Über den bau der eischale von bulimus (Helicidae)

Zusammenfassung Der kohlensaure Kalk der untersuchten Helicideneischalen — Bulimus maximus (Durchmesser der Schale 23,6 x 25,1 mm, Dicke 0,25 mm), nicht näher bestimmte Schneckeneischale aus Sta. Catharina Brazil (Durchmesser 22,5 x 16,3 mm, Dicke 0,15 mm) — ist Calcit gemäß Optik (negativ einachsiges Konoskopbild) and Meigenscher Reaktion (in Übereinstimmung mit Kellys Beobachtungen bei Bulimus oblongus). Der Phosphatgehalt der Schale ist äuBerst gering trotz reichlichen Vorkommens der KELLyschen Phosphatkörnehen; diese sind in Wirklichkeit Gaseinschüisse. Erhitzen von Schalenstiicken braunt den Kalk bei Verkohlung der organischen Substanz durch and durch ; these durchsetzt also die Calcitkristalle, in Übereinstimmung mit Kellys Erfahrungen beim Entkalken. Erhitzen his zum Verbrennen der organischen Substanz (Wiederweißwerden der Schalenstücke) hebt die Doppelbrechung auf (Umwandlung des Calciumcarbonats in -oxyd); zugleich erscheint bräunliche Trübung im durchfallenden Licht wohl infolge des Austretens der Kohlensäure.Die Mammillenschicht auf der Innenseite der Schale besteht aus einzelnen Calcitindividuen oder Gruppen von solchen; diese Kristallkörnchen wachsen (zum Teil) zu den annähernd senkrecht stehenden Prismen aus, deren optische Achse rneist gegen die Schalenfläche geneigt ist. Vor allem bei Bulimus maximus lassen die Prismen eine innere grobgeschichtete and eine äußere feinstreifige Lage unterscheiden; die erste enthält die Gaseinschliisse, die sich bei der Schneckeneischale aus Sta. Catharina Brazil bis in die Mammillen hinein finden, and von rundlicher Form sind, während she bei Bulimus maximus zum Teil spaltenartig erscheinen. An manchen Stellen der Eischale aus Sta. Catharina Brazil tragen die Mamillen an ihrem freien Ende Scheiben aus radial gestellten Kalknadeln oder Rosetten aus größeren Kristallen, die bis zur Berührung benachbarter auswachsen können.     

Orchid seed sensitivity to nitrate reflects habitat preferences and soil nitrate content

• Orchids are distributed around the world, however, the factors shaping their specific distribution and habitat preferences are largely unknown. Moreover, many orchids are at risk of becoming threatened as landscapes change, sometimes declining without apparent reason. One important factor affecting plant distribution is nutrient levels in the environment. Nitrates can inhibit not only orchid growth and persistence, but also seed germination.
• We used in vitro axenic cultures to exactly determine the germination sensitivity of seven orchid species to nitrates and correlated this with soil properties of the natural sites and with the species’ habitat preferences.
• We found high variation in response to nitrate between species. Orchids from oligotrophic habitats were highly sensitive, while orchids from more eutrophic habitats were almost insensitive. Sensitivity to nitrate was also associated with soil parameters that indicated a higher nitrification rate.
• Our results indicate that nitrate can affect orchid distribution via direct inhibition of seed germination. Nitrate levels in soils are increasing rapidly due to intensification of agricultural processes and concurrent soil pollution, and we propose this increase could cause a decline in some orchid species.

     

Ecosystem function and species loss – a microcosm study

There are too many kinds of organisms to be able to study and manage each, yet the loss of a single species can sometimes unravel an ecosystem. Such `fusewire species'– critical in the same sense that an electrical fuse can cut out a whole circuit – would be a rewarding focus for research and management effort. However, this approach can only be effective if these `fusewires' represent but a small proportion of the number of species in the system.  

Aim

To demonstrate methods for measuring what proportion of the species in a system are critical to ecosystem function.  

Methods

The prevalence of fusewire species was measured in manipulative experiments on an aquatic microcosm.  

Results

No single genus deletion caused changes in key characteristics of the system.  

Main conclusions

Comparison of these results with other published studies shows that the proportion of critical fusewire species varies amongst different ecosystems. The oxidation pond microcosms were shown to contain no single species indispensable to system function. They appear to be ill-suited to a management strategy which focuses on priority eukaryote species. However, a single study provides no evidence that this result is general or even typical of other kinds of ecosystems; it is presented here as an empirical model. Other methods of investigation are available; they are less experimentally rigorous but more practical. These could provide important guidance in planning an approach to management in a particular ecosystem.