Your search keyword '"Mark Q Martindale"' showing total 290 results

101. Phylogenetic analysis of lineage relationships among hyperiid amphipods as revealed by examination of the mitochondrial gene, cytochrome oxidase I (COI)

Author

Mark Q. Martindale, Steven H. D. Haddock, and William E. Browne

Subjects

Amphipoda, Taxon, biology, Phylogenetic tree, Range (biology), Lineage (evolution), Molecular phylogenetics, Zoology, Animal Science and Zoology, Pelagic zone, Plant Science, biology.organism_classification, Crustacean

Abstract

Among metazoans, crustaceans display the greatest disparity between body plans and are second only to the insects in overall species diversity. Within the crustaceans, the Amphipoda rank as one of the most speciose extant orders. Amphipods have successfully invaded a variety of ecosystems, including the pelagic midwater environment. Despite their abundance in varied and dissimilar habitats, and the use of traditional morphological and systematic comparative analyses, phylogenetic relationships among amphipods remain uncertain. The pelagic amphipods, hyperiids, have highly divergent life histories and morphological attributes in comparison to more familiar benthic, nearshore, intertidal, and terrestrial amphipods. Some of these adaptations are likely correlated with their pelagic life history and include features such as hypertrophied olfactory and visual systems, duplications of the eyes, and an array of modifications to the appendages. Many of these morphological features may represent homoplasies, thus masking the true phylogenetic relationships among extant hyperiid amphipods. Here, we sample a wide range of amphipod taxa for the COI gene and present the first preliminary molecular phylogeny among the hyperiids.

Published

2007

102. Surprisingly complex T-box gene complement in diploblastic metazoans

Author

Kevin Pang, Mark Q. Martindale, Shin Tochinai, and Atsuko Yamada

Subjects

food.ingredient, Phylogenetic tree, Nematostella, Germ layer, Anatomy, Biology, Sea anemone, biology.organism_classification, Genome, food, T-box, Evolutionary biology, Gene family, Gene, Ecology, Evolution, Behavior and Systematics, Developmental Biology

Abstract

Ctenophores and cnidarians are two metazoan groups that evolved at least 600 Ma, predating the Cambrian explosion. Although both groups are commonly categorized as diploblastic animals without derivatives of the mesodermal germ layer, ctenophores possess definitive contractile "muscle" cells. T-box family transcription factors are an evolutionarily ancient gene family, arising in the common ancestor of metazoans, and have been divided into eight groups in five distinct subfamilies, many of which are involved in the specification of mesodermal as well as ectodermally and endodermally derived structures. Here, we report the cloning and expression of five T-box genes from a ctenophore, Mnemiopsis leidyi. Phylogenetic analyses demonstrated that ctenophores possess members of at least three of the five T-box subfamilies, and expression studies suggested distinct roles of each T-box genes during gastrulation and early organogenesis. Moreover, genome searches of the sea anemone, Nematostella vectensis (anthozoan cnidarian), showed at least 13 T-box genes in Nematostella, which are divided into at least six distinct groups in the same three subfamilies found in ctenophores. Our results from two diploblastic animals indicate that the common ancestor of eumetazoans had a complex set of T-box genes and that two distinct subfamilies might have appeared during triploblastic evolution.

Published

2007

103. High-resolution fate map of the snail Crepidula fornicata: The origins of ciliary bands, nervous system, and muscular elements

Author

Andreas Hejnol, Jonathan Q. Henry, and Mark Q. Martindale

Subjects

Nervous system, Blastomeres, Mesoderm, Snails, Veliger, Biology, Nervous System, Fate mapping, Morphogenesis, medicine, Animals, Cell Lineage, Crepidula, Mantle (mollusc), Molecular Biology, Phylogeny, Fluorescent Dyes, Microscopy, Confocal, Muscles, Cell Differentiation, Cell Biology, Anatomy, biology.organism_classification, Ganglion, Cell biology, medicine.anatomical_structure, Embryology, Developmental Biology

Abstract

The littorinimorph gastropod Crepidula fornicata shows a spiralian cleavage pattern and has been the subject of studies in experimental embryology, cell lineage, and the organization of the larval nervous system. To investigate the contribution of early blastomeres to the veliger larva, we used intracellular cell lineage tracers in combination with high-resolution confocal imaging. This study corroborates many features derived from other spiralian fate maps (such as the origins of the hindgut and mesoderm from the 4d mesentoblast), but also yields new findings, particularly with respect to the origins of internal structures, such as the nervous system and musculature that have never been described in detail. The ectomesoderm in C. fornicata is mainly formed by micromeres of the 3rd quartet (principally 3a and 3b), which presumably represents a plesiomorphic condition for molluscs. The larval central nervous system is mainly formed by the micromeres of the 1st and 2nd quartet, of which 1a, 1c, and 1d form the anterior apical ganglion and nerve tracks to the foot and velum, and 2b and 2d form the visceral loop and the mantle cell. Our study shows that both first and second velar ciliary bands are generated by the same cells that form the prototroch in other spiralians and apparently bear no homology to the metatroch found in annelids.

Published

2007

104. Gastrulation in the cnidarian Nematostella vectensis occurs via invagination not ingression

Author

Marymegan Daly, Mark Q. Martindale, and Craig R. Magie

Subjects

food.ingredient, Morpholino, Mesenchyme, Nematostella, Ingression, Biology, food, Cell Movement, medicine, Animals, Molecular Biology, Gastrulation, Blastocoel, EMT, Gene Expression Regulation, Developmental, Gastrula, Cell Biology, Anatomy, Cell biology, Sea Anemones, medicine.anatomical_structure, Snail, embryonic structures, Snail Family Transcription Factors, Archenteron, Filopodia, Forkhead, Transcription Factors, Developmental Biology

Abstract

Gastrulation is a central event in metazoan development, involving many cellular behaviors including invagination, delamination, and ingression. Understanding the cell biology underlying gastrulation in many different taxa will help clarify the evolution of gastrulation mechanisms. Gastrulation in the anthozoan cnidarian Nematostella vectensis has been described as a combination of invagination and unipolar ingression through epithelial to mesenchymal transitions (EMT), possibly controlled by snail genes, important regulators of EMT in other organisms. Our examination, however, fails to reveal evidence of ingressing cells. Rather, we observe that endodermal cells constrict their apices, adopting bottle-like morphologies especially pronounced adjacent to the blastopore lip. They retain apical projections extending to the archenteron throughout gastrulation. Basally, they form actin-rich protrusions, including interdigitating filopodia that may be important in pulling the ectodermal and endodermal cells together. Endodermal cells retain cell–cell junctions while invaginating, and are organized throughout development. Never is the blastocoel filled by a mass of mesenchyme. Additionally, injection of splice-blocking morpholinos to Nematostella snail genes does not result in a phenotype despite dramatically reducing wild-type transcript, and overexpression of Snail-GFP in different clonal domains has no effect on cell behavior. These data indicate that EMT is not a major factor during gastrulation in Nematostella.

Published

2007

105. Expression of Pax gene family members in the anthozoan cnidarian, Nematostella vectensis

Author

Meg Daly, David Q. Matus, Mark Q. Martindale, and Kevin Pang

Subjects

Genetics, animal structures, food.ingredient, Pax genes, Starlet sea anemone, Nematostella, Biology, biology.organism_classification, Genome, body regions, food, embryonic structures, Homeobox, sense organs, PAX6, Bilateria, Gene, Ecology, Evolution, Behavior and Systematics, Developmental Biology

Abstract

Pax genes are a family of homeodomain transcription factors that have been isolated from protostomes (e.g., eight in Drosophilia) and deuterostomes (e.g., nine in vertebrates) as well as outside the Bilateria, from sponges, a placozoan, and several classes of cnidarians. The genome of an anthozoan cnidarian, the starlet sea anemone, Nematostella vectensis, has been surveyed by both degenerate polymerase chain reaction and in silico for the presence of Pax genes. N. vectensis possesses seven Pax genes, which are orthologous to cnidarian Pax genes (A,B,C, and D) previously identified in another anthozoan, a coral, Acropora millepora. Phylogenetic analyses including data from nonchordate deuterostomes indicates that there were five Pax gene classes in the protostome-deuterostome ancestor, but only three in the cnidarian-bilaterian ancestor, with PaxD class genes lost in medusozoan cnidarians. Pax genes play diverse roles in bilaterians, including eye formation (e.g., Pax6), segmentation (e.g., Pax3/7 class genes), and neural patterning (e.g., Pox-neuro, Pax2/5/8). We show the first expression data for members of all four Pax classes in a single species of cnidarian. N. vectensis Pax genes are expressed in both a cell-type and region-specific manner during embryogenesis, and likely play a role in patterning specific components of the cnidarian ectodermal nerve net. The results of these patterns are discussed with respect to Pax gene evolution in the Bilateria.

Published

2007

106. Genomic organization, gene structure, and developmental expression of three Clusteredotx genes in the sea anemoneNematostella vectensis

Author

John R. Finnerty, Maureen E. Mazza, Mark Q. Martindale, and Kevin Pang

Subjects

animal structures, food.ingredient, Nematostella, Biology, food, Genetics, medicine, Animals, Amino Acid Sequence, Bilateria, Phylogeny, Ecology, Evolution, Behavior and Systematics, Genomic organization, Genome, Otx Transcription Factors, Base Sequence, Gene Expression Regulation, Developmental, Starlet sea anemone, biology.organism_classification, Gastrulation, Sea Anemones, medicine.anatomical_structure, embryonic structures, Molecular Medicine, Homeobox, Animal Science and Zoology, Body region, Endoderm, Developmental Biology

Abstract

Otx homeodomain transcription factors have been studied in a variety of eumetazoan animals where they have roles in anterior neural development, endomesoderm formation, and the formation of larval ciliated fields. Here, we describe the gene structure and developmental expression of three Otx loci in the starlet sea anemone, Nematostella vectensis (phylum Cnidaria; class Anthozoa). Nematostella's three Otx genes (OtxA, OtxB, and OtxC) are located in a compact genomic cluster spanning 63.6 kb. The homeodomains of all three Otx genes are highly similar to their bilaterian counterparts, but only OtxB exhibits the conserved WSP motif that is located downstream of the homeodomain in many Otx proteins. The genomic organization, in concert with phylogenetic analyses, indicates that two tandem duplications occurred in the lineage leading to Nematostella some time after the Cnidaria diverged from the Bilateria. In situ hybridization reveals that otx is initially expressed by invaginating mesendodermal cells in the gastrula. Later, each of the three otx paralogs is expressed in three discrete larval body regions: in the endoderm of the foot or physa, in an endodermal ring surrounding the pharynx, and in the ectoderm of the tentacles. These data suggest that a single otx locus had already acquired diverse developmental functions in the cnidarian-bilaterian ancestor. Furthermore, following two gene duplications in the line leading to Nematostella, there have been only minor alterations in the spatiotemporal expression of the three Otx paralogs. However, the absence of a conserved protein domain in OtxA and OtxC suggests functional evolution of the protein itself.

Published

2007

107. Ctenophora

Author

David K. Simmons and Mark Q. Martindale

Abstract

The ctenophore nervous system is very complex with various specialized sensory cells, peripheral nerve nets, a centralized apical organ, neurons identifiable in all animal layers (epidermis, mesoglea, and gastrodermis), and with extensive regional specialization. The genomic content of nervous system genes (neural transcription factors, pre- and post- synaptic scaffold, neurotransmitter enzymes, and axon guidance genes) in ctenophores is the most reduced of any animal, more similar to that of the sponges, than to placozoans, cnidarians, and bilaterians. It is curious why ctenophores, but not sponges and placozoans, have such a highly diverse nervous system, even though sponges and placozoans have a larger number of genes traditionally thought to be involved with neural development and function. The proposed phylogenetic placement of the ctenophore divergence, at the base of the Metazoa, suggests that some form of a nervous system was already present at the ctenophore-extant animal split, and that this nervous system became exquisitely adapted for life as pelagic gelloplankton in ctenophores; while sponges and Trichoplax failed to exploit or lost this system. Conversely, ctenophores could have independently evolved their nervous system from the generic genetic components pre-existing in its extinct metazoan ancestors, and nervous systems were invented again by the cnidarian–bilaterian ancestor. Regardless, our current understanding of nervous system structure and genomic data from bilaterians, all four non-bilaterian phyla, and various protists, strongly suggests that ctenophores possess the absolute minimum genetic requirements for a functional nervous system of any animal. Consequentially, ctenophores are also most likely the oldest extant animal to possess a functional nervous system.

