Dynamics of the glutamic acid 242 side chain in cytochrome c oxidase

In many cytochrome c oxidases glutamic acid 242 is required for proton transfer to the binuclear heme a(3)/Cu(B) site, and for proton pumping. When present, the side chain of Glu-242 is orientated "down" towards the proton-transferring D-pathway in all available crystal structures. A nonpolar cavity "above" Glu-242 is empty in these structures. Yet, proton transfer from Glu-242 to the binuclear site, and for proton-pumping, is well established, and the cavity has been proposed to at least transiently contain water molecules that would mediate proton transfer. Such proton transfer has been proposed to require isomerisation of the Glu-242 side chain into an "up" position pointing towards the cavity. Here, we have explored the molecular dynamics of the protonated Glu-242 side chain. We find that the "up" position is preferred energetically when the cavity contains four water molecules, but the "down" position is favoured with less water. We conclude that the cavity might be deficient in water in the crystal structures, possibly reflecting the "resting" state of the enzyme, and that the "up/down" equilibrium of Glu-242 may be coupled to the presence of active-site water molecules produced by O(2) reduction.     

Gene expression changes associated with the anti-angiogenic activity of kallikrein-related peptidase 3 (KLK3) on human umbilical vein endothelial cells

Kallikrein-related peptidase 3 (KLK3, also known as prostate-specific antigen, PSA) is a chymotrypsin-like kallikrein that has anti-angiogenic properties. We have previously shown in a human umbilical vein endothelial cell (HUVEC) model that the anti-angiogenic effect of KLK3 is related to its enzyme activity. However, the mechanism of this effect remains to be clarified. To this end, we used a DNA microarray to study KLK3-induced changes in gene expression associated with reduction of HUVEC tube formation. Among the 41,000 genes studied, 311 were differentially expressed between control and KLK3-treated cells. These changes were enriched in several pathways, including those associated with proteasome, ubiquitin-mediated proteolysis, focal adhesion and regulation of the actin cytoskeleton. Furthermore, the changes were opposite to those previously described to occur during tubulogenesis. In conclusion, our results show that KLK3 induces gene expression changes in HUVECs. Although these changes might be relevant for the mechanism by which KLK3 exerts its anti-angiogenic activity, it cannot be judged from the present results whether they reflect the primary mechanism mediating the effect of KLK3 or are secondary to morphogenic differentiation.     

Solution structures and integrin binding activities of an RGD peptide with two isomers

The Arg-Gly-Asp (RGD) sequence serves as the primary integrin recognition site in extracellular matrix proteins, and peptides containing this sequence can mimic the activities of the matrix proteins. Depending on the context of the RGD sequence, an RGD-containing peptide may bind to all of the RGD-directed integrins, to a few, or to only a single one. We have previously isolated from a phage-displayed peptide library a cyclic peptide that binds avidly to the alpha(v)beta3 and alpha(v)beta5 integrins but does not bind to other closely related integrins. This peptide, ACDCRGDCFCG, exists in two natural configurations depending on internal disulfide bonding. The peptide with the 1-4; 2-3 disulfide bond arrangement accounts for most of the alpha(v) integrin binding activity, whereas the 1-3; 2-4 peptide is about 10-fold less potent. Solution structure analysis by nuclear magnetic resonance reveals an entirely different presentation of the RGD motif in the two isomers of RGD-4C. These results provide new insight into the ligand recognition specificity of integrins.     

Two distinct regions in the model protein Peb1 are critical for its heterologous transport out of <Emphasis Type="Italic">Escherichia coli</Emphasis>

Background  

Escherichia coli is frequently the first-choice host organism in expression of heterologous recombinant proteins in basic research as well as in production of commercial, therapeutic polypeptides. Especially the secretion of proteins into the culture medium of E. coli is advantageous compared to intracellular production due to the ease in recovery of the recombinant protein. Since E. coli naturally is a poor secretor of proteins, a few strategies for optimization of extracellular secretion have been described. We have previously reported efficient secretion of the diagnostically interesting model protein Peb1 of Campylobacter jejuni into the growth medium of Escherichia coli strain MKS12 (ΔfliCfliD). To generate a more detailed understanding of the molecular mechanisms behind this interesting heterologous secretion system with biotechnological implications, we here analyzed further the transport of Peb1 in the E. coli host.     

