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Abstract
At a fundamental level most genes, signaling pathways, biological functions and organ systems are highly conserved between man and all vertebrate species. Leveraging this conservation, researchers are increasingly using the experimental advantages of the amphibian Xenopus to model human disease. The online Xenopus resource, Xenbase, enables human disease modeling by curating the Xenopus literature published in PubMed and integrating these Xenopus data with orthologous human genes, anatomy, and more recently with links to the Online Mendelian Inheritance in Man resource (OMIM) and the Human Disease Ontology (DO). Here we review how Xenbase supports disease modeling and report on a meta-analysis of the published Xenopus research providing an overview of the different types of diseases being modeled in Xenopus and the variety of experimental approaches being used. Text mining of over 50,000 Xenopus research articles imported into Xenbase from PubMed identified approximately 1,000 putative disease- modeling articles. These articles were manually assessed and annotated with disease ontologies, which were then used to classify papers based on disease type. We found that Xenopus is being used to study a diverse array of disease with three main experimental approaches: cell-free egg extracts to study fundamental aspects of cellular and molecular biology, oocytes to study ion transport and channel physiology and embryo experiments focused on congenital diseases. We integrated these data into Xenbase Disease Pages to allow easy navigation to disease information on external databases. Results of this analysis will equip Xenopus researchers with a suite of experimental approaches available to model or dissect a pathological process. Ideally clinicians and basic researchers will use this information to foster collaborations necessary to interrogate the development and treatment of human diseases.
FIGURE 1. Xenbase Gene Page for zic3. Gene-disease annotations are located below Interactants on the Summary tab of the Xenbase Gene Page. Disease Ontology (DO) annotations (red arrowhead) are made via DO-OMIM cross reference or manual curation. OMIM annotations (blue arrowhead) are imported from the National Center for Biotechnology Information (NCBI). DO and OMIM terms link to Xenbase Disease Pages.
FIGURE 2. Xenbase Disease Page for “DOID:0050545: visceral heterotaxy.” An example of a new Disease Page with disease-specific supporting information including associated human and model organism resource links. The representative disease and its descendants are displayed in a Disease Hierarchy with the number of associated Xenbase articles in parentheses. The Literature tab provides a list of all associated Xenbase articles.
FIGURE 3. DO and OMIM references on a Xenbase Article Page. Disease terms link directly to the collated data on a Disease Page for DO (red arrowhead) annotations and OMIM (blue arrowhead) annotations. Multiple disease annotations can be seen by clicking the [+/–] toggle to show more or fewer results. Article Pages also list GO terms as keywords to cover the major topics of an article.
FIGURE 4. Subnetworks from the DO. This figure shows MCL clustered subnetworks from a subset of the DO, consisting of terms annotated during our curation of the Xenbase human disease corpus detailed in the Supplementary Material. Nodes in the network are colored according to the number of direct annotations to the term they represent. Empty nodes have no direct annotations, blue nodes 1–5, yellow nodes 6–14 and purple nodes 15 and higher. Purple nodes and the yellow node(s) with the highest number of annotations for each cluster have been labeled. Cluster regions corresponding to high level DO terms have been highlighted for contrast and labeled. Some small subnetworks and singleton nodes have been moved to proximity with the high level DO term to which they are associated.
FIGURE 5. Human disease-specific Xenopus articles (1990–2017). This chart shows the number of articles published, by year, between 1990 and 2017 that our curation identified as utilizing Xenopus as a model system for studying human disease. Publication dates were obtained from NCBI’s PubMed database.
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1990,
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CRISPR/Cas9: An inexpensive, efficient loss of function tool to screen human disease genes in Xenopus.
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Xenopus metamorphosis as a model to study thyroid hormone receptor function during vertebrate developmental transitions.
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2004,
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Cross,
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2009,
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Dawson,
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1989,
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2016,
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Dominguez-Sola,
Non-transcriptional control of DNA replication by c-Myc.
