The barrel of the pelagic amphipod Phronima sedentaria (Forsk.) (Crustacea: hyperiidea)

Several pelagic animals have been postulated as the source of the transparent ‘barrel’ in which Phronima sedentaria(Forsk.) lives. It has been commonly held, although not on good evidence, that they are derived from tunicates. Many barrels, however, do not bear a close resemblance with the group most frequently proposed, pyrosomes. To clarify this zoological association, a sample of 70 barrels was submitted to data analysis. Principal coordinate analysis combining quantitative and qualitative characters disclosed six groups of barrels. These groups were subsequently thoroughly examined, and evidence found that they could only come from salps and pyrosomes. Observations on living animals are reported which support this conclusion. It is shown how salps and pyrosomes could be transformed into barrels, and a short discussion of what is thought to be a borderline case of host-parasite relationships is given.     

Characterization of an amphioxus paired box gene, AmphiPax2/5/8: developmental expression patterns in optic support cells, nephridium, thyroid-like structures and pharyngeal gill slits, but not in the midbrain-hindbrain boundary region

On the basis of developmental gene expression, the vertebrate central nervous system comprises: a forebrain plus anterior midbrain, a midbrain-hindbrain boundary region (MHB) having organizer properties, and a rhombospinal domain. The vertebrate MHB is characterized by position, by organizer properties and by being the early site of action of Wnt1 and engrailed genes, and of genes of the Pax2/5/8 subfamily. Wada and others (Wada, H., Saiga, H., Satoh, N. and Holland, P. W. H. (1998) Development 125, 1113-1122) suggested that ascidian tunicates have a vertebrate-like MHB on the basis of ascidian Pax258 expression there. In another invertebrate chordate, amphioxus, comparable gene expression evidence for a vertebrate-like MHB is lacking. We, therefore, isolated and characterized AmphiPax2/5/8, the sole member of this subfamily in amphioxus. AmphiPax2/5/8 is initially expressed well back in the rhombospinal domain and not where a MHB would be expected. In contrast, most of the other expression domains of AmphiPax2/5/8 correspond to expression domains of vertebrate Pax2, Pax5 and Pax8 in structures that are probably homologous - support cells of the eye, nephridium, thyroid-like structures and pharyngeal gill slits; although AmphiPax2/5/8 is not transcribed in any structures that could be interpreted as homologues of vertebrate otic placodes or otic vesicles. In sum, the developmental expression of AmphiPax2/5/8 indicates that the amphioxus central nervous system lacks a MHB resembling the vertebrate isthmic region. Additional gene expression data for the developing ascidian and amphioxus nervous systems would help determine whether a MHB is a basal chordate character secondarily lost in amphioxus. The alternative is that the MHB is a vertebrate innovation.     

The developing dorsal ganglion of the salp Thalia democratica,and the nature of the ancestral chordate brain

The development of the dorsal ganglion of the salp, Thalia democratica, is described from electron microscope reconstructions up to the stage of central neuropile formation. The central nervous system (CNS) rudiment is initially tubular with an open central canal. Early developmental events include: (i) the formation of a thick dorsal mantle of neuroblasts from which paired dorsal paraxial neuropiles arise; (ii) the differentiation of clusters of primary motor neurons along the ventral margin of the mantle; and (iii) the development from the latter of a series of peripheral nerves. The dorsal paraxial neuropiles ultimately connect to the large central neuropile, which develops later. Direct contact between neuroblasts and muscle appears to be involved in the development of some anterior nerves. The caudal nerves responsible for innervating more distant targets in the posterior part of the body develop without such contacts, which suggests that a different patterning mechanism may be employed in this part of the neuromuscular system. The results are compared with patterns of brain organization in other chordates. Because the salp CNS is symmetrical and generally less reduced than that of ascidian larvae, it is more easily compared with the CNS of amphioxus and vertebrates. The dorsal paraxial centres in the salp resemble the dorsolateral tectal centres in amphioxus in both position and organization; the central neuropile in salps likewise resembles the translumenal system in amphioxus. The neurons themselves are similar in that many of their neurites appear to be derived from the apical surface instead of the basal surface of the cell. Such neurons, with extensively developed apical neurites, may represent a new cell type that evolved in the earliest chordates in conjunction with the formation of translumenal or intralumenal integrative centres. In comparing the salp ganglion with vertebrates, we suggest that the main core of the ganglion is most like the mes-metencephalic region of the vertebrate brain, i.e. the zone occupied by the midbrain, isthmus, and anterior hindbrain. Counterparts of more anterior regions (forebrain) and posterior ones (segmented hindbrain) appear to be absent in salps, but are found in other tunicates, suggesting that evolution has acted quite differently on the main subdivisions of the CNS in different types of tunicates.     

