Edmund J. Stellwag

Genomic organization of the Hoxa4-Hoxa10 region from Morone saxatilis: implications for Hox gene evolution among vertebrates.

The physical mapping of Hox gene clusters from a limited number of vertebrates has shown an overall conservation in gene organization in which major evolutionary changes appear to be primarily restricted to the deletion of one or more genes, with the exception of the amplification of additional clusters as postulated from zebrafish. We have sequenced a 31 kb region of the HoxA cluster from the teleost Morone saxatilis (striped bass), both to provide a detailed physical map of this region and to better understand the nature of Hox cluster evolution among vertebrate taxa. We identified five linked Hox genes: Hoxa4, Hoxa5, Hoxa7, Hoxa9, and Hoxa10, which are organized similarly to those of other vertebrates. Furthermore, we have documented the absence of the Hoxa6 and Hoxa8 genes within the 31 kb contig. Comparison of our results to those published for other vertebrates suggests that the absence of Hoxa6 is a common characteristic of teleosts, whereas the absence of Hoxa8 is common to vertebrates in general, with the possible exception of zebrafish. Further comparisons between the HoxA genes from Morone with those from the pufferfish, Fugu rubripes, revealed the likely presence of a previously unreported Hoxa7 gene, or gene fragment, in the Fugu genome, which suggests that the Hoxa7 gene, unlike Hoxa6 or Hoxa8, is present in teleosts. In addition to these differences in vertebrate Hox cluster structure, we also observed a marked reduction in the length of the Hoxa4--a10 region between vertebrate lineages representative of teleosts and mammals. Comparative analysis of HoxA cluster organization among teleosts and mammals suggests that cluster length reduction and lineage-specific gene loss events are hallmarks of Hox cluster evolution.

Nuclear Progestin Receptor (Pgr) Knockouts in Zebrafish Demonstrate Role for Pgr in Ovulation but Not in Rapid Non-Genomic Steroid Mediated Meiosis Resumption

Progestins, progesterone derivatives, are the most critical signaling steroid for initiating final oocyte maturation (FOM) and ovulation, in order to advance fully-grown immature oocytes to become fertilizable eggs in basal vertebrates. It is well-established that progestin induces FOM at least partly through a membrane receptor and a non-genomic steroid signaling process, which precedes progestin triggered ovulation that is mediated through a nuclear progestin receptor (Pgr) and genomic signaling pathway. To determine whether Pgr plays a role in a non-genomic signaling mechanism during FOM, we knocked out Pgr in zebrafish using transcription activator-like effector nucleases (TALENs) and studied the oocyte maturation phenotypes of Pgr knockouts (Pgr-KOs). Three TALENs-induced mutant lines with different frame shift mutations were generated. Homozygous Pgr-KO female fish were all infertile while no fertility effects were evident in homozygous Pgr-KO males. Oocytes developed and underwent FOM normally in vivo in homozygous Pgr-KO female compared to the wild-type controls, but these mature oocytes were trapped within the follicular cells and failed to ovulate from the ovaries. These oocytes also underwent normal germinal vesicle breakdown (GVBD) and FOM in vitro, but failed to ovulate even after treatment with human chronic gonadotropin (HCG) or progestin (17α,20β-dihydroxyprogesterone or DHP), which typically induce FOM and ovulation in wild-type oocytes. The results indicate that anovulation and infertility in homozygous Pgr-KO female fish was, at least in part, due to a lack of functional Pgr-mediated genomic progestin signaling in the follicular cells adjacent to the oocytes. Our study of Pgr-KO supports previous results that demonstrate a role for Pgr in steroid-dependent genomic signaling pathways leading to ovulation, and the first convincing evidence that Pgr is not essential for initiating non-genomic progestin signaling and triggering of meiosis resumption.

