Pitx homeobox genes in Ciona and amphioxus show left-right asymmetry is a conserved chordate character and define the ascidian adenohypophysis

All vertebrates have directional asymmetries in the organization of their internal organs. In jawed vertebrates, development of asymmetry is controlled by a conserved molecular pathway that includes Pitx2, which is expressed by lateral plate mesoderm cells on the left side of the embryo. Pitx2 is a member of the Pitx homeobox gene family, the expression of which also marks stomodeal ectoderm and the adenohypophysis. Here we report the characterization of Pitx genes from Branchiostoma floridae (an amphioxus) and Ciona intestinalis (a urochordate), representatives of two basal chordate lineages and successively deeper outgroups to the vertebrates. Expression of B. floridae Pitx is similar to that reported from B. belcheri, a different amphioxus species. Expression of the Ciona Pitx ortholog in the embryonic primordial pharynx and adult neural complex leads us to propose the Ciona primordial pharynx and ciliated funnel are homologous to the adenohypophyseal placode and adenohypophysis, respectively. Additionally, in both species we identify asymmetrical left-sided expression of Pitx genes during embryonic development. This shows that asymmetrical Pitx gene expression, and by inference directional asymmetry, evolved before the radiation of living chordates and should be considered a chordate character.     

Pitx2c patterns anterior myocardium and aortic arch vessels and is required for local cell movement into atrioventricular cushions

Inactivation of the left-right asymmetry gene Pitx2 has been shown, in mice, to result in right isomerism with associated defects that are similar to that found in humans. We show that the Pitx2c isoform is expressed asymmetrically in a presumptive secondary heart field within the branchial arch and splanchnic mesoderm that contributes to the aortic sac and conotruncal myocardium. Pitx2c was expressed in left aortic sac mesothelium and in left splanchnic and branchial arch mesoderm near the junction of the aortic sac and branchial arch arteries. Mice with an isoform-specific deletion of Pitx2c had defects in asymmetric remodeling of the aortic arch vessels. Fatemapping studies using a Pitx2 cre recombinase knock-in allele showed that daughters of Pitx2-expressing cells populated the right and left ventricles, atrioventricular cushions and valves and pulmonary veins. In Pitx2 mutant embryos, descendents of Pitx2-expressing cells failed to contribute to the atrioventricular cushions and valves and the pulmonary vein, resulting in abnormal morphogenesis of these structures. Our data provide functional evidence that the presumptive secondary heart field, derived from branchial arch and splanchnic mesoderm, patterns the forming outflow tract and reveal a role for Pitx2c in aortic arch remodeling. Moreover, our findings suggest that a major function of the Pitx2-mediated left right asymmetry pathway is to pattern the aortic arches, outflow tract and atrioventricular valves and cushions.     

Xenopus neurula left-right asymmetry is respeficied by microinjecting TGF-beta5 protein

A variety of TGF-beta-related ligands regulate the left-right asymmetry of vertebrates but the involvement of TGF-betas in left-right specification has not been reported. We assessed whether TGF-beta signaling is involved in the left-right specification of Xenopus post-gastrula embryos by microinjecting Xenopus TGF-beta5 protein into the left or right flank of neurula-tailbud embryos. Injection on the right side of neurulae caused left-right reversal of the internal organs in 93% of the embryos, while injection on the left side caused less than 5% left-right reversal. Expression of Xenopus nodal related-1 (Xnr-1 ), Xenopus antivin and Xenopus Pitx2, which are normally expressed on the left, was unaltered by the left-side injection. In contrast, right-side injection into neurulae induced the expression of these genes predominantly on the right side. Right-side injection into tailbud embryos caused bilateral expression of these handed genes. Time course analysis of asymmetric gene expression revealed that Xnr-1 could be induced by TGF-beta5 at late neurula stage, while antivin and Pitx2 could be induced by TGF-beta5 at the latertail bud stage. Injection of the antisense morpholino oligonucleotide against Xenopus TGF-beta5 into the left dorsal blastomere inhibited the normal left-handed expression of Xnr-1 and Pitx2, and caused the organ reversal in the injected embryos. These results suggest that normal left-right balance of endogenous TGF-beta5 signaling in the neurula embryo may be needed to determine the laterality of the asymmetric genes and to generate the correct left-right axis.     