A new model for the evolution of carnivory in the bladderwort plant (utricularia): adaptive changes in cytochrome C oxidase (COX) provide respiratory power

The evolution of carnivorous plants has been modeled as a selective tradeoff between photosynthetic costs and benefits in nutrient-poor habitats. Although possibly applicable for pitfall and flypaper trappers, more variables may be required for active trapping systems. Bladderwort (utricularia) suction traps react to prey stimuli with an extremely rapid release of elastic instability. Trap setting requires considerable energy to engage an active ion transport process whereby water is pumped out through the thin bladder walls to create negative internal pressure. Accordingly, empirical estimates have shown that respiratory rates in bladders are far greater than in leafy structures. Cytochrome C oxidase (COX) is a multi-subunit enzyme that catalyzes the respiratory reduction of oxygen to water and couples this reaction to translocation of protons, generating a transmembrane electrochemical gradient that is used for the synthesis of adenosine triphosphate (ATP). We have previously demonstrated that two contiguous cysteine residues in helix 3 of COX subunit I (COX I) have evolved under positive Darwinian selection. This motif, absent in approximately 99.9 % of databased COX I proteins from eukaryotes, Archaea, and Bacteria, lies directly at the docking point of COX I helix 3 and cytochrome C. Modeling of bovine COX I suggests the possibility that a vicinal disulfide bridge at this position could cause premature helix termination. The helix 3-4 loop makes crucial contacts with the active site of COX, and we postulate that the C-C motif might cause a conformational change that decouples (or partly decouples) electron transport from proton pumping. Such decoupling would permit bladderworts to optimize power output (which equals energy times rate) during times of need, albeit with a 20 % reduction in overall energy efficiency of the respiratory chain. A new model for the evolution of bladderwort carnivory is proposed that includes respiration as an additional tradeoff parameter.     

Human single‐chain urokinase is activated by the omptins PgtE of Salmonella enterica and Pla of Yersinia pestis despite mutations of active site residues

Fibrinolysis is important in cell migration and tightly regulated by specific inhibitors and activators; of the latter, urokinase (uPA) associates with enhancement of cell migration. Active uPA is formed through cleavage of the single‐chain uPA (scuPA). The Salmonella enterica strain 14028R cleaved human scuPA at the peptide bond Lys158‐Ile159, the site cleaved also by the physiological activator human plasmin. The cleavage led to activation of scuPA, while no cleavage or activation were detected with the mutant strain 14028R lacking the omptin protease PgtE. Complementation and expression studies confirmed the role of PgtE in scuPA activation. Similar cleavage and activation of scuPA were detected with recombinant Escherichia coli expressing the omptin genes pla from Yersinia pestis, ompT and ompP from E. coli, sopA from Shigella flexneri, and leo from Legionella pneumophila. For these omptins the activation of scuPA is the only shared function so far detected. Only poor cleavage and activation of scuPA were seen with YcoA of Y. pestis and YcoB of Yersinia pseudotuberculosis that are considered to be proteolytically inactive omptin variants. Point mutations of active site residues in Pla and PgtE had different effects on the proteolysis of plasminogen and of scuPA, indicating versatility in omptin proteolysis.     

Metabarcoding Gastrointestinal Nematodes in Sympatric Endemic and Nonendemic Species in Ranomafana National Park,Madagascar

