Albert Chesneau

Transgenesis procedures in Xenopus.

Stable integration of foreign DNA into the frog genome has been the purpose of several studies aimed at generating transgenic animals or producing mutations of endogenous genes. Inserting DNA into a host genome can be achieved in a number of ways. In Xenopus, different strategies have been developed which exhibit specific molecular and technical features. Although several of these technologies were also applied in various model organizms, the attributes of each method have rarely been experimentally compared. Investigators are thus confronted with a difficult choice to discriminate which method would be best suited for their applications. To gain better understanding, a transgenesis workshop was organized by the X‐omics consortium. Three procedures were assessed side‐by‐side, and the results obtained are used to illustrate this review. In addition, a number of reagents and tools have been set up for the purpose of gene expression and functional gene analyses. This not only improves the status of Xenopus as a powerful model for developmental studies, but also renders it suitable for sophisticated genetic approaches. Twenty years after the first reported transgenic Xenopus, we review the state of the art of transgenic research, focusing on the new perspectives in performing genetic studies in this species.

Regulation of XSnail2 Expression by Rho GTPases

We analyzed the effects of Rho GTPases on XSnail2 expression during neural crest (NC) ontogeny in Xenopus laevis embryos. The ectopic expression of both dominant‐negative (N−) and constitutively active (V−) Rho GTPase mutants after RNA or DNA microinjection disrupted the endogenous expression of XSnail2, XFoxD3, and XSnail1. V14RhoA and N17Rac1 were inhibitory, whereas N19RhoA and V12Rac1 increased NC marker gene expression. In reporter assays using a XSnail2 promoter–green fluorescent protein (GFP) construct (α700BA‐GFP), the ectopic expression of V14RhoA, N17Rac1, or the Rac1 inhibitor NSC 23766 decreased reporter expression in NC‐neural plate, whereas N19RhoA or the RhoA inhibitor Y27632 and V12Rac1 enhanced it. Similarly, transgenic embryos expressing Rho GTPase mutants and GFP under control of the α700BA promoter displayed variations similar to those observed for ectopic RNA and DNA expression. These results show that Rho GTPases can regulate the expression of XSnail2 during NC ontogeny. Developmental Dynamics 236:2555–2566, 2007.

Reduced levels of survival motor neuron protein leads to aberrant motoneuron growth in a Xenopus model of muscular atrophy.

Spinal muscular atrophy (SMA) is a neurodegenerative disease characterized by motor neuron loss and skeletal muscle atrophy. The loss of function of the smn1 gene, the main supplier of survival motor neuron protein (SMN) protein in human, leads to reduced levels of SMN and eventually to SMA. Here, we ask if the amphibian Xenopus tropicalis can be a good model system to study SMA. Inhibition of the production of SMN using antisense morpholinos leads to caudal muscular atrophy in tadpoles. Of note, early developmental patterning of muscles and motor neurons is unaffected in this system as well as acetylcholine receptors clustering. Muscular atrophy seems to rather result from aberrant pathfinding and growth arrest and/or shortening of motor axons. This event occurs in the absence of neuronal cell bodies apoptosis, a process comparable to that of amyotrophic lateral sclerosis. Xenopus tropicalis is revealed as a complementary animal model for the study of SMA.

Live imaging of targeted cell ablation in Xenopus: a new model to study demyelination and repair

Live imaging studies of the processes of demyelination and remyelination have so far been technically limited in mammals. We have thus generated a Xenopus laevis transgenic line allowing live imaging and conditional ablation of myelinating oligodendrocytes throughout the CNS. In these transgenic pMBP-eGFP-NTR tadpoles the myelin basic protein (MBP) regulatory sequences, specific to mature oligodendrocytes, are used to drive expression of an eGFP (enhanced green fluorescent protein) reporter fused to the Escherichia coli nitroreductase (NTR) selection enzyme. This enzyme converts the innocuous prodrug metronidazole (MTZ) to a cytotoxin. Using two-photon imaging in vivo, we show that pMBP-eGFP-NTR tadpoles display a graded oligodendrocyte ablation in response to MTZ, which depends on the exposure time to MTZ. MTZ-induced cell death was restricted to oligodendrocytes, without detectable axonal damage. After cessation of MTZ treatment, remyelination proceeded spontaneously, but was strongly accelerated by retinoic acid. Altogether, these features establish the Xenopus pMBP-eGFP-NTR line as a novel in vivo model for the study of demyelination/remyelination processes and for large-scale screens of therapeutic agents promoting myelin repair.

The mariner transposons belonging to the irritans subfamily were maintained in chordate genomes by vertical transmission.

Mariner-like elements (MLEs) belong to the Tc1-mariner superfamily of DNA transposons, which is very widespread in animal genomes. We report here the first complete description of a MLE, Xtmar1, within the genome of a poikilotherm vertebrate, the amphibian Xenopus tropicalis. A close relative, XlMLE, is also characterized within the genome of a sibling species, Xenopus laevis. The phylogenetic analysis of the relationships between MLE transposases reveals that Xtmar1 is closely related to Hsmar2 and Bytmar1 and that together they form a second distinct lineage of the irritans subfamily. All members of this lineage are also characterized by the 36- to 43-bp size of their imperfectly conserved inverted terminal repeats and by the –8-bp motif located at their outer extremity. Since XlMLE, Xlmar1, and Hsmar2 are present in species located at both extremities of the vertebrate evolutionary tree, we looked for MLE relatives belonging to the same subfamily in the available sequencing projects using the amino acid consensus sequence of the Hsmar2 transposase as an in silico probe. We found that irritansMLEs are present in chordate genomes including most craniates. This therefore suggests that these elements have been present within chordate genomes for 750 Myr and that the main way they have been maintained in these species has been via vertical transmission. The very small number of stochastic losses observed in the data available suggests that their inactivation during evolution has been very slow.

