Transmission electron microscopy of marine crustacean eggs

Ultrastructural investigations of eggs can be important in helping to understand embryonic development. There are few transmission electron microscope studies of marine arthropod eggs, however, as they have proved difficult to fix and infiltrate with resin. Here, we describe a modification of a standard method that allows the preparation of the quite different eggs of the marine copepod, Acartia tonsa and the lobster, Homarus gammarus, for transmission electron microscopy. By using double fixation and an extended resin infiltration time we obtained good preparations for electron microscopy. We anticipate that these modifications to the standard protocol will be widely applicable and useful for the study of the eggs and early developmental stages of many marine arthropod taxa. Les recherches sur l'ultrastructure des oeufs peuvent être importantes en aidant à comprendre le développement embryonnaire. Il existe cependant peu d'études en microscopie électronique à transmission sur les oeufs d'arthropodes marins, car il est difficile de les fixer et d'y infiltrer de la résine. Dans ce travail, nous décrivons une modification de la méthode standard, qui permet la préparation pour la microscopie électronique à transmission d'oeufs aussi différents que ceux du copépode marin Acartia tonsa et du homard Homarus gammarus. En utilisant une double fixation et un temps plus long d'infiltration de la résine, nous avons obtenu de bonnes préparations pour la microscopie électronique. Nous prévoyons que ces modifications du protocole standard seront largement applicables et utiles pour l'étude des oeufs et des premiers stades de développement de nombreux taxons d'arthropodes marins.

Genetic analysis of Continuous Plankton Recorder (CPR) samples

Genetic analysis of Continuous Plankton Recorder (CPR) samples is enabling greater taxonomic resolution and the study of plankton population structure. Here, we present some results from the genetic analysis of CPR samples collected in the North Sea and north-eastern Atlantic that reveal the impacts of climate on benthic-pelagic coupling and the food web. We show that pronounced changes in the North Sea meroplankton are related to an increased abundance and spatial distribution of the larvae of the benthic echinoderm, Echinocardium cordatum. Key stages of reproduction in E. cordatum, gametogenesis and spawning, are influenced by winter and spring sea temperature (January-May). A stepwise increase in sea temperature after 1987, which has created warmer conditions earlier in the year, together with increased summer phytoplankton, may benefit the reproduction and survival of this benthic species. Competition between the larvae of E. cordatum and other holozooplanlcton taxa may now be altering the trophodynamics of the summer pelagic ecosystem. In the north-eastern Atlantic the genetic analysis of fish larvae sampled by the CPR has revealed an unprecedented increase in the abundance of juvenile snake pipefish, Entelurus aequoreiis since 2002. We argue that increased sea surface temperatures in winter and spring when the eggs of E. aqueoreus, which are brooded by the male, are developing and the young larvae are growing in the plankton are a likely cause. The increased abundance of this species in Atlantic and adjacent European seas already appears to be influencing the marine food web.