ARDRA and RAPD-fingerprinting reject the sibling species concept for the ciliate Paramecium caudatum (Ciliophora, Protoctista)

Morphologically indistinguishable sibling species also known as syngens are a characteristic taxonomic feature of the ciliate genus Paramecium . This has been convincingly demonstrated for the P. aurelia species complex. For a long time this feature has also been assumed for P. caudatum . Classical morphology based techniques of taxonomic analysis are often inefficient to study sibling specie. We therefore investigated 14 P. caudatum strains of seven supposedly different syngens using random amplified polymorphic DNA (RAPD)-fingerprinting and amplified ribosomal DNA restriction analyses (ARDRA, Riboprinting). The RAPD patterns revealed by five different random primers were similar between the different strains of the same syngen (similarity index ranging from 73 to 91%) and also between strains of supposedly different syngens (similarity index ranging from 67 to 91%). The amplified 18S rRNA-fragments of supposedly different syngens, as well as the restriction patterns of these fragments digested by five different endonucleases, were identical for all investigated P. caudatum stains. Consequently we reject the sibling species hypothesis for P. caudatum . According to our molecular analysis, P. caudatum is not a species complex, but just one single species.     

Sulfide Intrusion and Detoxification in the Seagrass Zostera marina

Gaseous sulfide intrusion into seagrasses growing in sulfidic sediments causes little or no harm to the plant, indicating the presence of an unknown sulfide tolerance or detoxification mechanism. We assessed such mechanism in the seagrass Zostera marina in the laboratory and in the field with scanning electron microscopy coupled to energy dispersive X-ray spectroscopy, chromatographic and spectrophotometric methods, and stable isotope tracing coupled with a mass balance of sulfur compounds. We found that Z. marina detoxified gaseous sediment-derived sulfide through incorporation and that most of the detoxification occurred in underground tissues, where sulfide intrusion was greatest. Elemental sulfur was a major detoxification compound, precipitating on the inner wall of the aerenchyma of underground tissues. Sulfide was metabolized into thiols and entered the plant sulfur metabolism as well as being stored as sulfate throughout the plant. We conclude that avoidance of sulfide exposure by reoxidation of sulfide in the rhizosphere or aerenchyma and tolerance of sulfide intrusion by incorporation of sulfur in the plant are likely major survival strategies of seagrasses in sulfidic sediments.