β-trefoil fold

The recently identified fungal protease inhibitors cnispin, from Clitocybe nebularis, and cospin, from Coprinopsis cinerea, are both β-trefoil proteins highly specific for trypsin. The reactive site residue of cospin, Arg27, is located on the β2–β3 loop. We show here, that the reactive site residue in cnispin is Lys127, located on the β11–β12 loop. Cnispin is a substrate-like inhibitor and the β11–β12 loop is yet another β-trefoil fold loop recruited for serine protease inhibition. By site-directed mutagenesis of the P1 residues in the β2–β3 and β11–β12 loops in cospin and cnispin, protease inhibitors with different specificities for trypsin and chymotrypsin inhibition have been engineered. Double headed inhibitors of trypsin or trypsin and chymotrypsin were prepared by introducing a second specific site residue into the β2–β3 loop in cnispin and into the β11–β12 loop in cospin. These results show that β-trefoil protease inhibitors from mushrooms exhibit broad plasticity of loop utilization in protease inhibition.     

Structural and Functional Characterization of the NHR1 Domain of the Drosophila Neuralized E3 Ligase in the Notch Signaling Pathway

The Notch signaling pathway is critical for many developmental processes and requires complex trafficking of both Notch receptor and its ligands, Delta and Serrate. In Drosophila melanogaster, the endocytosis of Delta in the signal-sending cell is essential for Notch receptor activation. The Neuralized protein from D. melanogaster (Neur) is a ubiquitin E3 ligase, which binds to Delta through its first neuralized homology repeat 1 (NHR1) domain and mediates the ubiquitination of Delta for endocytosis. Tom, a Bearded protein family member, inhibits the Neur-mediated endocytosis through interactions with the NHR1 domain. We have identified the domain boundaries of the novel NHR1 domain, using a screening system based on our cell-free protein synthesis method, and demonstrated that the identified Neur NHR1 domain had binding activity to the 20-residue peptide corresponding to motif 2 of Tom by isothermal titration calorimetry experiments. We also determined the solution structure of the Neur NHR1 domain by heteronuclear NMR methods, using a ¹⁵N/¹³C-labeled sample. The Neur NHR1 domain adopts a characteristic β-sandwich fold, consisting of a concave five-stranded antiparallel β-sheet and a convex seven-stranded antiparallel β-sheet. The long loop (L6) between the β6 and β7 strands covers the hydrophobic patch on the concave β-sheet surface, and the Neur NHR1 domain forms a compact globular fold. Intriguingly, in spite of the slight, but distinct, differences in the topology of the secondary structure elements, the structure of the Neur NHR1 domain is quite similar to those of the B30.2/SPRY domains, which are known to mediate specific protein-protein interactions. Further NMR titration experiments of the Neur NHR1 domain with the 20-residue Tom peptide revealed that the resonances originating from the bottom area of the β-sandwich (the L3, L5, and L11 loops, as well as the tip of the L6 loop) were affected. In addition, a structural comparison of the Neur NHR1 domain with the first NHR domain of the human KIAA1787 protein, which is from another NHR subfamily and does not bind to the 20-residue Tom peptide, suggested the critical amino acid residues for the interactions between the Neur NHR1 domain and the Tom peptide. The present structural study will shed light on the role of the Neur NHR1 domain in the Notch signaling pathway.     

Loop‐loop interactions govern multiple steps in indole‐3‐glycerol phosphate synthase catalysis

Substrate binding, product release, and likely chemical catalysis in the tryptophan biosynthetic enzyme indole‐3‐glycerol phosphate synthase (IGPS) are dependent on the structural dynamics of the β1α1 active‐site loop. Statistical coupling analysis and molecular dynamic simulations had previously indicated that covarying residues in the β1α1 and β2α2 loops, corresponding to Arg54 and Asn90, respectively, in the Sulfolobus sulfataricus enzyme (ssIGPS), are likely important for coordinating functional motions of these loops. To test this hypothesis, we characterized site mutants at these positions for changes in catalytic function, protein stability and structural dynamics for the thermophilic ssIGPS enzyme. Although there were only modest changes in the overall steady‐state kinetic parameters, solvent viscosity and solvent deuterium kinetic isotope effects indicated that these amino acid substitutions change the identity of the rate‐determining step across multiple temperatures. Surprisingly, the N90A substitution had a dramatic effect on the general acid/base catalysis of the dehydration step, as indicated by the loss of the descending limb in the pH rate profile, which we had previously assigned to Lys53 on the β1α1 loop. These changes in enzyme function are accompanied with a quenching of ps‐ns and µs‐ms timescale motions in the β1α1 loop as measured by nuclear magnetic resonance studies. Altogether, our studies provide structural, dynamic and functional rationales for the coevolution of residues on the β1α1 and β2α2 loops, and highlight the multiple roles that the β1α1 loop plays in IGPS catalysis. Thus, substitution of covarying residues in the active‐site β1α1 and β2α2 loops of indole‐3‐glycerol phosphate synthase results in functional, structural, and dynamic changes, highlighting the multiple roles that the β1α1 loop plays in enzyme catalysis and the importance of regulating the structural dynamics of this loop through noncovalent interactions with nearby structural elements.     

