Oncogenic Pathway Combinations Predict Clinical Prognosis in Gastric Cancer

Many solid cancers are known to exhibit a high degree of heterogeneity in their deregulation of different oncogenic pathways. We sought to identify major oncogenic pathways in gastric cancer (GC) with significant relationships to patient survival. Using gene expression signatures, we devised an in silico strategy to map patterns of oncogenic pathway activation in 301 primary gastric cancers, the second highest cause of global cancer mortality. We identified three oncogenic pathways (proliferation/stem cell, NF-κB, and Wnt/β-catenin) deregulated in the majority (>70%) of gastric cancers. We functionally validated these pathway predictions in a panel of gastric cancer cell lines. Patient stratification by oncogenic pathway combinations showed reproducible and significant survival differences in multiple cohorts, suggesting that pathway interactions may play an important role in influencing disease behavior. Individual GCs can be successfully taxonomized by oncogenic pathway activity into biologically and clinically relevant subgroups. Predicting pathway activity by expression signatures thus permits the study of multiple cancer-related pathways interacting simultaneously in primary cancers, at a scale not currently achievable by other platforms.     

Regulation of ceramide channels by Bcl-2 family proteins

Mitochondrial outer membrane permeabilization to proteins, an irreversible step in apoptosis by which critical proteins are released, is tightly regulated by Bcl-2 family proteins. The exact nature of the release pathway is still undefined. Ceramide is an important sphingolipid, involved in various cellular processes including apoptosis. Here we describe the structural properties of ceramide channels and their regulation by the anti-apoptotic and pro-apoptotic proteins of the Bcl-2 family. The evolutionarily conserved regulation of ceramide channels by Bcl-2 family proteins, consistent with their role in apoptosis, lends credibility to the notion that ceramide channels constitute the protein release pathway.     

Influence of ultraviolet radiation on spore liberation in marine macroalgae Ulva fasciata (Ulvales,Chlorophyceae) and Gracilaria corticata (Gracilariales,Rhodophyceae)

The effect of ultraviolet‐B (UV‐B) and UV‐A radiation on spore liberation in the intertidal marine macroalgae Ulva fasciata Delile (Chlorophyceae) and Gracilaria corticata J.Agardh (Rhodophyceae) was investigated. The two algae were exposed to UV‐A and UV‐B radiation separately for 10, 20, 30, 45 and 60 min and percentage inhibition of spore liberation was determined in controlled laboratory conditions. The spore liberation period in UV treated algae was extended for 4 days in U. fasciata and 9 days in G. corticata. UV‐B radiation inhibited spore liberation as much as 76.6% in U. fasciata and 55.5% in G. corticata at 60 min exposure. A significant positive correlation was observed between percentage inhibition of spore liberation and length of UV‐B exposure in both U. fasciata and in G. corticata. Similarly, UV‐A radiation also inhibited spore liberation as much as 75% in the former and 50% in the latter. There was a significant correlation between inhibition of spore liberation and length of UV‐A exposure in U. fasciata and in G. corticata. Analysis of variance results showed inhibition of spore liberation at 60 min of UV exposure differed significantly with that of other exposure lengths. The present findings reveal that UV‐A radiation also had an impact on spore liberation but to a lesser extent than UV‐B radiation. Thallus thickness and plant location on the shore determines their exposure to UV radiation. High UV impact was seen for U. fasciata growing in the upper parts of the intertidal region with a thin sheet like thallus and high surface area resulting in higher inhibition of spore liberation than in G. corticata.     

Functional biogeography as evidence of gene transfer in hypersaline microbial communities

Background

Horizontal gene transfer (HGT) plays a major role in speciation and evolution of bacteria and archaea by controlling gene distribution within an environment. However, information that links HGT to a natural community using relevant population-genetics parameters and spatial considerations is scarce. The Great Salt Lake (Utah, USA) provides an excellent model for studying HGT in the context of biogeography because it is a contiguous system with dispersal limitations due to a strong selective salinity gradient. We hypothesize that in spite of the barrier to phylogenetic dispersal, functional characteristics—in the form of HGT—expand beyond phylogenetic limitations due to selective pressure.

Methodology and Results

To assay the functional genes and microorganisms throughout the GSL, we used a 16S rRNA oligonucleotide microarray (Phylochip) and a functional gene array (GeoChip) to measure biogeographic patterns of nine microbial communities. We found a significant difference in biogeography based on microarray analyses when comparing Sørensen similarity values for presence/absence of function and phylogeny (Student''s t-test; p = 0.005).

