NIBBS-search for fast and accurate prediction of phenotype-biased metabolic systems

Understanding of genotype-phenotype associations is important not only for furthering our knowledge on internal cellular processes, but also essential for providing the foundation necessary for genetic engineering of microorganisms for industrial use (e.g., production of bioenergy or biofuels). However, genotype-phenotype associations alone do not provide enough information to alter an organism's genome to either suppress or exhibit a phenotype. It is important to look at the phenotype-related genes in the context of the genome-scale network to understand how the genes interact with other genes in the organism. Identification of metabolic subsystems involved in the expression of the phenotype is one way of placing the phenotype-related genes in the context of the entire network. A metabolic system refers to a metabolic network subgraph; nodes are compounds and edges labels are the enzymes that catalyze the reaction. The metabolic subsystem could be part of a single metabolic pathway or span parts of multiple pathways. Arguably, comparative genome-scale metabolic network analysis is a promising strategy to identify these phenotype-related metabolic subsystems. Network Instance-Based Biased Subgraph Search (NIBBS) is a graph-theoretic method for genome-scale metabolic network comparative analysis that can identify metabolic systems that are statistically biased toward phenotype-expressing organismal networks. We set up experiments with target phenotypes like hydrogen production, TCA expression, and acid-tolerance. We show via extensive literature search that some of the resulting metabolic subsystems are indeed phenotype-related and formulate hypotheses for other systems in terms of their role in phenotype expression. NIBBS is also orders of magnitude faster than MULE, one of the most efficient maximal frequent subgraph mining algorithms that could be adjusted for this problem. Also, the set of phenotype-biased metabolic systems output by NIBBS comes very close to the set of phenotype-biased subgraphs output by an exact maximally-biased subgraph enumeration algorithm ( MBS-Enum ). The code (NIBBS and the module to visualize the identified subsystems) is available at http://freescience.org/cs/NIBBS.     

Characterization of the West Nile virus protease substrate specificity and inhibitors

West Nile virus (WNV), a mosquito-borne member of Flaviviridae, is a human pathogen causing widespread disease for which there is no vaccine or chemotherapy. The two-component viral serine protease consists of a heterodimeric complex between the hydrophilic domain of the cofactor, NS2B (NS2BH) and the protease domain (NS3-pro). The protease is essential for polyprotein processing followed by assembly of viral replicase and genome replication. Therefore, the protease is an excellent target for development of antiviral therapeutics. Here, we report the expression in Escherichia coli, purification, and characterization of biochemical and kinetic properties of the WNV protease. Furthermore, we show that the WNV and the dengue virus type 2 (DENV-2) proteases are inhibited by aprotinin with inhibitor constants of 0.16 and 0.026 microM, respectively. Molecular modeling of the WNV protease/aprotinin complex, based on the known crystal structures of the WNV NS2BH-N3pro and aprotinin, suggest a potentially strong interaction between the P2 Lys and the protease activator peptide, NS2BH. This conclusion based on molecular modeling is in agreement with our data of a higher k(cat)/Km value with the substrate, Boc-Gly-Lys-Arg-MCA than the Boc-Gly-Arg-Arg-MCA and is also consistent with the results of an earlier study that were based on substrate-based inhibitor peptides.     

Cell cycle inhibition and retinoblastoma protein overexpression prevent Purkinje cell death in organotypic slice cultures

Purkinje cells are vulnerable to a number of physical, chemical, and genetic insults during development and maturity. Normal development of these cells depends on the cell-cell interactions between granule and astroglial cell populations. Apoptotic death in Purkinje neurons had been shown to be associated with cell cycle activation, and new DNA synthesis is associated with Purkinje cell death in staggerer and lurcher mutant mice. Here using an in vitro organotypic slice culture model from 9 (P9) and 4 days (P4) old postnatal rats we show that the cyclin dependent kinase (cdk) inhibitors (roscovitine, olomoucine, and flavopiridol) protect the Purkinje cells from cell death. The results are more pronounced in the cerebellar sections from P4 rats. Analysis of Purkinje neurons in sections from P4 rats after 1 week of culturing showed that while there were very limited calbindin positive neurons in the untreated sections the cdk inhibitor treated sections had a notably higher number. Although treatment with cdk inhibitors inhibited Purkinje cell loss significantly, the morphology of these neurons was abnormal, with stunted dendrites and axons. Since the retinoblastoma protein (Rb) is the major pocket protein involved in determining the differentiated state of neurons we examined the effect of over-expressing Rb in the organotypic cultures. Rb overexpression significantly inhibited the Purkinje cell death and these neurons maintained their normal morphology. Thus our studies show that the cell death in Purkinje neurons observed in organotypic cultures is cell cycle dependent and the optimal survival requires Rb.     

