Conserved chromatin and repetitive patterns reveal slow genome evolution in frogs.

Frogs are an ecologically diverse and phylogenetically ancient group of anuran amphibians that include important vertebrate cell and developmental model systems, notably the genus Xenopus. Here we report a high-quality reference genome sequence for the western clawed frog, Xenopus tropicalis, along with draft chromosome-scale sequences of three distantly related emerging model frog species, Eleutherodactylus coqui, Engystomops pustulosus, and Hymenochirus boettgeri. Frog chromosomes have remained remarkably stable since the Mesozoic Era, with limited Robertsonian (i.e., arm-preserving) translocations and end-to-end fusions found among the smaller chromosomes. Conservation of synteny includes conservation of centromere locations, marked by centromeric tandem repeats associated with Cenp-a binding surrounded by pericentromeric LINE/L1 elements. This work explores the structure of chromosomes across frogs, using a dense meiotic linkage map for X. tropicalis and chromatin conformation capture (Hi-C) data for all species. Abundant satellite repeats occupy the unusually long (~20 megabase) terminal regions of each chromosome that coincide with high rates of recombination. Both embryonic and differentiated cells show reproducible associations of centromeric chromatin and of telomeres, reflecting a Rabl-like configuration. Our comparative analyses reveal 13 conserved ancestral anuran chromosomes from which contemporary frog genomes were constructed.

Obtaining Xenopus tropicalis Eggs.

Xenopus is a powerful model system for cell and developmental biology in part because frogs produce thousands of eggs and embryos year-round. For cell biological studies, egg extracts can mimic many processes in a cell-free system. For developmental biology, Xenopus embryos are a premier system, combining cut-and-paste embryology with modern gene manipulation tools. Xenopus tropicalis are particularly suited to genetic studies because of their diploid genome, as compared to the tetraploid genome of Xenopus laevis When collecting eggs, there are differences in timing of steps, amounts of hormone administered, and handling of females between these species. In this protocol, X. tropicalis females are induced with a hormone that stimulates ovulation, and then eggs are collected. To administer the ovulation hormone and express eggs, it is necessary to be comfortable with handling frogs. Proficient handling of X. tropicalis requires practice, as they are relatively small, active, and slippery.

Raising and Maintaining Xenopus tropicalis from Tadpole to Adult.

Xenopus tropicalis is a powerful model organism for cell and developmental biology research. Recently, precise gene-editing methods such as CRISPR-Cas9 have allowed facile creation of mutants. The ability to raise and maintain lines of wild-type and mutant animals through all life stages is thus critical for researchers using this model organism. The long fertile life (>8-10 yr) and relatively hardy nature of X. tropicalis makes this a straightforward process. Environmental parameters such as water temperature, pH, and conductivity often vary slightly among husbandry protocols. However, the stability of these variables is essential for rearing success. This protocol describes conditions to optimally raise and maintain X. tropicalis from embryos to adulthood.

Xenopus Tadpole Craniocardiac Imaging Using Optical Coherence Tomography.

Optical coherence tomography (OCT) imaging can be used to visualize craniocardiac structures in the Xenopus model system. OCT is analogous to ultrasound, utilizing light instead of sound to create a gray-scale image from the echo time delay of infrared light reflected from the specimen. OCT is a high-speed, cross-sectional, label-free imaging modality, which can outline dynamic in vivo morphology at resolutions approaching histological detail. OCT imaging can acquire 2D and 3D data in real time to assess cardiac and facial structures. Additionally, during cardiac imaging, Doppler imaging can be used to assess the blood flow pattern in relation to the intracardiac structures. Importantly, OCT can reproducibly and efficiently provide comprehensive, nondestructive in vivo cardiac and facial phenotyping. Tadpoles do not require preprocessing and thus can be further raised or analyzed after brief immobilization during imaging. The rapid development of the Xenopus model combined with a rapid OCT imaging protocol allows the identification of specific gene/teratogen phenotype relationships in a short period of time. Loss- or gain-of-function experiments can be evaluated in 4-5 d, and OCT imaging only requires ∼5 min per tadpole. Thus, we find this pairing an efficient workflow for screening numerous candidate genes derived from human genomic studies to in-depth mechanistic studies.