Conclusion and Significance

Biogeographic patterns exhibit behavior associated with horizontal gene transfer in that informational genes (16S rRNA) have a lower similarity than functional genes, and functional similarity is positively correlated with lake-wide selective pressure. Specifically, high concentrations of chromium throughout GSL correspond to an average similarity of chromium resistance genes that is 22% higher than taxonomic similarity. This suggests active HGT may be measured at the population level in microbial communities and these biogeographic patterns may serve as a model to study bacteria adaptation and speciation.     

On the activity loss of hydrolases in organic solvents: II. a mechanistic study of subtilisin Carlsberg

Background  

Enzymes have been extensively used in organic solvents to catalyze a variety of transformations of biological and industrial significance. It has been generally accepted that in dry aprotic organic solvents, enzymes are kinetically trapped in their conformation due to the high-energy barrier needed for them to unfold, suggesting that in such media they should remain catalytically active for long periods. However, recent studies on a variety of enzymes demonstrate that their initial high activity is severely reduced after exposure to organic solvents for several hours. It was speculated that this could be due to structural perturbations, changes of the enzyme's pH memory, enzyme aggregation, or dehydration due to water removal by the solvents. Herein, we systematically study the possible causes for this undesirable activity loss in 1,4-dioxane.     

Translational competence of ribosomes released from a premature termination codon is modulated by NMD factors

In addition to their well-documented roles in the promotion of nonsense-mediated mRNA decay (NMD), yeast Upf proteins (Upf1, Upf2/Nmd2, and Upf3) also manifest translational regulatory functions, at least in vitro, including roles in premature translation termination and subsequent reinitiation. Here, we find that all upfΔ strains also fail to reinitiate translation after encountering a premature termination codon (PTC) in vivo, a result that led us to seek a unifying mechanism for all of these translation phenomena. Comparisons of the in vitro translational activities of wild-type (WT) and upf1Δ extracts were utilized to test for a Upf1 role in post-termination ribosome reutilization. Relative to WT extracts, non-nucleased extracts lacking Upf1 had approximately twofold decreased activity for the translation of synthetic CAN1/LUC mRNA, a defect paralleled by fewer ribosomes per mRNA and reduced efficiency of the 60S joining step at initiation. These deficiencies could be complemented by purified FLAG-Upf1, or 60S subunits, and appeared to reflect diminished cycling of ribosomes from endogenous PTC-containing mRNAs to exogenously added synthetic mRNA in the same extracts. This hypothesis was tested, and supported, by experiments in which nucleased WT or upf1Δ extracts were first challenged with high concentrations of synthetic mRNAs that were templates for either normal or premature translation termination and then assayed for their capacity to translate a normal mRNA. Our results indicate that Upf1 plays a key role in a mechanism coupling termination and ribosome release at a PTC to subsequent ribosome reutilization for another round of translation initiation.     

Immobilization of acidic lipase derived from Pseudomonas gessardii onto mesoporous activated carbon for the hydrolysis of olive oil

Mesoporous activated carbon (MAC) derived from rice husk is used for the immobilization of acidic lipase (ALIP) produced from Pseudomonas gessardii. The purified acidic lipase had the specific activity and molecular weight of 1473 U/mg and 94 kDa respectively. To determine the optimum conditions for the immobilization of lipase onto MAC, the experiments were carried out by varying the time (10–180 min), pH (2–8), temperature (10–50 °C) and the initial lipase activity (49 × 10³, 98 × 10³, 147 × 10³ and 196 × 10³ U/l in acetate buffer). The optimum conditions for immobilization of acidic lipase were found to be: time—120 min; pH 3.5; temperature—30 °C, which resulted in achieving a maximum immobilization of 1834 U/g. The thermal stability of the immobilized lipase was comparatively higher than that in its free form. The free and immobilized enzyme kinetic parameters (K_m and V_max) were found using Michaelis–Menten enzyme kinetics. The K_m values for free enzyme and immobilized one were 0.655 and 0.243 mM respectively. The immobilization of acidic lipase onto MAC was confirmed using Fourier Transform-Infrared Spectroscopy, X-ray diffraction analysis and scanning electron microscopy.