Pumilio 2 controls translation by competing with eIF4E for 7-methyl guanosine cap recognition

Pumilio 2 (Pum2) interacts with the 3′ UTR-containing pumilio binding element (PBE) of RINGO/SPY mRNA to repress translation in Xenopus oocytes. Here, we show that Pum2 also binds directly to the 5′ 7mG cap structure; in so doing, it precludes eIF4E from binding the cap. Using deletion analysis, we have mapped the cap interaction domain of Pum2 to the amino terminus of the protein and identified a conserved tryptophan residue that mediates this specific interaction. Reporter mRNA-based assays demonstrate that Pum2 requires the conserved tryptophan to repress translation in injected Xenopus oocytes. Thus, in addition to its suggested role in regulating poly(A) tail length and mRNA stability, our results suggest that vertebrate Pumilio can repress translation by blocking the assembly of the essential initiation complex on the cap.     

Electron-microscopic studies on the pathogenesis of exencephaly and cranioschisis induced in the rat after neural tube closure: role of the neuroepithelium and choroid plexus

Exencephaly was induced in Wistar rat fetuses by the administration of a single dose of cyclophosphamide (15 mg/kg) in saline, after neural tube closure. The neuroepithelium (NE) and the choroid plexus were studied electron-microscopically in sections taken from a few hours after treatment to day 19 of gestation. The reduction in polyribosomes and condensation of the nucleus and cytoplasm were followed by cell death and fragmentation in the NE. Such cellular debris were phagocytosed and digested by the apparently normal neuroblasts. Cell proliferation was inhibited. The progressive loss of cells and lack of neuropil arborisation resulted in the expansion of the extracellular space and reduced intercellular contacts. The internal and external limiting membranes became weak. The vascular endothelium was attenuated. There were no obvious discontinuities of endothelium, but clusters of extravascular red blood cells, particularly in the vicinity of capillaries, in the cavitations in the NE and in the ventricular lumen were prominent by day 15. Subsequently, the cavities in the NE frankly communicated with the ventricle internally and subcutaneous blebs externally. The choroid plexus of exencephalic embryos was more extensive than that of the age-matched controls. Hydropic vacuoles, dense bodies, distended mitochondria, clusters of vesicles in basal cytoplasm and lakes of monoparticulate glycogen progressively increased in the plexus cells. Pericapillary oedema was obvious in the core of the plexus. These observations suggest that, in addition to cell death and reduced cell proliferation, haemorrhage, oedema and enhanced cerebrospinal fluid production contribute to reopening of the closed neural tube in this model.     

A glutathione-specific aldose reductase of Leishmania donovani and its potential implications for methylglyoxal detoxification pathway

Methylglyoxal is mainly catabolized by two major enzymatic pathways. The first is the ubiquitous detoxification pathway, the glyoxalase pathway. In addition to the glyoxalase pathway, aldose reductase pathway also plays a crucial role in lowering the levels of methylglyoxal. The gene encoding aldose reductase (ALR) has been cloned from Leishmania donovani, a protozoan parasite causing visceral leishmaniasis. DNA sequence analysis revealed an open reading frame (ORF) of approximately 855 bp encoding a putative protein of 284 amino acids with a calculated molecular mass of 31.7 kDa and a predicted isoelectric point of 5.85. The sequence identity between L. donovani ALR (LdALR) and mammals and plants is only 36-44%. The ORF is a single copy gene. A protein with a molecular mass that matched the estimated approximately 74 kDa according to the amino acid composition of LdALR with a maltose binding tag present at its N-terminal end was induced by heterologous expression of LdALR in Escherichia coli. In the presence of glutathione, recombinant LdALR reduced methylglyoxal with a K(m) of approximately 112 microM. Comparative structural analysis of the human ALR structure with LdALR model suggests that the active site anchoring the N-terminal end of the glutathione is highly conserved. However, the C-terminal end of the glutathione backbone is expected to be exposed in LdALR, as the residues anchoring the C-terminal end of the glutathione backbone come from the three loop regions in human, which are apparently shortened in the LdALR structure. Thus, the computational analysis provides clues about the expected mode of glutathione binding and its interactions with the protein. This is the first report of the role of an ALR in the metabolic disposal of methylglyoxal in L. donovani and of thiol binding to a kinetoplastid aldose reductase.     