Obtaining Xenopus tropicalis Embryos by In Vitro Fertilization.

Xenopus is a powerful model system for cell and developmental biology in part because frogs produce thousands of eggs and embryos year-round. In vitro fertilization (IVF) is ideal for obtaining developmentally synchronized embryos for microinjection or when natural mating has failed to produce a fertilization. In IVF, females are induced to ovulate, and then eggs are collected by manual expression. After testes are collected from a euthanized male frog, the eggs are fertilized in vitro. The embryos are then treated with cysteine to remove the sticky protective jelly coat. Dejellied embryos are much easier to manipulate during microinjection or when sorting in a Petri dish. The jelly coat is also very difficult to penetrate with an injection needle. After microinjection, embryos are maintained in Petri dishes until desired stages are reached. Although in vitro fertilization in X. laevis and X. tropicalis is similar, critical differences in solutions, handling of testis, response of fertilized eggs directly after introduction of sperm, and developmental timing are required for successful fertilization in X. tropicalis.

Obtaining Xenopus tropicalis Embryos by Natural Mating.

Xenopus is a powerful model system for cell and developmental biology in part because frogs produce thousands of eggs and embryos year-round. Natural matings are a simple and common method to obtain embryos for injection or other experimental use or to raise to adulthood. This method does not require sacrificing a male as in vitro fertilization (IVF) does. Male and female frogs are injected with an ovulation hormone, placed together in a mating bucket, and left for 4-6 h or overnight to mate. Embryos are then collected, treated with cysteine to remove the sticky jelly coat, and used for injections and/or raised to later stages or adulthood. For embryos raised past free-swimming stages, the cysteine step can optionally be skipped, and tadpoles can be allowed to hatch naturally from the jelly coat. Although there are many similarities between natural mating protocols for Xenopus laevis and Xenopus tropicalis, there are key differences such as hormone dosage, timing of ovulation, and embryo incubation temperature. Here we provide a specific protocol for inducing natural matings in X. tropicalis.

Microinjection of Xenopus tropicalis Embryos.

Microinjection is an important technique used to study development in the oocyte and early embryo. In Xenopus, substances such as DNA, mRNA, and morpholino oligonucleotides have traditionally been injected into Xenopus laevis, because of their large embryo size and the relatively long time from their fertilization to first division. In the past few decades, Xenopus tropicalis has become an important model in developmental biology; it is particularly useful in genetic studies. The advent and rapid development of CRISPR-Cas9 technology has provided an array of targeted gene manipulations for which X. tropicalis is particularly suited. The equipment and protocol for X. tropicalis microinjection is broadly transferable from X. laevis There are important differences between the species to consider, however, including the smaller embryo size and faster embryo development time in X. tropicalis There are a number of solutions and reagents that differ in concentration and composition as well. Here we describe a microinjection protocol specifically for studies in X. tropicalis.

A chromosome-scale genome assembly and dense genetic map for Xenopus tropicalis.

The Western clawed frog Xenopus tropicalis is a diploid model system for both frog genetics and developmental biology, complementary to the paleotetraploid X. laevis. Here we report a chromosome-scale assembly of the X. tropicalis genome, improving the previously published draft genome assembly through the use of new assembly algorithms, additional sequence data, and the addition of a dense genetic map. The improved genome enables the mapping of specific traits (e.g., the sex locus or Mendelian mutants) and the characterization of chromosome-scale synteny with other tetrapods. We also report an improved annotation of the genome that integrates deep transcriptome sequence from diverse tissues and stages. The exon-intron structures of these genes are highly conserved relative to both X. laevis and human, as are chromosomal linkages ("synteny") and local gene order. A network analysis of developmental gene expression will aid future studies.

CRISPR/Cas9 F0 Screening of Congenital Heart Disease Genes in Xenopus tropicalis.