Published

2015

108. The mid-developmental transition and the evolution of animal body plans

Author

Natalia Mostov, Sandie M. Degnan, Eitan Winter, Tamar Hashimshony, Martin E. Feder, Bernard M. Degnan, Itai Yanai, Sally Khair, Oleg Simakov, Naftalie Senderovich, Nagayasu Nakanishi, Shang-Yun Liu, Leon Anavy, Selene L. Fernandez-Valverde, Michal Levin, Ekaterina Kovalev, Joseph F. Ryan, Detlev Arendt, Karina Yaniv, David Simmons, Tomas Larsson, Jochen C. Rink, David H. Silver, Mark Q. Martindale, Ayelet Jerafi-Vider, and Alison G. Cole

Subjects

0301 basic medicine, Range (biology), media_common.quotation_subject, information science, Gene regulatory network, Embryonic Development, Biology, Models, Biological, Evolution, Molecular, 03 medical and health sciences, 0302 clinical medicine, Species Specificity, Phylogenetics, Animals, Gene Regulatory Networks, Genes, Developmental, Phyletic gradualism, Conserved Sequence, Phylogeny, media_common, Body Patterning, Regulation of gene expression, Genetics, Multidisciplinary, Phylum, Gene Expression Regulation, Developmental, 030104 developmental biology, Body plan, Phenotype, Evolutionary developmental biology, bacteria, Transcriptome, 030217 neurology & neurosurgery

Abstract

Animals are grouped into ~35 'phyla' based upon the notion of distinct body plans. Morphological and molecular analyses have revealed that a stage in the middle of development--known as the phylotypic period--is conserved among species within some phyla. Although these analyses provide evidence for their existence, phyla have also been criticized as lacking an objective definition, and consequently based on arbitrary groupings of animals. Here we compare the developmental transcriptomes of ten species, each annotated to a different phylum, with a wide range of life histories and embryonic forms. We find that in all ten species, development comprises the coupling of early and late phases of conserved gene expression. These phases are linked by a divergent 'mid-developmental transition' that uses species-specific suites of signalling pathways and transcription factors. This mid-developmental transition overlaps with the phylotypic period that has been defined previously for three of the ten phyla, suggesting that transcriptional circuits and signalling mechanisms active during this transition are crucial for defining the phyletic body plan and that the mid-developmental transition may be used to define phylotypic periods in other phyla. Placing these observations alongside the reported conservation of mid-development within phyla, we propose that a phylum may be defined as a collection of species whose gene expression at the mid-developmental transition is both highly conserved among them, yet divergent relative to other species.

Published

2015

109. Par system components are asymmetrically localized in ectodermal epithelia, but not during early development in the sea anemone Nematostella vectensis

Author

Thomas Q Stephenson, Casey W. Dunn, Miguel Salinas-Saavedra, and Mark Q. Martindale

Subjects

food.ingredient, animal structures, biology, Polarity, Polarity (physics), Research, Embryogenesis, Zoology, Nematostella vectensis, Nematostella, Sea anemone, biology.organism_classification, Embryonic stem cell, Cell biology, Cnidaria, food, Cell polarity, Genetics, Bilateria, Developmental biology, Ecology, Evolution, Behavior and Systematics, Par proteins, Developmental Biology

Abstract

Background The evolutionary origins of cell polarity in metazoan embryos are unclear. In most bilaterian animals, embryonic and cell polarity are set up during embryogenesis with the same molecules being utilized to regulate tissue polarity at different life stages. Atypical protein kinase C (aPKC), lethal giant larvae (Lgl), and Partitioning-defective (Par) proteins are conserved components of cellular polarization, and their role in establishing embryonic asymmetry and tissue polarity have been widely studied in model bilaterian groups. However, the deployment and role of these proteins in animals outside Bilateria has not been studied. We address this by characterizing the localization of different components of the Par system during early development of the sea anemone Nematostella vectensis, a member of the clade Cnidaria, the sister group to bilaterian animals. Results Immunostaining using specific N. vectensis antibodies and the overexpression of mRNA-reporter constructs show that components of the N. vectensis Par system (NvPar-1, NvPar-3, NvPar-6, NvaPKC, and NvLgl) distribute throughout the microtubule cytoskeleton of eggs and early embryos without clear polarization along any embryonic axis. However, they become asymmetrically distributed at later stages, when the embryo forms an ectodermal epithelial layer. NvLgl and NvPar-1 localize in the basolateral cortex, and NvaPKC, NvPar-6, and NvPar-3 at the apical zone of the cell in a manner seen in bilaterian animals. Conclusions The cnidarian N. vectensis exhibits clear polarity at all stages of early embryonic development, which appears to be established independent of the Par system reported in many bilaterian embryos. However, in N. vectensis, using multiple immunohistochemical and fluorescently labeled markers in vivo, components of this system are deployed to organize epithelial cell polarity at later stages of development. This suggests that Par system proteins were co-opted to organize early embryonic cell polarity at the base of the Bilateria and that, therefore, different molecular mechanisms operate in early cnidarian embryogenesis. Electronic supplementary material The online version of this article (doi:10.1186/s13227-015-0014-6) contains supplementary material, which is available to authorized users.

Published

2015

110. Major diversification of voltage-gated K + channels occurred in ancestral parahoxozoans

Author

Bishoy Kamel, Andriy Anishkin, Mark Q. Martindale, Damian B. van Rossum, Mónica Medina, Sarah A. Rhodes, Xiaofan Li, Jose Chu Luo, Timothy Jegla, Fortunay H. Diatta, David Simmons, Hansi Liu, Jessica K. Sassic, and Liana Trigg

Subjects

Subfamily, Hydra, Protein subunit, Molecular Sequence Data, Biology, Evolution, Molecular, Mice, Xenopus laevis, Phylogenetics, Animals, Humans, Gene family, Amino Acid Sequence, Shaker, Databases, Protein, Phylogeny, Genetics, Multidisciplinary, KCNQ Potassium Channels, Phylogenetic tree, urogenital system, Ctenophora, biology.organism_classification, PNAS Plus, Evolutionary biology, Shaker Superfamily of Potassium Channels, Lernaean Hydra

Abstract

We examined the origins and functional evolution of the Shaker and KCNQ families of voltage-gated K(+) channels to better understand how neuronal excitability evolved. In bilaterians, the Shaker family consists of four functionally distinct gene families (Shaker, Shab, Shal, and Shaw) that share a subunit structure consisting of a voltage-gated K(+) channel motif coupled to a cytoplasmic domain that mediates subfamily-exclusive assembly (T1). We traced the origin of this unique Shaker subunit structure to a common ancestor of ctenophores and parahoxozoans (cnidarians, bilaterians, and placozoans). Thus, the Shaker family is metazoan specific but is likely to have evolved in a basal metazoan. Phylogenetic analysis suggested that the Shaker subfamily could predate the divergence of ctenophores and parahoxozoans, but that the Shab, Shal, and Shaw subfamilies are parahoxozoan specific. In support of this, putative ctenophore Shaker subfamily channel subunits coassembled with cnidarian and mouse Shaker subunits, but not with cnidarian Shab, Shal, or Shaw subunits. The KCNQ family, which has a distinct subunit structure, also appears solely within the parahoxozoan lineage. Functional analysis indicated that the characteristic properties of Shaker, Shab, Shal, Shaw, and KCNQ currents evolved before the divergence of cnidarians and bilaterians. These results show that a major diversification of voltage-gated K(+) channels occurred in ancestral parahoxozoans and imply that many fundamental mechanisms for the regulation of action potential propagation evolved at this time. Our results further suggest that there are likely to be substantial differences in the regulation of neuronal excitability between ctenophores and parahoxozoans.

Published

2015

111. Ether-à-go-go family voltage-gated K+ channels evolved in an ancestral metazoan and functionally diversified in a cnidarian–bilaterian ancestor

Author

Michael J. Layden, Anna P. Sberna, Xiaofan Li, Alexandra S. Martinson, Timothy Jegla, Fortunay H. Diatta, Mark Q. Martindale, and David Simmons

Subjects

food.ingredient, Physiology, Xenopus, Nematostella, Aquatic Science, Sea anemone, medicine.disease_cause, Evolution, Molecular, Origins of the ‘neuronal Tool Box', Cnidaria, food, medicine, Animals, Molecular Biology, Gene, Ecology, Evolution, Behavior and Systematics, In Situ Hybridization, Phylogeny, Mutation, biology, Phylogenetic tree, Base Sequence, Anatomy, biology.organism_classification, Potassium channel, Cell biology, Sea Anemones, Potassium Channels, Voltage-Gated, Insect Science, Animal Science and Zoology, Cnidocyte, Erg

Abstract

We examined the evolutionary origins of the ether-à-go-go (EAG) family of voltage-gated K+ channels, which have a strong influence on the excitability of neurons. The bilaterian EAG family comprises three gene subfamilies (Eag, Erg and Elk) distinguished by sequence conservation and functional properties. Searches of genome sequence indicate that EAG channels are metazoan specific, appearing first in ctenophores. However, phylogenetic analysis including two EAG family channels from the ctenophore Mnemiopsis leidyi indicates that the diversification of the Eag, Erg and Elk gene subfamilies occurred in a cnidarian/bilaterian ancestor after divergence from ctenophores. Erg channel function is highly conserved between cnidarians and mammals. Here we show that Eag and Elk channels from the sea anemone Nematostella vectensis (NvEag and NvElk) also share high functional conservation with mammalian channels. NvEag, like bilaterian Eag channels, has rapid kinetics, whereas NvElk activates at extremely hyperpolarized voltages, which is characteristic of Elk channels. Potent inhibition of voltage activation by extracellular protons is conserved between mammalian and Nematostella EAG channels. However, characteristic inhibition of voltage activation by Mg2+ in Eag channels and Ca2+ in Erg channels is reduced in Nematostella because of mutation of a highly conserved aspartate residue in the voltage sensor. This mutation may preserve sub-threshold activation of Nematostella Eag and Erg channels in a high divalent cation environment. mRNA in situ hybridization of EAG channels in Nematostella suggests that they are differentially expressed in distinct cell types. Most notable is the expression of NvEag in cnidocytes, a cnidarian-specific stinging cell thought to be a neuronal subtype.

Published

2015

112. Evolutionary Origins of the Shaker Family of Voltage-Gated Potassium Channels

Author

Fortunay H. Diatta, Xiaofan Li, Sarah A. Rhodes, Timothy Jegla, Jessica K. Sassic, Mark Q. Martindale, Liana Trigg, Hansi Liu, and David Simmons

Subjects

0303 health sciences, food.ingredient, Subfamily, Phylogenetic tree, Lineage (evolution), Biophysics, Nematostella, Biology, 03 medical and health sciences, 0302 clinical medicine, food, Sister group, Evolutionary biology, Phylogenetics, Botany, Gene family, Shaker, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The Shaker family of voltage-gated K+ channels in bilaterians consists of four closely related gene subfamilies (Shaker, Shab, Shaw and Shal) that regulate neuronal excitability in diverse ways. We examined the evolutionary origins of the gene family by characterizing Shaker channels in early branching metazoan lineages. Shaker family channels can be definitively identified by the combination of a voltage-dependent potassium channel core and a cytosolic domain (T1) that mediates subfamily-specific tetrameric assembly. The Shaker, Shab, Shaw and Shal subfamilies are present in cnidarians, a close sister group to the bilaterians. We show that all four subfamilies are highly conserved on a functional level in the sea anemone Nematostella vectensis, an emerging cnidarian model organism. The Nematostella Shaker, Shal and Shaw subfamilies include cnidarian-specific expansions of regulatory subunits that extend functional diversity through the formation of heteromeric channels. We were unable to identify Shaker family genes in choanoflagellates or sponges, but found over 40 Shaker family genes in a ctenophore (Mnemiopsis leidyi). Ctenophores are the earliest branching metazoans with a nervous system. Phylogenetic analysis indicates that the ctenophore Shaker family expanded independently and diverged prior to emergence of the Shaker, Shab, Shal and Shaw subfamilies. The phylogeny and functional analysis support Shaker as the oldest of these subfamilies. Two Mnemiopsis Shaker family subunits heteromerize with Nematostella and mouse Shaker subfamily channels, but not with Shab, Shaw or Shal. Thus the subunit interface of Shaker subfamily may retain ancestral features. Our results indicate that the Shaker family is metazoan-specific and was present by the time neurons evolved. However, the Shaker, Shab, Shal and Shaw subfamilies evolved in the cnidarian/bilaterian lineage long after the evolution of the first nervous systems.

