Niche partitioning in orbweaving spiders Meta menardi and Metellina merianae (Tetragnathidae)

Hypogean habitats are relatively simple exhibiting low diversity, low production and relative constancy of environmental factors, and are therefore appropriate for studying species coexistence in situ. We investigated the coexistence of two closely related, similarly sized orb-weaving spider species, Meta menardi and Metellina merianae, living syntopically in a Slovenian cave. We studied the annual dynamics of both species within a mixed population, and the impact of the ambient temperature, relative humidity, airflow and illumination, and compared their trophic niches to legacy data on prey of both species from 55 caves in Slovenia. We predicted a large overlap in their spatial niches and substantial differences in their temporal and trophic niches. We found that their spatial niches overlap greatly with few exceptions, mostly on the dates of notable meteorological changes in the cave but that their temporal niches differ significantly with r-strategy resembling epigean annual dynamic in M. merianae and a steady low abundance course in M. menardi within the cave. We also found that different predatory strategies significantly segregate their trophic niches: M. merianae uses a typical orb-weaving hunting strategy, while M. menardi combines web hunting with off-web hunting. Our findings suggest that both the diverse dynamics and trophic niches enable the coexistence of M. menardi and M. merianae despite their similar spatial niches, and that M. menardi, in particular, is optimally adapted to the epigean/hypogean ecotone.     

Assessment of genetic stability of two micropropagated wild olive species using flow cytometry and microsatellite markers

Micropropagated plants from two wild-olive species, Olea maderensis and O. europaea ssp. europaea var. sylvestris were screened for genetic stability. O. maderensis shoots were elongated/multiplied on OMG medium with zeatin (9.12 μM), and rooted on 1/2 OMG with NAA (3.22 μM). O. europaea var. sylvestris shoots were elongated/multiplied on OM medium with zeatin, and rooting was optimal after a hormonal shock (IBA 100 μM) followed by transfer to the same medium without growth regulators. In both species, acclimatization was successful and plants looked normal and morphologically identical to the donor field trees. Genetic variability was assessed at several stages of the micropropagation process using flow cytometry (FCM) and nuclear microsatellites (SSR). No changes in ploidy level were found among micropropagated plants, though small deviations, putatively due to the negative effects of cytosolic compounds on propidium iodide staining, between these and field plants were observed. In SSRs analyses, ten SSR markers were able to distinguish between genotypes. No mutations were found in these tested SSR loci among the donor tree and micropropagated plants, suggesting, for the tested markers, genetic uniformity throughout the process. The FCM and SSR results obtained do not exclude the occurrence of other changes in the nuclear genome but, considering the morphological stability of micropropagated plants, indicate that both protocols are suitable and efficient for large scale, true-to-type micropropagation of these two wild olive species.     

The role of water chemistry in the distribution of Austropotamobius pallipes (Crustacea Decapoda Astacidae) in Piedmont (Italy)

Over the last decades, the populations of Austropotamobius pallipes have decreased markedly all over Europe. If we evaluate the ecological factors that determine its presence, we will have information that could guide conservation decisions. This study aims to investigate the chemical-physical demands of A. pallipes in NW Italy. To this end, we investigated 98 sites. We performed Principal Component Analysis using chemical-physical parameters, collected in both presence and absence sites. We then used principal components with eigenvalue > 1 to run Discriminant Function Analysis and Logistic Regression. The statistics on the concentration of Ca²⁺, water hardness, pH and BOD₅ were significantly different in the presence and in the absence sites. pH and BOD₅ played the most important role in separating the presence from the absence locations. These findings are further evidence that we should reduce dissolved organic matter and fine particles in order to contribute to species management and conservation.     

