Ouabain-stimulated trafficking regulation of the Na/K-ATPase and NHE3 in renal proximal tubule cells

We have demonstrated that ouabain regulates protein trafficking of the Na/K-ATPase α1 subunit and NHE3 (Na/H exchanger, isoform 3) via ouabain-activated Na/K-ATPase signaling in porcine LLC-PK1 cells. To investigate whether this mechanism is species-specific, ouabain-induced regulation of the α1 subunit and NHE3 as well as transcellular (22)Na(+) transport were compared in three renal proximal tubular cell lines (human HK-2, porcine LLC-PK1, and AAC-19 originated from LLC-PK1 in which the pig α1 was replaced by ouabain-resistant rat α1). Ouabain-induced inhibition of transcellular (22)Na(+) transport is due to an ouabain-induced redistribution of the α1 subunit and NHE3. In LLC-PK1 cells, ouabain also inhibited the endocytic recycling of internalized NHE3, but has no significant effect on recycling of endocytosed α1 subunit. These data indicated that the ouabain-induced redistribution of the α1 subunit and NHE3 is not a species-specific phenomenon, and ouabain-activated Na/K-ATPase signaling influences NHE3 regulation.     

Discovering Functional Modules across Diverse Maize Transcriptomes Using COB,the Co-Expression Browser

Tools that provide improved ability to relate genotype to phenotype have the potential to accelerate breeding for desired traits and to improve our understanding of the molecular variants that underlie phenotypes. The availability of large-scale gene expression profiles in maize provides an opportunity to advance our understanding of complex traits in this agronomically important species. We built co-expression networks based on genome-wide expression data from a variety of maize accessions as well as an atlas of different tissues and developmental stages. We demonstrate that these networks reveal clusters of genes that are enriched for known biological function and contain extensive structure which has yet to be characterized. Furthermore, we found that co-expression networks derived from developmental or tissue atlases as compared to expression variation across diverse accessions capture unique functions. To provide convenient access to these networks, we developed a public, web-based Co-expression Browser (COB), which enables interactive queries of the genome-wide networks. We illustrate the utility of this system through two specific use cases: one in which gene-centric queries are used to provide functional context for previously characterized metabolic pathways, and a second where lists of genes produced by mapping studies are further resolved and validated using co-expression networks.     

Influence of foraging behavior and host spatial distribution on the localized spread of the emerald ash borer, <Emphasis Type="Italic">Agrilus planipennis</Emphasis>

Management programs for invasive species are often developed at a regional or national level, but physical intervention generally takes place over relatively small areas occupied by newly founded, isolated populations. The ability to predict how local habitat variation affects the expansion of such newly founded populations is essential for efficiently targeting resources to slow the spread of an invasive species. We assembled a coupled map lattice model that simulates the local spread of newly founded colonies of the emerald ash borer (Agrilus planipennis Fairmaire), a devastating forest insect pest of ash (Fraxinus spp.) trees. Using this model, we investigated the spread of A. planipennis in environments with different Fraxinus spp. distributions, and explored the consequences of ovipositional foraging behavior on the local spread of A. planipennis. Simulations indicate that increased larval density, resulting from lower host tree density or higher initial population sizes, can increase the spread rate during the first few years after colonization by increasing a density-dependent developmental rate and via host resource depletion. Both the radial spread rate and population size were greatly influenced by ovipositional foraging behavior. Two known behaviors of ovipositing A. planipennis females, attraction towards areas with high ash tree density and attraction to stressed trees, had opposing effects on spread. Results from this model illustrate the significant influence of resource distribution and foraging behavior on localized spread, and the importance of these factors when formulating strategies to monitor and manage invasive pests.     