Transcription Enhancer Factor-1-dependent Expression of the α-Tropomyosin Gene in the Three Muscle Cell Types

In vertebrates, the actin-binding proteins tropomyosins are encoded by four distinct genes that are expressed in a complex pattern during development and muscle differentiation. In this study, we have characterized the transcriptional machinery of the α-tropomyosin (α-Tm) gene in muscle cells. Promoter analysis revealed that a 284-bp proximal promoter region of the Xenopus laevis α-Tm gene is sufficient for maximal activity in the three muscle cell types. The transcriptional activity of this promoter in the three muscle cell types depends on both distinct and common cis-regulatory sequences. We have identified a 30-bp conserved sequence unique to all vertebrate α-Tm genes that contains an MCAT site that is critical for expression of the gene in all muscle cell types. This site can bind transcription enhancer factor-1 (TEF-1) present in muscle cells both in vitro and in vivo. In serum-deprived differentiated smooth muscle cells, TEF-1 was redistributed to the nucleus, and this correlated with increased activity of the α-Tm promoter. Overexpression of TEF-1 mRNA in Xenopus embryonic cells led to activation of both the endogenous α-Tm gene and the exogenous 284-bp promoter. Finally, we show that, in transgenic embryos and juveniles, an intact MCAT sequence is required for correct temporal and spatial expression of the 284-bp gene promoter. This study represents the first analysis of the transcriptional regulation of the α-Tm gene in vivo and highlights a common TEF-1-dependent regulatory mechanism necessary for expression of the gene in the three muscle lineages.

Database of queryable gene expression patterns for Xenopus.

The precise localization of gene expression within the developing embryo, and how it changes over time, is one of the most important sources of information for elucidating gene function. As a searchable resource, this information has up until now been largely inaccessible to the Xenopus community. Here, we present a new database of Xenopus gene expression patterns, queryable by specific location or region in the embryo. Pattern matching can be driven either from an existing in situ image, or from a user‐defined pattern based on development stage schematic diagrams. The data are derived from the work of a group of 21 Xenopus researchers over a period of 4 days. We used a novel, rapid manual annotation tool, XenMARK, which exploits the ability of the human brain to make the necessary distortions in transferring data from the in situ images to the standard schematic geometry. Developmental Dynamics 238:1379–1388, 2009.

A large scale screen for neural stem cell markers in Xenopus retina

Neural stem cell research suffers from a lack of molecular markers to specifically assess stem or progenitor cell properties. The organization of the Xenopus ciliary marginal zone (CMZ) in the retina allows the spatial distinction of these two cell types: stem cells are confined to the most peripheral region, while progenitors are more central. Despite this clear advantage, very few genes specifically expressed in retinal stem cells have been discovered so far in this model. To gain insight into the molecular signature of these cells, we performed a large‐scale expression screen in the Xenopus CMZ, establishing it as a model system for stem cell gene profiling. Eighteen genes expressed specifically in the CMZ stem cell compartment were retrieved and are discussed here. These encode various types of proteins, including factors associated with proliferation, mitotic spindle organization, DNA/RNA processing, and cell adhesion. In addition, the publication of this work in a special issue on Xenopus prompted us to give a more general illustration of the value of large‐scale screens in this model species. Thus, beyond neural stem cell specific genes, we give a broader highlight of our screen outcome, describing in particular other retinal cell markers that we found. Finally, we present how these can all be easily retrieved through a novel module we developed in the web‐based annotation tool XenMARK, and illustrate the potential of this powerful searchable database in the context of the retina.

Developmental Cell Death During Xenopus Metamorphosis Involves BID Cleavage and Caspase 2 and 8 Activation

Elimination of tadpole organs during Xenopus metamorphosis is largely achieved through apoptosis, and recent evidence suggest involvement of the mitochondrial death route and bax‐initiated caspase‐3 and ‐9 deployment. However, events upstream of the activation of Bax are unknown. In other models, proteins of the BH3‐only group such as BID are known to assure this function. We show that Xenopus bid transcript levels increase at metamorphosis in larval cells destined to disappear. This increase correlates with an abrupt rise in Caspase‐2 and ‐8 mRNA levels and an enhanced activity of Caspase‐2 and ‐8. In BIDGFP transgenic animals tail regression is accelerated. The cleavage of BIDGFP fusion protein during natural or T3‐induced metamorphosis was specifically inhibited by caspase‐8 inhibitors. Our results show that tail regression at metamorphosis implicates an apoptotic pathway inducible by T3 hormone in an organ autonomous manner and involving the cell death executioners BID and Caspases‐2 and ‐8. Developmental Dynamics 235:2083–2094, 2006.

Stem Cells and Regeneration in the Xenopus Retina

The ability to regenerate damaged cells in the retina varies tremendously among species, being restricted for most of them to specific developmental stages. Regarding vertebrates, only the newt was thought to exhibit full regenerative capacity upon retinectomy in the adulthood. The recent discovery that the anuran amphibian Xenopus can regenerate its retina after metamorphosis opened new avenues to investigate the cellular and molecular mechanisms involved in this process. In this review, we provide an historical overview of regeneration studies in Xenopus. Particular emphasis is given to the cellular sources contributing to retinal replacement, the involvement of tissue interactions and the importance of the injury paradigm. We also describe recent progress and promises in the field brought by the development of 3D tissue culture methods and transgenic Xenopus models.