Molecular cloning,expression profile,odorant affinity,and stability of two odorant‐binding proteins in Macrocentrus cingulum Brischke (Hymenoptera: Braconidae)

The polyembryonic endoparasitoid wasp Macrocentrus cingulum Brischke (Hymenoptera: Braconidae) is deployed successfully as a biocontrol agent for corn pest insects from the Lepidopteran genus Ostrinia in Europe and throughout Asia, including Japan, Korea, and China. The odorants are recognized, bound, and solubilized by odorant‐binding protein (OBP) in the initial biochemical recognition steps in olfaction that transport them across the sensillum lymph to initiate behavioral response. In the present study, we examine the odorant‐binding effects on thermal stability of McinOBP2, McinOBP3, and their mutant form that lacks the third disulfide bonds. Real‐time PCR experiments indicate that these two are expressed mainly in adult antennae, with expression levels differing by sex. Odorant‐binding affinities of aldehydes, terpenoids, and aliphatic alcohols were measured with circular dichroism spectroscopy based on changes in the thermal stability of the proteins upon their affinities to odorants. The obtained results reveal higher affinity of trans‐caryophelle, farnesene, and cis‐3‐Hexen‐1‐ol exhibits to both wild and mutant McinOBP2 and McinOBP3. Although conformational flexibility of the mutants and shape of binding cavity make differences in odorant affinity between the wild‐type and mutant, it suggested that lacking the third disulfide bond in mutant proteins may have chance to incorrect folded structures that reduced the affinity to these odorants. In addition, CD spectra clearly indicate proteins enriched with α‐helical content.     

Comprehensive mapping of cystic fibrosis mutations to CFTR protein identifies mutation clusters and molecular docking predicts corrector binding site

Cystic Fibrosis (CF) is caused by mutations in the CFTR gene, of which over 2000 have been reported to date. Mutations have yet to be analyzed in aggregate to assess their distribution across the tertiary structure of the CFTR protein, an approach that could provide valuable insights into the structure‐function relationship of CFTR. In addition, the binding site of Class I correctors (VX‐809, VX‐661, and C18) is not well understood. In this study, exonic CFTR mutations and mutant allele frequencies described in 3 curated databases (ABCMdb, CFTR1, and CFTR2, comprising >130 000 data points) were mapped to 2 different structural models: a homology model of full‐length CFTR protein in the open‐channel state, and a cryo‐electron microscopy core‐structure of CFTR in the closed‐channel state. Accordingly, residue positions of 6 high‐frequency mutant CFTR alleles were found to spatially co‐localize in CFTR protein, and a significant cluster was identified at the NBD1:ICL4 interdomain interface. In addition, immunoblotting confirmed the approximate binding site of Class I correctors, demonstrating that these small molecules act via a similar mechanism in vitro, and in silico molecular docking generated binding poses for their complex with the cryo‐electron microscopy structure to suggest the putative corrector binding site is a multi‐domain pocket near residues F374‐L375. These results confirm the significance of interdomain interfaces as susceptible to disruptive mutation, and identify a putative corrector binding site. The structural pharmacogenomics approach of mapping mutation databases to protein models shows promise for facilitating drug discovery and personalized medicine for monogenetic diseases.     

The low‐molecular‐mass,penicillin‐binding proteins DacB and DacC combine to modify peptidoglycan cross‐linking and allow stable Type IV pilus expression in Neisseria gonorrhoeae

Neisseria gonorrhoeae is the causative agent of the sexually transmitted infection gonorrhea and is adapted to survive in humans, its only host. The N. gonorrhoeae cell wall is critical for maintaining envelope integrity, resisting immune cell killing and production of cytotoxic peptidoglycan (PG) fragments. Deletion of the N. gonorrhoeae strain FA1090 genes encoding two predicted low‐molecular‐mass, penicillin‐binding proteins (LMM PBPs), DacB and DacC, substantially altered the PG cross‐linking. Loss of the DacB peptidase resulted in global alterations to the PG composition, while loss of the DacC protein affected a much narrower subset of PG peptide components. A double ΔdacB/ΔdacC mutant resembled the ΔdacB single mutant, but had an even greater level of cross‐linked PG. While single ΔdacB or ΔdacC mutants did not show any major phenotypes, the ΔdacB/ΔdacC mutant displayed an altered cellular morphology, decreased resistance to antibiotics and increased sensitivity to detergent‐mediated death. Loss of the two proteins also drastically reduced the number of Type IV pili (Tfp), a critical virulence factor. The decreased piliation reduced transformation efficiency and correlated with increased growth rate. While these two LMM PBPs differentially alter the PG composition, their overlapping effects are essential to proper envelope function and expression of factors critical for pathogenesis.     