In the US and Europe, birth defects are the leading cause of infant mortality. Among birth defects, Congenital Heart Disease (CHD) occurs in approximately 8 out of 1000 live births, affects 1.3 million newborns per year worldwide, and has the highest mortality rate. While there is evidence to indicate that CHD does have a genetic basis, most of the CHD burden remains unexplained genetically. Fortunately, new genomics technologies are enabling genetic analyses of CHD patients. Whole exome sequencing of trios as well as copy number variations assayed by high-density SNP arrays can now be obtained at high efficiency and relatively low cost. These efforts are identifying a number of sequence variations in patients with CHD, but only a small percentage have second unrelated alleles to validate them as disease causing. Importantly, most of these candidate genes do not have an identified molecular mechanism implicating them in cardiac development. Therefore, there is a pressing need to develop rapid functional assays to evaluate candidate genes for a role in cardiac development, and then to investigate the underlying developmental mechanisms. Most recently, the advent of CRISPR/Cas9 genome editing technology has greatly enhanced the ability to manipulate and observe the function of the genome in model systems and cell culture. Incorporating the power of a developmental system such as Xenopus tropicalis with the CRISPR/Cas9 system and the microscale imaging modality optical coherence tomography (OCT), the analysis of thousands of different genes in cardiac development becomes possible.

CRISPR-Cpf1 mediates efficient homology-directed repair and temperature-controlled genome editing.

Cpf1 is a novel class of CRISPR-Cas DNA endonucleases, with a wide range of activity across different eukaryotic systems. Yet, the underlying determinants of this variability are poorly understood. Here, we demonstrate that LbCpf1, but not AsCpf1, ribonucleoprotein complexes allow efficient mutagenesis in zebrafish and Xenopus. We show that temperature modulates Cpf1 activity by controlling its ability to access genomic DNA. This effect is stronger on AsCpf1, explaining its lower efficiency in ectothermic organisms. We capitalize on this property to show that temporal control of the temperature allows post-translational modulation of Cpf1-mediated genome editing. Finally, we determine that LbCpf1 significantly increases homology-directed repair in zebrafish, improving current approaches for targeted DNA integration in the genome. Together, we provide a molecular understanding of Cpf1 activity in vivo and establish Cpf1 as an efficient and inducible genome engineering tool across ectothermic species.

Measuring Absolute RNA Copy Numbers at High Temporal Resolution Reveals Transcriptome Kinetics in Development.

Transcript regulation is essential for cell function, and misregulation can lead to disease. Despite technologies to survey the transcriptome, we lack a comprehensive understanding of transcript kinetics, which limits quantitative biology. This is an acute challenge in embryonic development, where rapid changes in gene expression dictate cell fate decisions. By ultra-high-frequency sampling of Xenopus embryos and absolute normalization of sequence reads, we present smooth gene expression trajectories in absolute transcript numbers. During a developmental period approximating the first 8 weeks of human gestation, transcript kinetics vary by eight orders of magnitude. Ordering genes by expression dynamics, we find that "temporal synexpression" predicts common gene function. Remarkably, a single parameter, the characteristic timescale, can classify transcript kinetics globally and distinguish genes regulating development from those involved in cellular metabolism. Overall, our analysis provides unprecedented insight into the reorganization of maternal and embryonic transcripts and redefines our ability to perform quantitative biology.

CRISPR/Cas9: An inexpensive, efficient loss of function tool to screen human disease genes in Xenopus.

Congenital malformations are the major cause of infant mortality in the US and Europe. Due to rapid advances in human genomics, we can now efficiently identify sequence variants that may cause disease in these patients. However, establishing disease causality remains a challenge. Additionally, in the case of congenital heart disease, many of the identified candidate genes are either novel to embryonic development or have no known function. Therefore, there is a pressing need to develop inexpensive and efficient technologies to screen these candidate genes for disease phenocopy in model systems and to perform functional studies to uncover their role in development. For this purpose, we sought to test F0 CRISPR based gene editing as a loss of function strategy for disease phenocopy in the frog model organism, Xenopus tropicalis. We demonstrate that the CRISPR/Cas9 system can efficiently modify both alleles in the F0 generation within a few hours post fertilization, recapitulating even early disease phenotypes that are highly similar to knockdowns from morpholino oligos (MOs) in nearly all cases tested. We find that injecting Cas9 protein is dramatically more efficacious and less toxic than cas9 mRNA. We conclude that CRISPR based F0 gene modification in X. tropicalis is efficient and cost effective and readily recapitulates disease and MO phenotypes.