Human Enterovirus 109: a Novel Interspecies Recombinant Enterovirus Isolated from a Case of Acute Pediatric Respiratory Illness in Nicaragua

Enteroviruses (Picornaviridae family) are a common cause of human illness worldwide and are associated with diverse clinical syndromes, including asymptomatic infection, respiratory illness, gastroenteritis, and meningitis. In this study, we report the identification and complete genome sequence of a novel enterovirus isolated from a case of acute respiratory illness in a Nicaraguan child. Unbiased deep sequencing of nucleic acids from a nose and throat swab sample enabled rapid recovery of the full-genome sequence. Phylogenetic analysis revealed that human enterovirus 109 (EV109) is most closely related to serotypes of human enterovirus species C (HEV-C) in all genomic regions except the 5′ untranslated region (5′ UTR). Bootstrap analysis indicates that the 5′ UTR of EV109 is likely the product of an interspecies recombination event between ancestral members of the HEV-A and HEV-C groups. Overall, the EV109 coding region shares 67 to 72% nucleotide sequence identity with its nearest relatives. EV109 isolates were detected in 5/310 (1.6%) of nose and throat swab samples collected from children in a pediatric cohort study of influenza-like illness in Managua, Nicaragua, between June 2007 and June 2008. Further experimentation is required to more fully characterize the pathogenic role, disease associations, and global distribution of EV109.The genus Enterovirus (EV) in the family Picornaviridae is a group of related viruses that are associated with a spectrum of disease, ranging from subclinical infections to acute respiratory and gastrointestinal illness to more severe manifestations, such as aseptic meningitis, encephalitis, and acute flaccid paralysis (16, 32). Enteroviruses are small, nonenveloped viruses that share a genomic organization. The RNA genome is a ∼7.5 kb single-stranded, positive-sense, polyadenylated molecule, with a single, long open reading frame flanked by 5′ and 3′ untranslated regions (UTRs). The 5′ UTR is ∼700 nucleotides in length and contains highly structured secondary elements with internal ribosomal entry site (IRES) function. The ∼2,200-amino-acid (aa) polyprotein is cotranslationally processed by viral proteases to yield structural (VP4, VP2, VP3, and VP1) and nonstructural (2A, 2B, 2C, 3A, 3B, 3C, and 3D) proteins (32). Current enterovirus classification is based on the high sequence divergence within the VP1 capsid region, which has been shown to correspond with serotype neutralization (27, 28). Human enterovirus (HEV) types are currently classified into four species, human enterovirus A (HEV-A), HEV-B, HEV-C (including poliovirus), and HEV-D, based on the four phylogenetic clusters observed in comparisons of the coding region sequences. An enterovirus is considered a new type within a species if it possesses <75% nucleotide identity and <85% amino acid identity with known members across the VP1 sequence (27, 30). Molecular identification methods play a crucial role in rapid, sensitive enterovirus diagnostics and have led to the recent discovery of several novel enteroviruses (29, 31, 40, 42, 44). Most approaches target a limited number of conserved regions in the 5′ UTR and VP4-VP2 junction or seek to ascertain serotype information by probing antigenic regions, such as VP1 (5).Picornavirus RNA-dependent RNA polymerases are highly error prone and lack proofreading ability, resulting in a misincorporation frequency of 1 per 10³ to 10⁴ nucleotides (48). The relative infidelity of these polymerases is believed to enable rapid adaptability under selective pressure. Large-impact evolutionary events, such as recombination within and between enterovirus serotypes, also contribute to their evolution and genetic diversity (3, 8, 26, 39) and may lead to changes in disease associations with human enterovirus infections. Human enteroviruses are classified into four species based on coding region sequence phylogeny, and intraspecies recombination events between enteroviruses that are closely related in the coding region are well documented (26, 38, 39). All known enterovirus 5′ UTR sequences, however, cluster into two groups containing either HEV-A and -B sequences or HEV-C and -D sequences. Recent findings have described enterovirus genomes with a coding region that clusters with one species and a 5′ UTR that clusters with a different species, suggesting possible interspecies recombination events (41, 44). Understanding the recombination-driven evolution of HEV-C viruses is of particular public health concern due to the viruses'' ability to recombine with vaccine poliovirus, resulting in circulating, highly neurovirulent vaccine-derived polioviruses (17, 21, 34). It is unclear whether recombination events between poliovirus and HEV-C viruses allow for the rapid acquisition of traits that increase pathogenic and circulation potential.The enterovirus pathogenicity spectrum is related to tissue tropism and is largely determined by cellular receptor usage. Most picornaviruses use receptors from the immunoglobulin superfamily of proteins, such as intracellular adhesion molecule-1 (ICAM-1) or coxsackievirus-adenovirus receptor (CAR) (36). A distinct subgroup of HEV-C viruses, which includes coxsackievirus (CAV) A1, A19, and A22 and enterovirus 104, has not yet been grown successfully in cell culture, and the receptor molecule for this subgroup is unknown (6). HEV-C viruses are believed to be the ancestral source of poliovirus, which resulted from a capsid mutation that caused a cellular receptor switch from ICAM-1 to CD155 (poliovirus receptor [PVR]) (17).In this study, we report the discovery and characterization of a novel human enterovirus type within species HEV-C, for which we propose the designation human enterovirus 109 (EV109). Sequence analysis reveals considerable nucleotide divergence in the 5′ UTR between EV109 and other HEV-C types, and scanning bootstrap analysis supports the hypothesis that EV109 is the product of an interspecies recombination event with an ancestral member of the HEV-A group. Viral capsid amino acid alignments and homology modeling reveal the predicted three-dimensional arrangement of divergent and conserved residues of EV109 compared with other related enteroviruses. We also report highly similar EV109 isolates within multiple cases of acute pediatric respiratory illness in Managua, Nicaragua.     

