Prior immunization with severe acute respiratory syndrome (SARS)-associated coronavirus (SARS-CoV) nucleocapsid protein causes severe pneumonia in mice infected with SARS-CoV

The details of the mechanism by which severe acute respiratory syndrome-associated coronavirus (SARS-CoV) causes severe pneumonia are unclear. We investigated the immune responses and pathologies of SARS-CoV-infected BALB/c mice that were immunized intradermally with recombinant vaccinia virus (VV) that expressed either the SARS-CoV spike (S) protein (LC16m8rVV-S) or simultaneously all the structural proteins, including the nucleocapsid (N), membrane (M), envelope (E), and S proteins (LC16m8rVV-NMES) 7-8 wk before intranasal SARS-CoV infection. The LC16m8rVV-NMES-immunized group exhibited as severe pneumonia as the control groups, although LC16m8rVV-NMES significantly decreased the pulmonary SARS-CoV titer to the same extent as LC16m8rVV-S. To identify the cause of the exacerbated pneumonia, BALB/c mice were immunized with recombinant VV that expressed the individual structural proteins of SARS-CoV (LC16mOrVV-N, -M, -E, -S) with or without LC16mOrVV-S (i.e., LC16mOrVV-N, LC16mOrVV-M, LC16mOrVV-E, or LC16mOrVV-S alone or LC16mOrVV-N + LC16mOrVV-S, LC16mOrVV-M + LC16mOrVV-S, or LC16mOrVV-E + LC16mOrVV-S), and infected with SARS-CoV more than 4 wk later. Both LC16mOrVV-N-immunized mice and LC16mOrVV-N + LC16mOrVV-S-immunized mice exhibited severe pneumonia. Furthermore, LC16mOrVV-N-immunized mice upon infection exhibited significant up-regulation of both Th1 (IFN-gamma, IL-2) and Th2 (IL-4, IL-5) cytokines and down-regulation of anti-inflammatory cytokines (IL-10, TGF-beta), resulting in robust infiltration of neutrophils, eosinophils, and lymphocytes into the lung, as well as thickening of the alveolar epithelium. These results suggest that an excessive host immune response against the nucleocapsid protein of SARS-CoV is involved in severe pneumonia caused by SARS-CoV infection. These findings increase our understanding of the pathogenesis of SARS.     

Amyloidogenic Potential of Transthyretin Variants: INSIGHTS FROM STRUCTURAL AND COMPUTATIONAL ANALYSES*