Prolactin-dependent modulation of organogenesis in the vertebrate: Recent discoveries in zebrafish☆

The scientific literature is replete with evidence of the multifarious functions of the prolactin (PRL)/growth hormone (GH) superfamily in adult vertebrates. However, little information is available on the roles of PRL and related hormones prior to the adult stage of development. A limited number of studies suggest that GH functions to stimulate glucose transport and protein synthesis in mouse blastocytes and may be involved during mammalian embryogenesis. In contrast, the evidence for a role of PRL during vertebrate embryogenesis is limited and controversial. Genes encoding GH/PRL hormones and their respective receptors are actively transcribed and translated in various animal models at different time points, particularly during tissue remodeling. We have addressed the potential function of GH/PRL hormones during embryonic development in zebrafish by the temporary inhibition of in vivo PRL translation. This treatment caused multiple morphological defects consistent with a role of PRL in embryonic-stage organogenesis. The affected organs and tissues are known targets of PRL activity in fish and homologous structures in mammalian species. Traditionally, the GH/PRL hormones are viewed as classical endocrine hormones, mediating functions through the circulatory system. More recent evidence points to cytokine-like actions of these hormones through either an autocrine or a paracrine mechanism. In some situations they could mimic actions of developmentally regulated genes as suggested by experiments in multiple organisms. In this review, we present similarities and disparities between zebrafish and mammalian models in relation to PRL and PRLR activity. We conclude that the zebrafish could serve as a suitable alternative to the rodent model to study PRL functions in development, especially in relation to organogenesis.

Chemical dispersant potentiates crude oil impacts on growth, reproduction, and gene expression in Caenorhabditis elegans

The economic, environmental, and human health impacts of the deepwater horizon (DWH) oil spill have been of significant concern in the general public and among scientists. This study employs parallel experiments to test the effects of crude oil from the DWH oil well, chemical dispersant Corexit 9500A, and dispersant-oil mixture on growth and reproduction in the model organism Caenorhabditis elegans. Both the crude oil and the dispersant significantly inhibited the reproduction of C. elegans. Dose-dependent inhibitions of hatched larvae production were observed in worms exposed to both crude oil and dispersant. Importantly, the chemical dispersant Corexit 9500A potentiated crude oil effects; dispersant-oil mixture induced more significant effects than oil or dispersant-alone exposures. While oil-alone exposure and dispersant-alone exposure have none to moderate inhibitory effects on hatched larvae production, respectively, the mixture of dispersant and oil induced much more significant inhibition of offspring production. The production of hatched larvae was almost completely inhibited by several high concentrations of the dispersant-oil mixture. This suggests a sensitive bioassay for future investigation of oil/dispersant impacts on organisms. We also investigated the effects of crude oil/dispersant exposure at the molecular level by measuring the expressions of 31 functional genes. Results showed that the dispersant and the dispersant-oil mixture induced aberrant expressions of 12 protein-coding genes (cat-4, trxr-2, sdhb-1, lev-8, lin-39, unc-115, prdx-3, sod-1, acr-16, ric-3, unc-68, and acr-8). These 12 genes are associated with a variety of biological processes, including egg-laying, oxidative stress, muscle contraction, and neurological functions. In summary, the toxicity potentiating effect of chemical dispersant must be taken into consideration in future crude oil cleanup applications.

Comparative analysis of Hox paralog group 2 gene expression during Nile tilapia (Oreochromis niloticus) embryonic development

The hindbrain and pharyngeal arch-derived structures of vertebrates are determined, at least in part, by Hox paralog group 2 genes. In sarcopterygians, the Hoxa2 gene alone appears to specify structures derived from the second pharyngeal arch (PA2), while in zebrafish (Danio rerio), either of the two Hox PG2 genes, hoxa2b or hoxb2a, can specify PA2-derived structures. We previously reported three Hox PG2 genes in striped bass (Morone saxatilis), including hoxa2a, hoxa2b, and hoxb2a and observed that only HoxA cluster genes are expressed in PA2, indicative that they function alone or together to specify PA2. In this paper, we present the cloning and expression analysis of Nile tilapia (Oreochromis niloticus) Hox PG2 genes and show that all three genes are expressed in the hindbrain and in PA2. The expression of hoxb2a in PA2 was unexpected given the close phylogenetic relationship of Nile tilapia and striped bass, both of which are members of the order Perciformes. A reanalysis of striped bass hoxb2a expression demonstrated that it is expressed in PA2 with nearly the same temporal and spatial expression pattern as its Nile tilapia ortholog. Further, we determined that Nile tilapia and striped bass hoxa2a orthologs are expressed in PA2 well beyond the onset of chondrogenesis whereas neither hoxa2b nor hoxb2a expression persist until this stage, which, according to previous hypotheses, suggests that hoxa2a orthologs in these two species function alone as selector genes of PA2 identity.

