Snake venomics of two poorly known Hydrophiinae: Comparative proteomics of the venoms of terrestrial Toxicocalamus longissimus and marine Hydrophis cyanocinctus

The venom proteomes of Toxicocalamus longissimus and Hydrophis cyanocinctus, a fossorial and a marine species, respectively, of the Hydrophiinae genus of Elapidae, were investigated by Edman degradation of RP-HPLC isolated proteins, and de novo MS/MS sequencing of in-gel derived tryptic peptide ions. The toxin arsenal of T. longissimus is made up of 1-2 type-I PLA(2) molecules, which account for 6.5% of the venom proteins, a minor PIII-SVMP (1.4% of the venom toxins), and ~20 members of the 3FTx family comprising 92% of the venom proteome. Seventeen proteins (5 type-I PLA(2)s and 12 3FTxs) were found in the venom of H. cyanocinctus. Three-finger toxins and type-I PLA(2) proteins comprise, respectively, 81% and 19% of its venom proteome. The simplicity of the H. cyanocinctus venom proteome is highlighted by the fact that only 6 venom components (3 short-chain neurotoxins, two long-chain neurotoxins, and one PLA(2) molecule) exhibit relative abundances >5%. As expected from its high neurotoxin abundance, the LD(50) for mice of H. cyanocinctus venom was fairly low, 0.132μg/g (intravenous) and 0.172μg/g (intraperitoneal). Our data indicate that specialization towards a lethal cocktail of 3FTx and type-I PLA(2) molecules may represent a widely adopted trophic solution throughout the evolution of Elapidae. Our results also points to a minimization of the molecular diversity of the toxin arsenal of the marine snake Hydrophis cyanocinctus in comparison to the venom proteome of its terrestrial relatives, and highlight that the same evolutionary solution, economy of the toxin arsenal, has been convergently adopted by different taxa in response to opposite selective pressures, loss and gain of neurotoxicity.     

Bcr and Abr Cooperate in Negatively Regulating Acute Inflammatory Responses

Bcr and Abr are GTPase-activating proteins for the small GTPase Rac. Both proteins are expressed in cells of the innate immune system, including neutrophils and macrophages. The function of Bcr has been linked to the negative regulation of neutrophil reactive oxygen species (ROS) production, but the function of Abr in the innate immune system was unknown. Here, we report that mice lacking both proteins are severely affected in two models of experimental endotoxemia, including exposure to Escherichia coli lipopolysaccharide and polymicrobial sepsis, with extensive microvascular leakage, resulting in severe pulmonary edema and hemorrhage. Additionally, in vivo-activated neutrophils of abr and bcr null mutant mice produced excessive tissue-damaging myeloperoxidase (MPO), elastase, and ROS. Moreover, the secretion of the tissue metalloproteinase MMP9 by monocytes and ROS by elicited macrophages was abnormally high. In comparison, ROS production from bone marrow monocytes was not significantly different from that of controls, and the exocytosis of neutrophil secondary and tertiary granule products, including lactoferrin, was normal. These data show that Abr and Bcr normally curb very specific functions of mature tissue innate immune cells, and that each protein has distinct as well as partly overlapping functions in the downregulation of inflammatory processes.BCR originally was discovered as a human gene on chromosome 22 that, in chronic myeloid leukemia, becomes fused to the c-ABL tyrosine kinase gene originating from chromosome 9 (18). The normal gene encodes a 160-kDa protein that contains a domain with GTPase-activating (GAP) activity toward Rho family GTPases (7, 11, 12, 32, 36). There is only one other gene in mouse and human, called ABR, that is closely homologous to BCR (17). Abr shares several domains with Bcr, which includes a Dbl homology (DH) domain and a GAP domain. Bcr has an additional N-terminal part consisting of a coiled-coil and a serine/threonine kinase domain that is not present in Abr, suggesting that each GAP has a distinct cellular function.Rho GTPases, including Rho, Rac, and Cdc42, play important roles in many functions of cells of the innate immune system (16). They cycle between active GTP and inactive GDP-bound conformations. GAP proteins catalyze the conversion of bound GTP to GDP on Rho GTPases and thus act as negative, inactivating regulators.In previous studies, we showed that both Abr and Bcr specifically act as GAPs for Rac and not for the related Cdc42 (6). To investigate the normal cellular function of these two related GAPs, we generated mice defective in the production of Abr or Bcr through gene targeting. Mice that lack both proteins have defects in the architecture of the inner ear, with the partial absence of otoconia and hair cells. Additionally, postnatal cerebellar development is abnormal, with a persistence of ectopic granule cells at the cerebellar surface. These combined abnormalities cause persistent circling and balance problems (20, 21).As reported previously, neutrophils from mice lacking Bcr produce increasing amounts of reactive oxygen species (ROS), and bcr^−/− mice injected with Escherichia coli lipopolysaccharide (LPS) are much more severely affected than are wild-type mice (39). We further explored the role of Bcr and Abr in the innate immune system with a detailed study of bone marrow-derived macrophages (BMM). Interestingly, macrophages isolated from double-knockout (abr × bcr^−/−) mice exhibited multiple defects. These include aberrant actin cytoskeletal organization and the increased colony-stimulating factor 1-stimulated chemotaxis and phagocytosis of opsonized zymosan or E. coli (6).In the current study, we examined whether the defects observed in vitro result in an observable phenotype in vivo, under inflammatory conditions. Here, we report that Abr plays a distinct role in negatively regulating the innate immune system in vivo, as well as exhibiting overlap with the function of Bcr. Mice lacking both Abr and Bcr have a severely impaired ability to resolve septic shock, showing that the activity of both proteins is required for the appropriate negative control of innate immune responses.     

