Advances in the Xenopus Immunome: Diversification, Expansion, and Contraction

Overview

Journal Dev Comp Immunol

Specialty Allergy & Immunology

Date 2023 May 12

PMID 37172665

Authors

Dionysia Dimitrakopoulou

Collins N Khwatenge

Christina James-Zorn

Matthieu Paiola

Eleanor Wise Bellin

Yun Tian

Nivitha Sundararaj

Emma J Polak

Leon Grayfer

Daron Barnard

Yuko Ohta

Marko Horb

Yongming Sang

Jacques Robert

Affiliations

Soon will be listed here.

Abstract

Xenopus is a genus of African clawed frogs including two species, X. tropicalis and X. laevis that are extensively used in experimental biology, immunology, and biomedical studies. The availability of fully sequenced and annotated Xenopus genomes is strengthening genome-wide analyses of gene families and transgenesis to model human diseases. However, inaccuracies in genome annotation for genes involved in the immune system (i.e., immunome) hamper immunogenetic studies. Furthermore, advanced genome technologies (e.g., single-cell and RNA-Seq) rely on well-annotated genomes. The annotation problems of Xenopus immunome include a lack of established orthology across taxa, merged gene models, poor representation in gene pages on Xenbase, misannotated genes and missing gene IDs. The Xenopus Research Resource for Immunobiology in collaboration with Xenbase and a group of investigators are working to resolve these issues in the latest versions of genome browsers. In this review, we summarize the current problems of previously misannotated gene families that we have recently resolved. We also highlight the expansion, contraction, and diversification of previously misannotated gene families.

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