Your search keyword '"E. Schwager"' showing total 3 results

1. Distal-lessanddachshundpattern both plesiomorphic and apomorphic structures in chelicerates: RNA interference in the harvestmanPhalangium opilio(Opiliones)

Author

Gonzalo Giribet, Evelyn E. Schwager, Elizabeth L. Jockusch, Cassandra G. Extavour, and Prasahant P. Sharma

Subjects

Appendage, biology, Dachshund, Opiliones, Anatomy, biology.organism_classification, Arthropod mouthparts, Phalangium opilio, Evolutionary biology, Chelicerata, Arthropod, Ecology, Evolution, Behavior and Systematics, Arthropod leg, Developmental Biology

Abstract

SUMMARY The discovery of genetic mechanisms that can transform a morphological structure from a plesiomorphic (¼primitive) state to an apomorphic (¼derived) one is a cardinal objective of evolutionary developmental biology. However, this objective is often impeded for many lineages of interest by limitations in taxonomic sampling, genomic resources, or functional genetic methods. In order to investigate the evolution of appendage morphology within Chelicerata, the putative sister group of the remaining arthropods, we developed an RNA interference (RNAi) protocol for the harvestmanPhalangiumopilio.Wesilencedtheleggapgenes Distal‐less (Dll) and dachshund (dac) in the harvestman via zygotic injections of double‐stranded RNA (dsRNA), and used in situ hybridization to confirm RNAi efficacy. Consistent with the conserved roles of these genes in patterning the proximo‐ distal axis of arthropod appendages, we observed that embryos injected with Dll dsRNA lacked distal parts of appendages and appendage‐like structures, such as the labrum, the chelicerae, the pedipalps, and the walking legs, whereas embryos injected with dac dsRNA lacked the medial podomeres femur and patella in the pedipalps and walking legs. In addition, we detected a role for these genes in patterning structures that do not occur in well‐established chelicerate models (spiders and mites). Dll RNAi additionally results in loss of the preoral chamber, which is formed from pedipalpal and leg coxapophyses, and the ocularium, a dorsal outgrowth bearing the eyes. In one case, we observed that an embryo injected with dac dsRNA lacked the proximal segment of the chelicera, a plesiomorphic podomere that expresses dac in wild‐type embryos. This may support the hypothesis thatlossofthecheliceraldacdomainunderliesthetransitionto the two‐segmented chelicera of derived arachnids.

Published

2013

2. Evolution of the chelicera: adachshunddomain is retained in the deutocerebral appendage of Opiliones (Arthropoda, Chelicerata)

Author

Cassandra G. Extavour, Evelyn E. Schwager, Prashant P. Sharma, and Gonzalo Giribet

Subjects

Appendage, Arachnid, biology, Dachshund, Opiliones, Anatomy, biology.organism_classification, eye diseases, Arthropod mouthparts, Evolutionary biology, Chelicerata, Arthropod, Ecology, Evolution, Behavior and Systematics, Arthropod leg, Developmental Biology

Abstract

The proximo-distal axis of the arthropod leg is patterned by mutually antagonistic developmental expression domains of the genes extradenticle, homothorax, dachshund, and Distal-less. In the deutocerebral appendages (the antennae) of insects and crustaceans, the expression domain of dachshund is frequently either absent or, if present, is not required to pattern medial segments. By contrast, the dachshund domain is entirely absent in the deutocerebral appendages of spiders, the chelicerae. It is unknown whether absence of dachshund expression in the spider chelicera is associated with the two-segmented morphology of this appendage, or whether all chelicerates lack the dachshund domain in their chelicerae. We investigated gene expression in the harvestman Phalangium opilio, which bears the plesiomorphic three-segmented chelicera observed in "primitive" chelicerate orders. Consistent with patterns reported in spiders, in the harvestman chelicera homothorax, extradenticle, and Distal-less have broadly overlapping developmental domains, in contrast with mutually exclusive domains in the legs and pedipalps. However, unlike in spiders, the harvestman chelicera bears a distinct expression domain of dachshund in the proximal segment, the podomere that is putatively lost in derived arachnids. These data suggest that a tripartite proximo-distal domain structure is ancestral to all arthropod appendages, including deutocerebral appendages. As a corollary, these data also provide an intriguing putative genetic mechanism for the diversity of arachnid chelicerae: loss of developmental domains along the proximo-distal axis.

Published

2012

3. Hox gene expression in the harvestman Phalangium opilio reveals divergent patterning of the chelicerate opisthosoma

Author

Cassandra G. Extavour, Evelyn E. Schwager, Prashant P. Sharma, and Gonzalo Giribet

Subjects

Arachnid, animal structures, biology, Opisthosoma, Anatomy, Opiliones, biology.organism_classification, Phalangium opilio, Phylogenetics, Evolutionary biology, embryonic structures, Homeobox, Hox gene, Gene, Ecology, Evolution, Behavior and Systematics, Developmental Biology

Abstract

Among chelicerates, Hox gene expression has only been investigated in representatives of two arachnid orders to date: Acari (mites and ticks) and Araneae (spiders). Limited data are available for the "primitive" arachnid orders, such as Scorpiones (scorpions) and Opiliones (harvestmen). Here, we present the first data on Hox gene expression in the harvestman Phalangium opilio. Ten Hox genes of this species were obtained from a de novo assembled developmental transcriptome using the Illumina GAII platform. All 10 genes are expressed in characteristic Hox-like expression patterns, and the expression of the anterior and central Hox genes is similar to those of other chelicerates. However, intriguingly, the three posteriormost genes-Ultrabithorax, abdominal-A, and Abdominal-B-share an identical anterior expression boundary in the second opisthosomal segment, and their expression domains extend through the opisthosoma to the posterior growth zone. The overlap in expression domains of the posterior Hox genes is correlated with the absence of opisthosomal organs posterior to the tubular tracheae, which occur on the second opisthosomal segment. Together with the staggered profile of posterior Hox genes in spiders, these data suggest the involvement of abdominal-A and Abdominal-B in the evolution of heteronomous patterning of the chelicerate opisthosoma, providing a mechanism that helps explain the morphological diversity of chelicerates.

Published

2012