Long-range effects of tag sequence on marginally stabilized structure in HIV-1 p24 capsid protein monitored using NMR

N-terminal domain of HIV-1 p24 capsid protein is a globular fold composed of seven helices and two β-strands with a flexible structure including the α4–5 loop and both N- and C-terminal ends. However, the protein shows a high tendency (48%) for an intrinsically disordered structure based on the PONDR VL-XT prediction from the primary sequence. To assess the possibility of marginally stabilized structure under physiological conditions, the N-terminal domain of p24 was destabilized by the addition of an artificial flexible tag to either N- or C-terminal ends, and it was analyzed using T₁, T₂, hetero-nuclear NOE, and amide-proton exchange experiments. When the C-terminal tag (12 residues) was attached, the regions of the α3–4 loop and helix 6 as well as the α4–5 loop attained the flexible structures. Furthermore, in the protein containing the N-terminal tag (27 residues), helix 4 in addition to the above-mentioned area including α3–4 and α4–5 loops as well as helix 6 exhibited highly disordered structures. Thus, the long-range effects of the existence of tag sequence was observed in the stepwise manner of the appearance of disordered structures (step 1: α4–5 loop, step 2: α3–4 loop and helix 6, and step 3: helix 4). Furthermore, the disordered regions in tagged proteins were consistent with the PONDR VL-XT disordered prediction. The dynamic structure located in the middle part (α3–4 loop to helix 6) of the protein shown in this study may be related to the assembly of the viral particle.     

Crystal Structure of a Full-Length Autotransporter

The autotransporter (AT) secretion mechanism is the most common mechanism for the secretion of virulence factors across the outer membrane (OM) from pathogenic Gram-negative bacteria. In addition, ATs have attracted biotechnological and biomedical interest for protein display on bacterial cell surfaces. Despite their importance, the mechanism by which passenger domains of ATs pass the OM is still unclear. The classical view is that the β-barrel domain provides the conduit through which the unfolded passenger moves, with the energy provided by vectorial folding of the β-strand-rich passenger on the extracellular side of the OM. We present here the first structure of a full-length AT, the esterase EstA from Pseudomonas aeruginosa, at a resolution of 2.5 Å. EstA has a relatively narrow, 12-stranded β-barrel that is covalently attached to the passenger domain via a long, curved helix that occupies the lumen of the β-barrel. The passenger has a structure that is dramatically different from that of other known passengers, with a globular fold that is dominated by α-helices and loops. The arrangement of secondary-structure elements suggests that the passenger can fold sequentially, providing the driving force for passenger translocation. The esterase active-site residues are located at the apical surface of the passenger, at the entrance of a large hydrophobic pocket that contains a bound detergent molecule that likely mimics substrate. The EstA structure provides insight into AT mechanism and will facilitate the design of fusion proteins for cell surface display.     

Sequence composition effects on denatured state loop formation in iso-1-cytochrome c variants: polyalanine versus polyglycine inserts

Protein folding is dependent on the formation and persistence of simple loops during the earliest events of the folding process. Ease of loop formation and persistence is believed to be dependent on the steric properties of the residues involved in loop formation. We have investigated this conformational factor in the denatured state of iso-1-cytchrome c using a five alanine insert in front of a unique histidine in the N-terminal region of the protein. The alanine residues have then been progressively substituted with sterically less-constrained glycine residues. Guanidine-HCl unfolding shows that all variants have a free energy of unfolding of approximately 2 kcal/mol. The low stability of these variants is well accounted for by stabilization of the denatured state by histidine-heme loop formation. The stability of the 22 residue histidine-heme loop has been measured in 3 M guanidine hydrochloride for all variants. Surprisingly, relative to alanine, glycine has only a very modest effect on equilibrium loop stability. Thus, the greater flexibility that glycine confers on the main-chain provides no advantage in terms of the persistence of simple loops early in folding. The underlying basis for the similar behavior of loops with polyalanine versus polyglycine inserts is discussed in terms of the current knowledge of the structure and loop formation kinetics of glycine versus alanine-rich peptides.     

Molecular Basis for the Structural Stability of an Enclosed β-Barrel Loop

We present molecular dynamics simulation studies of the structural stability of an enclosed loop in the β domain of the Escherichia coli O157:H7 autotransporter EspP. Our investigation revealed that, in addition to its excellent resistance to thermal perturbations, EspP loop 5 (L5) also has remarkable mechanical stability against pulling forces along the membrane norm. These findings are consistent with the experimental report that EspP L5 helps to maintain the permeability barrier in the outer membrane. In contrast to the major secondary structure elements of globular proteins such as ubiquitin, whose resistance to thermal and mechanical perturbations depends mainly on backbone hydrogen bonds and hydrophobic interactions, the structural stability of EspP L5 can be attributed mainly to geometric constraints and side-chain interactions dominated by hydrogen bonds. Examination of B-factors from available high-resolution structures of membrane-embedded β barrels indicates that most of the enclosed loops have stable structures. This finding suggests that loops stabilized by geometric constraints and side-chain interactions might be used more generally to restrict β-barrel channels for various functional purposes.