EVIDENCE FOR INHIBITORS OF SPORANGIUM FORMATION IN LAMINARIA DIGITATA (PHAEOPHYCEAE) DURING THE SEASON OF RAPID GROWTH

The pathway from the intercalary frond meristem to distal frond portions was blocked in experimental sporophytes of Laminaria digitata (Huds.) Lamour. in January by cutting 2 or 3 holes (15–25 mm diameter) 5 cm from the base of the frond. This procedure resulted in the formation of sori adjacent to the distal edge of the holes within 5–10 weeks. Frond portions that were cut at least 20 cm away from the stipe–frond transition readily formed sori within 5–7 weeks after isolation from the rest of the thallus. These findings suggest that the basal actively dividing and expanding part of the laminarian frond is the source of inhibitors of sporangium formation that move in a distal direction and keep the young frond free of sori during the season of rapid growth (i.e. during the first part of the year). The natural occurrence of sori during the season of slow growth (i.e. the second part of the year in the Northern Hemisphere) may be due to reduced synthesis and export of inhibitors of sporangium formation from the more or less resting basal meristem.     

First contribution to the bionomics of the pollen wasp Ceramius palaestinensis (Giordani Soika, 1957) (Hymenoptera: Vespidae: Masarinae) in Turkey

Data about the bionomics of the pollen wasp Ceramius palaestinensis (Giordani Soika, 1957) are presented for the first time. Ceramius palaestinensis is characterized by the following ethological elements: (i) the nest is excavated in non-friable soil; (ii) the burrow is surmounted by a turret from earth extracted from within the burrow; (iii) the nest is possibly perennial; (iv) the nest has a relatively short, vertical to sub-vertical main shaft with an expansion at the bottom; (v) the main shaft is not terminated by a cell; (vi) secondary shafts are absent; (vii) the cells are sub-horizontal, all at different depths; (viii) brood cells are constructed mud-cells built within an excavated cell, formed from earth excavated within the burrow; (ix) imagines visit only flowers of Trifolium (Fabaceae) and brood cells are provisioned exclusively with pollen from this plant genus; Trifolium species varying considerably in inflorescence morphology lead to different positions of foraging wasps on the inflorescences during flower visits; Trifolium resupinatum or T. clusii inflorescences with resupinate flowers function as a disc-shaped pseudanthium with the vexilla of the flowers arranged on the outer periphery serving as petal-like exhibition organs; and (x) males patrol and perch at water collection sites, at flowers and within nesting aggregations; copulations or copulatory attempts are observed there.     

Protein folding in the periplasm of Escherichia coli

With the discovery of molecular chaperones and the development of heterologous gene expression techniques, protein folding in bacteria has come into focus as a potentially limiting factor in expression and as a topic of interest in its own right. Many proteins of importance in biotechnology contain disulphide bonds, which form in the Escherichia coli periplasm, but most work on protein folding in the periplasm of E. coli is very recent and is often speculative. This MicroReview gives a short overview of the possible fates of a periplasmic protein from the moment it is translocated, as well as of the E. coli proteins involved in this process. After an introduction to the specific physiological situation in the periplasm of E. coli, we discuss the proteins that might help other proteins to obtain their correctly folded conformation — disulphide isomerase, rotamase, parts of the translocation apparatus and putative periplasmic chaperones — and briefly cover the guided assembly of multi-subunit structures. Finally, our MicroReview turns to the fate of misfolded proteins: degradation by periplasmic proteases and aggregation phenomena.     

Implementing large-scale and long-term functional biodiversity research: The Biodiversity Exploratories

Functional biodiversity research explores drivers and functional consequences of biodiversity changes. Land use change is a major driver of changes of biodiversity and of biogeochemical and biological ecosystem processes and services. However, land use effects on genetic and species diversity are well documented only for a few taxa and trophic networks. We hardly know how different components of biodiversity and their responses to land use change are interrelated and very little about the simultaneous, and interacting, effects of land use on multiple ecosystem processes and services. Moreover, we do not know to what extent land use effects on ecosystem processes and services are mediated by biodiversity change. Thus, overall goals are on the one hand to understand the effects of land use on biodiversity, and on the other to understand the modifying role of biodiversity change for land-use effects on ecosystem processes, including biogeochemical cycles. To comprehensively address these important questions, we recently established a new large-scale and long-term project for functional biodiversity, the Biodiversity Exploratories (www.biodiversity-exploratories.de). They comprise a hierarchical set of standardized field plots in three different regions of Germany covering manifold management types and intensities in grasslands and forests. They serve as a joint research platform for currently 40 projects involving over 300 people studying various aspects of the relationships between land use, biodiversity and ecosystem processes through monitoring, comparative observation and experiments. We introduce guiding questions, concept and design of the Biodiversity Exploratories – including main aspects of selection and implementation of field plots and project structure – and we discuss the significance of this approach for further functional biodiversity research. This includes the crucial relevance of a common study design encompassing variation in both drivers and outcomes of biodiversity change and ecosystem processes, the interdisciplinary integration of biodiversity and ecosystem researchers, the training of a new generation of integrative biodiversity researchers, and the stimulation of functional biodiversity research in real landscape contexts, in Germany and elsewhere.     

The Banana Forests of Kilimanjaro: Biodiversity and Conservation of the Chagga Homegardens

Natural flora, vegetation, diversity and structure of 62 traditional coffee–banana plantations on Kilimanjaro were investigated and compared with the other vegetation formations on this volcano on basis of over 1400 plots following the method of Braun-Blanquet. The vegetation of the so-called Chagga homegardens belongs floristically to the formation of ruderal vegetation forming two main communities that are determined by altitude. These coffee–banana plantations maintain a high biodiversity with about 520 vascular plant species including over 400 non-cultivated plants. Most species (194) occurring in the Chagga homegardens are forest species, followed by 128 ruderal species, including 41 neophytes. Typical of the agroforestry system of the Chagga homegardens is their multilayered vegetation structure similar to a tropical montane forest with trees, shrubs, lianas, epiphytes and herbs. Beside relicts of the former forest cover, which lost most of their former habitats, there are on the other hand (apophytic) forest species, which were directly or indirectly favoured by the land use of the Chagga people. High demand of wood, the introduction of coffee varieties that are sun-tolerant and low coffee prizes on the world marked endanger this effective and sustainable system.