Published

2015

113. Mesodermal gene expression during the embryonic and larval development of the articulate brachiopod Terebratalia transversa

Author

Andreas Hejnol, Yale J. Passamaneck, and Mark Q. Martindale

Subjects

Mesoderm, animal structures, Matematikk og naturvitenskap: 400::Basale biofag: 470::Genetikk og genomikk: 474 [VDP], Gene expression, Genetics, medicine, Spiralia, Mathematics and natural scienses: 400::Basic biosciences: 470::Genetics and genomics: 474 [VDP], Ecology, Evolution, Behavior and Systematics, Brachiopod, biology, Ectomesoderm, Research, biology.organism_classification, Embryonic stem cell, Cell biology, Gastrulation, medicine.anatomical_structure, embryonic structures, Terebratalia transversa, Archenteron, NODAL, Developmental biology, Developmental Biology

Abstract

Background Brachiopods undergo radial cleavage, which is distinct from the stereotyped development of closely related spiralian taxa. The mesoderm has been inferred to derive from the archenteron walls following gastrulation, and the primary mesoderm derivative in the larva is a complex musculature. To investigate the specification and differentiation of the mesoderm in the articulate brachiopod Terebratalia transversa, we have identified orthologs of genes involved in mesoderm development in other taxa and investigated their spatial and temporal expression during the embryonic and larval development of T. transversa. Results Orthologs of 17 developmental regulatory genes with roles in the development of the mesoderm in other bilaterian animals were found to be expressed in the developing mesoderm of T. transversa. Five genes, Tt.twist, Tt.GATA456, Tt.dachshund, Tt.mPrx, and Tt.NK1, were found to have expression throughout the archenteron wall at the radial gastrula stage, shortly after the initiation of gastrulation. Three additional genes, Tt.Pax1/9, Tt.MyoD, and Tt.Six1/2, showed expression at this stage in only a portion of the archenteron wall. Tt.eya, Tt.FoxC, Tt.FoxF, Tt.Mox, Tt.paraxis, Tt.Limpet, and Tt.Mef2 all showed initial mesodermal expression during later gastrula or early larval stages. At the late larval stage, Tt.dachshund, Tt.Limpet, and Tt.Mef2 showed expression in nearly all mesoderm cells, while all other genes were localized to specific regions of the mesoderm. Tt.FoxD and Tt.noggin both showed expression in the ventral mesoderm at the larval stages, with gastrula expression patterns in the archenteron roof and blastopore lip, respectively. Conclusions Expression analyses support conserved roles for developmental regulators in the specification and differentiation of the mesoderm during the development of T. transversa. Expression of multiple mesodermal factors in the archenteron wall during gastrulation supports previous morphological observations that this region gives rise to larval mesoderm. Localized expression domains during gastrulation and larval development evidence early regionalization of the mesoderm and provide a basis for hypotheses regarding the molecular regulation underlying the complex system of musculature observed in the larva. Electronic supplementary material The online version of this article (doi:10.1186/s13227-015-0004-8) contains supplementary material, which is available to authorized users.

Published

2015

114. Ctenophora

Author

Mark Q. Martindale and Jonathan Q. Henry

Published

2015

115. Cell specification and the role of the polar lobe in the gastropod mollusc Crepidula fornicata

Author

Kimberly J. Perry, Mark Q. Martindale, and Jonathan Q. Henry

Subjects

Blastomeres, Time Factors, D quadrant, Evolution, Polar lobe, Cleavage Stage, Ovum, Gastropoda, Embryonic Development, Veliger, Cleavage (embryo), Models, Biological, Induction, Quadrant (abdomen), medicine, Animals, Cell Lineage, Crepidula, Spiralian, Molecular Biology, Body Patterning, biology, Embryogenesis, Gene Expression Regulation, Developmental, Embryo, Cell Differentiation, Blastomere, Anatomy, Cell Biology, biology.organism_classification, Biological Evolution, Lobe, medicine.anatomical_structure, Mollusca, Developmental Biology

Abstract

A small polar lobe forms at the first and second cleavage divisions in the gastropod mollusc Crepidula fornicata. These lobes normally fuse with the blastomeres that give rise to the D quadrant at the two- and four-cell stages (cells ultimately generating the 4d mesentoblast and D quadrant organizer). Significantly, removal of the small polar lobe had no noticeable effect on subsequent development of the veliger larva. The behavior of the polar lobe and characteristic early cell shape changes involving protrusion of the 3D macromere at the 24-cell suggest that the D quadrant is specified prior to the sixth cleavage division. On the other hand, blastomere deletion experiments indicate that the D quadrant is not determined until the time of formation of the 4d blastomere (mesentoblast). In fact, embryos can undergo regulation to form normal-appearing larvae if the prospective D blastomere or 3D macromere is removed. Removal of the 4d mesentoblast leads to highly disorganized, radial development. Removal of the first quartet micromeres at the 8-cell stage also leads to the development of radialized larvae. These findings indicate that the embryos of C. fornicata follow the mode of development exhibited by equal-cleaving spiralians, which involves conditional specification of the D quadrant organizer via inductive interactions, presumably from the first quartet micromeres.

Published

2006

116. Expression of otd orthologs in the amphipod crustacean, Parhyale hawaiensis

Author

Ernst A. Wimmer, William E. Browne, Mark Q. Martindale, and Bernhard G. M. Schmid

Subjects

animal structures, Base Sequence, biology, Parhyale, Embryogenesis, Genes, Homeobox, Gene Expression Regulation, Developmental, Ectoderm, Anatomy, biology.organism_classification, Gastrulation, medicine.anatomical_structure, Crustacea, Gene duplication, Genetics, medicine, Animals, Developmental biology, In Situ Hybridization, Phylogeny, Gap gene, DNA Primers, Developmental Biology, Parhyale hawaiensis

Abstract

The arthropod head is a complex metameric structure. In insects, orthodenticle (otd) functions as a 'head gap gene' and plays a significant role in patterning and development of the anterior head ectoderm, the protocerebrum, and the ventral midline. In this study, we characterize the structure and developmental deployment of two otd paralogs in the amphipod crustacean, Parhyale hawaiensis. Photd1 is initially expressed at gastrulation through germband stages in a bilaterally symmetric, restricted region of the anterior head ectoderm and also in a single column of cells along the ventral midline. Late in embryogenesis, Photd1 is expressed within the developing anterior brain and the expression along the embryonic midline has become restricted to a stereotypic group of segmentally reiterated cells. The second ortholog Photd2, however, has a unique temporal-spatial expression pattern and is not detected until after the head lobes have been organized in the developing ectoderm of the germband during late germband stages. Anteriorly, Photd2 is coincident with the Photd1 head expression domain; however, Photd2 is not detected along the ventral midline during formation of the germband and only appears in the ventral midline late in embryonic development in a restricted group of cells distinct from those expressing Photd1. The early expression of Photd1 in the anterior head ectoderm is consistent with a role as a head gap gene. The more posterior expression of Photd1 is suggestive of a role in patterning the embryonic ventral midline. Photd2 expression appears too late to play a role in early head patterning but may contribute to latter patterning in restricted regions of both the head and the ventral midline. The comparative analysis of otd reveals the divergence of gene expression and gene function associated with duplication of this important developmental gene.

Published

2006

117. Dorso/Ventral Genes Are Asymmetrically Expressed and Involved in Germ-Layer Demarcation during Cnidarian Gastrulation

Author

Mark Q. Martindale, Gerald H. Thomsen, and David Q. Matus

Subjects

EVO_ECOL, Cell signaling, animal structures, Molecular Sequence Data, DEVBIO, Ectoderm, Germ layer, Sea anemone, Ligands, General Biochemistry, Genetics and Molecular Biology, Evolution, Molecular, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Enhancer, Body Patterning, 030304 developmental biology, 0303 health sciences, Models, Genetic, Agricultural and Biological Sciences(all), biology, Biochemistry, Genetics and Molecular Biology(all), Gene Expression Profiling, Gene Expression Regulation, Developmental, Proteins, Anatomy, biology.organism_classification, Cell biology, Gastrulation, Sea Anemones, medicine.anatomical_structure, Endoderm, Chordin, General Agricultural and Biological Sciences, Receptors, Transforming Growth Factor beta, 030217 neurology & neurosurgery, Signal Transduction

Abstract

Summary Cnidarians (corals, sea anemones, hydroids, and jellyfish) are a basal taxon closely related to bilaterally symmetrical animals [1–3] and have been characterized as diploblastic and as radially symmetrical around their longitudinal axis. We show that some orthologs of key bilaterian dorso/ventral (D/V) patterning genes, including the TGFβ signaling molecules NvDpp and NvBMP5-8 and their antagonist NvChordin , are initially expressed asymmetrically at the onset of gastrulation in the anthozoan sea anemone Nematostella vectensis . Surprisingly, unlike flies and vertebrates, the TGFβ ligands and their antagonist are colocalized at the onset of gastrulation but then segregate by germ layer as gastrulation proceeds. TGFβ ligands, their extracellular enhancer, NvTolloid , and components of their downstream signaling pathway ( NvSmad1/5 and NvSmad4 ) are all coexpressed in presumptive endoderm, indicating that only planar TGFβ signaling operates at these stages. NvChordin expression forms a boundary between TGFβ-expressing endodermal cells and aboral ectoderm. Manipulation of nuclear β-catenin localization affects TGFβ ligand and antagonist expression, suggesting that the ancestral role of the dpp/chordin antagonism during gastrulation may have been in germ-layer segregation and/or epithelial patterning rather than dorsal/ventral patterning.

Published

2006

118. The evolution of metazoan axial properties

Author

Mark Q. Martindale

Subjects

Gene regulatory network, Gene Expression Regulation, Developmental, Zoology, Cell Differentiation, Biology, Invertebrates, Multicellular organism, Developmental genetics, Molecular evolution, Phylogenetics, Evolutionary biology, Genetics, Animals, Molecular Biology, Phylogeny, Genetics (clinical), Body Patterning

Abstract

Renewed interest in the developmental basis of organismal complexity, and the emergence of new molecular tools, is improving our ability to study the evolution of metazoan body plans. The most substantial changes in body-plan organization occurred early in metazoan evolution; new model systems for studying basal metazoans are now being developed, and total-genome-sequencing initiatives are underway for at least three of the four most important taxa. The elucidation of how the gene networks that are involved in axial organization, germ-layer formation and cell differentiation are used differently during development is generating a more detailed understanding of the events that have led to the current diversity of multicellular life.

Published

2005

119. The cell lineage of the polyplacophoran, Chaetopleura apiculata: variation in the spiralian program and implications for molluscan evolution

Author

Akiko Okusu, Mark Q. Martindale, and Jonathan Q. Henry

Subjects

0106 biological sciences, Blastomeres, Spicule, Embryo, Nonmammalian, Chaetopleura apiculata, Prototroch, Development, Eye, Larval ocelli, 010603 evolutionary biology, 01 natural sciences, Chiton, 03 medical and health sciences, Sponge spicule, Shell, Animals, Cell Lineage, Mollusca, Molecular Biology, Phylogeny, 030304 developmental biology, Embryonic Induction, 0303 health sciences, biology, Simple eye in invertebrates, Anatomy, Cell Biology, Trochophore, biology.organism_classification, Biological Evolution, Body plan, Evolutionary biology, Larva, Patella vulgata, Developmental Biology

Abstract

Polyplacophorans, or chitons, are an important group of molluscs, which are argued to have retained many plesiomorphic features of the molluscan body plan. Polyplacophoran trochophore larvae posses several features that are distinctly different from those of their sister trochozoan taxa, including modifications of the ciliated prototrochal cells, the postrochal position of the larval eyes or ocelli, epidermal calcareous spicules, and a collection of serially reiterated epidermal shell plates. Despite these differences, chitons demonstrate a canonical pattern of equal spiral cleavage shared by other spiralian phyla that permits the identification of homologous cells across this animal clade. Cell lineage analysis using intracellular labeling on one chiton species, Chaetopleura apiculata, shows that the ocelli are generated from different lineal precursors (second-quartet micromeres: 2a, 2c) compared to those in all other spiralians studied to date (first-quartet micromeres: 1a, 1c). This situation implies that significant changes have also occurred in terms of the inductive interactions that control eye development in the spiralians. Although radical departures from the spiralian developmental program are seen in some molluscs (i.e., cephalopods), the findings presented here indicate that important changes can occur even within the highly constrained framework of the spiral cleavage program. Among spiralians, variation has been reported for the origin of the anterior, sensory, apical organ, which arises from the 1c and 1d micromeres in C. apiculata. The prototroch of C. apiculata consists of two to three irregular rows of ciliated cells but arise from 1q and 2q daughters, similar to that of Ischnochiton rissoi, as well as the gastropod, Patella vulgata. Despite certain early claims, there is no supporting evidence that any of the shell plates arise pretrochally in C. apiculata. The first seven of eight definitive shell plates that arise in the larva originate from shell secreting grooves in the postrochal region (derived from 2c, 2d, 3d). Earlier descriptions indicate that the eighth plate arises later at metamorphosis, and as this is formed posteriorly, it too forms in the postrochal region. On the other hand, epidermal spicules originate from both pretrochal and postrochal cells (1a,1d, 2a, 2c, 3c, 3d). The significance of these observations is discussed in light of various hypotheses concerning the origin of the conchiferan shell. This study reveals conservation, as well as evolutionary novelty, in the assignment of specific cell fates in the spiralians.