Enhancer evolution in chordates: Lessons from functional analyses of cephalochordate cis-regulatory modules

Chordates comprise three major groups, cephalochordates (amphioxus), tunicates (urochordates), and vertebrates. Since cephalochordates were the early branching group, comparisons between amphioxus and other chordates help us to speculate about ancestral chordates. Here, I summarize accumulating data from functional studies analyzing amphioxus cis-regulatory modules (CRMs) in model systems of other chordate groups, such as mice, chickens, clawed frogs, fish, and ascidians. Conservatism and variability of CRM functions illustrate how gene regulatory networks have evolved in chordates. Amphioxus CRMs, which correspond to CRMs deeply conserved among animal phyla, govern reporter gene expression in conserved expression domains of the putative target gene in host animals. In addition, some CRMs located in similar genomic regions (intron, upstream, or downstream) also possess conserved activity, even though their sequences are divergent. These conservative CRM functions imply ancestral genomic structures and gene regulatory networks in chordates. However, interestingly, if expression patterns of amphioxus genes do not correspond to those of orthologs of experimental models, some amphioxus CRMs recapitulate expression patterns of amphioxus genes, but not those of endogenous genes, suggesting that these amphioxus CRMs are close to the ancestral states of chordate CRMs, while vertebrates/tunicates innovated new CRMs to reconstruct gene regulatory networks subsequent to the divergence of the cephalochordates. Alternatively, amphioxus CRMs may have secondarily lost ancestral CRM activity and evolved independently. These data help to solve fundamental questions of chordate evolution, such as neural crest cells, placodes, a forebrain/midbrain, and genome duplication. Experimental validation is crucial to verify CRM functions and evolution.     

Left and right contributions to the<Emphasis Type="Italic"> Xenopus</Emphasis> heart: implications for asymmetric morphogenesis

The left-right asymmetry of the vertebrate heart is evident in the topology of the heart loop, and in the dissimilar morphology of the left and right chambers. How left-right asymmetric gene expression patterns influence the development of these features is not understood, since the individual roles of the left and right sides of the embryo in heart looping or chamber morphogenesis have not been specifically defined. To this end, we have constructed a bilateral heart-specific fate map of the left and right contributions to the developing heart in the Xenopus embryo. Both the left and right sides contribute to the conoventricular segment of the heart loop; however, the left side contributes to the inner curvature and ventral face of the loop while the right side contributes to the outer curvature and dorsal aspect. In contrast, the left atrium is derived mainly from the original left side of the embryo, while the right atrium is derived primarily from the right side. A comparison of our fate map with the domain of expression of the left-right gene, Pitx2, in the left lateral plate mesoderm, reveals that this Pitx2-expressing region is fated to form the inner curvature of the heart loop, the left atrioventricular canal, and the dorsal aspect of the left atrium. We discuss the implications of these results for the role of left-right asymmetric gene expression in heart looping and chamber morphogenesis.     

Pitx2 regulates cardiac left-right asymmetry by patterning second cardiac lineage-derived myocardium

Current models of left-right asymmetry hold that an early asymmetric signal is generated at the node and transduced to lateral plate mesoderm in a linear signal transduction cascade through the function of the Nodal signaling molecule. The Pitx2 homeobox gene functions at the final stages of this cascade to direct asymmetric morphogenesis of selected organs including the heart. We previously showed that Pitx2 regulated an asymmetric pathway that was independent of cardiac looping suggesting a second asymmetric cardiac pathway. It has been proposed that in the cardiac outflow tract Pitx2 functions in both cardiac neural crest, as a target of canonical Wnt-signaling, and in the mesoderm-derived cardiac second lineage. We used fate mapping, conditional loss of function, and chimera analysis in mice to investigate the role of Pitx2 in outflow tract morphogenesis. Our findings reveal that Pitx2 is dispensable in the cardiac neural crest but functions in second lineage myocardium revealing that this cardiac progenitor field is patterned asymmetrically.     

Regulation of left-right asymmetry by thresholds of Pitx2c activity

Although much progress has been made in understanding the molecular mechanisms regulating left-right asymmetry, the final events of asymmetric organ morphogenesis remain poorly understood. The phenotypes of human heterotaxia syndromes, in which organ morphogenesis is uncoupled, have suggested that the early and late events of left-right asymmetry are separable. The Pitx2 homeobox gene plays an important role in the final stages of asymmetry. We have used two new Pitx2 alleles that encode progressively higher levels of Pitx2c in the absence of Pitx2a and Pitx2b, to show that different organs have distinct requirements for Pitx2c dosage. The cardiac atria required low Pitx2c levels, while the duodenum and lungs used higher Pitx2c doses for normal development. As Pitx2c levels were elevated, the duodenum progressed from arrested rotation to randomization, reversal and finally normal morphogenesis. In addition, abnormal duodenal morphogenesis was correlated with bilateral expression of Pitx2c. These data reveal an organ-intrinsic mechanism, dependent upon dosage of Pitx2c, that governs asymmetric organ morphogenesis. They also provide insight into the molecular events that lead to the discordant organ morphogenesis of heterotaxia.     

Cloning and expression of a Pitx homeobox gene from the lamprey,a jawless vertebrate

The Pitx homeobox gene family has important roles in vertebrate pituitary, eye, branchial arch, hindlimb and brain development, as well as a key function in regulating left-right asymmetry. Here we report the isolation of a Pitx gene, PitxA, from two lamprey species, Lampetra planeri and Petromyzon marinus. Molecular phylogenetics show PitxA is most closely related to the Pitx1 and Pitx2 genes of jawed vertebrates, however resolution in the trees is insufficient to determine if PitxA is orthologous to a specific jawed vertebrate gene. In situ hybridisation studies show lamprey PitxA is expressed in the developing nasohypohyseal system and stomodeal ectoderm from early development through to early ammocoette larvae. PitxA expression was also detected in several areas of the developing brain, in the developing optic system, in pharyngeal endoderm and endostyle and in the lateral somite. These results show some key aspects of Pitx gene expression in gnathostomes are primitive for all living vertebrates.     

