Matthias Gerberding scite author profile

Studying the relationship between development and evolution and its role in the generation of biological diversity has been reinvigorated by new techniques in genetics and molecular biology. However, exploiting these techniques to examine the evolution of development requires that a great deal of detail be known regarding the embryonic development of multiple species studied in a phylogenetic context. Crustaceans are an enormously successful group of arthropods and extant species demonstrate a wide diversity of morphologies and life histories. One of the most speciose orders within the Crustacea is the Amphipoda. The embryonic development of a new crustacean model system, the amphipod Parhyale hawaiensis, is described in a series of discrete stages easily identified by examination of living animals and the use of commonly available molecular markers on fixed specimens. Complete embryogenesis occurs in 250 h at 26 degrees C and has been divided into 30 stages. This staging data will facilitate comparative analyses of embryonic development among crustaceans in particular, as well as between different arthropod groups. In addition, several aspects of Parhyale embryonic development make this species particularly suitable for a broad range of experimental manipulations.

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Cell lineage analysis of the amphipod crustaceanParhyale hawaiensisreveals an early restriction of cell fates

Gerberding

Browne

Patel

2002

118

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In the amphipod crustacean, Parhyale hawaiensis, the first few embryonic cleavages are total and generate a stereotypical arrangement of cells. In particular, at the eight-cell stage there are four macromeres and four micromeres, and each of these cells is uniquely identifiable. We describe our studies of the cell fate pattern of these eight blastomeres, and find that the eight clones resulting from these cells set up distinct cell lineages that differ in terms of proliferation, migration and cell fate. Remarkably, the cell fate of each blastomere is restricted to a single germ layer. The ectoderm originates from three of the macromeres, while the remaining macromere generates the visceral mesoderm. Two of the micromeres generate the somatic mesoderm, a third micromere generates the endoderm and the fourth micromere generates the germline. These findings demonstrate for the first time a total cleavage pattern in an arthropod which results in an invariant cell fate of the blastomeres, but notably, the cell lineage pattern of Parhyale reported shows no clear resemblance to those found in spiralians, nematodes or deuterostomes. Finally, the techniques we have developed for the analysis of Parhyale development suggest that this arthropod may be particularly useful for future functional analyses of crustacean development.

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Germ cells in the crustacean Parhyale hawaiensis depend on Vasa protein for their maintenance but not for their formation

Özhan

Havemann

Gerberding

2009

Developmental Biology

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Germ cells are a population of cells that do not differentiate to form somatic tissue but form the egg and sperm that ensure the reproduction of the organism. To understand how germ cells form, holds a key for identifying what sets them apart from all other cells of the organism. There are large differences between embryos regarding where and when germ cells form but the expression of Vasa protein is a common trait of germ cells. We studied the role of vasa during germ cell formation in the crustacean Parhyale hawaiensis. In a striking difference to the posterior specification of the group of germ cells in the arthropod model Drosophila, all germ cells in Parhyale originate from a single germ line progenitor cell of the 8-cell stage. We found vasa RNA ubiquitously distributed from 1-cell to 16-cell stage in Parhyale and localized to the germ cells from 32-cell stage onwards. Localization of vasa RNA to the germ cells is controlled by its 3'UTR and this could be mimicked by fluorescently labeled 3'UTR RNA. Vasa protein was first detectable at the 100-cell stage. MO-mediated inhibition of vasa translation caused germ cells to die after gastrulation. This means that in Parhyale Vasa protein is not required for the initial generation of the clone of germ cells but is required for their subsequent proliferation and maintenance. It also means that the role of vasa changed substantially during an evolutionary switch in the crustaceans by Parhyale from the specification of a group of germ cells to that of a single germ line progenitor. This is the first functional study of vasa in an arthropod beyond Drosophila.

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