Published

2004

120. Investigating the origins of triploblasty: 'mesodermal' gene expression in a diploblastic animal, the sea anemoneNematostella vectensis(phylum, Cnidaria; class, Anthozoa)

Author

Mark Q. Martindale, Kevin Pang, and John R. Finnerty

Subjects

Mesoderm, Embryo, Nonmammalian, animal structures, food.ingredient, Molecular Sequence Data, Nematostella, Ectoderm, Germ layer, Histogenesis, Biology, food, medicine, Animals, Amino Acid Sequence, Molecular Biology, Bilateria, Conserved Sequence, Phylogeny, Sequence Homology, Amino Acid, Gene Expression Regulation, Developmental, Anatomy, biology.organism_classification, Sea Anemones, medicine.anatomical_structure, Evolutionary biology, embryonic structures, Triploblasty, Endoderm, Sequence Alignment, Developmental Biology

Abstract

Mesoderm played a crucial role in the radiation of the triploblastic Bilateria, permitting the evolution of larger and more complex body plans than in the diploblastic, non-bilaterian animals. The sea anemone Nematostella is a non-bilaterian animal, a member of the phylum Cnidaria. The phylum Cnidaria (sea anemones, corals, hydras and jellyfish) is the likely sister group of the triploblastic Bilateria. Cnidarians are generally regarded as diploblastic animals, possessing endoderm and ectoderm,but lacking mesoderm. To investigate the origin of triploblasty, we studied the developmental expression of seven genes from Nematostella whose bilaterian homologs are implicated in mesodermal specification and the differentiation of mesodermal cell types (twist, snailA, snailB, forkhead,mef2, a GATA transcription factor and a LIMtranscription factor). Except for mef2, the expression of these genes is largely restricted to the endodermal layer, the gastrodermis. mef2is restricted to the ectoderm. The temporal and spatial expression of these`mesoderm' genes suggests that they may play a role in germ layer specification. Furthermore, the predominantly endodermal expression of these genes reinforces the hypothesis that the mesoderm and endoderm of triploblastic animals could be derived from the endoderm of a diploblastic ancestor. Alternatively, we consider the possibility that the diploblastic condition of cnidarians is a secondary simplification, derived from an ancestral condition of triploblasty.

Published

2004

121. Fundamental properties of the spiralian developmental program are displayed by the basal nemertean Carinoma tremaphoros (Palaeonemertea, Nemertea)

Author

Svetlana A. Maslakova, Jon L. Norenburg, and Mark Q. Martindale

Subjects

Microinjections, Cleavage Stage, Ovum, Prototroch, Cleavage (embryo), Fluorescence, Epigenesis, Genetic, Phylogenetics, Spiral cleavage, Animals, Nemertean, Cell Lineage, Palaeonemertea, Molecular Biology, Mollusca, Phylogeny, Body Patterning, Nemertea, Microscopy, Confocal, Annelid, biology, Phylogenetic tree, fungi, Molluscan cross, Cell Biology, Blastomere, Anatomy, biology.organism_classification, Invertebrates, Evolutionary biology, Annelid cross, Developmental Biology

Abstract

The first description of the cleavage program of the palaeonemertean Carinoma tremaphoros (a member of a basal clade of the Nemertea) is illustrated by confocal microscopy and microinjection and compared to development of more derived nemerteans and other eutrochozoans (Annelida, Mollusca, Sipunculida and Echiurida). Lineage tracers were injected into individual blastomeres of C. tremaphoros at the 2-, 4-, 8- and 16-cell stage. Subsequent development was followed to the formation of simple (so-called planuliform) planktonic larvae to establish the ultimate fates of the blastomeres. Results of labeling experiments demonstrate that the development of C. tremaphoros bears closer similarity to other Eutrochozoa than development of a previously studied hoplonemertean (Nemertopsis bivittata) and a heteronemertean (Cerebratulus lacteus) in that the first cleavage plane bears an invariant relationship to the plane of bilateral symmetry of the larval body. Additionally, our cell-labeling experiments support the earlier suggestion that the transitory pre-oral belt of cells in the larvae of C. tremaphoros corresponds to the prototroch of other Eutrochozoa. A unique feature of development of C. tremaphoros includes the oblique orientation of the trochal lineages with respect to the anterior–posterior axis of the larva. The significance and application of cleavage characters such as presence of molluscan vs. annelid cross for phylogenetic analyses is reviewed. We argue that molluscan or annelid cross, neither of which are present in nemerteans, are merely two out of much greater variety of patterns created by the differences in the relative size and timing of formation of micromere quartets and none can be considered, by itself, as evidence of close phylogenetic relationship between phyla.

Published

2004

122. An ancient role for nuclear β-catenin in the evolution of axial polarity and germ layer segregation

Author

Melanie Hong, Kevin Pang, Mark Q. Martindale, Patricia N. Lee, Christine A. Byrum, Joanna M. Bince, Athula H. Wikramanayake, and Ronghui Xu

Subjects

Cell Nucleus, Genetics, Multidisciplinary, Beta-catenin, biology, Embryogenesis, Active Transport, Cell Nucleus, Wnt signaling pathway, Cell Polarity, Gastrula, Germ layer, Anthozoa, Immunohistochemistry, Embryonic stem cell, Cell biology, Gastrulation, Cytoskeletal Proteins, Endomesoderm, Cell polarity, Trans-Activators, biology.protein, Animals, Lithium Chloride, Germ Layers, beta Catenin

Abstract

The human oncogene beta-catenin is a bifunctional protein with critical roles in both cell adhesion and transcriptional regulation in the Wnt pathway. Wnt/beta-catenin signalling has been implicated in developmental processes as diverse as elaboration of embryonic polarity, formation of germ layers, neural patterning, spindle orientation and gap junction communication, but the ancestral function of beta-catenin remains unclear. In many animal embryos, activation of beta-catenin signalling occurs in blastomeres that mark the site of gastrulation and endomesoderm formation, raising the possibility that asymmetric activation of beta-catenin signalling specified embryonic polarity and segregated germ layers in the common ancestor of bilaterally symmetrical animals. To test whether nuclear translocation of beta-catenin is involved in axial identity and/or germ layer formation in 'pre-bilaterians', we examined the in vivo distribution, stability and function of beta-catenin protein in embryos of the sea anemone Nematostella vectensis (Cnidaria, Anthozoa). Here we show that N. vectensis beta-catenin is differentially stabilized along the oral-aboral axis, translocated into nuclei in cells at the site of gastrulation and used to specify entoderm, indicating an evolutionarily ancient role for this protein in early pattern formation.

Published

2003

123. Expression of the 22 nucleotide let-7 heterochronic RNA throughout the Metazoa: a role in life history evolution?

Author

Emili Saló, Mark Q. Martindale, Jaume Baguñà, Adam M. McCoy, Gary Ruvkun, Eva Jimenez, and Amy E. Pasquinelli

Subjects

Untranslated region, Genetics, Life Cycle Stages, biology, Regulator, RNA, biology.organism_classification, Invertebrates, Evolution, Molecular, MicroRNAs, Nematode, Animals, RNA, Helminth, Caenorhabditis elegans Proteins, Gene, Bilateria, Platyhelminths, Heterochrony, Phylogeny, Ecology, Evolution, Behavior and Systematics, Developmental Biology

Abstract

SUMMARY The22nucleotidelet-7smalltemporalRNAhasbeen found consistently in samples from diverse bilateria butnot from sponge or cnidarians. Here we further examine thephylogenetic distribution of this regulatory RNA by samplingrepresentativesofdiversemetazoan lineages.The22nucleo-tide let-7 RNAisdetectableintricladandpolycladplatyhelminths,nemertean, and chaetognath but not ctenophore or acoelmetazoans. These results support recent arguments thatacoels are distinct from other acoelomate platyhelminths. Weargue that let-7 is not a bilaterian or triploblast synapomorphybut instead evolved later in metazoan evolution, perhaps inassociation with complex life history traits. INTRODUCTION The let-7 gene was first identified in the nematode Caeno-rhabditis elegans as an essential regulator of developmentaltiming (Reinhart et al. 2000). It encodes a 22 nucleotide (nt)RNA that negatively regulates the expression of protein-coding genes that contain regions of complementarity in their3 0 -untranslated regions (UTRs) (Reinhart et al. 2000; Slacket al. 2000). Expression of let-7 RNA is undetectable until thelast larval stages in C. elegans, where it directs larval to adultcell fate transitions in certain tissues (Reinhart et al. 2000). Amajor target of let-7 mediated down-regulation is the lin-41protein-coding gene, which contains two complementary sitesin its 3

Published

2003

124. Early evolution of a homeobox gene: the parahox gene Gsx in the Cnidaria and the Bilateria

Author

John R. Finnerty, Kevin Pang, Mark Q. Martindale, Pat Burton, and David A. Paulson

Subjects

food.ingredient, Lineage (evolution), Molecular Sequence Data, ParaHox, Nematostella, Evolution, Molecular, Cnidaria, food, Phylogenetics, Animals, Amino Acid Sequence, Planula, Bilateria, Phylogeny, Ecology, Evolution, Behavior and Systematics, Body Patterning, Homeodomain Proteins, Regulation of gene expression, Sequence Homology, Amino Acid, biology, Genes, Homeobox, Gene Expression Regulation, Developmental, Anatomy, biology.organism_classification, Evolutionary biology, Homeobox, Developmental Biology

Abstract

Homeobox transcription factors are commonly involved in developmental regulation in diverse eukaryotes, including plants, animals, and fungi. The origin of novel homeobox genes is thought to have contributed to many evolutionary innovations in animals. We perform a molecular phylogenetic analysis of cnox2, the best studied homeobox gene from the phylum Cnidaria, a very ancient lineage of animals. Among three competing hypotheses, our analysis decisively favors the hypothesis that cnox2 is orthologous to the gsx gene of Bilateria, thereby establishing the existence of this specific homeobox gene in the eumetazoan stem lineage, some 650-900 million years ago. We assayed the expression of gsx in the planula larva and polyp of the sea anemone Nematostella vectensis using in situ hybridization and reverse transcriptase polymerase chain reaction. The gsx ortholog of Nematostella, known as anthox2, is expressed at high levels in the posterior planula and the corresponding "head" region of the polyp. It cannot be detected in the anterior planula or the corresponding "foot" region of the polyp. We have attempted to reconstruct the evolution of gsx spatiotemporal expression in cnidarians and bilaterians using a phylogenetic framework. Because of the surprisingly high degree of variability in gsx expression within the Cnidaria, it is currently not possible to infer unambiguously the ancestral cnidarian condition or the ancestral eumetazoan condition for gsx expression.

Published

2003

125. Protein evolution: structure-function relationships of the oncogene beta-catenin in the evolution of multicellular animals

Author

John R. Finnerty, Mark Q. Martindale, and Stephan Schneider

Subjects

Models, Molecular, Most recent common ancestor, Amino Acid Motifs, Computational biology, Biology, Evolution, Molecular, Structure-Activity Relationship, Transduction (genetics), Species Specificity, Gene Duplication, Gene duplication, Animals, Amino Acid Sequence, Cell adhesion, Gene, Conserved Sequence, Phylogeny, beta Catenin, Genetics, chemistry.chemical_classification, myr, Genomics, Sequence Analysis, DNA, General Medicine, Protein Structure, Tertiary, Amino acid, Cytoskeletal Proteins, chemistry, Mutation, Proteome, Trans-Activators, Animal Science and Zoology

Abstract

Beta-catenin functions as a cytoskeletal linker protein in cadherin-mediated adhesion and as a signal mediator in wnt-signal transduction pathways. We use a novel integrative approach, combining evolutionary, genomic, and three-dimensional structural data to analyze and trace the structural and functional evolution of beta-catenin genes. This approach also enabled us to examine the effects of gene duplication on the structure and function of beta-catenin genes in Drosophila, C. elegans, and vertebrates. By sampling a large number of different taxa, we identified both ancestral and derived motifs and residues within the different regions of the beta-catenin proteins. Projecting amino acid substitutions onto the three- dimensional structure established for mouse beta-catenin, we identified specific domains that exhibit loss and gain of selective constraints during beta catenin evolution. Structural changes, changes in the amino acid substitution rate, and the appearance of novel functional domains in beta-catenin can be mapped to specific branches on the metazoan tree. Together, our analyses suggest that a single, beta-catenin gene fulfilled both adhesion and signaling functions in the last common ancestor of metazoans some 700 million years ago. In addition, gene duplications facilitated the evolution of beta-catenins with novel functions and allowed the evolution of multiple, single-function proteins (cell adhesion or wnt-signaling) from the ancestral, dual-function protein. Integrative methods such as those we have applied here, utilizing the ‘natural experiments’ present in animal diversity, can be employed to identify novel and shared functional motifs and residues in virtually any protein among the proteomes of model systems and humans. J. Exp. Zool. (Mol. Dev. Evol.) 295B:25–44, 2003. © 2003 Wiley-Liss, Inc.