PITX2 controls asymmetric gonadal development in both sexes of the chick and can rescue the degeneration of the right ovary

The gonads arise on the ventromedial surface of each mesonephros. In most birds, female gonadal development is unusual in that only the left ovary becomes functional, whereas that on the right degenerates during embryogenesis. Males develop a pair of equally functional testes. We show that the chick gonads already have distinct morphological and molecular left-right (L-R) characteristics in both sexes at indifferent (genital ridge) stages and that these persist, becoming more elaborate during sex determination and differentiation, but have no consequences for testis differentiation. We find that these L-R differences depend on the L-R asymmetry pathway that controls the situs of organs such as the heart and gut. Moreover, a key determinant of this, Pitx2, is expressed asymmetrically, such that it is found only in the left gonad in both sexes from the start of their development. Misexpression of Pitx2 on the right side before and during gonadogenesis is sufficient to transform the right gonad into a left-like gonad. In ZW embryos, this transformation rescues the degenerative fate of the right ovary, allowing for the differentiation of left-like cortex containing meiotic germ cells. There is therefore a mechanism in females that actively promotes the underlying L-R asymmetry initiated by Pitx2 and the degeneration of the right gonad, and a mechanism in males that allows it to be ignored or overridden.     

文昌鱼左右体轴建立机制的研究进展

两侧对称动物左右体轴建立机制研究是发育生物学领域重要的基础科学问题之一.文昌鱼(amphioxus)由于其特殊的进化地位以及与脊椎动物相似的胚胎发育模式和身体构筑方式,是研究动物左右体轴建立机制的理想模式物种.近年来随着文昌鱼室内全人工繁育技术、高效显微注射技术和基因敲除技术的建立,国内外学者在左右体轴建立机制研究上取...     

Origins of anteroposterior patterning and Hox gene regulation during chordate evolution

All chordates share a basic body plan and many common features of early development. Anteroposterior (AP) regions of the vertebrate neural tube are specified by a combinatorial pattern of Hox gene expression that is conserved in urochordates and cephalochordates. Another primitive feature of Hox gene regulation in all chordates is a sensitivity to retinoic acid during embryogenesis, and recent developmental genetic studies have demonstrated the essential role for retinoid signalling in vertebrates. Two AP regions develop within the chordate neural tube during gastrulation: an anterior 'forebrain-midbrain' region specified by Otx genes and a posterior 'hindbrain-spinal cord' region specified by Hox genes. A third, intermediate region corresponding to the midbrain or midbrain-hindbrain boundary develops at around the same time in vertebrates, and comparative data suggest that this was also present in the chordate ancestor. Within the anterior part of the Hox-expressing domain, however, vertebrates appear to have evolved unique roles for segmentation genes, such as Krox-20, in patterning the hindbrain. Genetic approaches in mammals and zebrafish, coupled with molecular phylogenetic studies in ascidians, amphioxus and lampreys, promise to reveal how the complex mechanisms that specify the vertebrate body plan may have arisen from a relatively simple set of ancestral developmental components.     

A conserved role for the nodal signaling pathway in the establishment of dorso-ventral and left-right axes in deuterostomes

Nodal factors play crucial roles during embryogenesis of chordates. They have been implicated in a number of developmental processes, including mesoderm and endoderm formation and patterning of the embryo along the anterior-posterior and left-right axes. We have analyzed the function of the Nodal signaling pathway during the embryogenesis of the sea urchin, a non-chordate organism. We found that Nodal signaling plays a central role in axis specification in the sea urchin, but surprisingly, its first main role appears to be in ectoderm patterning and not in specification of the endoderm and mesoderm germ layers as in vertebrates. Starting at the early blastula stage, sea urchin nodal is expressed in the presumptive oral ectoderm where it controls the formation of the oral-aboral axis. A second conserved role for nodal signaling during vertebrate evolution is its involvement in the establishment of left-right asymmetries. Sea urchin larvae exhibit profound left-right asymmetry with the formation of the adult rudiment occurring only on the left side. We found that a nodal/lefty/pitx2 gene cassette regulates left-right asymmetry in the sea urchin but that intriguingly, the expression of these genes is reversed compared to vertebrates. We have shown that Nodal signals emitted from the right ectoderm of the larva regulate the asymmetrical morphogenesis of the coelomic pouches by inhibiting rudiment formation on the right side of the larva. This result shows that the mechanisms responsible for patterning the left-right axis are conserved in echinoderms and that this role for nodal is conserved among the deuterostomes. We will discuss the implications regarding the reference axes of the sea urchin and the ancestral function of the nodal gene in the last section of this review.