Amphioxus and tunicates as evolutionary model systems

One important question in evolutionary biology concerns the origin of vertebrates from invertebrates. The current consensus is that the proximate ancestor of vertebrates was an invertebrate chordate. Today, the invertebrate chordates comprise cephalochordates (amphioxus) and tunicates (each a subphylum in the phylum Chordata, which also includes the vertebrate subphylum). It was widely accepted that, within the chordates, tunicates represent the sister group of a clade of cephalochordates plus vertebrates. However, recent studies suggest that the evolutionary positions of tunicates and cephalochordates should be reversed, the implications of which are considered here. We also review the two major groups of invertebrate chordates and compare relative advantages (and disadvantages) of each as model systems for elucidating the origin of the vertebrates.     

Ascidians and the plasticity of the chordate developmental program

Little is known about the ancient chordates that gave rise to the first vertebrates, but the descendants of other invertebrate chordates extant at the time still flourish in the ocean. These invertebrates include the cephalochordates and tunicates, whose larvae share with vertebrate embryos a common body plan with a central notochord and a dorsal nerve cord. Tunicates are now thought to be the sister group of vertebrates. However, research based on several species of ascidians, a diverse and wide-spread class of tunicates, revealed that the molecular strategies underlying their development appear to diverge greatly from those found in vertebrates. Furthermore, the adult body plan of most tunicates, which arises following an extensive post-larval metamorphosis, shows little resemblance to the body plan of any other chordate. In this review, we compare the developmental strategies of ascidians and vertebrates and argue that the very divergence of these strategies reveals the surprising level of plasticity of the chordate developmental program and is a rich resource to identify core regulatory mechanisms that are evolutionarily conserved in chordates. Further, we propose that the comparative analysis of the architecture of ascidian and vertebrate gene regulatory networks may provide critical insight into the origin of the chordate body plan.     

A conserved non-reproductive GnRH system in chordates

Gonadotropin-releasing hormone (GnRH) is a neuroendocrine peptide that plays a central role in the vertebrate hypothalamo-pituitary axis. The roles of GnRH in the control of vertebrate reproductive functions have been established, while its non-reproductive function has been suggested but less well understood. Here we show that the tunicate Ciona intestinalis has in its non-reproductive larval stage a prominent GnRH system spanning the entire length of the nervous system. Tunicate GnRH receptors are phylogenetically closest to vertebrate GnRH receptors, yet functional analysis of the receptors revealed that these simple chordates have evolved a unique GnRH system with multiple ligands and receptor heterodimerization enabling complex regulation. One of the gnrh genes is conspicuously expressed in the motor ganglion and nerve cord, which are homologous structures to the hindbrain and spinal cord of vertebrates. Correspondingly, GnRH receptor genes were found to be expressed in the tail muscle and notochord of embryos, both of which are phylotypic axial structures along the nerve cord. Our findings suggest a novel non-reproductive role of GnRH in tunicates. Furthermore, we present evidence that GnRH-producing cells are present in the hindbrain and spinal cord of the medaka, Oryzias latipes, thereby suggesting the deep evolutionary origin of a non-reproductive GnRH system in chordates.     

Pax2 expression patterns in the developing chick inner ear

The fate specification of the developing vertebrate inner ear could be determined by complex regulatory genetic pathways involving the Pax2/5/8 genes. Pax2 expression has been reported in the otic placode and vesicle of all vertebrates that have been studied. Loss-of-function experiments suggest that the Pax2 gene plays a key role in the development of the cochlear duct and acoustic ganglion. Despite all these data, the role of Pax2 gene in the specification of the otic epithelium is still only poorly defined. In the present work, we report a detailed study of the spatial and temporal Pax2 expression patterns during the development of the chick inner ear. In the period analysed, Pax2 is expressed only in some presumptive sensory patches, but not all, even though all sensory patches show the scattered Pax2 expression pattern later on. We also show that Pax2 is also expressed in several non-sensory structures.     