Published

2003

126. The Radiata and the evolutionary origins of the bilaterian body plan

Author

Jonathan J. Henry, Mark Q. Martindale, and John R. Finnerty

Subjects

Cnidaria, biology, Phylum, Ctenophora, Radiata, Zoology, Context (language use), biology.organism_classification, Body plan, Phylogenetics, Evolutionary biology, Genetics, Animals, Molecular Biology, Phylogeny, Ecology, Evolution, Behavior and Systematics, Body Patterning, Ancestor

Abstract

The apparent conservation of cellular and molecular developmental mechanisms observed in a handful of bilaterian metazoans has spawned a "race" to reconstruct the bilaterian ancestor. Knowledge of this ancestor would permit us to reconstruct the evolutionary changes that have occurred along specific bilaterian lineages. However, comparisons among extant bilaterians provide an unnecessarily limited view of the ancestral bilaterian. Since the original bilaterians are believed by many to be derived from a radially symmetrical ancestor, additional evidence might be obtained by examining present-day radially symmetrical animals. We briefly review pertinent features of the body plans of the extant radial eumetazoan phyla, the Cnidaria, and Ctenophora, in the context of revealing potential evolutionary links to the bilaterians.

Published

2002

127. Antagonistic BMP-cWNT signaling in the cnidarian Nematostella vectensis: Implications for the evolution of mesoderm

Author

David Simmons, Naveen Wijesena, and Mark Q. Martindale

Subjects

0301 basic medicine, 03 medical and health sciences, Embryology, Mesoderm, 030104 developmental biology, food.ingredient, food, medicine.anatomical_structure, medicine, Nematostella, Biology, Developmental Biology, Cell biology

Published

2017

128. Phylogenetic evidence for the modular evolution of metazoan signalling pathways

Author

Mark Q. Martindale and Leslie S. Babonis

Subjects

0301 basic medicine, Cell signaling, Phylogenetic tree, Biology, Body size, General Biochemistry, Genetics and Molecular Biology, Modular evolution, Cell biology, Evolution, Molecular, 03 medical and health sciences, 030104 developmental biology, Evolutionary biology, Animals, Section II: Major Evolutionary Transitions and Innovations, General Agricultural and Biological Sciences, Signalling pathways, Phylogeny, Signal Transduction

Abstract

Communication among cells was paramount to the evolutionary increase in cell type diversity and, ultimately, the origin of large body size. Across the diversity of Metazoa, there are only few conserved cell signalling pathways known to orchestrate the complex cell and tissue interactions regulating development; thus, modification to these few pathways has been responsible for generating diversity during the evolution of animals. Here, we summarize evidence for the origin and putative function of the intracellular, membrane-bound and secreted components of seven metazoan cell signalling pathways with a special focus on early branching metazoans (ctenophores, poriferans, placozoans and cnidarians) and basal unikonts (amoebozoans, fungi, filastereans and choanoflagellates). We highlight the modular incorporation of intra- and extracellular components in each signalling pathway and suggest that increases in the complexity of the extracellular matrix may have further promoted the modulation of cell signalling during metazoan evolution. Most importantly, this updated view of metazoan signalling pathways highlights the need for explicit study of canonical signalling pathway components in taxa that do not operate a complete signalling pathway. Studies like these are critical for developing a deeper understanding of the evolution of cell signalling. This article is part of the themed issue ‘Evo-devo in the genomics era, and the origins of morphological diversity’.

Published

2017

129. In vivo imaging of Nematostella vectensis embryogenesis and late development using fluorescent probes

Author

Miguel Salinas-Saavedra, Timothy Q. DuBuc, Eric Röttinger, Marten Postma, Anna A. Dattoli, Mark Q. Martindale, Leslie S. Babonis, Institut de Recherche sur le Cancer et le Vieillissement (IRCAN), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université Côte d'Azur (UCA), The Whitney Laboratory for Marine Bioscience [St. Augustine, FL, USA], University of Florida [Gainesville] (UF), Swammerdam Institute for Life Sciences, University of Amsterdam [Amsterdam] (UvA), and Molecular Cytology (SILS, FNWI)

Subjects

food.ingredient, animal structures, mTurquoise2, Embryonic Development, Nematostella vectensis, Mitosis, Nematostella, Biology, Microtubules, Nuclear envelope, 03 medical and health sciences, 0302 clinical medicine, food, Live cell imaging, In vivo, Animals, Cytoskeleton, [SDV.BDD]Life Sciences [q-bio]/Development Biology, Actin, Cytokinesis, Fluorescent Dyes, 030304 developmental biology, 0303 health sciences, Microvilli, Methodology Article, Regeneration (biology), Lifeact, Cell Biology, Actins, EB1, Cell biology, Actin Cytoskeleton, Sea Anemones, 030217 neurology & neurosurgery, Preclinical imaging

Abstract

Background Cnidarians are the closest living relatives to bilaterians and have been instrumental to studying the evolution of bilaterian properties. The cnidarian model, Nematostella vectensis, is a unique system in which embryology and regeneration are both studied, making it an ideal candidate to develop in vivo imaging techniques. Live imaging is the most direct way for quantitative and qualitative assessment of biological phenomena. Actin and tubulin are cytoskeletal proteins universally important for regulating many embryological processes but so far studies in Nematostella primarily focused on the localization of these proteins in fixed embryos. Results We used fluorescent probes expressed in vivo to investigate the dynamics of Nematostella development. Lifeact-mTurquoise2, a fluorescent cyan F-actin probe, can be visualized within microvilli along the cellular surface throughout embryonic development and is stable for two months after injection. Co-expression of Lifeact-mTurquoise2 with End-Binding protein1 (EB1) fused to mVenus or tdTomato-NLS allows for the visualization of cell-cycle properties in real time. Utilizing fluorescent probes in vivo helped to identify a concentrated ‘flash’ of Lifeact-mTurquoise2 around the nucleus, immediately prior to cytokinesis in developing embryos. Moreover, Lifeact-mTurquoise2 expression in adult animals allowed the identification of various cell types as well as cellular boundaries. Conclusion The methods developed in this manuscript provide an alternative protocol to investigate Nematostella development through in vivo cellular analysis. This study is the first to utilize the highly photo-stable florescent protein mTurquoise2 as a marker for live imaging. Finally, we present a clear methodology for the visualization of minute temporal events during cnidarian development. Electronic supplementary material The online version of this article (doi:10.1186/s12860-014-0044-2) contains supplementary material, which is available to authorized users.

Published

2014

130. Developmental and light-entrained expression of melatonin and its relationship to the circadian clock in the sea anemone Nematostella vectensis

Author

Solange Castro Afeche, José Cipolla-Neto, Adam M. Reitzel, Yale J. Passamaneck, Antonio C. Marques, Rafael Peres, and Mark Q. Martindale

Subjects

Genetics, Research, Period (gene), Circadian clock, HORMÔNIOS, Biology, Cell biology, Melatonin, CLOCK, Pineal gland, medicine.anatomical_structure, Embryogenesis, medicine, Zeitgeber, Circadian rhythm, Molecular clock, In situ hybridization, hormones, hormone substitutes, and hormone antagonists, Ecology, Evolution, Behavior and Systematics, Developmental Biology, medicine.drug

Abstract

Background The primary hormone of the vertebrate pineal gland, melatonin, has been identified broadly throughout the eukaryotes. While the role for melatonin in cyclic behavior via interactions with the circadian clock has only been reported in vertebrates, comparative research has shown that the transcription-translation loops of the animal circadian clock likely date to the cnidarian-bilaterian ancestor, leaving open significant questions about the evolutionary origin of melatonin signaling in circadian behavior by interacting with the molecular clock. Results Expression of melatonin in adult anemones showed peak expression at the end of light period (zeitgeber time (ZT) = 12) when cultured under diel conditions, coinciding with expression of genes and enzyme activity for members of the melatonin synthesis pathway (tryptophan hydroxylase and hydroxyindol-O-methyltransferase), which also showed rhythmic expression. During embryogenesis and juvenile stages, melatonin showed cyclic oscillations in concentration, peaking in midday. Spatial (in situ hybridization) and quantitative (real-time PCR) transcription of clock genes during development of N. vectensis showed these ‘clock’ genes are expressed early in the development, prior to rhythmic oscillations, suggesting functions independent of a function in the circadian clock. Finally, time-course studies revealed that animals transferred from diel conditions to constant darkness lose circadian expression for most of the clock genes within 4 days, which can be reset by melatonin supplementation. Conclusions Our results support an ancient role for melatonin in the circadian behavior of animals by showing cyclic expression of this hormone under diel conditions, light-dependent oscillations in genes in the melatonin synthesis pathway, and the function of melatonin in initiating expression of circadian clock genes in the cnidarian N. vectensis. The differences in expression melatonin and the circadian clock gene network in the adult stage when compared with developmental stages of N. vectensis suggests new research directions to characterize stage-specific mechanisms of circadian clock function in animals.

Published

2014

131. Expression of multiple Sox genes through embryonic development in the ctenophore Mnemiopsis leidyi is spatially restricted to zones of cell proliferation

Author

Kevin Pang, David Simmons, Christine E. Schnitzler, Andreas D. Baxevanis, and Mark Q. Martindale

Subjects

endocrine system, Sense organ, Somatic cell, Biology, Bioinformatics, Lobate, Mnemiopsis leidyi, Genetics, Gene family, Gene, Cell proliferation, Ecology, Evolution, Behavior and Systematics, Ctenophore, Stem cell, urogenital system, Mnemiopsis, Research, biology.organism_classification, Ctenophora, Evolutionary biology, embryonic structures, Sox, Mnemiopsis leidy, Developmental biology, SOX gene family, Developmental Biology

Abstract

Background: The Sox genes, a family of transcription factors characterized by the presence of a high mobility group (HMG) box domain, are among the central groups of developmental regulators in the animal kingdom. They are indispensable in progenitor cell fate determination, and various Sox family members are involved in managing the critical balance between stem cells and differentiating cells. There are 20 mammalian Sox genes that are divided into five major groups (B, C, D, E, and F). True Sox genes have been identified in all animal lineages but not outside Metazoa, indicating that this gene family arose at the origin of the animals. Whole-genome sequencing of the lobate ctenophore Mnemiopsis leidyi allowed us to examine the full complement and expression of the Sox gene family in this early-branching animal lineage. Results: Our phylogenetic analyses of the Sox gene family were generally in agreement with previous studies and placed five of the six Mnemiopsis Sox genes into one of the major Sox groups: SoxB (MleSox1), SoxC (MleSox2), SoxE (MleSox3, MleSox4), and SoxF (MleSox5), with one unclassified gene (MleSox6). We investigated the expression of five out of six Mnemiopsis Sox genes during early development. Expression patterns determined through in situ hybridization generally revealed spatially restricted Sox expression patterns in somatic cells within zones of cell proliferation, as determined by EdU staining. These zones were located in the apical sense organ, upper tentacle bulbs, and developing comb rows in Mnemiopsis, and coincide with similar zones identified in the cydippid ctenophore Pleurobrachia. Conclusions: Our results are consistent with the established role of multiple Sox genes in the maintenance of stem cell pools. Both similarities and differences in juvenile cydippid stage expression patterns between Mnemiopsis Sox genes and their orthologs from Pleurobrachia highlight the importance of using multiple species to characterize the evolution of development within a given phylum. In light of recent phylogenetic evidence that Ctenophora is the earliest-branching animal lineage, our results are consistent with the hypothesis that the ancient primary function of Sox family genes was to regulate the maintenance of stem cells and function in cell fate determination. publishedVersion