Role of Hox PG2 genes in Nile tilapia pharyngeal arch specification: implications for gnathostome pharyngeal arch evolution.

SUMMARY Phylogenetic reconstructions suggest that the ancestral osteichthyan Hox paralog group 2 gene complement was composed of two genes, Hoxa2 and b2, both of which have been retained in tetrapods, but only one of which functions as a selector gene of second pharyngeal arch identity (PA2). Genome duplication at the inception of the teleosts likely generated four Hox PG2 genes, only two of which, hoxa2b and b2a, have been preserved in zebrafish, where they serve as functionally redundant PA2 selector genes. Evidence from our laboratory has shown that other telelosts, specifically striped bass and Nile tilapia, harbor three transcribed Hox PG2 genes, hoxa2a, a2b, and b2a, with unspecified function(s). We have focused on characterizing the function of the three Nile tilapia Hox PG2 genes as a model to examine the effects of postgenome duplication gene loss on the evolution of developmental gene function. We studied Hox PG2 gene function in tilapia by examining the effects of independent morpholino oligonucleotide (MO)‐induced knockdowns on pharyngeal arch morphology and Hox gene expression patterns. Morphological defects resulting from independent MO‐induced knockdowns of tilapia hoxa2a, a2b, and b2a included the expected PA2 to PA1 homeotic transformations previously observed in tetrapods and zebrafish, as well as concordant and unexpected morphological changes in posterior arch‐derived cartilages. Of particular interest, was the observation of a MO‐induced supernumerary arch between PA6 and PA7, which occurred concomitantly with other MO‐induced pharyngeal arch defects. Beyond these previously unreported morphant‐induced transformations, a comparison of Hox PG2 gene expression patterns in tilapia Hox PG2 morphants were indicative of arch‐specific auto‐ and cross‐regulatory activities as well as a Hox paralog group 2 interdependent regulatory network for control of pharyngeal arch specification.

Embryonic Development and Skeletogenesis of the Pharyngeal Jaw Apparatus in the Cichlid Nile Tilapia (Oreochromis niloticus)

The evolution of a specialized pharyngeal jaw apparatus (PJA) has been argued to be the key evolutionary innovation that allowed the explosive adaptive radiation of cichlid fishes in East African lakes. Subsequent studies together with recent molecular phylogenies have shown that similar innovations evolved independently several times within the teleosts, which poses the questions: (1) how similar are the developmental mechanisms responsible for these changes in divergent taxa and (2) how did such complex features arise independently in evolution? A detailed knowledge of PJA development in cichlids and other teleosts is needed to address these questions. Here, we provide a detailed account of the development of the PJA in one species of cichlid, the Nile tilapia (Oreochromis niloticus), from the early segmentation and patterning of its embryonic precursors – pharyngeal arches 3 to 7 – to its ossification. We find that pharyngeal segmentation occurs sequentially from anterior to posterior during early segmentation stages through the mid‐pharyngula period. We show a clear combinatorial code of Hox gene expression such that each posterior arch is defined by a distinctive Hox signature. Posterior arch chondrogenesis in tilapia is essentially complete by the end of the hatching period, and most elements become ossified over the next two days. Our results reveal that both the fusion of lower jaw bones and articulation between the neurocranium and upper jaws occur during post‐embryonic development. Abstract end data should be: Anat Rec, 2009.