Evolution of developmental roles of Pax2/5/8 paralogs after independent duplication in urochordate and vertebrate lineages

Background

Gene duplication provides opportunities for lineage diversification and evolution of developmental novelties. Duplicated genes generally either disappear by accumulation of mutations (nonfunctionalization), or are preserved either by the origin of positively selected functions in one or both duplicates (neofunctionalization), or by the partitioning of original gene subfunctions between the duplicates (subfunctionalization). The Pax2/5/8 family of important developmental regulators has undergone parallel expansion among chordate groups. After the divergence of urochordate and vertebrate lineages, two rounds of independent gene duplications resulted in the Pax2, Pax5, and Pax8 genes of most vertebrates (the sister group of the urochordates), and an additional duplication provided the pax2a and pax2b duplicates in teleost fish. Separate from the vertebrate genome expansions, a duplication also created two Pax2/5/8 genes in the common ancestor of ascidian and larvacean urochordates.

Results

To better understand mechanisms underlying the evolution of duplicated genes, we investigated, in the larvacean urochordate Oikopleura dioica, the embryonic gene expression patterns of Pax2/5/8 paralogs. We compared the larvacean and ascidian expression patterns to infer modular subfunctions present in the single pre-duplication Pax2/5/8 gene of stem urochordates, and we compared vertebrate and urochordate expression to infer the suite of Pax2/5/8 gene subfunctions in the common ancestor of olfactores (vertebrates + urochordates). Expression pattern differences of larvacean and ascidian Pax2/5/8 orthologs in the endostyle, pharynx and hindgut suggest that some ancestral gene functions have been partitioned differently to the duplicates in the two urochordate lineages. Novel expression in the larvacean heart may have resulted from the neofunctionalization of a Pax2/5/8 gene in the urochordates. Expression of larvacean Pax2/5/8 in the endostyle, in sites of epithelial remodeling, and in sensory tissues evokes like functions of Pax2, Pax5 and Pax8 in vertebrate embryos, and may indicate ancient origins for these functions in the chordate common ancestor.

Conclusion

Comparative analysis of expression patterns of chordate Pax2/5/8 duplicates, rooted on the single-copy Pax2/5/8 gene of amphioxus, whose lineage diverged basally among chordates, provides new insights into the evolution and development of the heart, thyroid, pharynx, stomodeum and placodes in chordates; supports the controversial conclusion that the atrial siphon of ascidians and the otic placode in vertebrates are homologous; and backs the notion that Pax2/5/8 functioned in ancestral chordates to engineer epithelial fusions and perforations, including gill slit openings.     

Fgfrl1, a fibroblast growth factor receptor-like gene, is found in the cephalochordate Branchiostoma floridae but not in the urochordate Ciona intestinalis

FGFRL1 is a novel member of the fibroblast growth factor receptor family that controls the formation of musculoskeletal tissues. Some vertebrates, including man, cow, dog, mouse, rat and chicken, possess a single copy the FGFRL1 gene. Teleostean fish have two copies, fgfrl1a and fgfrl1b, because they have undergone a whole genome duplication. Vertebrates belong to the chordates, a phylum that also includes the subphyla of the cephalochordates (e.g. Branchiostoma floridae) and urochordates (tunicates, e.g. Ciona intestinalis). We therefore investigated whether other chordates might also possess an FGFRL1 related gene. In fact, a homologous gene was found in B. floridae (amphioxus). The corresponding protein showed 60% sequence identity with the human protein and all sequence motifs identified in the vertebrate proteins were also conserved in amphioxus Fgfrl1. In contrast, the genome of the urochordate C. intestinalis and those from more distantly related invertebrates including the insect Drosophila melanogaster and the nematode Caenorhabditis elegans did not appear to contain any related sequences. Thus, the FGFRL1 gene might have evolved just before branching of the vertebrate lineage from the other chordates.     