Sympatric species are known to host the same parasites species. Nevertheless, surveys examining parasite assemblages in sympatric species are rare. To understand how parasite assemblages in sympatric host species differ in a given locality, we used a noninvasive identification method based on high-throughput sequencing. We collected fecal samples from sympatric species in Ranomafana National Park, Madagascar, from September to December in 2010, 2011, and 2012 and identified their parasites by metabarcoding, sequencing a region of the small ribosomal subunit (18S) gene. Our survey included 11 host species, including endemic primates, rodents, frogs, gastropods, and nonendemic rats and dogs. We collected 872 samples, of which 571 contained nematodes and 249 were successfully sequenced. We identified nine putative species of parasites, although their correspondence to actual parasite species is not clear as the resolution of the marker gene differs between nematode clades. For the host species that we successfully sampled with 10 or more positive occurrences of nematodes, i.e., mouse lemurs (Microcebus rufus), black rats (Rattus rattus), and frogs (Anura), the parasite assemblage compositions differed significantly among host species, sampling sites, and sampling years. Our metabarcoding method shows promise in interrogating parasite assemblages in sympatric host species and our results emphasize the importance of choosing marker regions for parasite identification accuracy.     

Expression of Semliki Forest virus nsP1-specific methyltransferase in insect cells and in Escherichia coli.

We have expressed the Semliki Forest virus (SFV)-specific nonstructural protein nsP1 both in insect cells and in Escherichia coli in the absence of other viral proteins. A substantial amount of nsP1 was synthesized in Sf9 cells infected with the recombinant Autographa californica nuclear polyhedrosis virus (AcNPV) AcNPV-nsP1. These cells had a high level of guanine-7-methyltransferase activity compared with that of wild-type AcNPV-infected cells. The methyltransferase activity and nsP1 were mostly in the mitochondrial pellet fraction (P15). The enzymatic activity was increased by treatment with deoxycholate (DOC), as in the case of SFV-infected BHK cells. The material released by DOC treatment from P15 of the AcNPV-nsP1-infected cells was analyzed by gel filtration and sucrose gradient centrifugation. Both the methyltransferase activity and nsP1 were in aggregates. nsP1 expressed in E. coli at 37 degrees C sedimented at 15,000 x g, whereas after expression at 15 degrees C, both nsP1 and methyltransferase activity were in the supernatant fraction. Paradoxically, the activity from E. coli was completely inhibited by Triton X-100 and DOC. Sucrose gradient analysis showed that even the "soluble" nsP1-methyltransferase was in aggregates. The methyltransferase activities in the P15 fractions of SFV-infected BHK cells and AcNPV-nsP1-infected Sf9 cells and in E. coli catalyzed linear incorporation of the [3H]methyl group from S-adenosylmethionine to GTP for a 60-min period. The enzymes from the three sources had similar substrate specificities and Km values for S-adenosylmethionine. In addition to GTP, they all methylated dGTP and GpppG, but not m7GTP or GpppA, or in vitro-transcribed RNAs with GpppA and GpppG caps. The unique properties of SFV-specific nsP1 methyltransferase are discussed.     

Morphological and molecular characterisation of Paranoplocephala buryatiensis n. sp. and P. longivaginata Chechulin & Gulyaev, 1998 (Cestoda: Anoplocephalidae) in voles of the genus Clethrionomys

A new species, Paranoplocephala buryatiensis n. sp. (Cestoda:Anoplocephalidae), is described from the grey-sided vole Clethrionomys rufocanus (Sundevall) in the Republic of Buryatia (Russian Federation) and compared with P. longivaginata Chechulin & Gulyaev, 1998, a parasite of the red vole C. rutilus (Pallas) in the same region. P. buryatiensis n. sp. and P. longivaginata both have an exceptionally long vagina and cirrus, unique features among known species of Paranoplocephala Lühe, 1910. The new species differs from P. longivaginata primarily by its wider and more robust body, lower length/width ratio of mature proglottides, tendency of testes to occur in two separate groups, seminal receptacle of a different shape and the position of the cirrus-sac with respect to the ventral longitudinal osmoregulatory canal. The cytochrome oxidase subunit I (COI) sequence data support the independent status of these species, and show that they form a monophyletic assemblage within Paranoplocephala (sensu lato). Assuming cospeciation, an indirect calibration using host speciation dates estimated a rate of mtDNA substitution of 1.0–1.7% pairwise (0.5–0.85% per lineage) sequence divergence per million years. A faunistic review of Paranoplocephala species in C. rufocanus and C. rutilus in the Holarctic region is presented.