Japanese Medaka Hox Paralog Group 2 : Insights Into the Evolution of Hox PG2 Gene Composition and Expression in the Osteichthyes

Hox paralog group 2 (PG2) genes function to specify the development of the hindbrain and pharyngeal arch-derived structures in the Osteichthyes. In this article, we describe the cDNA cloning and embryonic expression analysis of Japanese medaka (Oryzias latipes) Hox PG2 genes. We show that there are only two functional canonical Hox genes, hoxa2a and b2a, and that a previously identified hoxa2b gene is a transcribed pseudogene, psihoxa2b. The functional genes, hoxa2a and b2a, were expressed in developing rhombomeres and pharyngeal arches in a manner that was relatively well conserved compared with zebrafish (Danio rerio) but differed significantly from orthologous striped bass (Morone saxatilis) and Nile tilapia (Oreochromis niloticus) genes, which, we suggest, may be owing to effects of post-genome duplication loss of a Hox PG2 gene in the medaka and zebrafish lineages. psihoxa2b was expressed at readily detectable levels in several noncanonical Hox expression domains, including the ventral aspect of the neural tube, the pectoral fin buds and caudal-most region of the embryonic trunk, indicative that regulatory control elements needed for spatio-temporal expression have diverged from their ancestral counterparts. Comparative expression analyses showed medaka hoxa2a and b2a expression in the 2nd pharyngeal arch (PA2) beyond the onset of chondrogenesis, which, according to previous hypotheses, suggests these genes function redundantly as selector genes of PA2 identity. We conclude that Hox PG2 gene composition and expression have diverged significantly during osteichthyan evolution and that this divergence in teleosts may be related to lineage-dependent differential gene loss following an actinopterygian-specific whole genome duplication.

Spatio-temporal patterns of Hox paralog group 3–6 gene expression during Japanese medaka (Oryzias latipes) embryonic development

Clustered Hox genes encode transcription factors that pattern the regional identities of tissues along the anterior-posterior (A-P) axis of animals during embryonic development. They are expressed along the A-P axis collinear with their physical location within a cluster. Several studies have examined the expression of teleost Hox genes from paralog groups (PG) 1-4 in the rhombomeres of the hindbrain and the anterior pharyngeal arches. However, little is known about Hox gene expression within the posterior pharyngeal arches (PA3-7) of teleosts. Here we present the spatio-temporal expression patterns of Hox paralog group (PG) 3-6 in the neural tube and posterior arches of the Japanese medaka (Oryzias latipes). We show that medaka Hox gene expression patterns in the hindbrain are divergent spatially from orthologous genes in mouse and other evolutionarily divergent teleosts, which suggests divergence of cis-regulatory sequences directing hindbrain expression. Further, our study is the first to show the complete teleost Hox PG3-6 expression code in the posterior arches up to the chondrogenic stage of the cranio-facial skeletal elements. This study will provide the basis for comparative teleost Hox gene expression profiles in PA3-7 and may help in understanding the mechanisms underlying development of divergent morphological pharyngeal arch skeletal structures among evolutionarily divergent teleosts.

Are Genome Evolution, Organism Complexity and Species Diversity Linked?

Abstract Fishes represent an extremely diverse group of vertebrates with a deeply rooted evolutionary history. An understanding of their biology is being enriched by advancements in phylogenetic analysis and genomics, which are providing the framework for deciphering their evolutionary relationships and the molecular details that govern their evolution. Recent discoveries about the structure and function of fish genomes suggest the occurrence of large-scale genome level duplications within the stem lineage of the Actinopterygii (ray-finned fishes). However, little is understood about the effects, if any, of this event in relation to organismal complexity or species diversity. In this manuscript, I propose a hypothesis to test whether there is a likely relationship linking vertebrate genomes, organisms and species diversity. In so doing, I discuss the problems inherent in defining the complexity of genomes and organisms and provide simplifying assumptions that enable a preliminary test of the hypothesis. Results of this test suggest the likelihood of linkage between large-scale genome changes and organismal complexity early in vertebrate evolution but not in the evolution of the ray-finned fishes. A particularly interesting implication of the results is that there may be a limit to the effects of genome level duplications on organismal complexity and species diversity.