Relationship between mutation of serine residue at 315th position in M. tuberculosis catalase-peroxidase enzyme and Isoniazid susceptibility: An in silico analysis

Remarkable advances have been made in the drug therapy of tuberculosis. However much remains to be learned about the molecular and structural basis of drug resistance in Mycobacterium tuberculosis. It is known that, activation of Isoniazid (INH) is mediated by Mycobacterium tuberculosis catalase-peroxidase (MtBKatG) and mutation at position 315 (serine to threonine) leads to resistance. We have conducted studies on the drug resistance through docking and binding analysis supported by time-scale (∼1000 ps) and unrestrained all-atom molecular dynamics simulations of wild and mutant MtBKatG. The study showed conformational changes of binding residues. Mutant (S315T) showed high docking score and INH binding affinity as compared to wild enzyme. In molecular dynamics simulation, mutant enzyme exhibited less structure fluctuation at INH binding residues and more degree of fluctuation at C-terminal domain compared to wild enzyme. Our computational studies and data endorse that MtBKatG mutation (S315T) decrease the flexibility of binding residues and made them rigid by altering the conformational changes, in turn it hampers the INH activity. We ascertain from this work that, this study on structural mechanism of resistance development in Mycobacterium tuberculosis would lead to new therapeutics based on the result obtained in this study.     

Purification and Characterization of a Polygalacturonase-Inhibiting Protein from Phaseolus vulgaris L

Homogeneous endo-polygalacturonase (PG) was covalently bound to cyanogen-bromide-activated Sepharose, and the resulting PG-Sepharose conjugate was utilized to purify, by affinity chromatography, a protein from Phaseolus vulgaris hypocotyls that binds to and inhibits PG. Isoelectric focusing of the purified PG-inhibiting protein (PGIP) showed a major protein band that coincided with PG-inhibiting activity. PGIP formed a complex with PG at pH 5.0 and at low salt concentrations. The complex dissociated in 0.5 m Na-acetate and pH values lower than 4.5 or higher than 6.0. Formation of the PG-PGIP complex resulted in complete inhibition of PG activity. PG activity was restored upon dissociation of the complex. The protein exhibited inhibitory activity toward PGs from Colletotrichum lindemuthianum, Fusarium moniliforme and Aspergillus niger. The possible role of PGIP in regulating the activity of fungal PG's and their ability to elicit plant defense reactions are discussed.     

Polygalacturonase-inhibiting protein is a structural component of plant cell wall

It is generally believed that plants "evolved a strategy of defending themselves from a phytopathogen attack" during evolution. This metaphor is used frequently, but it does not facilitate understanding of the mechanisms providing plant resistance to the invasion of foreign organisms and to other unfavorable external factors, as well as the role of these mechanisms in plant growth and development. Information on processes involving one of the plant resistance factors--polygalacturonase-inhibiting protein (PGIP)--is considered in this review. The data presented here indicate that PGIP, being an extracellular leucine-rich repeat-containing protein, performs important functions in the structure of plant cell wall. Amino acid residues participating in PGIP binding to homogalacturonan in the cell wall have been determined. The degree of methylation and the mode of distribution of homogalacturonan methyl groups are responsible for the formation of a complex structure, which perhaps determines the specificity of PGIP binding to pectin. PGIP is apparently one of the components of plant cell wall determining some of its mechanical properties; it is involved in biochemical processes related to growth, expansion, and maceration, and it influences plant morphology. Polygalacturonase (PG) is present within practically all plant tissues, but the manifestation of its activity varies significantly depending on physiological conditions in the tissue. Apparently, the regulation of PG functioning in apoplast significantly affects the development of processes associated with the modification of the structure of plant cell wall. PGIP can regulate PG activity through binding to homogalacturonan. The genetically determined structure of PGIP in plants determines the mode of its interaction with an invader and perhaps is one of the factors responsible for the set of pathogens causing diseases in a given plant species.     