Breeding based remobilization of Tol2 transposon in Xenopus tropicalis.

Xenopus is a powerful model for studying a diverse array of biological processes. However, despite multiple methods for transgenesis, relatively few transgenic reporter lines are available and commonly used. Previous work has demonstrated that transposon based strategies are effective for generating transgenic lines in both invertebrate and vertebrate systems. Here we show that the Tol2 transposon can be remobilized in the genome of X. tropicalis and passed through the germline via a simple breeding strategy of crossing transposase expressing and transposon lines. This remobilization system provides another tool to exploit transgenesis and opens new opportunities for gene trap and enhancer trap strategies.

A novel domain in translational GTPase BipA mediates interaction with the 70S ribosome and influences GTP hydrolysis.

BipA is a universally conserved prokaryotic GTPase that exhibits differential ribosome association in response to stress-related events. It is a member of the translation factor family of GTPases along with EF-G and LepA. BipA has five domains. The N-terminal region of the protein, consisting of GTPase and beta-barrel domains, is common to all translational GTPases. BipA domains III and V have structural counterparts in EF-G and LepA. However, the C-terminal domain (CTD) of the protein is unique to the BipA family. To investigate how the individual domains of BipA contribute to the biological properties of the protein, deletion constructs were designed and their GTP hydrolysis and ribosome binding properties assessed. Data presented show that removal of the CTD abolishes the ability of BipA to bind to the ribosome and that ribosome complex formation requires the surface provided by domains III and V and the CTD. Additional mutational analysis was used to outline the BipA-70S interaction surface extending across these domains. Steady state kinetic analyses revealed that successive truncation of domains from the C-terminus resulted in a significant increase in the intrinsic GTP hydrolysis rate and a loss of ribosome-stimulated GTPase activity. These results indicate that, similar to other translational GTPases, the ribosome binding and GTPase activities of BipA are tightly coupled. Such intermolecular regulation likely plays a role in the differential ribosome binding by the protein.

Identification of mutants in inbred Xenopus tropicalis.

Xenopus tropicalis offers the potential for genetic analysis in an amphibian. In order to take advantage of this potential, we have been inbreeding strains of frogs for future mutagenesis. While inbreeding a population of Nigerian frogs, we identified three mutations in the genetic background of this strain. These mutations are all recessive embryonic lethals. We show that multigenerational mutant analysis is feasible and demonstrate that mutations can be identified, propagated, and readily characterized using hybrid, dihybrid, and even trihybrid crosses. In addition, we are optimizing conditions to raise frogs rapidly and present our protocols for X. tropicalis husbandry. We find that males mature faster than females (currently 4 versus 6 months to sexual maturity). Here we document our progress in developing X. tropicalis as a genetic model organism and demonstrate the utility of the frog to study the genetics of early vertebrate development.

Development of interlimb movement synchrony in the rat fetus.

In the fetal rat, interlimb synchrony is a prominent form of temporally organized spontaneous motor activity in which movement of different limbs occurs at nearly the same instant. In the present study, synchrony profiles were created for different pairwise combinations of limbs over the last 5 days of gestation. Observed rates of synchrony differentiated from randomized time series from Gestational Day 19 to Day 21 (E19-E21), with forelimb synchrony emerging earlier than that of other limb pairs. Synchrony profiles were elevated at the shortest intervals between successive limb movements, indicating that movements became more tightly coupled toward the end of gestation. Interlimb synchrony appears to be a robust method of quantifying fetal movement and may prove useful as a tool for assessing prenatal nervous system functioning.