Excessive abundance and dynamics of unusual ecdysteroids in Pycnogonum litorale ström (Arthropoda, Pantopoda).

In embryos, larvae, and juveniles of Pycnogonum litorale, unusual ecdysteroids have been found at excessively high levels. Concentrations and dynamics of the following eight ecdysteroids were determined by HPLC: 20-hydroxyecdysone, 20-hydroxyecdysone 22-glycolate, (25R) and (25S) isomers of 20,26-dihydroxyecdysone 22-acetate, 22-deoxy-20,26-dihydroxyecdysone, 20-hydroxyecdysone 22-acetate, 22-deoxy-20-hydroxyecdysone, and ecdysone 22-glycolate. The excessively high content of ecdysteroids is found in all developmental stages. Juvenile pycnogonids contain the highest total ecdysteroid amounts ever found in arthropods: 0.1% of their body dry weight. 20-Hydroxyecdysone 22-acetate is the prominent ecdysteroid and represents at all stages of both sexes, 66.2-85.8% of the total ecdysteroids. This compound, as well as all other ecdysteroids without a free 22-OH group, are presumed to be inactive as molting hormones. In contrast to these compounds, 20-hydroxyecdysone is present only in amounts similar to those in other arthropods. Furthermore, it is the only ecdysteroid with its peak at apolysis. It is regarded as the molt-promoting hormone. The origin and function of the other ecdysteroids in different developmental stages are discussed.

20-Hydroxyecdysone stimulates molting in pycnogonid larvae (Arthropoda, Pantopoda).

Molting in pycnogonid larvae, Pycnogonum litorale, is accelerated by exposing the animals to 20-hydroxyecdysone at concentrations of 10 to 1000 ppm during Days 5 to 9 after the first ecdysis. Hormone application at the beginning or at the end of the molt cycle, as well as treatment all through the molt cycle, delays or even inhibits the molt by upsetting the sequence of molting processes.

Common origin and phylogenetic diversification of animal hormonal systems.

The comparative view leads to the following main conclusions: Hormones are intercellular messengers in multicellular organisms. However, the receptor mechanism, the ability of forming receptors to substances in the cell's environment and the ability to synthesize most of the substances which serve as hormones in metazoans, are present in unicellular organisms, too. The main achievement of multicellular organisms in evolving hormonal mechanisms is due to their ability of differentiation. Though the whole genome and the ability to synthesize certain substances is, in principle, common to all body cells, the forming of certain substances and the ability to react to them in a certain way is delegated to certain cell groups only. This may be common to many intercellular messenger substances such as chalons, prostaglandins, morphogenetic and tissue-specific growth substances. A special feature in hormonal systems is that the two sites of release and reaction are distinct and are located at a distance from each other. Possibly this is the main or even the only difference from other intercellular messengers. However, it is of great functional importance because it enables hormones to control the temporal coordination of entirely different processes in different tissues located at a distance from each other or distributed all over the body. This feature is common to all compounds presently known as hormones. While the localization of receptors in target cells, as well as the nature of the releasing tissue or the mode of transport through the blood, may be too marrow borders for a definition (for instance in animal groups without a closed blood circulation system) the fact that there is transport over a distance is not. The fact that release and reaction sites are located at a distance from each other within the multicellular body may serve as a definition of "hormones' based on a common phylogenetic root and functional importance. On this common base different animal phyla have evolved different hormonal systems in relation to the particular problems of long distance temporal control of physiological processes posed by their special type of organization.

Ecdysteroids in the pycnogonid Pycnogonum litorale (STROM) (Arthropoda, Pantopoda).

Two ecdysteroids were isolated from juveniles and adults as well as from eggs of the pycnogonid Pycnogonum litorale Ström and characterized by bioassay, thin layer chromatography, gas liquid chromatography, and high performance liquid chromatography. One of the hormones could be identified as 20-hydroxyecdysone whereas the other behaves in HPLC in a way that is similar to but not identical with ecdysone. This unidentified ecdysone-like hormone exceeded 20-hydroxyecdysone in all developmental stages (1.67:1 to 3:1). Determination of moulting hormone titers by a radioimmunoassay showed highest amounts of hormones in juvenile females (150 ng/mg tissue dry wt). The results are compared with those obtained from other arthropods and are discussed in view of the evolution of hormonal systems.