Rational design of TNFα binding proteins based on the de novo designed protein DS119

De novo protein design offers templates for engineering tailor‐made protein functions and orthogonal protein interaction networks for synthetic biology research. Various computational methods have been developed to introduce functional sites in known protein structures. De novo designed protein scaffolds provide further opportunities for functional protein design. Here we demonstrate the rational design of novel tumor necrosis factor alpha (TNFα) binding proteins using a home‐made grafting program AutoMatch. We grafted three key residues from a virus 2L protein to a de novo designed small protein, DS119, with consideration of backbone flexibility. The designed proteins bind to TNFα with micromolar affinities. We further optimized the interface residues with RosettaDesign and significantly improved the binding capacity of one protein Tbab1‐4. These designed proteins inhibit the activity of TNFα in cellular luciferase assays. Our work illustrates the potential application of the de novo designed protein DS119 in protein engineering, biomedical research, and protein sequence‐structure‐function studies.     

A protein critical for cell constriction in the Gram‐negative bacterium Caulobacter crescentus localizes at the division site through its peptidoglycan‐binding LysM domains

During division of Gram‐negative bacteria, invagination of the cytoplasmic membrane and inward growth of the peptidoglycan (PG) are followed by the cleavage of connective septal PG to allow cell separation. This PG splitting process requires temporal and spatial regulation of cell wall hydrolases. In Escherichia coli, LytM factors play an important role in PG splitting. Here we identify and characterize a member of this family (DipM) in Caulobacter crescentus. Unlike its E. coli counterparts, DipM is essential for viability under fast‐growth conditions. Under slow‐growth conditions, the ΔdipM mutant displays severe defects in cell division and FtsZ constriction. Consistent with its function in division, DipM colocalizes with the FtsZ ring during the cell cycle. Mutagenesis suggests that the LytM domain of DipM is essential for protein function, despite being non‐canonical. DipM also carries two tandems of the PG‐binding LysM domain that are sufficient for FtsZ ring localization. Localization and fluorescence recovery after photobleaching microscopy experiments suggest that DipM localization is mediated, at least in part, by the ability of the LysM tandems to distinguish septal, multilayered PG from non‐septal, monolayered PG.     

Inhibitory effects of soluble MD‐2 and soluble CD14 on bacterial growth

The effects of the soluble forms of the endotoxin receptor molecules sMD‐2 and sCD14 on bacterial growth were studied. When Escherichia coli and Bacillus subtilis were incubated at 37°C for 18 hr with either sMD‐2 or sCD14, growth of these bacteria was significantly inhibited as evaluated by viable cell counts and NADPH/NADH activity. A mutant of sCD14 (sCD14d57‐64) lacking a region essential for LPS binding did not inhibit the growth of E. coli, whereas this mutant did inhibit the growth of B. subtilis. Addition of excess PG to the bacterial culture reversed the inhibitory effect of sMD‐2 on the growth of B. subtilis, but not on the growth of E. coli. Furthermore, when evaluated by ELISA, both sMD‐2 and sCD14 bound specifically to PG. Taken together, these results indicate that sMD‐2 and sCD14 inhibit the growth of both Gram‐positive and Gram‐negative bacteria and further suggest that binding to PG and LPS is involved in the inhibitory effect of sMD‐2 on Gram‐positive bacteria and of sCD14 on Gram‐negative bacteria, respectively.     

Simultaneously inhibiting undecaprenyl phosphate production and peptidoglycan synthases promotes rapid lysis in Escherichia coli

Peptidoglycan (PG) is a highly cross‐linked polysaccharide that encases bacteria, resists the effects of turgor and confers cell shape. PG precursors are translocated across the cytoplasmic membrane by the lipid carrier undecaprenyl phosphate (Und‐P) where they are incorporated into the PG superstructure. Previously, we found that one of our Escherichia coli laboratory strains (CS109) harbors a missense mutation in uppS, which encodes an enzymatically defective Und‐P(P) synthase. Here, we show that CS109 cells lacking the bifunctional aPBP PBP1B (penicillin binding protein 1B) lyse during exponential growth at elevated temperature. PBP1B lysis was reversed by: (i) reintroducing wild‐type uppS, (ii) increasing the availability of PG precursors or (iii) overproducing PBP1A, a related bifunctional PG synthase. In addition, inhibiting the catalytic activity of PBP2 or PBP3, two monofunctional bPBPs, caused CS109 cells to lyse. Limiting the precursors required for Und‐P synthesis in MG1655, which harbors a wild‐type allele of uppS, also promoted lysis in mutants lacking PBP1B or bPBP activity. Thus, simultaneous inhibition of Und‐P production and PG synthases provokes a synergistic response that leads to cell lysis. These findings suggest a biological connection that could be exploited in combination therapies.     