Published

2014

132. Functional evolution of Erg potassium channel gating reveals an ancient origin for IKr

Author

Timothy Jegla, Michael J. Layden, Damian B. van Rossum, Fortunay H. Diatta, Mark Q. Martindale, Alexandra S. Martinson, and Sarah A. Rhodes

Subjects

Patch-Clamp Techniques, genetic structures, Xenopus, Molecular Sequence Data, Action Potentials, Gating, Models, Biological, Evolution, Molecular, Species Specificity, Repolarization, Animals, Placozoa, Cloning, Molecular, Caenorhabditis elegans, Genetics, Multidisciplinary, biology, Base Sequence, Models, Genetic, Reverse Transcriptase Polymerase Chain Reaction, Computational Biology, Depolarization, Cardiac action potential, Bayes Theorem, Sequence Analysis, DNA, Biological Sciences, biology.organism_classification, Phenotype, Potassium channel, eye diseases, Ether-A-Go-Go Potassium Channels, Cell biology, Sea Anemones, Daphnia, Caenorhabditis, sense organs, Erg, Ion Channel Gating

Abstract

Mammalian Ether-a-go-go related gene (Erg) family voltage-gated K(+) channels possess an unusual gating phenotype that specializes them for a role in delayed repolarization. Mammalian Erg currents rectify during depolarization due to rapid, voltage-dependent inactivation, but rebound during repolarization due to a combination of rapid recovery from inactivation and slow deactivation. This is exemplified by the mammalian Erg1 channel, which is responsible for IKr, a current that repolarizes cardiac action potential plateaus. The Drosophila Erg channel does not inactivate and closes rapidly upon repolarization. The dramatically different properties observed in mammalian and Drosophila Erg homologs bring into question the evolutionary origins of distinct Erg K(+) channel functions. Erg channels are highly conserved in eumetazoans and first evolved in a common ancestor of the placozoans, cnidarians, and bilaterians. To address the ancestral function of Erg channels, we identified and characterized Erg channel paralogs in the sea anemone Nematostella vectensis. N. vectensis Erg1 (NvErg1) is highly conserved with respect to bilaterian homologs and shares the IKr-like gating phenotype with mammalian Erg channels. Thus, the IKr phenotype predates the divergence of cnidarians and bilaterians. NvErg4 and Caenorhabditis elegans Erg (unc-103) share the divergent Drosophila Erg gating phenotype. Phylogenetic and sequence analysis surprisingly indicates that this alternate gating phenotype arose independently in protosomes and cnidarians. Conversion from an ancestral IKr-like gating phenotype to a Drosophila Erg-like phenotype correlates with loss of the cytoplasmic Ether-a-go-go domain. This domain is required for slow deactivation in mammalian Erg1 channels, and thus its loss may partially explain the change in gating phenotype.

Published

2014

133. Initiating a regenerative response; cellular and molecular features of wound healing in the cnidarian Nematostella vectensis

Author

Nikki Traylor-Knowles, Timothy Q. DuBuc, and Mark Q. Martindale

Subjects

MAPK/ERK pathway, Transcription, Genetic, Microarray, Physiology, Nematostella vectensis, Apoptosis, Nematostella, Plant Science, Matrix metalloproteinase, Structural Biology, Cnidarians, Extracellular Signal-Regulated MAP Kinases, Metalloproteinase, Oligonucleotide Array Sequence Analysis, Agricultural and Biological Sciences(all), Receptors, Notch, integumentary system, Lateral gene transfer, Up-Regulation, Cell biology, ERK signaling, General Agricultural and Biological Sciences, Research Article, Biotechnology, food.ingredient, MAP Kinase Signaling System, Down-Regulation, Wound healing, Biology, Real-Time Polymerase Chain Reaction, Models, Biological, Time-Lapse Imaging, General Biochemistry, Genetics and Molecular Biology, Cnidaria, food, Downregulation and upregulation, Animals, Regeneration, RNA, Messenger, Transcription factor, Ecology, Evolution, Behavior and Systematics, Biochemistry, Genetics and Molecular Biology(all), Microarray analysis techniques, Gastrulation, Mucins, Cell Biology, Molecular biology, Glycoprotein, Developmental Biology

Abstract

Background Wound healing is the first stage of a series of cellular events that are necessary to initiate a regenerative response. Defective wound healing can block regeneration even in animals with a high regenerative capacity. Understanding how signals generated during wound healing promote regeneration of lost structures is highly important, considering that virtually all animals have the ability to heal but many lack the ability to regenerate missing structures. Cnidarians are the phylogenetic sister taxa to bilaterians and are highly regenerative animals. To gain a greater understanding of how early animals generate a regenerative response, we examined the cellular and molecular components involved during wound healing in the anthozoan cnidarian Nematostella vectensis. Results Pharmacological inhibition of extracellular signal-regulated kinases (ERK) signaling blocks regeneration and wound healing in Nematostella. We characterized early and late wound healing events through genome-wide microarray analysis, quantitative PCR, and in situ hybridization to identify potential wound healing targets. We identified a number of genes directly related to the wound healing response in other animals (metalloproteinases, growth factors, transcription factors) and suggest that glycoproteins (mucins and uromodulin) play a key role in early wound healing events. This study also identified a novel cnidarian-specific gene, for a thiamine biosynthesis enzyme (vitamin B synthesis), that may have been incorporated into the genome by lateral gene transfer from bacteria and now functions during wound healing. Lastly, we suggest that ERK signaling is a shared element of the early wound response for animals with a high regenerative capacity. Conclusions This research describes the temporal events involved during Nematostella wound healing, and provides a foundation for comparative analysis with other regenerative and non-regenerative species. We have shown that the same genes that heal puncture wounds are also activated after oral-aboral bisection, indicating a clear link with the initiation of regenerative healing. This study demonstrates the strength of using a forward approach (microarray) to characterize a developmental phenomenon (wound healing) at a phylogenetically important crossroad of animal evolution (cnidarian-bilaterian ancestor). Accumulation of data on the early wound healing events across numerous systems may provide clues as to why some animals have limited regenerative abilities.

Published

2014

134. A cleavage clock regulates features of lineage-specific differentiation in the development of a basal branching metazoan, the ctenophore Mnemiopsis leidyi

Author

Kevin Pang, Jonathan Q. Henry, Mark Q. Martindale, and Antje H. L. Fischer

Subjects

Cell type, Cytochalasin B, Zoology, Cell cycle arrest, 03 medical and health sciences, 0302 clinical medicine, Genetics, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Cell lineage, Ctenophore, 0303 health sciences, biology, Mnemiopsis, Research, Cilium, Actinomycin, Comb cell, Photocyte, Blastomere, Marine invertebrates, Comb jelly, biology.organism_classification, Evolutionary biology, Embryology, Puromycin, Developmental biology, 030217 neurology & neurosurgery, Developmental Biology

Abstract

BackgroundAn important question in experimental embryology is to understand how the developmental potential responsible for the generation of distinct cell types is spatially segregated over developmental time. Classical embryological work showed that ctenophores, a group of gelatinous marine invertebrates that arose early in animal evolution, display a highly stereotyped pattern of early development and a precocious specification of blastomere fates. Here we investigate the role of autonomous cell specification and the developmental timing of two distinct ctenophore cell types (motile compound comb-plate-like cilia and light-emitting photocytes) in embryos of the lobate ctenophore,Mnemiopsis leidyi.ResultsInMnemiopsis, 9 h after fertilization, comb plate cilia differentiate into derivatives of the E lineage, while the bioluminescent capability begins in derivatives of the M lineage. Arresting cleavage with cytochalasin B at the 1-, 2- or 4-cell stage does not result in blastomere death; however, no visible differentiation of the comb-plate-like cilia or bioluminescence was observed. Cleavage arrest at the 8- or 16-cell stage, in contrast, results in the expression of both differentiation products. Fate-mapping experiments indicate that only the lineages of cells that normally express these markers in an autonomous fashion during normal development express these traits in cleavage-arrested 8- and 16-cell stage embryos. Lineages that form comb plates in a non-autonomous fashion (derivatives of the M lineage) do not. Timed actinomycin D and puromycin treatments show that transcription and translation are required for comb formation and suggest that the segregated material might be necessary for activation of the appropriate genes. Interestingly, even in the absence of cytokinesis, differentiation markers appear to be activated at the correct times. Treatments with a DNA synthesis inhibitor, aphidicolin, show that the number of nuclear divisions, and perhaps the DNA to cytoplasmic ratio, are critical for the appearance of lineage-specific differentiation.ConclusionOur work corroborates previous studies demonstrating that the cleavage program is causally involved in the spatial segregation and/or activation of factors that give rise to distinct cell types in ctenophore development. These factors are segregated independently to the appropriate lineage at the 8- and the 16-cell stages and have features of a clock, such that comb-plate-like cilia and light-emitting photoproteins appear at roughly the same developmental time in cleavage-arrested embryos as they do in untreated embryos. Nuclear division, which possibly affects DNA-cytoplasmic ratios, appears to be important in the timing of differentiation markers. Evidence suggests that the 60-cell stage, just prior to gastrulation, is the time of zygotic gene activation. Such cleavage-clock-regulated phenomena appear to be widespread amongst the Metazoa and these cellular and molecular developmental mechanisms probably evolved early in metazoan evolution.

Published

2014

135. Multiple Inductive Signals Are Involved in the Development of the Ctenophore Mnemiopsis leidyi

Author

Jonathan J. Henry and Mark Q. Martindale

Subjects

0106 biological sciences, Mesoderm, Time Factors, animal structures, Lineage (genetic), Cell lineage, Models, Biological, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, mesoderm, medicine, Animals, Cell Lineage, endoderm, induction, Molecular Biology, Body Patterning, 030304 developmental biology, Genetics, 0303 health sciences, biology, basal metazoan, Mnemiopsis, fungi, Embryogenesis, Cell Biology, Biological evolution, biology.organism_classification, Biological Evolution, Invertebrates, Embryonic stem cell, Cell biology, Blastocyst, medicine.anatomical_structure, Microscopy, Fluorescence, Endoderm, Developmental Biology

Abstract

Ctenophores possess eight longitudinally arrayed rows of comb plate cilia. Previous intracellular cell lineage analysis has shown that these comb rows are derived from two embryonic lineages, both daughters of the four e(1) micromeres (e(11) and e(12)) and a single daughter of the four m(1) micromeres (the m(12) micromeres). Although isolated e(1) micromeres will spontaneously generate comb plates, cell deletion experiments have shown that no comb plates appear during embryogenesis following the removal of e(1) descendents. Thus, the m(1) lineage requires the inductive interaction of the e(1) lineage to contribute to comb plate formation. Here we show that, although m(12) cells are normally the only m(1) derivatives to contribute to comb plate formation, m(11) cells are capable of generating comb plates in the absence m(12) cells. The reason that m(11) cells do not normally make comb rows may be attributable either to their more remote location relative to critical signaling centers (e.g., e(1) descendants) or to inhibitory signals that may be provided by other nearby cells such as sister cells m(12). In addition, we show that the signals provided by the e(1) lineage are not sufficient for m(1)-derived comb plate formation. Signals provided by endomesodermal progeny of either the E or the M lineages (the 3E or 2M macromeres) are also required.

Published

2001

136. Comparative Analysis of Hox Gene Expression in the PolychaeteChaetopterus: Implications for the Evolution of Body Plan Regionalization1

Author

Steven Q. Irvine and Mark Q. Martindale

Subjects

Polychaete, animal structures, Annelid, biology, Differential regulation, Anatomy, Chaetopterus, biology.organism_classification, Body plan, Expression (architecture), Evolutionary biology, Gene expression, General Earth and Planetary Sciences, Hox gene, General Environmental Science

Abstract

The Hox genes are widely regarded as candidates for involvement in major evolutionary changes in body plan organization. We examine Hox gene expression data for several taxa, in relation to recent work on the polychaete annelid Chaetopterus. The work in Chaetopterus shows the basic conservation of colinearity of anterior expression boundaries seen in other groups. It also reveals novel patterns including early expression in the larval growth zone and later formation of posterior boundaries that correlate with morphological transitions in the polychaete body plan. The polychaete gene expression pattern is compared with those of Hox gene homologs in other taxa to reveal differences that represent evolutionary changes in Hox gene regulation between lineages. Correlations between Hox gene expression differences and morphological differences are examined, focussing on a number of cases in which posterior Hox gene expression boundaries correlate with morphological transitions. Differential regulation of these posterior expression boundaries is proposed as a possible mechanism for changes body plan regionalization.

