Transforming genes among three different oncogenic subgroups of human adenoviruses have similar replicative functions.

We have examined the functional similarity of the transforming genes for replicative functions among three different subgroups of human adenoviruses (A, B, and C), using mutant complementation as an assay. A host range deletion mutant (dl201.2) of Ad2 (nononcogenic subgroup C) lacking about 5% of the viral DNA covering two early gene blocks (E1a and E1b) involved in cellular transformation was isolated and tested for its ability to replicate in nonpermissive KB cells in the presence of Ad7 (weakly oncogenic group B) or ad12 (highly oncogenic group A). The complementation of the mutant defect was demonstrated by cleaving the viral DNA extracted from mixed infected cells or the DNA extracted from purified virions from mixed infected cells with restriction endonuclease BamHI, which produces a different cleavage pattern with the DNA of each serotype. It was found that the defects in E1a plus E1b of dl201.2 could be complemented by Ad7 and Ad12, indicating that these genes in Ad2, Ad7, and Ad12 have similar functions during productive infection.     

A unique subgenomic species of adenovirus 2 DNA generated under high multiplicities of infection.

We have identified a novel subgenomic viral DNA in KB cells infected with adenovirus 2 (Ad2) under high multiplicities of infection. KB cells were infected with Ad2 at multiplicities of infection greater than 100 PFU/cell. 32P-labeled viral DNA was selectively extracted by a modification of the method of Hirt (8) from the infected cells and analyzed by electrophoresis on agarose gels. In addition to full-length DNA (33 to 23 x 10(6) daltons), a unique subgenomic DNA species of about 12 to 13% (2.6 x 10(6) daltons) of full-length DNA in size was found in the infected cells. This subgenomic DNA was found to be double stranded and was not packaged inside the virus particles. This DNA could be isolated in large amounts (30 to 50% of total viral DNA) from infected cells. When cleaved with restriction endonuclease KpnI, the subgenomic DNA yielded two fragments, each corresponding to about 6% and 7% of the full-length genome in size.     

Length weight relationship of five deep sea fishes from Kerala,south west coast of India

Length–weight relationships (LWRs) were estimated for five deep sea fishes viz. Astronesthes martensii, Glyptophidium macropus, Neobythites multistriatus, Physiculus roseus, Synagrops japonicus from Kerala, south west coast of India. Fishes were collected from commercial trawlers monthly from February 2018 to March 2019 operating at depth ranged from 270 m (Lat. 9°29.35′ N, Long. 75°44.74′ E) to 350 m (Lat. 9°26. 49′ N, Long. 75°42.36′ E) in the south east Arabian Sea. Correlation coefficients (r²) were found high for all species, with b value ranged from 2.923 to 3.404.     

Phosphorylation of the pro-apoptotic protein BIK: mapping of phosphorylation sites and effect on apoptosis

BIK is a pro-apoptotic BCL-2 family member and is the founding member of a subfamily of pro-apoptotic proteins known as "BH3-alone" proteins. Ectopic expression of BIK induces apoptosis in variety of mammalian cells. BIK complexes with various anti-apoptotic BCL-2 family proteins such as adenovirus E1B-19K and BCL-2 via the BH3 domain. However, the heterodimerization activity of BIK alone is insufficient for its apoptotic activity. Previous studies have shown that phosphorylation regulates the functional activity of both anti-apoptotic and pro-apoptotic members of the BCL-2 family. Here, we have examined phosphorylation of BIK and its effect on the apoptotic activity of BIK. We show that BIK exists as a phosphoprotein and is phosphorylated at residues 33 (threonine) and 35 (serine). Mutation of the phosphorylation sites, in which the Thr and Ser residues were changed to alanine residues, reduced the apoptotic activity of BIK without significantly affecting its ability to heterodimerize with BCL-2. Our results suggest that phosphorylation of BIK is required for eliciting efficient apoptotic activity. Partial purification of the protein kinase from HeLa cell cytoplasmic extracts suggest that BIK may be phosphorylated by a casein kinase II-related enzyme.     