Molecular dynamic simulations of nanomechanic chaperone peptide and effects of in silico His mutations on nanostructured function

The nanoscale peptide YSGVCHTDLHAWHGDWPLPVK exhibits molecular chaperone activity and prevents protein aggregation under chemical and/or thermal stress. Here, His mutations of this peptide and their impact on chaperone activity were evaluated using theoretical techniques. Molecular dynamic (MD) simulations with simulated annealing (SA) of different mutant nanopeptides were employed to determine the contribution of the scaffolding His residues (H45, H49, H52), when mutated to Pro, on chaperone action in vitro. The in silico mutations of His residues to Pro (H45P, H49P, H52P) revealed loss of secondary ordered strand structure. However, a small part of the strand conformation was formed in the middle region of the native chaperone peptide. The His‐to‐Pro mutations resulted in decreased gyration radius (R_g) values and surface accessibility of the mutant peptides under the simulation times. The invariant dihedral angle (ϕ) values and the disrupting effects of the Pro residues indicated the coil conformation of mutant peptides. The failure of the chaperone‐like action in the Pro mutant peptides was consistent with their decreased effective accessible surfaces. The high variation of Φ value for His residues in native chaperone peptide leads to high flexibility, such as a minichaperone acting as a nanomachine at the molecular level. Our findings demonstrate that the peptide strand conformation motif with high flexibility at nanoscale is critical for chaperone activity. Copyright © 2008 European Peptide Society and John Wiley & Sons, Ltd.     

The cleidocranial dysplasia‐related R131G mutation in the Runt‐related transcription factor RUNX2 disrupts binding to DNA but not CBF‐β

Cleidocranial dysplasia (CCD) is caused by haploinsufficiency in RUNX2 function. We have previously identified a series of RUNX2 mutations in Korean CCD patients, including a novel R131G missense mutation in the Runt‐homology domain. Here, we examine the functional consequences of the RUNX2^R131G mutation, which could potentially affect DNA binding, nuclear localization signal, and/or heterodimerization with core‐binding factor‐β (CBF‐β). Immunofluorescence microscopy and western blot analysis with subcellular fractions show that RUNX2^R131G is localized in the nucleus. Immunoprecipitation analysis reveals that heterodimerization with CBF‐β is retained. However, precipitation assays with biotinylated oligonucleotides and reporter gene assays with RUNX2 responsive promoters together reveal that DNA‐binding activity and consequently the transactivation of potential of RUNX2^R131G is abrogated. We conclude that loss of DNA binding, but not nuclear localization or CBF‐β heterodimerization, causes RUNX2 haploinsufficiency in patients with the RUNX2^R131G mutation. Retention of specific functions including nuclear localization and binding to CBF‐β of the RUNX2^R131G mutation may render the mutant protein an effective competitor that interferes with wild‐type function. J. Cell. Biochem. 110: 97–103, 2010. © 2010 Wiley‐Liss, Inc.     

Insights into PG‐binding,conformational change,and dimerization of the OmpA C‐terminal domains from Salmonella enterica serovar Typhimurium and Borrelia burgdorferi

Salmonella enterica serovar Typhimurium can induce both humoral and cell‐mediated responses when establishing itself in the host. These responses are primarily stimulated against the lipopolysaccharide and major outer membrane (OM) proteins. OmpA is one of these major OM proteins. It comprises a N‐terminal eight‐stranded β‐barrel transmembrane domain and a C‐terminal domain (OmpA^CTD). The OmpA^CTD and its homologs are believed to bind to peptidoglycan (PG) within the periplasm, maintaining bacterial osmotic homeostasis and modulating the permeability and integrity of the OM. Here we present the first crystal structures of the OmpA^CTD from two pathogens: S. typhimurium (STOmpA^CTD) in open and closed forms and causative agent of Lyme Disease Borrelia burgdorferi (BbOmpA^CTD), in closed form. In the open form of STOmpA^CTD, an aspartate residue from a long β2‐α3 loop points into the binding pocket, suggesting that an anion group such as a carboxylate group from PG is favored at the binding site. In the closed form of STOmpA^CTD and in the structure of BbOmpA^CTD, a sulfate group from the crystallization buffer is tightly bound at the binding site. The differences between the closed and open forms of STOmpA^CTD, suggest a large conformational change that includes an extension of α3 helix by ordering a part of β2‐α3 loop. We propose that the sulfate anion observed in these structures mimics the carboxylate group of PG when bound to STOmpA^CTD suggesting PG‐anchoring mechanism. In addition, the binding of PG or a ligand mimic may enhance dimerization of STOmpA^CTD, or possibly that of full length STOmpA.     