Stabilized β-catenin in lung epithelial cells changes cell fate and leads to tracheal and bronchial polyposis

The precise mechanisms by which β-catenin controls morphogenesis and cell differentiation remain largely unknown. Using embryonic lung development as a model, we deleted exon 3 of β-catenin via Nkx2.1-cre in the Catnb[+/lox(ex3)] mice and studied its impact on epithelial morphogenesis. Robust selective accumulation of truncated, stabilized β-catenin was found in Nkx2.1-cre;Catnb[+/lox(ex3)] lungs that were associated with the formation of polyp-like structures in the trachea and main-stem bronchi. Characterization of polyps suggests that accumulated β-catenin impacts epithelial morphogenesis in at least two ways. “Intracellular” accumulation of β-catenin blocked differentiation of spatially-appropriate airway epithelial cell types, Clara cells, ciliated cells and basal cells, and activated UCHL1, a marker for pulmonary neuroendocrine cells. There was also evidence for a “paracrine” impact of β-catenin accumulation, potentially mediated via activation of Bmp4 that inhibited Clara and ciliated, but not basal cell differentiation. Thus, excess β-catenin can alter cell fate determination by both direct and paracrine mechanisms.     

Characterization of bacterial populations recovered from the teat canals of lactating dairy and beef cattle by 16S rRNA gene sequence analysis

Bovine mastitis is of major concern to the dairy industry worldwide. The bovine teat canal is the primary route through which pathogens enter the mammary gland. The microflora of the teat canals of dairy and beef cattle was investigated by analysis of 16S rRNA gene sequences. The goal was to examine the global difference between dairy cattle, which are sanitized on a regular basis, and beef cattle, which receive little sanitary management. A diverse population of 16S rRNA gene sequences was recovered from both the dairy and the beef herd samples, with diversity higher in the beef sample. Analysis revealed the presence of 90 operational taxonomic units (OTUs) among 156 sequences, with 45 OTUs in the dairy sample and 53 OTUs in the beef sample. Only eight OTUs were common to both samples. Members of the classes Clostridia and Bacilli dominated both samples, followed by Actinobacteria and Proteobacteria. The dairy sample contained a cluster (20/80 clones) of Staphylococcaceae members, seven of which were identifiable as coagulase-negative Staphylococcus species. The beef sample was dominated by members of the genus Clostridia, many of which have not been previously cultured. The results suggest that the microorganisms present in the bovine teat canal are more diverse than previously described.     

Cytokine response following transthoracic and transhiatal esophagectomy in patients with esophageal cancer

Curative esophageal resection is usually performed using either a transthoracic (TT) or transhiatal (TH) approach. Forty patients with esophageal squamous cell carcinoma who underwent esophagectomies (24 TT and 16 TH), 12 patients who underwent surgery for gastric cancer, and 16 healthy individuals were enrolled in this study. Blood samples were taken from the patients, pre- and post-surgery. The levels of synthesis of T-helper 1 and 2 cytokines were assessed in vitro in the presence of mitogen. Our initial data indicated that at admission, 24 h before surgery, blood cells from both groups of esophageal cancer patients produced significantly lower levels of the Th1 cytokines, IFN-gamma and IL-2 than those from cells of healthy donors. Cells collected from gastric cancer patients prior to surgery produced intermediate levels of IFN-gamma and IL-2: significantly lower than healthy donors, and slightly more (non-significant) than esophageal cancer patients. These results contrast with those for the production of Th2 cytokines prior to surgery, which did not differ significantly between any groups: either the esophageal or gastric cancer patients, or healthy donors. Th1 and Th2 cytokine production was then studied using blood cells collected seven days after surgery. Cells from both groups of esophageal cancer patients, undergoing either TT or TH surgery, produced significantly lower levels of the Th1 cytokines, IFN-gamma and IL-2 than those from cells of gastric cancer patients who had undergone surgery. Postoperative and preoperative production was compared. For patients who had undergone TT esophageal resection, we observed that the post-operative production of IL-2, IL-5 and IL-13 was significantly lower than the pre-operative production of those cytokines. Such reduced post-operative compared to pre-operative production was only significant in patients who had undergone TT esophagectomy. A similar, but non-significant trend was observed in patients who had undergone either TH esophagectomy, or gastrectomy. The results indicate that digestive tract cancer patients, both esophageal and gastric, have (prior to surgery), a significantly reduced, basal, mitogen-induced production of Th1 but not of Th2 cytokine. Post-operatively, a significantly reduced production of Th1 and Th2 cytokines, except for IFN-gamma, was observed only in patients who had undergone surgical esophageal resection using the TT method.     