Requirement of BAX for efficient adenovirus-induced apoptosis

Infection of human epithelial cells with adenoviruses induces an apoptosis paradigm that is efficiently suppressed by the expression of viral E1B-19K protein, which is a functional homolog of the cellular antiapoptosis protein BCL-2. The mechanisms of adenovirus (Ad)-induced apoptosis appear to involve the cellular BCL-2 family proapoptotic proteins. Recent genetic studies with fibroblasts derived from mutant mouse embryos indicate that a class of the BCL-2 family proapoptotic proteins (designated BH-123 or multidomain proteins) such as BAX and BAK constitutes an essential component of the core apoptosis machinery in animal cells. We have examined the role of BAX in Ad-induced apoptosis in human epithelial cells using two colon cancer cell lines, HCT116Bax (Bax(+/-)) and HCT116BaxKO (Bax(-/-)) (L. Zhang, J. Yu, B. H. Park, K. W. Kinzler, and B. Vogelstein, Science 290:989-992, 2000). Infection of Bax(+/-) cells with an Ad type 2 mutant (dl250) defective in expression of the E1B-19K protein resulted in enhanced cytopathic effect, large plaques on cell monolayers, fragmentation of cellular DNA, and enhanced cell death. These mutant phenotypes were not efficiently expressed in Bax(-/-) cells, suggesting that BAX is essential for Ad-induced apoptosis. Infection of Bax(+/-) cells with dl250 induced increased levels of an N-terminally processed form of BAX. Cells infected with the 19K mutant also contained enhanced levels of truncated BAX in membrane-inserted form. Our results suggest that at least a part of the mechanism utilized by E1B-19K to suppress apoptosis during Ad infection may involve modulation of the activities of BAX.     

Predicting functional associations from metabolism using bi-partite network algorithms

Background  

Metabolic reconstructions contain detailed information about metabolic enzymes and their reactants and products. These networks can be used to infer functional associations between metabolic enzymes. Many methods are based on the number of metabolites shared by two enzymes, or the shortest path between two enzymes. Metabolite sharing can miss associations between non-consecutive enzymes in a serial pathway, and shortest-path algorithms are sensitive to high-degree metabolites such as water and ATP that create connections between enzymes with little functional similarity.     

Fate map of serotonin transporter-expressing cells in developing mouse heart

Serotonin regulates cardiovascular functions during embryogenesis and adulthood. However, the source of serotonin in the cardiovascular system and the role of circulating serotonin and serotonin transporter (SERT) in the regulation of cardiovascular functions are still unclear. We used a cell fate approach to map the regions of the mouse heart expressing SERT, utilizing a Cre/loxP system driven by SERT gene expression. Cell labelling was first detected at E10.5 and was mapped until E18.5. We found labelling in the outflow tract, part of right ventricle and to a very limited extent in the left ventricle. Interestingly, the distribution pattern of SERT-fated cells was remarkably similar to that obtained with markers of the second heart field lineage. In addition, we observed staining of atrioventricular valves, consistent with valvular abnormalities observed in SERT-/-animals. Overall, our data reveal specific and regionally restricted distribution of SERT-expressing cells in the developing heart of mouse.     

Theoretical investigation on the glycan‐binding specificity of Agrocybe cylindracea galectin using molecular modeling and molecular dynamics simulation studies

Galectins are β‐galactoside binding proteins which have the ability to serve as potent antitumor, cancer biomarker, and induce tumor cell apoptosis. Agrocybe cylindracea galectin (ACG) is a fungal galectin which specifically recognizes α(2,3)‐linked sialyllactose at the cell surface that plays extensive roles in the biological recognition processes. To investigate the change in glycan‐binding specificity upon mutations, single point and double point site‐directed in silico mutations are performed at the binding pocket of ACG. Molecular dynamics (MD) simulation studies are carried out for the wild‐type (ACG) and single point (ACG1) and double point (ACG2) mutated ACGs to investigate the dynamics of substituted mutants and their interactions with the receptor sialyllactose. Plausible binding modes are proposed for galectin–sialylglycan complexes based on the analysis of hydrogen bonding interactions, total pair‐wise interaction energy between the interacting binding site residues and sialyllactose and binding free energy of the complexes using molecular mechanics–Poisson–Boltzmann surface area. Our result shows that high contribution to the binding in different modes is due to the direct and water‐mediated hydrogen bonds. The binding specificity of double point mutant Y59R/N140Q of ACG2 is found to be high, and it has 26 direct and water‐mediated hydrogen bonds with a relatively low‐binding free energy of −47.52 ± 5.2 kcal/mol. We also observe that the substituted mutant Arg59 is crucial for glycan‐binding and for the preference of α(2,3)‐linked sialyllactose at the binding pocket of ACG2 galectin. When compared with the wild‐type and single point mutant, the double point mutant exhibits enhanced affinity towards α(2,3)‐linked sialyllactose, which can be effectively used as a model for biological cell marker in cancer therapeutics. Copyright © 2015 John Wiley & Sons, Ltd.