Published

2001

137. Regulation and Regeneration in the Ctenophore Mnemiopsis leidyi

Author

Jonathan Q. Henry and Mark Q. Martindale

Subjects

Cell specific, 0303 health sciences, biology, Body Patterning, Mnemiopsis, Regeneration (biology), 030302 biochemistry & molecular biology, Cell Biology, Anatomy, Cell lineage, biology.organism_classification, Invertebrates, Models, Biological, Embryonic stem cell, 03 medical and health sciences, Body plan, Evolutionary biology, Animals, Regeneration, Molecular Biology, Process (anatomy), Signal Transduction, 030304 developmental biology, Developmental Biology

Abstract

Lobate ctenophores (tentaculates) generally exhibit a remarkable ability to regenerate missing structures as adults. On the other hand, their embryos exhibit a highly mosaic behavior when cut into halves or when specific cells are ablated. These deficient embryos do not exhibit embryonic regulation, and generate incomplete adult body plans. Under certain conditions, however, these deficient animals are subsequently able to replace the missing structures during the adult phase in a process referred to as “post-regeneration.” We have determined that successful post-regeneration can be predicted on the basis of a modified polar coordinate model, and the rules of intercalary regeneration, as defined by French et al. (V. French, P. J. Bryant, and S. V. Bryant, 1976, Science 193, 969–981.) The model makes certain assumptions about the organization of the ctenophore body plan that fit well with what we have determined on the basis of cell lineage fates maps, and their twofold rotational (“biradial”) symmetry. The results suggest that cells composing the ctenophore adult body plan possess positional information, which is utilized to reconstruct the adult body plan. More specifically, we have found that the progeny of three specific cell lineages are required to support post-regeneration of the comb rows (the e1, e2, and m1 micromeres). Furthermore, post-regeneration of the comb rows involves a suite of cell–cell inductive interactions, which are similar to those that take place during their embryonic formation. The significance of these findings is discussed in terms of the organization of the ctenophore body plan, and the mechanisms involved in cell fate specification. This situation is also contrasted with that of the atentaculate ctenophores, which are unable to undergo post-regeneration.

Published

2000

138. Combined-method phylogenetic analysis of Hox and ParaHox genes of the metazoa

Author

Matthew J. Kourakis and Mark Q. Martindale

Subjects

Genetics, animal structures, Phylogenetic tree, ParaHox, Sequence alignment, General Medicine, Biology, Conserved sequence, Body plan, Phylogenetics, Evolutionary biology, embryonic structures, Animal Science and Zoology, Hox gene, Gene

Abstract

The clustered Hox genes show a conserved role in patterning the body axis of bilaterian metazoans. Increasingly, a broader phylogenetic sampling of non-model system organisms is being examined to detect a correlation, if any, between Hox gene evolution, and body plan innovations. To assess how Hox gene expression and function evolve with changing cluster arrangements, we must be able to reliably assign gene orthologies between Hox genes. Recent evidence suggests that a four-gene proto-Hox cluster duplicated to form the precursor of the present cluster and an additional sister-cluster, the ParaHox group. Here, phylogenetic methods are used to determine Hox-gene orthologies and to infer probable clustering events leading to the current bilaterian Hox complement. This analysis supports the ParaHox hypothesis and gives first confirmation that ind (intermediate neuroblasts defective) is an anterior ParaHox ortholog from protostomes. This analysis supports a proto-Hox cluster of four genes in which the central-class member of the ParaHox cluster may have been lost. It is also proposed here that ancestral diploblasts had central-class members of both Hox and ParaHox clusters. Primitive Hox gene ancestors are estimated by phylogenetic methods and found to have no strong affinity to any particular class of extant Hox members.

Published

2000

139. Larval Ontogenetic Stages of Chaetopterus: Developmental Heterochrony in the Evolution of Chaetopterid Polychaetes

Author

Mark Q. Martindale, Steven Q. Irvine, and Oleg Chaga

Subjects

Polychaete, Larva, Time Factors, Phylogenetic tree, biology, Ontogeny, Lineage (evolution), Polychaeta, Morphology (biology), Gastrula, RNA Probes, Anatomy, Chaetopterus, biology.organism_classification, Biological Evolution, Tubulin, Evolutionary biology, Animals, RNA, Messenger, General Agricultural and Biological Sciences, Heterochrony, In Situ Hybridization, Phylogeny

Abstract

Seven post-gastrulation larval stages are described for the sedentary polychaete Chaetopterus. Analysis of larval anatomy and morphology through ontogeny reveals significant differences in the temporal sequence of segmentation, and in the character of segments formed, from the typical embryological pattern described for other polychaete families, such as nereidids or spionids. When compared in alternative phylogenetic schemes, these differences represent significant developmental heterochrony, among other evolutionary transitions, which has arisen in the chaetopterid lineage. The heterochrony is correlated with the extreme morphological regionalization along the anterior-posterior body axis, a feature that is also characteristic of chaetopterids.

Published

1999

140. Ancient origins of axial patterning genes: Hox genes and ParaHox genes in the Cnidaria

Author

Mark Q. Martindale and John R. Finnerty

Subjects

animal structures, food.ingredient, Molecular Sequence Data, ParaHox, Nematostella, Homology (biology), Cnidaria, food, Animals, Amino Acid Sequence, Hox gene, Gene, Bilateria, Phylogeny, Ecology, Evolution, Behavior and Systematics, Body Patterning, Genetics, Base Sequence, Sequence Homology, Amino Acid, biology, Phylogenetic tree, Genes, Homeobox, DNA, biology.organism_classification, Homeotic gene, Developmental Biology

Abstract

Among the bilaterally symmetrical, triploblastic animals (the Bilateria), a conserved set of developmental regulatory genes are known to function in patterning the anterior-posterior (AP) axis. This set includes the well-studied Hox cluster genes, and the recently described genes of the ParaHox cluster, which is believed to be the evolutionary sister of the Hox cluster (Brooke et al. 1998). The conserved role of these axial patterning genes in animals as diverse as frogs and flies is believed to reflect an underlying homology (i.e., all bilaterians derive from a common ancestor which possessed an AP axis and the developmental mechanisms responsible for patterning the axis). However, the origin and early evolution of Hox genes and ParaHox genes remain obscure. Repeated attempts have been made to reconstruct the early evolution of Hox genes by analyzing data from the triphoblastic animals, the Bilateria (Schubert et al. 1993; Zhang and Nei 1996). A more precise dating of Hox origins has been elusive due to a lack of sufficient information from outgroup taxa such as the phylum Cnidaria (corals, hydras, jellyfishes, and sea anemones). In combination with outgroup taxa, another potential source of information about Hox origins is outgroup genes (e.g., the genes of the ParaHox cluster). In this article, we present cDNA sequences of two Hox-like genes (anthox2 and anthox6) from the sea anemone, Nematostella vectensis. Phylogenetic analysis indicates that anthox2 (= Cnox2) is homologous to the GSX class of ParaHox genes, and anthox6 is homologous to the anterior class of Hox genes. Therefore, the origin of Hox genes and ParaHox genes occurred prior to the evolutionary split between the Cnidaria and the Bilateria and predated the evolution of the anterior-posterior axis of bilaterian animals. Our analysis also suggests that the central Hox class was invented in the bilaterian lineage, subsequent to their split from the Cnidaria.

Published

1999

141. [Untitled]

Author

Jonathan J. Henry and Mark Q. Martindale

Subjects

Genetic Processes, Late period, biology, Evolutionary biology, Phylum, Ecology, Ecology (disciplines), Secondary loss, Segmentation, Spiralia, Cell lineage, Aquatic Science, biology.organism_classification

Abstract

It is clear that the spiralian developmental program represents a highly flexible platform for the generation of diverse larval and adult body plans. The widespread occurrence of this pattern of early development attests to its tremendous evolutionary success. Despite the large degree of conservation in the spiral cleavage pattern and other basic aspects of early development, changes in cell fate maps and in the mechanisms of blastomere specification have arisen. While we have learned a great deal about this mode of development, a number of important questions remain to be answered. To what extent do these conditions apply to the lesser studied spiralian phyla? What constraints have led to the preservation of the early spiral cleavage program? How has this developmental program been adapted for the construction of the various spiralian body plans (e.g. the segmental body plans of annelids or to the potential secondary loss of segmentation)? Are most changes associated with the elaboration of these different larval and adult body plans restricted to the late period of development? What molecular/genetic processes underlie this developmental program? Clearly, the spiralian phyla represent an important group of organisms for further studies on development and evolution.

Published

1999

142. The evolution of the Hox cluster: insights from outgroups

Author

John R. Finnerty and Mark Q. Martindale

Subjects

Homeodomain Proteins, Phylogenetic tree, Ecology, Hox cluster, Genes, Homeobox, Biology, Ingroups and outgroups, Evolution, Molecular, Taxon, Evolutionary biology, Multigene Family, Genetics, Animals, Humans, Hox gene, Developmental Biology

Abstract

Two burgeoning research trends are helping to reconstruct the evolution of the Hox cluster with greater detail and clarity. First, Hox genes are being studied in a broader phylogenetic sampling of taxa: the past year has witnessed important new data from teleost fishes, onychophorans, myriapods, polychaetes, glossiphoniid leeches, ribbon worms, and sea anemones. Second, commonly accepted notions of animal relationships are being challenged by alternative phylogenetic hypotheses that are causing us to rethink the evolutionary relationships of important metazoan lineages, especially arthropods, annelids, nematodes, and platyhelminthes.

Published

1998

143. The Cell Lineage of a Polyclad Turbellarian Embryo Reveals Close Similarity to Coelomate Spiralians

Author

Mark Q. Martindale, Jonathan J. Henry, and Barbara C. Boyer

Subjects

0106 biological sciences, Mesoderm, Embryo, Nonmammalian, animal structures, Ectoderm, polyclad, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Species Specificity, medicine, Animals, Spiralia, cell lineage, Molecular Biology, 030304 developmental biology, 0303 health sciences, Flatworm, biology, Embryo, Anatomy, Blastomere, Turbellaria, Cell Biology, biology.organism_classification, Biological Evolution, developmental evolution, medicine.anatomical_structure, Evolutionary biology, embryonic structures, Endoderm, Developmental Biology

Abstract

Recent molecular evidence suggests the turbellarian Platyhelminthes may represent the extant basal members of the Spiralia and therefore probably exhibit ancient features of the spiralian developmental program. The stereotypic quartet spiral cleavage pattern of the polyclad turbellarian embryo, among other features, indicates that this group may be closely related to the ancestral flatworm; however, polyclad embryos have been the subject of few experimental studies. Here we report the results of a cell lineage analysis of the embryo of the polycladHoploplana inquilinabased on microinjection of DiI into cleavage-stage blastomeres following formation of each of the four quartets of micromeres. The first quartet gives rise to most of the lateral and anterior ectoderm of the Müller's larva; the second quartet forms largely dorsal and ventral ectoderm as well as the circular muscles; the third quartet forms only small clones of ectoderm; and only the 4d cell of the fourth quartet contributes to larval structure, forming the longitudinal muscles, mesenchyme, and probably endoderm. Our results demonstrate a striking similarity between the cell lineages of polyclad and higher spiralian embryos, in which the four quadrants also bear the same relationships to the larval axes and give rise to comparable larval structures, including derivation of mesoderm from both ectodermal (2b) and endodermal precursors (4d).

