Molecular biodiversity. Case study: Porifera (sponges)

Biological diversity--or biodiversity--is the term given to the variety of life on Earth and the natural patterns it forms. The biodiversity we see today is the fruit of billions of years of evolution, shaped by natural processes and, increasingly, by the influence of humans. It forms the web of life of which we are an integral part and upon which we so fully depend. The research on molecular biodiversity tries to lay the scientific foundation of a rational conservation policy that has its roots in various disciplines including systematics/taxonomy (species richness), present day ecology (diversity of ecological systems), and functional genetics (genetic diversity). The results of ongoing genome analyses (genome projects and expressed sequence tag projects) and the achievements of molecular evolution may allow us not only to quantitate the diversity of the present biota but also to extrapolate to their diversification in the future. A link between biodiversity and genomics/molecular evolution will create a platform which we hope may facilitate a sustainable management of organismic life and ensure its exploitation for human benefit. In the present review we outline possible strategies, using the Porifera (sponges) as a prominent example. On the basis of solid taxonomy and ecological data, the high value of this phylum for human application becomes obvious, especially with regard to the field of chemical ecology and the desire to find novel potential drugs for clinical use. In addition, the benefit of trying to make sense of molecular biodiversity using sponges as an example can be seen in the fact that the study of these animals, which are "living fossils", gives us a good insight into the history of our planet, especially with respect to the evolution of Metazoa.     

Hierarchien in der Struktur und Funktion von sauerstoffbindenden Proteinen

The structures of respiratory proteins such as hemoglobins and hemocyanins show obvious hierarchies. They belong to the class of allosteric macromolecules with cooperative functional properties, as do key metabolic enzymes. When examining the molecular mechanisms on which allostery and cooperativity are based, it could be shown for arthropod hemocyanins that the structural hierarchy of these macromolecules is reflected in a functional hierarchy. This relationship is described quantitatively in the "nesting" model. This model also offers explanations for the physiological significance of the prominent hierarchy of these molecules.     

Sauerstoff und Kohlendioxid — Schlüsselverbindungen des Lebens

Für Anregungen danken wir den Professoren P. Böger, P. Fabian, H. Flohn, M. Schidlowski und F. Wagner.