Learning to Attend to Threat Accelerates and Enhances Memory Consolidation

Practice on a procedural task involves within-session learning and between-session consolidation of learning, with the latter requiring a minimum of about four hours to evolve due to involvement of slower cellular processes. Learning to attend to threats is vital for survival and thus may involve faster memory consolidation than simple procedural learning. Here, we tested whether attention to threat modulates the time-course and magnitude of learning and memory consolidation effects associated with skill practice. All participants (N = 90) practiced in two sessions on a dot-probe task featuring pairs of neutral and angry faces followed by target probes which were to be discriminated as rapidly as possible. In the attend-threat training condition, targets always appeared at the angry face location, forming an association between threat and target location; target location was unrelated to valence in a control training condition. Within each attention training condition, duration of the between-session rest interval was varied to establish the time-course for emergence of consolidation effects. During the first practice session, we observed robust improvement in task performance (online, within-session gains), followed by saturation of learning. Both training conditions exhibited similar overall learning capacities, but performance in the attend-threat condition was characterized by a faster learning rate relative to control. Consistent with the memory consolidation hypothesis, between-session performance gains (delayed gains) were observed only following a rest interval. However, rest intervals of 1 and 24 hours yielded similar delayed gains, suggesting accelerated consolidation processes. Moreover, attend-threat training resulted in greater delayed gains compared to the control condition. Auxiliary analyses revealed that enhanced performance was retained over several months, and that training to attend to neutral faces resulted in effects similar to control. These results provide a novel demonstration of how attention to threat can accelerate and enhance memory consolidation effects associated with skill acquisition.     

Cooperativity of lectin binding to lymphocytes,and its relevance to mitogenic stimulation

The relationship between the binding patterns of soybean agglutinin, peanut agglutinin (both in their native (unaggregated) form and in their polymerized form), and of Phaseolus vulgaris leucoagglutinin, to neuraminidase-treated lymphocytes from different sources, and the mitogenic activity of these lectins, was studied. In all cases investigated, binding of a lectin to lymphocytes which resulted in stimulation was a positive cooperative process. Our findings support the assumption that clustering of receptors and conformational changes in membrane structure are prerequisites for mitogenic stimulation.     

WIKI4, a Novel Inhibitor of Tankyrase and Wnt/?-Catenin Signaling

The Wnt/ß-catenin signaling pathway controls important cellular events during development and often contributes to disease when dysregulated. Using high throughput screening we have identified a new small molecule inhibitor of Wnt/ß-catenin signaling, WIKI4. WIKI4 inhibits expression of ß-catenin target genes and cellular responses to Wnt/ß-catenin signaling in cancer cell lines as well as in human embryonic stem cells. Furthermore, we demonstrate that WIKI4 mediates its effects on Wnt/ß-catenin signaling by inhibiting the enzymatic activity of TNKS2, a regulator of AXIN ubiquitylation and degradation. While TNKS has previously been shown to be the target of small molecule inhibitors of Wnt/ß-catenin signaling, WIKI4 is structurally distinct from previously identified TNKS inhibitors.