Published

1998

144. Conservation of the Spiralian Developmental Program: Cell Lineage of the Nemertean,Cerebratulus lacteus

Author

Jonathan J. Henry and Mark Q. Martindale

Subjects

0106 biological sciences, Mesoderm, Microinjections, Zygote, Ectoderm, 010603 evolutionary biology, 01 natural sciences, Nervous System, 03 medical and health sciences, Endomesoderm, Fate mapping, evolution, medicine, Animals, Cell Lineage, Spiralia, Molecular Biology, 030304 developmental biology, Fluorescent Dyes, Nemertea, 0303 health sciences, biology, spiralians, Embryo, cell specification, Cell Differentiation, Anatomy, Blastomere, Cell Biology, biology.organism_classification, Invertebrates, Cell biology, dorsoventral axis, Clone Cells, medicine.anatomical_structure, Microscopy, Fluorescence, Larva, Cell Division, Developmental Biology

Abstract

Lineage tracers were injected into individual blastomeres in embryos of the indirect-developing nemerteanCerebratulus lacteusthrough the formation of the fourth quartet of micromeres. Subsequent development was followed to the formation of feeding pilidium larvae to establish their ultimate fates. Results showed that these blastomeres have unique fates, and their clones give rise to highly predictable regions of the larval body. As in other spiralians, four discrete cell quadrants can be identified. For the most part, their identities are homologous to the typical spiralian A, B, C, and D cell quadrants. In some respects their fates differ from the typical spiralian fate map; however, these can be understood in terms of simple modifications of the early cleavage program. Unlike most spiralians, the first quartet micromeres in the eight-celled embryo are larger than the corresponding vegetal macromeres, and generate most of the larval ectoderm. All four of these micromeres contribute to the apical organ and generate four bilaterally situated domains of ectoderm, where the progeny of the 1a and 1d micromeres lie to the left of the median plane while those of 1b and 1c lie to the right. Unlike the progeny of the first quartet, those of the second quartet are situated in left (2a), ventral (2b), right (2c), and dorsal (2d) positions. The third quartet micromeres generate clones situated in a bilaterally symmetrical fashion similar to those of the first quartet. The alternating axial relationships exhibited by successive micromere quartets are a characteristic of spiralian development. Unlike other spiralian larvae possessing a ciliary band, the pilidium larval ciliary band is formed by all blastomeres of the first and second micromere quartets, as well as 3c and 3d. Ectomesoderm is derived from two blastomeres (3a and 3b), which give rise to the extensive array of the larval muscle cells.C. lacteusalso possesses a true mesentoblast (4d) which gives rise to a pair of mesodermal bandlets, and scattered mesenchymal cells. The dual origin of the mesoderm, as both ectomesoderm and endomesoderm, appears to be a condition present in all spiralians. The gut is formed by all the fourth quartet micromeres as well as the vegetal macromeres (4A, 4B, 4C, 4D). Despite differences in the determination of axial properties and some modifications in quadrant fates, nemerteans appear to be constructed on the typical spiralian developmental platform.

Published

1998

145. The Development of Radial and Biradial Symmetry: The Evolution of Bilaterality

Author

Jonathan Q. Henry and Mark Q. Martindale

Subjects

Intermediate form, Evolutionary biology, General Earth and Planetary Sciences, Bilateral symmetry, Anatomy, Biology, biology.organism_classification, Bilateria, General Environmental Science

Abstract

SYNOPSIS. Understanding the evolutionary origin of novel metazoan body plans continues to be one of the most sought after answers in biology. Perhaps the most profound change that may have occurred in the Metazoa is the appearance of bilaterally symmetrical forms from a presumably radially symmetrical ancestor. The symmetry properties of bilaterally symmetrical larval and adult metazoans are generally set up during the cleavage period while most “radially” symmetrical cnidarians do not display a stereotyped cleavage program. Ctenophores display biradial symmetry and may represent one intermediate form in the transition to bilateral symmetry. The early development of cnidarians and ctenophores is compared with respect to the timing and mechanisms of axial determination. The origin of the dorsal-ventral axis, and indeed the relationships of the major longitudinal axes, in cnidarians, ctenophores, and bilaterian animals are far from certain. The realization that many of the molecular mechanisms of axial determination are conserved throughout the Bilateria allows one to formulate a set of predictions as to their possible role in the origins of bilaterian ancestors.

Published

1998

146. Homeoboxes in Sea Anemones (Cnidaria; Anthozoa): A PCR-Based Survey of Nematostella vectensis and Metridium senile

Author

Mark Q. Martindale and John R. Finnerty

Subjects

Cnidaria, food.ingredient, Molecular Sequence Data, Nematostella, Polymerase Chain Reaction, Evolution, Molecular, Mice, food, Sequence Homology, Nucleic Acid, Anthozoa, Animals, Amino Acid Sequence, Cloning, Molecular, Phylogeny, Regulator gene, Homeodomain Proteins, Metridium, Base Sequence, Sequence Homology, Amino Acid, biology, Genes, Homeobox, Anatomy, biology.organism_classification, Biological Evolution, Recombinant Proteins, Sea Anemones, Evolutionary biology, Caenorhabditis, Homeobox, Drosophila, General Agricultural and Biological Sciences, Sequence Alignment, Information Systems

Abstract

Homeobox genes belong to a phylogenetically widespread family of regulatory genes that play important roles in pattern formation and cell-fate specification in several model systems (e.g., Drosophila, mouse, and C. elegans). Although the evolution of many classes of homeobox genes predates the diversification of the Bilateria, comparatively little is known about homeobox genes in outgroups to the Bilateria, such as the Cnidaria. We used the polymerase chain reaction to recover 12 partial homeoboxes from 2 species of sea anemones, Metridium senile and Nematostella vectensis (phylum Cnidaria; class Anthozoa). These homeoboxes appear to represent 9 distinct, mutually paralogous homeobox genes, 5 of which belong to previously identified cnidarian homeobox classes, and 4 of which appear to represent previously unidentified classes. The evolutionary relationships between the homeodomains of sea anemones and of bilaterian animals were assessed through database searches and phylogenetic analyses. As many as 5 of the anemone homeoboxes may belong to the Hox class, which suggests that the Hox gene complement of cnidarians is larger than previously expected. Homologs of the even-skipped gene of Drosophila were also identified in both Metridium and Nematostella.

Published

1997

147. A Survey of Homeobox Genes inChaetopterus variopedatusand Analysis of Polychaete Homeodomains

Author

John D. Hunter, Steven Q. Irvine, Mark Q. Martindale, and Sonja A. Warinner

Subjects

Male, animal structures, Cell Adhesion Molecules, Neuronal, Xenopus, Molecular Sequence Data, ParaHox, Xenopus Proteins, Chaetopterus variopedatus, Models, Biological, Polymerase Chain Reaction, Homeobox protein Nkx-2.5, Mice, Gene cluster, Genetics, Animals, Drosophila Proteins, Amino Acid Sequence, Eye Proteins, Hox gene, Molecular Biology, Phylogeny, Ecology, Evolution, Behavior and Systematics, Homeodomain Proteins, Likelihood Functions, Base Sequence, Sequence Homology, Amino Acid, biology, Genes, Homeobox, Polychaeta, HNF1B, biology.organism_classification, embryonic structures, Insect Proteins, Homeobox, Drosophila, Homeotic gene

Abstract

A survey of genomic DNA from the polychaete Chaetopterus variopedatus was conducted using the polymerase chain reaction. Twelve unique homeobox-containing gene fragments were recovered. Phylogenetic analysis indicates that seven of the fragments are from genes belonging to Hox homeobox classes. Other fragments show orthology with Xlox, caudal, and Prh homeobox classes, with two fragments not definitely assignable to a homeobox class by our analysis. Orthology with gene sequences reported for the polychaete Ctenodrilus serratus, by Dick and Buss (1994), was calculated and indicated that at least eight of the C. variopedatus fragments are homologous to these previously reported sequences. Tabulation of the Hox gene relationships suggest that polychaetes have representative genes of each of the Hox cognate groups except Abd-B. This conclusion further suggests that the Hox cluster in the basal protostome ancestor had already undergone the gene duplications leading to the complete complement of homeotic genes known in Drosophila, with the possible loss of Abd-B in the polychaete lineage.

Published

1997

148. Reassessing embryogenesis in the Ctenophora: the inductive role of e1 micromeres in organizing ctene row formation in the ‘mosaic’ embryo, Mnemiopsis leidyi

Author

Mark Q. Martindale and Jonathan J. Henry

Subjects

Embryonic Induction, Blastomeres, biology, Mnemiopsis, Embryogenesis, Embryo, Blastomere, Anatomy, Carbocyanines, biology.organism_classification, Cleavage (embryo), Invertebrates, Embryonic stem cell, Cell biology, Ctenophora, Animals, Molecular Biology, Body Patterning, Fluorescent Dyes, Developmental Biology

Abstract

Ctenophores are a phylum of diploblastic marine animals displaying biradial symmetry organized along an oral aboral axis. One of the apomorphic sets of adult structures in ctenophores are the eight external comb rows, which run along the oral-aboral axis. Comb rows consist of serial arrays of individual comb plates of cilia, which beat in a coordinated fashion for locomotory behavior. Classical cell lineage experiments using chalk particles indicated that comb rows are derived exclusively from the four e1 micromeres at the 16-cell stage. This conclusion was also supported by the fact that no ctene rows (or their underly ing endodermal canals) form when all four e1 micromeres were deleted. We have used intracellular diI cell lineage tracing to determine that, in addition to e1 micromeres, the four m1 micromeres also make significant contributions to the ctene rows. Thus, e1 micromere derivatives not only generate comb plates but are required for ctene row formation by m1 derivatives. These results demonstrate that inductive interactions are an important component of early development in ctenophores and indicate that e1 micromeres influence the development of adjacent cell lineages (both m1 and endodermal lineages) during ctenophore embryogenesis. In addition, intracellular labeling has revealed that there are subtle variations in the composition of clones derived from identified embryonic blastomeres. Together these findings reveal a picture of ctenophore embryogenesis, which is in marked contrast to the former rigid ‘mosaic’ reputation of ctenophore devel opment, and invite speculation as to the role of the cleavage program in embryonic patterning in the lower Metazoa.

Published

1997

149. The origin and evolution of animal appendages

Author

Henry Roehl, Gregory A. Wray, Beverley Sherbon, Billie J. Swalla, Sean B. Carroll, Jennifer K. Grenier, Christopher J. Lowe, Judith Kimble, Mark Q. Martindale, Muriel H. Walker, John F. Fallon, Steven M. Irvine, Grace Panganiban, and Laura S. Corley

Subjects

Insecta, Limb Buds, Nematoda, Annelida, Movement, Molecular Sequence Data, Tetrapod, Eating, Mice, Animals, Amino Acid Sequence, Deep homology, Phylogeny, Homeodomain Proteins, Appendage, Multidisciplinary, Annelid, Sequence Homology, Amino Acid, biology, Lobopodia, Fishes, Genetic Variation, Extremities, Anatomy, Biological Sciences, biology.organism_classification, Biological Evolution, Invertebrates, Echinoderm, Evolutionary biology, Vertebrates, Drosophila, Arthropod, Tube feet, Echinodermata

Abstract

Animals have evolved diverse appendages adapted for locomotion, feeding and other functions. The genetics underlying appendage formation are best understood in insects and vertebrates. The expression of the Distal-less ( Dll ) homeoprotein during arthropod limb outgrowth and of Dll orthologs ( Dlx ) in fish fin and tetrapod limb buds led us to examine whether expression of this regulatory gene may be a general feature of appendage formation in protostomes and deuterostomes. We find that Dll is expressed along the proximodistal axis of developing polychaete annelid parapodia, onychophoran lobopodia, ascidian ampullae, and even echinoderm tube feet. Dll/Dlx expression in such diverse appendages in these six coelomate phyla could be convergent, but this would have required the independent co-option of Dll/Dlx several times in evolution. It appears more likely that ectodermal Dll/Dlx expression along proximodistal axes originated once in a common ancestor and has been used subsequently to pattern body wall outgrowths in a variety of organisms. We suggest that this pre-Cambrian ancestor of most protostomes and the deuterostomes possessed elements of the genetic machinery for and may have even borne appendages.

Published

1997

150. The Genome of the Ctenophore Mnemiopsis leidyi and Its Implications for Cell Type Evolution

Author

James C. Mullikin, Bernard Koch, Tyra G. Wolfsberg, Paul Havlak, Joseph F. Ryan, Mark Q. Martindale, Christine E. Schnitzler, Andreas D. Baxevanis, Anh Dao Nguyen, R. Travis Moreland, Steven H. D. Haddock, Nicholas H. Putnam, Stephen A. Smith, David Simmons, Kevin Pang, Warren R. Francis, and Casey W. Dunn

Subjects

Genome, Multidisciplinary, Base Sequence, Mnemiopsis, Ctenophora, Neurogenesis, Molecular Sequence Data, Anatomy, Biology, Muscle Development, biology.organism_classification, Biological Evolution, Amphimedon queenslandica, Mesoderm, Evolutionary biology, Phylogenetics, Trichoplax, Animals, Placozoa, Cell Lineage, Gene, Phylogeny

Abstract

An understanding of ctenophore biology is critical for reconstructing events that occurred early in animal evolution. Toward this goal, we have sequenced, assembled, and annotated the genome of the ctenophore Mnemiopsis leidyi. Our phylogenomic analyses of both amino acid positions and gene content suggest that ctenophores rather than sponges are the sister lineage to all other animals. Mnemiopsis lacks many of the genes found in bilaterian mesodermal cell types, suggesting that these cell types evolved independently. The set of neural genes in Mnemiopsis is similar to that of sponges, indicating that sponges may have lost a nervous system. These results present a newly supported view of early animal evolution that accounts for major losses and/or gains of sophisticated cell types, including nerve and muscle cells.

Published

2013