Some problems of the origin of the vertebrata

A.O. Kowalevsky was the first to examine in 1865–1867 the groups related to ancestors of vertebrates. They were represented by lancelet (Branchiostoma) and tunicates (Ascidia). As Grobben (1908) divided metazoans which are more advanced than coelenterates into protostomes and deuterostomes, searching for remote relatives of vertebrates was performed among deuterostomes. For a long time, enteropneusts were considered to be probable ancestors of vertebrates and chordates as a whole. Subsequently, this concept was replaced by the hypothesis that chordates evolved from aberrant deuterostomes with a calcitic skeleton, which were named Stylophora or Calcichordata (Jeffries, 1986). Based on the data on the homeobox genes, Malakhov (2006) proposed that chordates could have acquired characters of deuterostomes independently of echinoderms. A separate position is occupied by the theory of Sepp (1959), who proposed that vertebrates appeared as a result of “duplication” of marine annelids. The most primitive living vertebrates, Cyclostomata, have a hypophysis which is enclosed in an unusually long canal under the brain and opens in an aperture just anterior to the brain. Cyclostomata, along with Paleozoic armored fishlike forms, compose the most primitive vertebrate group, Agnatha.     

Distinct roles of Fgf8, Foxi1, Dlx3b and Pax8/2 during otic vesicle induction and maintenance in medaka

The development of the vertebrate inner ear is a complex process that has been investigated in several model organisms. In this work, we examined genetic interactions regulating early development of otic structures in medaka. We demonstrate that misexpression of Fgf8, Dlx3b and Foxi1 during early gastrulation is sufficient to produce ectopic otic vesicles. Combined misexpression strongly increases the appearance of this phenotype. By using a heat-inducible promoter we were furthermore able to separate the regulatory interactions among Fgf8, Foxi1, Dlx3b, Pax8 and Pax2 genes, which are active during different stages of early otic development. In the preplacodal stage we suggest a central position of Foxi1 within a regulatory network of early patterning genes including Dlx3b and Pax8. Different pathways are active after the placodal stage with Dlx3b playing a central role. There Dlx3b regulates members of the Pax-Six-Eya-Dach network and also strongly affects the early dorsoventral marker genes Otx1 and Gbx2.     

Sensory ecology of salps (Tunicata,thaliacea): More questions than answers

There is still relatively little known about the natural history of gelatinous animals in the plankton, and their sensory ecology remains largely a matter of surmise, based on limited morphological, physiological and behavioral data. Pelagic tunicates are among the most widely distributed and abundant of the gelatinous zooplank‐ton, and display a range of behavior that is apparently cued by aspects of their environment. Different kinds of information may be important for different scales of behavior. Feeding and predator avoidance are likely to be affected by near‐field stimuli from visual, chemical or mechanical sources, while far‐field information such as gravity, light, temperature, or pressure are likely to cue behavior spanning larger time and space scales, such as vertical or ontogenetic migration, aggregation and reproductive cycles. A variety of sensory structures have been described in pelagic tunicates, including photoreceptors of varying complexity, and several structures that have been suggested to be mechano‐ or chemoreceptors. Focussing on salps, this paper describes behavior that depends on sensory information, reviews the known structure and function of sensory receptors, and suggests some hypotheses on mechanisms defining the sensory ecology of these planktonic organisms.     

The amphioxus T-box gene, AmphiTbx15/18/22, illuminates the origins of chordate segmentation

Amphioxus and vertebrates are the only deuterostomes to exhibit unequivocal somitic segmentation. The relative simplicity of the amphioxus genome makes it a favorable organism for elucidating the basic genetic network required for chordate somite development. Here we describe the developmental expression of the somite marker, AmphiTbx15/18/22, which is first expressed at the mid-gastrula stage in dorsolateral mesendoderm. At the early neurula stage, expression is detected in the first three pairs of developing somites. By the mid-neurula stage, expression is downregulated in anterior somites, and only detected in the penultimate somite primordia. In early larvae, the gene is expressed in nascent somites before they pinch off from the posterior archenteron (tail bud). Integrating functional, phylogenetic and expression data from a variety of triploblast organisms, we have reconstructed the evolutionary history of the Tbx15/18/22 subfamily. This analysis suggests that the Tbx15/18/22 gene may have played a role in patterning somites in the last common ancestor of all chordates, a role that was later conserved by its descendents following gene duplications within the vertebrate lineage. Furthermore, the comparison of expression domains within this gene subfamily reveals similarities in the genetic bases of trunk and cranial mesoderm segmentation. This lends support to the hypothesis that the vertebrate head evolved from an ancestor possessing segmented cranial mesoderm.