Human transthyretin (TTR) is an amyloidogenic protein whose mild amyloidogenicity is enhanced by many point mutations affecting considerably the amyloid disease phenotype. To ascertain whether the high amyloidogenic potential of TTR variants may be explained on the basis of the conformational change hypothesis, an aim of this work was to determine structural alterations for five amyloidogenic TTR variants crystallized under native and/or destabilizing (moderately acidic pH) conditions. While at acidic pH structural changes may be more significant because of a higher local protein flexibility, only limited alterations, possibly representing early events associated with protein destabilization, are generally induced by mutations. This study was also aimed at establishing to what extent wild-type TTR and its amyloidogenic variants are intrinsically prone to β-aggregation. We report the results of a computational analysis predicting that wild-type TTR possesses a very high intrinsic β-aggregation propensity which is on average not enhanced by amyloidogenic mutations. However, when located in β-strands, most of these mutations are predicted to destabilize the native β-structure. The analysis also shows that rat and murine TTR have a lower intrinsic β-aggregation propensity and a similar native β-structure stability compared with human TTR. This result is consistent with the lack of in vitro amyloidogenicity found for both murine and rat TTR. Collectively, the results of this study support the notion that the high amyloidogenic potential of human pathogenic TTR variants is determined by the destabilization of their native structures, rather than by a higher intrinsic β-aggregation propensity.Protein misfolding and aggregation are involved in the pathogenesis of particularly relevant human deposition diseases, known as amyloidoses. In such diseases, normally soluble proteins undergo misfolding and become insoluble, causing the extracellular deposition of fibrillar aggregates (for reviews, see Ref. 1, 2). To date, more than 40 distinct human proteins have been associated with amyloidoses. For some of such proteins, including transthyretin (TTR),⁴ lysozyme, gelsolin, ApoAI, and ApoAII, fibrinogen A α-chain and cystatin C, the amyloidogenic potential is induced, or is enhanced as in the case of TTR (see below), by specific mutations. The most frequent hereditary amyloidoses are caused by the genetic variants of human TTR (2).TTR is a homotetramer of about 55 kDa involved in the transport of thyroxine in the extracellular fluids and in the co-transport of vitamin A, by forming a macromolecular complex with retinol-binding protein, the specific plasma carrier of retinol (3–5). Its three-dimensional structure is known at high resolution (6, 7). The structure is characterized by a large predominance of β-strands, and its four monomers are arranged according to a 222 symmetry, where one of the 2-fold symmetry axes of the molecule coincides with a long channel that transverses the entire tetramer and harbors two symmetrical binding sites for the thyroid hormone thyroxine. Each monomer contains eight β-strands (A-H), arranged in a β-sandwich of two four-stranded β-sheets, with a short α-helix connecting two of the eight β-strands. In the tetramer, the four monomers are organized as a dimer of dimers. Two monomers are held together, forming a stable dimer through a net of H-bond interactions involving the two external β-strands H and F. The two dimers associate back to back and form the tetramer, by interacting mostly through hydrophobic contacts between residues of the AB and GH loops.Normal TTR possesses an inherent potential, albeit low, to generate amyloid fibrils, giving rise to Senile Systemic Amyloidosis (SSA) in ∼25% of the population aged over 80 years (8). More than 100 point mutations are described for human TTR. Most of them are involved in the hereditary amyloidoses known as familial amyloidotic polyneuropathy (FAP) or cardiomyopathy (FAC) (9). Single point mutations enhance the amyloidogenicity of TTR, so that patients show an earlier age of onset and a faster disease progression compared with SSA patients. The observation that single point mutations can drastically influence the disease phenotype is particularly relevant. In fact, the study of pathogenic TTR variants may provide clues to the mechanism of their abnormal behavior leading to amyloid formation. Although amyloidogenic proteins in general may be structurally unrelated to each other, and lead to various pathological phenotypes in humans, the amyloid fibrils originating from different proteins share the common cross-β structure, consisting in continuous β-sheets lying parallel to the longitudinal axis of the fibril, with the constituent β-strands running perpendicular to this axis. Therefore, the amyloidogenic proteins have to undergo structural alterations to be able to generate the cross-β structure, i.e. new β-pairing interactions have to be established on the way to fibril formation. However, the molecular mechanisms underlying protein misfolding and aggregation into highly ordered fibrillar structures are not clarified definitely, although significant progress is recently been made toward their elucidation (1, 10, 11).Based on the seminal observation that the rates of aggregation into amyloid fibrils in vitro correlate with simple physico-chemical amino acid features (12), several algorithms were introduced in recent years to predict, with good success, the intrinsic β-aggregation propensities of protein and peptide sequences (for a review, see Ref. 13). The intrinsic β-aggregation propensity is a measure of the tendency polypeptide chains may have to aggregate into the amyloid structure, provided that aggregation proceeds from unstructured monomers. The prediction of intrinsic propensities to β-aggregation for amyloidogenic or non-amyloidogenic variants of the same sequence was used to explain in several instances their relative ability to speed up/slow down in vitro fibrillogenesis or the enhancement/reduction of their amyloidogenic potential in vivo (14). However, a high intrinsic aggregation propensity may not result in an actual aggregation, due to the protecting role of the ordered native structure (15, 16). Therefore, the amyloidogenic potential in the TTR variants may depend further on the change of stability in the native TTR tetramer induced by mutations. In particular, it remains to be clarified to what extent human TTR possesses an intrinsic propensity to β-aggregation, and whether amyloidogenic mutations enhance such a propensity, or only destabilize the TTR tetramer, thereby facilitating the misfolding and misassembly of a protein which is in itself prone to β-aggregation.With regard to the pathway from native to misfolded TTR and to amyloid aggregation, the results of a number of in vitro studies are consistent with the rate-limiting dissociation of the TTR tetramer, followed by misfolding of TTR monomers and their downhill polymerization to generate pathological aggregates (17–25). The crystal structures of amyloidogenic TTR variants are generally well conserved (26–30). Accordingly, the functional properties of the variants, such as the ability to interact with retinol-binding protein (5), are maintained, being consistent with the fact that large conformational changes are not induced by amyloidogenic mutations, at least under native-like conditions (11). In vitro studies have shown that a moderately acidic medium (pH 4–5) facilitates TTR fibrillogenesis (17) and that the extent of fibril formation is remarkably enhanced for amyloidogenic TTR variants in comparison to wild-type TTR (31). Recently, it has been shown by x-ray analysis that an acidic pH (4.6) causes a large local conformational change in an amyloidogenic TTR variant (I84S) affecting two subunits within the tetramer, which probably destabilizes the TTR tetramer (32). In contrast, no significant structural changes for wild-type TTR at pH 4.6 and for I84S TTR at neutral pH were found, suggesting that conformational changes associated with a destabilization of the TTR native state may be induced or enhanced in amyloidogenic TTR variants by partially denaturing conditions (32). Pursuing these observations, we extend here our investigation to include other amyloidogenic TTR variants in comparison to the wild-type protein, with the aim to unravel structural alterations that are possibly associated with an enhanced amyloidogenic potential, according to the conformational change hypothesis (11). In addition, we report the results of a computational analysis of the mutational effects on both the intrinsic propensity to β-aggregation and the stability of the native β-structure. The same analysis is performed on murine and rat TTRs, whose structural organizations are very similar to that of the human protein (33, 34).     

