The linear ubiquitin-specific deubiquitinase gumby regulates angiogenesis.

A complex interaction of signalling events, including the Wnt pathway, regulates sprouting of blood vessels from pre-existing vasculature during angiogenesis. Here we show that two distinct mutations in the (uro)chordate-specific gumby (also called Fam105b) gene cause an embryonic angiogenic phenotype in gumby mice. Gumby interacts with disheveled 2 (DVL2), is expressed in canonical Wnt-responsive endothelial cells and encodes an ovarian tumour domain class of deubiquitinase that specifically cleaves linear ubiquitin linkages. A crystal structure of gumby in complex with linear diubiquitin reveals how the identified mutations adversely affect substrate binding and catalytic function in line with the severity of their angiogenic phenotypes. Gumby interacts with HOIP (also called RNF31), a key component of the linear ubiquitin assembly complex, and decreases linear ubiquitination and activation of NF-κB-dependent transcription. This work provides support for the biological importance of linear (de)ubiquitination in angiogenesis, craniofacial and neural development and in modulating Wnt signalling.

A tryptophan hydroxlyase 1 reporter that directs Cre recombinase extinguishable placental alkaline phosphatase expression in serotonergic (5-HT) neurons and peripheral tissues.

The serotonergic (5-HT) system modulates many behaviors and has been implicated in psychiatric disorders, but the density of 5-HT processes has complicated analyses. We have used regulatory regions from the Tryptophan hydroxylase 1 (Tph1) gene to drive expression of LoxP-flanked placental alkaline phosphatase (PLAP) to generate the Tph1-Lox-PLAP reporter mouse line. In these mice, PLAP is expressed in the hindbrain raphe nuclei and in peripheral tissues known to express Tph1. Tph1 is expressed at low levels in neurons. While, in Tph1-Lox-PLAP mice, most PLAP-expressing neurons are monoaminergic, PLAP was expressed in only 5-10% of neurons expressing the predominant neuronal 5-HT biosynthetic enzyme Tph2, serotonin transporter (SERT) or aromatic amino acid decarboxylase (AADC). To test this reporter further, we examined the brains of mice carrying the anorexia (anx) mutation, in which increased overall density of 5-HT immunoreactivity had been previously observed at P21. PLAP-labeling of processes in anx/anx and anx/+ mice was reduced at P0. By P10, distribution of PLAP-labeled processes in anx/+ and +/+ cortices was indistinguishable, but differed markedly from that seen in the cortical layers of anx/anx mice. Thus, the Tph1-LoxP-PLAP reporter revealed a dosage sensitive role of the anx mutation in the early 5-HT system and later cortical layer-specific differences in 5-HT process distribution in anx/anx mice. Thus, the Tph1-LoxP-PLAP reporter provides a sensitive indicator for analyses of serotonergic cells in the brain and periphery.

Generation of a transgenic mouse line expressing GFP-Cre protein from a Hoxb4 neural enhancer.

Here, we describe a transgenic mouse line, in which expression of green fluorescent protein fused to Cre recombinase (GFP-Cre) is directed by the early neuronal enhancer (ENE) of Hoxb4. In E9.0-13.5 transgenic embryos, Cre activity coincided with endogenous Hoxb4 throughout the neural tube up to the r6/r7 boundary in the hindbrain, the dorsal root ganglia, and the Xth cranial ganglia. Unexpectedly, Cre activity was also consistently detected in the trigeminal (Vth) cranial nerve, which is devoid of endogenous Hoxb4 expression. Strong GFP dependent fluorescence appeared slightly later in E9.5-E11.5 embryos, and reflected the later expression pattern expected for Hoxb4-ENE directed expression in the neural tube up to the r7/r8 not r6/r7 boundary. Thus, with the exception of the trigeminal nerve, this reporter faithfully reproduces endogenous embryonic neural Hoxb4 expression, and provides an excellent reagent for in vivo gene manipulations in neuronal Hoxb4 positive cells as well as the developing trigeminal nerve. This transgenic mouse line should prove especially useful for determining the fate map of neuronal populations arising in rhombomeres 7 and 8 on its own and in combination with the small set of other existing rhombomere-specific Cre recombinase expressing lines.

A genetic screen for mutations that affect cranial nerve development in the mouse.

Cranial motor and sensory nerves arise stereotypically in the embryonic hindbrain, act as sensitive indicators of general and region-specific neuronal development, and are directly or indirectly affected in many human disorders, particularly craniofacial syndromes. The molecular genetic hierarchies that regulate cranial nerve development are mostly unknown. Here, we describe the first mouse genetic screen that has used direct immunohistochemical visualization methods to systematically identify genetic loci required for cranial nerve development. After screening 40 pedigrees, we recovered seven new neurodevelopmental mutations. Two mutations model human genetic syndromes. Mutation 7-1 causes facial nerve anomalies and a reduced lower jaw, and is located in a region of conserved synteny with an interval associated with the micrognathia and mental retardation of human cri-du-chat syndrome. Mutation 22-1 is in the Pax3 gene and, thus, models human Waardenburg syndrome. Three mutations cause global axon guidance deficits: one interferes with initial motor axon extension from the neural tube, another causes overall axon defasciculation, and the third affects general choice point selection. Another two mutations affect the oculomotor nerve specifically. Oculomotor nerve development, which is disrupted by six mutations, appears particularly sensitive to genetic perturbations. Phenotypic comparisons of these mutants identifies a "transition zone" that oculomotor axons enter after initial outgrowth and in which new factors govern additional progress. The number of interesting neurodevelopmental mutants revealed by this small-scale screen underscores the promise of similar focused genetic screens to contribute significantly to our understanding of cranial nerve development and human craniofacial syndromes.

International Cancer Genome Consortium Data Portal--a one-stop shop for cancer genomics data.

The International Cancer Genome Consortium (ICGC) is a collaborative effort to characterize genomic abnormalities in 50 different cancer types. To make this data available, the ICGC has created the ICGC Data Portal. Powered by the BioMart software, the Data Portal allows each ICGC member institution to manage and maintain its own databases locally, while seamlessly presenting all the data in a single access point for users. The Data Portal currently contains data from 24 cancer projects, including ICGC, The Cancer Genome Atlas (TCGA), Johns Hopkins University, and the Tumor Sequencing Project. It consists of 3478 genomes and 13 cancer types and subtypes. Available open access data types include simple somatic mutations, copy number alterations, structural rearrangements, gene expression, microRNAs, DNA methylation and exon junctions. Additionally, simple germline variations are available as controlled access data. The Data Portal uses a web-based graphical user interface (GUI) to offer researchers multiple ways to quickly and easily search and analyze the available data. The web interface can assist in constructing complicated queries across multiple data sets. Several application programming interfaces are also available for programmatic access. Here we describe the organization, functionality, and capabilities of the ICGC Data Portal.

BioMart Central Portal: an open database network for the biological community.

BioMart Central Portal is a first of its kind, community-driven effort to provide unified access to dozens of biological databases spanning genomics, proteomics, model organisms, cancer data, ontology information and more. Anybody can contribute an independently maintained resource to the Central Portal, allowing it to be exposed to and shared with the research community, and linking it with the other resources in the portal. Users can take advantage of the common interface to quickly utilize different sources without learning a new system for each. The system also simplifies cross-database searches that might otherwise require several complicated steps. Several integrated tools streamline common tasks, such as converting between ID formats and retrieving sequences. The combination of a wide variety of databases, an easy-to-use interface, robust programmatic access and the array of tools make Central Portal a one-stop shop for biological data querying. Here, we describe the structure of Central Portal and show example queries to demonstrate its capabilities.