Molecular interaction of human serum albumin with paracetamol: Spectroscopic and molecular modeling studies

The interaction between paracetamol and human serum albumin (HSA) under physiological conditions has been investigated by fluorescence, circular dichroism (CD) and docking. Fluorescence data revealed that the fluorescence quenching of HSA by paracetamol was the result of the formed complex of HSA–paracetamol, and the binding constant (K_a) and binding number obtained is 1.3 × 10⁴ at 298 K and 2, respectively for the primary binding site. Circular dichorism spectra showed the induced conformational changes in HSA by the binding of paracetamol. Moreover, protein–ligand docking study indicated that paracetamols (two paracetamols bind to HSA) bind to residues located in the subdomain IIIA.     

Evidence that TNF-β (lymphotoxin α) can activate the inflammatory environment in human chondrocytes

Introduction

Inflammatory cytokines play a key role in the pathogenesis of joint diseases such as rheumatoid arthritis (RA). Current therapies target mainly tumor necrosis factor α (TNF-α) as this has proven benefits. However, a large number of patients do not respond to or become resistant to anti-TNF-α therapy. While the role of TNF-α in RA is quite evident, the role of TNF-β, also called lymphotoxin-α (LT-α), is unclear. In this study we investigated whether TNF-β and its receptor play a role in chondrocytes in the inflammatory environment.

Methods

An in vitro model of primary human chondrocytes was used to study TNF-β-mediated inflammatory signaling.

Results

Cytokine-induced inflammation enhances TNF-β and TNF-β-receptor expression in primary human chondrocytes accompanied by the up-regulation of inflammatory (cyclooxygenase-2), matrix degrading (matrix metalloproteinase-9 and -13) and apoptotic (p53, cleaved caspase-3) signaling pathways, all known to be regulated by NF-κB. In contrast, anti-TNF-β, similar to the natural NF-κB inhibitor (curcumin, diferuloylmethane) or the knockdown of NF-κB by using antisense oligonucleotides (ASO), suppressed IL-1β-induced NF-κB activation and its translocation to the nucleus, and abolished the pro-inflammatory and apoptotic effects of IL-1β. This highlights, at least in part, the crucial role of NF-κB in TNF-β-induced-inflammation in cartilage, similar to that expected for TNF-α. Finally, the adhesiveness between TNF-β-expressing T-lymphocytes and the responding chondrocytes was significantly enhanced through a TNF-β-induced inflammatory microenvironment.

Conclusions

These results suggest for the first time that TNF-β is involved in microenvironment inflammation in chondrocytes during RA parallel to TNF-α, resulting in the up-regulation of NF-κB signaling and activation of pro-inflammatory activity.     

Engineering characterisation of a single well from 24-well and 96-well microtitre plates

The detailed engineering characterisation of shaken microtitre-plate bioreactors will enhance our understanding of microbial and mammalian cell culture in these geometries and will provide guidance on the scale-up of microwell results to laboratory and pilot scale stirred bioreactors. In this work computational fluid dynamics (CFD) is employed to provide a detailed characterisation of fluid mixing, energy dissipation rate and mass transfer in single well bioreactors from deep square 24-well and 96-well microtitre plates. The numerical predictions are generally found to be in good agreement with experimental observation of the fluid motion and measured values of the key engineering parameters. The CFD simulations have shown that liquid mixing is more intensive in 96-well than in 24-well bioreactors due to a significant axial component to the fluid velocity. Liquid motion is strongly dependent on the orbital shaking amplitude which generally has a greater impact than the shaking frequency. Average power consumptions of 70–100 W m⁻³ and 500–1000 W m⁻³, and overall mass transfer coefficient, k_La, values of 0.005–0.028 s⁻¹ and 0.056–0.10 s⁻¹ were obtained for 24-well and 96-well bioreactors respectively at an orbital shaking amplitude of 3 mm and shaking frequencies ranging from 500 rpm to 1500 rpm. The distribution of energy dissipation rates within each bioreactor showed these to be greatest at the walls of the well for both geometries. Batch culture kinetics of E. coli DH5 showed similar maximum specific growth rates and final biomass yields in shaken 24-well and shake flask bioreactors and in stirred miniature and 20 L bioreactors at matched k_La values. The CFD simulations thus give new insights into the local and overall engineering properties of microwell bioreactor geometries and further support their use as high throughput tools for the study and optimisation of microbial and mammalian cell culture kinetics at this scale.