Isolation of functional cDNA clones for human thymidylate synthase

Thymidine auxotrophic mutants of mouse FM3A cells due to thymidylate synthase deficiency can be transformed into prototrophs by DNA-mediated gene transfer using total human DNA (Ayusawa, D., Shimizu, K., Koyama, H., Takeishi, K., and Seno, T. (1983) J. Biol. Chem. 258, 48-53). From one such transformed cell clone, cloned recombinant lambda phages containing DNA fragments were obtained recently that were concluded by circumstantial genetic evidence to have been derived from the human thymidylate synthase gene (Takeishi, K., Ayusawa, D., Kaneda, S., Shimizu, K., and Seno, T. (1984) J. Biochem. (Tokyo) 95, 1477-1483). Using a DNA segment derived from the cloned genomic DNA fragment and free of repetitive sequences as a probe, functional cDNA corresponding to thymidylate synthase mRNA could be cloned from a cDNA library of SV40 transformed human fibroblasts constructed by Okayama and Berg (Okayama, H. and Berg, P. (1983) Mol. Cell. Biol. 3, 280-289). The cloned cDNA plasmid containing an insert of approximately 1.7-kilobase transformed mouse thymidine auxotrophic mutant cells to thymidine prototrophic cells at a frequency of 2-3 transformants/micrograms of DNA/10(5) cells, a value almost comparable to the highest so far reported. The resultant transformants retained the introduced cDNA and expressed human thymidylate synthase protein sufficient for supporting normal growth of otherwise auxotrophic mouse cells.     

Role in translation of a triple tandemly repeated sequence in the 5''-untranslated region of human thymidylate synthase mRNA.

A triple tandem repeat (TTR) consisting of 90 nucleotides exists immediately upstream of the ATG initiator codon in human thymidylate synthase (TS) cDNA (pcHTS-1). To investigate the role of the TTR in the expression of the TS cDNA, we used pcHTS-1 to construct mutant cDNA clones in which part of the TTR was deleted or an additional element was inserted. The mutant cDNA plasmid was introduced into murine TS-negative mutant cells and the relative translation efficiencies of the mutant cDNAs were determined by measuring the transient expression of TS activity and the amount of TS mRNA transcribed. The translation efficiency in transient expression of the mutants was increased by deletions covering all the first two repeated elements, and the part of the third closest to the ATG initiator codon, but was not affected by deletions of only parts of the first two repeated elements at the 5' end. The translation efficiency was also not affected by insertion of an additional repeated element into the TTR. These results suggest that the first two repeated elements at the 5' end both have inhibitory effects on translation of the TS mRNA, probably due to the unique structural feature of this element.     

Amelioration of pneumonia with Streptococcus pneumoniae infection by inoculation with a vaccine against highly pathogenic avian influenza virus in a non-human primate mixed infection model

Background  Highly pathogenic avian influenza virus (HPAIV) infection has a high mortality rate in humans. Secondary bacterial pneumonia with HPAIV infection has not been reported in human patients, whereas seasonal influenza viruses sometimes enhance bacterial pneumonia, resulting in substantial morbidity and mortality. Therefore, if HPAIV infection were accompanied by bacterial infection, an increase in mortality would be expected. We examined whether a vaccine against HPAIV prevents severe morbidity caused by mixed infection with HPAIV and bacteria.
Methods  H7N7 subtype of HPAIV and Streptococcus pneumoniae were inoculated into cynomolgus macaques with or without vaccination of inactivated whole virus particles .
Results  Vaccination against H7N7 HPAIV decreased morbidity caused by HPAIV and pneumonia caused by S. pneumoniae . Bacterial replication in lungs was decreased by vaccination against HPAIV, although the reduction in bacterial colonies was not significant.
Conclusions  Vaccination against HPAIV reduces pneumonia caused by bacterial superinfection and may improve prognosis of HPAIV-infected patients.     

Can Camera Traps Monitor Komodo Dragons a Large Ectothermic Predator?