Genetics of hypertension: From experimental animals to humans

Essential hypertension affects 20 to 30% of the population worldwide and contributes significantly to cardiovascular mortality and morbidity. Heridability of blood pressure is around 15 to 40% but there are also substantial environmental factors affecting blood pressure variability. It is assumed that blood pressure is under the control of a large number of genes each of which has only relatively mild effects. It has therefore been difficult to discover the genes that contribute to blood pressure variation using traditional approaches including candidate gene studies and linkage studies. Animal models of hypertension, particularly in the rat, have led to the discovery of quantitative trait loci harbouring one or several hypertension related genes, but translation of these findings into human essential hypertension remains challenging. Recent development of genotyping technology made large scale genome-wide association studies possible. This approach and the study of monogenic forms of hypertension has led to the discovery of novel and robust candidate genes for human essential hypertension, many of which require functional analysis in experimental models.     

Design of a novel nucleoside analog as potent inhibitor of the NAD<Superscript>+</Superscript> dependent deacetylase,SIRT2

Sirtuins (class III histone deacetylase) are evolutionarily conserved NAD⁺-dependent enzymes that catalyze the deacetylation of acetyl-lysine residues of histones and other target proteins. Because of their associations in various pathophysiological conditions, the identification of small molecule modulators has been of significant interest. In the present study, virtual screening was carried out with NCI Diversity Set II using crystal structure of hSIRT2 (PDB ID: 1J8F) as a model for the docking procedure to find potential compounds, which were then subjected to experimental tests for their in vitro SIRT2 inhibitory activity. One of the 40 compounds tested, NSC671136 (IUPAC name: 6-Acetyl-4-oxo-1,3-diphenyl-2-thioxo-1,2,3,4-tetrahydrothieno[2,3-d]pyrimidin-5-yl 2,4-dichlorobenzoate) has structurally unique scaffold, showed strong inhibitory activity towards SIRT2 with IC₅₀ of ~8.7 μM and to a lesser extent on SIRT1 activity. The reported compound is substantially potent compared to the published SIRT2 inhibitors and serves as an excellent base for future lead development.     

Crystal structure of the homolog of the oncoprotein gankyrin, an interactor of Rb and CDK4/6

The oncoprotein gankyrin plays a central role in tumorigenesis and cell proliferation. Gankyrin interacts with the retinoblastoma tumor suppressor (Rb) and cyclin-dependent kinase 4/6 (CDK4/6), increases phosphorylation at specific residues of Rb by CDK4/6 in vivo, and promotes tumorigenesis. The phosphorylation of Rb by CDK4/6 leads to the deregulation of the cell cycle during G1/S transition. Although how phosphorylation occurs on Rb has been studied extensively, the mechanism of site-specific phosphorylation of Rb remains unclear due to a lack of information on the structural arrangement of Rb and CDK4/6. Here, we have determined and refined to 2.3-A resolution the crystal structure of a gankyrin homolog, the non-ATPase subunit 6 (Nas6p) of the proteasome from yeast. The crystal structure reveals that Nas6p contains seven ankyrin repeats. The number of the repeats is different from that predicted from the primary structure. Nas6p also possesses an unusual curved structure with two acidic regions at the N- and C-terminal regions separated by one basic region, suggesting that it has at least two functional surfaces. The tertiary structure of Nas6p, together with the previous biochemical studies, indicates that the CDK4/6 and Rb binding surfaces of gankyrin are located at the N- and C-terminal regions, respectively, and face the same side of gankyrin. These observations suggest that gankyrin brings Rb and CDK4/6 together through gankyrin-Rb and gankyrin-CDK4/6 interactions and determines the relative positioning of the substrate (Rb) and the enzyme (CDK4/6). Our findings provide mechanistic insight into site-specific phosphorylation of Rb caused by CDK4/6.