2007,
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Dubey,
Modeling human craniofacial disorders in Xenopus.
2017,
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Duncan,
Xenopus as a model organism for birth defects-Congenital heart disease and heterotaxy.
2016,
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Dzierzak,
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Fainsod,
Xenopus embryos to study fetal alcohol syndrome, a model for environmental teratogenesis.
2018,
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Feehan,
Modeling Dominant and Recessive Forms of Retinitis Pigmentosa by Editing Three Rhodopsin-Encoding Genes in Xenopus Laevis Using Crispr/Cas9.
2017,
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Felix,
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2000,
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Fort,
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1989,
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Garfinkel,
An interspecies heart-to-heart: Using Xenopus to uncover the genetic basis of congenital heart disease.
2017,
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Hardwick,
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2015,
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Haynes-Gilmore,
A critical role of non-classical MHC in tumor immune evasion in the amphibian Xenopus model.
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Hellsten,
The genome of the Western clawed frog Xenopus tropicalis.
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Hertel,
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Hoogenboom,
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Howe,
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Joukov,
The BRCA1/BARD1 heterodimer modulates ran-dependent mitotic spindle assembly.
2006,
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Karimi,
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Khokha,
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2012,
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Kofent,
Xenopus as a model system for studying pancreatic development and diabetes.
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The Human Phenotype Ontology in 2017.
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Lambert,
Vestibular asymmetry as the cause of idiopathic scoliosis: a possible answer from Xenopus.
2009,
Pubmed
Lambert,
Restricted neural plasticity in vestibulospinal pathways after unilateral labyrinthectomy as the origin for scoliotic deformations.
2013,
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Landais,
Monoketone analogs of curcumin, a new class of Fanconi anemia pathway inhibitors.
2009,
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Lehmann-Horn,
Voltage-gated ion channels and hereditary disease.
1999,
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Lienkamp,
Using Xenopus to study genetic kidney diseases.
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Limon,
Microtransplantation of neurotransmitter receptors from postmortem autistic brains to Xenopus oocytes.
2008,
Pubmed
Ludwig,
Functional evaluation of Dent's disease-causing mutations: implications for ClC-5 channel trafficking and internalization.
2005,
Pubmed
Mandel,
The BMP pathway acts to directly regulate Tbx20 in the developing heart.
2010,
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Miledi,
Microtransplantation of functional receptors and channels from the Alzheimer's brain to frog oocytes.
2004,
Pubmed
Moody,
Fates of the blastomeres of the 32-cell-stage Xenopus embryo.
1987,
Pubmed
Moody,
Fates of the blastomeres of the 16-cell stage Xenopus embryo.
1987,
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Morgan,
Teratogenic potential of atrazine and 2,4-D using FETAX.
1996,
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Pa2G4 is a novel Six1 co-factor that is required for neural crest and otic development.
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Pubmed
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The Xenopus oocyte: a model for studying the metabolic regulation of cancer cell death.
2012,
Pubmed
Pratt,
Modeling human neurodevelopmental disorders in the Xenopus tadpole: from mechanisms to therapeutic targets.
2013,
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Proks,
A heterozygous activating mutation in the sulphonylurea receptor SUR1 (ABCC8) causes neonatal diabetes.
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Initiation of DNA replication requires the RECQL4 protein mutated in Rothmund-Thomson syndrome.
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Fanconi anemia proteins FANCD2 and FANCI exhibit different DNA damage responses during S-phase.
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Pubmed
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Using Xenopus to understand human disease and developmental disorders.
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Recessive mutations in PCBD1 cause a new type of early-onset diabetes.
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Targeted gene disruption in Xenopus laevis using CRISPR/Cas9.
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Study of the DNA damage checkpoint using Xenopus egg extracts.
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Yaoita,
Xenopus laevis alpha and beta thyroid hormone receptors.
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Ethanol exposure affects gene expression in the embryonic organizer and reduces retinoic acid levels.
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