Camera trapping has greatly enhanced population monitoring of often cryptic and low abundance apex carnivores. Effectiveness of passive infrared camera trapping, and ultimately population monitoring, relies on temperature mediated differences between the animal and its ambient environment to ensure good camera detection. In ectothermic predators such as large varanid lizards, this criterion is presumed less certain. Here we evaluated the effectiveness of camera trapping to potentially monitor the population status of the Komodo dragon (Varanus komodoensis), an apex predator, using site occupancy approaches. We compared site-specific estimates of site occupancy and detection derived using camera traps and cage traps at 181 trapping locations established across six sites on four islands within Komodo National Park, Eastern Indonesia. Detection and site occupancy at each site were estimated using eight competing models that considered site-specific variation in occupancy (ψ)and varied detection probabilities (p) according to detection method, site and survey number using a single season site occupancy modelling approach. The most parsimonious model [ψ (site), p (site*survey); ω = 0.74] suggested that site occupancy estimates differed among sites. Detection probability varied as an interaction between site and survey number. Our results indicate that overall camera traps produced similar estimates of detection and site occupancy to cage traps, irrespective of being paired, or unpaired, with cage traps. Whilst one site showed some evidence detection was affected by trapping method detection was too low to produce an accurate occupancy estimate. Overall, as camera trapping is logistically more feasible it may provide, with further validation, an alternative method for evaluating long-term site occupancy patterns in Komodo dragons, and potentially other large reptiles, aiding conservation of this species.     

A self-consistent knowledge-based approach to protein design

A simple and very efficient protein design strategy is proposed by developing some recently introduced theoretical tools which have been successfully applied to exactly solvable protein models. The design approach is implemented by using three amino acid classes and it is based on the minimization of an appropriate energy function. For a given native state the results of the design procedure are compared, through a statistical analysis, with the properties of an ensemble of sequences folding in the same conformation. If the success rate is computed on those sites designed with high confidence, it can be as high as 80%. The method is also able to identify key sites for the folding process: results for 2ci2 and barnase are in very good agreement with experimental results.     

The optimal strategy for brood-parasitism: how many eggs should be laid in the host's nest?

We consider the optimal strategy for intra-specific brood-parasitism, especially with respect to the number of eggs laid by the parasitic individual in the nest of non-parasitic individual, in particular, a host that does not reject the parasite's eggs. With a fundamental mathematical model, assuming that the survival probability of the parasite's offspring in the nest of the host is significantly smaller than that in parasite's own nest, we determine the optimal number of eggs laid in the nest of host that maximizes the expected reproductive fitness of the parasite. We show that the invasion success of brood-parasitism could significantly depend on the total number of eggs laid by the parasite in a breeding season, and that the successfully invading brood-parasitism could realize maximum fitness with a specific number of parasite's eggs laid in the nest of the host.     

Tetrapetalone A, a novel lipoxygenase inhibitor from Streptomyces sp

A simple new assay was designed for lipoxygenase inhibitors. This assay was used to find the novel lipoxygenase inhibitor, tetrapetalone A (1). Tetrapetalone A (1), C26H33NO7, was isolated from Streptomyces sp. USF-4727 strain. Its planar structure was determined by spectroscopic evidence and by methylating with diazomethane to show the presence of a novel tetracyclic skeleton and a beta-D-rhodinosyl moiety. The stereochemistry of 1 was investigated by the coupling constant in the 1H-NMR spectrum, NOE correlations, modified Mosher's method and derivation. We have reported the structural elucidation of 1 in our previous paper. However, further investigation gave another structure for 1, which is described in this paper. Tetrapetalone A showed similar inhibitory activity against soybean lipoxygenase to the two well-known lipoxygenase inhibitors, kojic acid and NDGA, while methylated tetrapetalone A (2) showed little inhibitory activity, even at a concentration of 1 mM.     

Learning effective amino acid interactions through iterative stochastic techniques

The prediction of the three-dimensional structures of the native states of proteins from the sequences of their amino acids is one of the most important challenges in molecular biology. An essential task for solving this problem within coarse-grained models is the deduction of effective interaction potentials between the amino acids. Over the years, several techniques have been developed to extract potentials that are able to discriminate satisfactorily between the native and nonnative folds of a preassigned protein sequence. In general, when these potentials are used in actual dynamical folding simulations, they lead to a drift of the native structure outside the quasinative basin. In this article, we present and validate an approach to overcome this difficulty. By exploiting several numerical and analytical tools, we set up a rigorous iterative scheme to extract potentials satisfying a prerequisite of any viable potential: the stabilization of proteins within their native basin (less than 3-4 A RMSD). The scheme is flexible and is demonstrated to be applicable to a variety of parameterizations of the energy function, and it provides in each case the optimal potentials.