DFT and MP2 study of the interaction between corannulene and alkali cations

Corannulene is an unsaturated hydrocarbon composed of fused rings, with one central five-membered ring and five peripheral six-membered rings. Its structure can be considered as a portion of C₆₀. Corannulene is a curved π surface, but unlike C₆₀, it has two accessible different faces: one concave (inside) and one convex (outside). In this work, computational modeling of the binding between alkali metal cations (Li⁺, Na⁺, and K⁺) and corannulene has been performed at the DFT and MP2 levels. Different corannulene···M⁺ complexes have been studied and the transition states interconnecting local minima were located. The alkali cations can be bound to a five or six membered ring in both faces. At the DFT level, binding to the convex face (outside) is favored relative to the concave face for the three alkali cations studied, as it was previously published. This out preference was found to decrease as cation size increases. At the MP2 level, although a similar trend is found, some different conclusions related to the in/out preference were obtained. According to our results, migration of cations can take place on the convex or on the concave face. Also, there are two ways to transform a concave complex in a convex complex: migration across the edge of corannulene and bowl-to-bowl inversion.     

The redox‐sensing regulator YodB senses quinones and diamide via a thiol‐disulfide switch in Bacillus subtilis

The MarR/DUF24‐type repressor YodB controls the azoreductase AzoR1, the nitroreductase YodC and the redox‐sensing regulator Spx in response to quinones and diamide in Bacillus subtilis. Previously, we showed using a yodBCys6‐Ala mutant that the conserved Cys6 apparently contributes to the DNA‐binding activity of YodB in vivo. Here, we present data that mutation of Cys6 to Ser led to a form of the protein that was reduced in redox‐sensing in response to diamide and 2‐methylhydroquinone (MHQ) in vivo. DNA‐binding experiments indicate that YodB is regulated by a reversible thiol‐modification in response to diamide and MHQ in vitro. Redox‐regulation of YodB involves Cys6‐Cys101' intermolecular disulfide formation by diamide and quinones in vitro. Diagonal Western blot analyses confirm the formation of intersubunit disulfides in YodB in vivo that require the conserved Cys6 and either of the C‐terminal Cys101' or Cys108' residues. This study reveals a thiol‐disulfide switch model of redox‐regulation for the YodB repressor to sense electrophilic compounds in vivo.     

Ultrastructural Architecture and Organization of the Spore Envelope during Development in Thelohania bracteata (Strickland, 1913) after Freeze-Etching*

An ultrastructural study was made of the spore envelope during development in the microsporidan, Thelohania bracteata. The frozen-etched outer (convex) face of the relatively thin spore coat in the earliest immature stage of development has a granular structure in regular array. The inner (concave) face bears particles as well as depressions arranged in a net-like pattern. The mature spore coat has a substructure of numerous microfibers, ～8 nm in diameter, arranged in a matrix and forming thin layers which run parallel to the spore surface. The mature spore coat possesses both outer and inner limiting layers. The outer (convex) face of the outer limiting layer is granular. The convex face of inner limiting layer bears many particles as well as many long, narrow depressions. The concave face of the inner limiting layer carries many stud-like projections, ～40 nm long and 30 nm high, which are complementary to the depressions observed on the convex face. In addition, the concave face has subunits ～15 nm in diameter, apparently arranged in a hexagonal pattern with a center to center distance of ～18 nm. The change in size of these projections, depressions, and subunits presumably is related to spore maturation.     

Requirement for C-terminal Extension to the RNA Binding Domain for Efficient RNA Binding by Ribosomal Protein L2

Ribosomal protein L2 is a primary 23S rRNA binding protein in the large ribosomal subunit. We examined the contribution of the N- and C-terminal regions of Bacillus stearothermophilus L2 (BstL2) to the 23S rRNA binding activity. The mutant desN, in which the N-terminal 59 residues of BstL2 were deleted, bound to the 23S rRNA fragment to the same extent as wild type BstL2, but the mutation desC, in which the C-terminal 74 amino acid residues were deleted, abolished the binding activity. These observations indicated that the C-terminal region is involved in 23S rRNA binding. Subsequent deletion analysis of the C-terminal region found that the C-terminal 70 amino acids are required for efficient 23S rRNA binding by BstL2. Furthermore, the surface plasmon resonance analysis indicated that successive truncations of the C-terminal residues increased the dissociation rate constants, while they had little influence on association rate constants. The result indicated that reduced affinities of the C-terminal deletion mutants were due only to higher dissociation rate constants, suggesting that the C-terminal region primarily functions by stabilizing the protein L2-23S rRNA complex.