Morphological Response of the Halophilic Fungal Genus Wallemia to High Salinity

The basidiomycetous genus Wallemia is an active inhabitant of hypersaline environments, and it has recently been described as comprising three halophilic and xerophilic species: Wallemia ichthyophaga, Wallemia muriae, and Wallemia sebi. Considering the important protective role the fungal cell wall has under fluctuating physicochemical environments, this study was focused on cell morphology changes, with particular emphasis on the structure of the cell wall, when these fungi were grown in media with low and high salinities. We compared the influence of salinity on the morphological characteristics of Wallemia spp. by light, transmission, and focused-ion-beam/scanning electron microscopy. W. ichthyophaga was the only species of this genus that was metabolically active at saturated NaCl concentrations. W. ichthyophaga grew in multicellular clumps and adapted to the high salinity with a significant increase in cell wall thickness. The other two species, W. muriae and W. sebi, also demonstrated adaptive responses to the high NaCl concentration, showing in particular an increased size of mycelial pellets at the high salinities, with an increase in cell wall thickness that was less pronounced. The comparison of all three of the Wallemia spp. supports previous findings relating to the extremely halophilic character of the phylogenetically distant W. ichthyophaga and demonstrates that, through morphological adaptations, the eukaryotic Wallemia spp. are representative of eukaryotic organisms that have successfully adapted to life in extremely saline environments.Hypersaline habitats had long been considered to be populated almost exclusively by prokaryotic organisms and the research on hypersaline environments had consequently been monopolized by bacteriologists. In 2000, the first reports appeared showing that fungi are active inhabitants of solar salterns (20). Until then, fungi able to survive in environments with a low amount of biologically available water (low water activity [a_w]) were only known as contaminants of foods preserved with high concentrations of salt or sugar. Since their first discovery in salterns, many new species have been discovered in natural hypersaline environments around the world, including some species that were previously known only as food-borne contaminants. Due to these discoveries, fungi are now recognized as an integral part of indigenous halophilic microbial communities since they can grow and adjust across the whole salinity range, from freshwater to almost saturated NaCl solutions (49). Most fungi differ from the majority of halophilic prokaryotes (16): they tend to be extremely halotolerant rather than halophilic and do not require salt to remain viable, with the exception of Wallemia spp.The order Wallemiales (Wallemiomycetes, Basidiomycota) was only recently introduced to define the single genus Wallemia, a phylogenetic maverick in the Basidiomycota (49). Until 2005, this genus contained only the species W. sebi. However, taxonomic analyses of isolates from sweet, salty, and dried foods (41) and from hypersaline evaporation ponds in the Mediterranean Sea, the Caribbean, and the Dead Sea (45, 49) have resolved this genus into three species: W. ichthyophaga, W. muriae, and W. sebi. The first two of these three Wallemia spp. require additional solutes in the growth media, and W. ichthyophaga is the most halophilic eukaryote described to date, since it cannot grow without the addition of 9% NaCl (wt/vol), and it still shows growth at a_w of 0.77, equivalent to 30% NaCl (wt/vol) (49).The survival, and especially the growth, of microorganisms in highly saline environments requires numerous adaptations (6, 18, 21, 34). The dominant representatives and the most thoroughly investigated halophilic fungi in hypersaline waters of the salterns are the black yeasts, and particularly the model organism Hortaea werneckii (20). An important level of adaptation of the black yeasts to high salinity is seen in their extremophilic ecotype, which is characterized by a special meristematic morphology and changes in cell wall structure and pigmentation (27). Other fungal osmoadaptations include the accumulation of osmolytes (27, 28, 40), the extrusion of sodium (5), modification of the plasma membrane (44) and the cell wall, and even changes in fungal colony morphology (27).The fungal cell wall is the first line of defense against environmental stress; therefore, adaptation at the cell wall level is expected to have one of the most important roles for successful growth at a low a_w (24, 32). The cell wall is essential for maintaining the osmotic homeostasis of cells, since it protects them against mechanical damage as well as high concentrations of salts (7). The central fibrillar glycan network of the cell wall is embedded in highly flexible amorphous cement, which allows considerable stretching with changing osmotic pressure (14, 29). Its balance between a rigid and a dynamic structure influences the shape of cells (14) and enables growth and hyphal branching (11).Since the species within the genus Wallemia have been recognized only recently (49), little is known about their mechanisms of adaptation to high salinity. To investigate the effects of low and high NaCl concentrations on cell morphology, with particular emphasis on cell wall ultrastructure, we compared W. ichthyophaga, the most halophilic fungal species known thus far, with the related xerophilic W. muriae and W. sebi. Micrographs were prepared by using light, transmission, and scanning electron microscopy. The results reveal how this eukaryotic genus uses adaptations at the cell wall level for thriving in extremely saline environments.     

A formerly incarcerated woman takes on policy

This paper examines a formerly incarcerated woman’s journey from prison to taking on policy change. It points to a personal experience of drug addiction, recovery and transformation and asks the question of how ex-prisoner may gain citizenship and develop partnerships within grassroots organizations. There is further discussion of how she became involved in advocacy and policy change and the way that formerly incarcerated people are seen by those in power. The paper also discusses the invisibility of those who have had the prison experience.     

Comparative transcriptome analysis of Methylibium petroleiphilum PM1 exposed to the fuel oxygenates methyl tert-butyl ether and ethanol

High-density whole-genome cDNA microarrays were used to investigate substrate-dependent gene expression of Methylibium petroleiphilum PM1, one of the best-characterized aerobic methyl tert-butyl ether (MTBE)-degrading bacteria. Differential gene expression profiling was conducted with PM1 grown on MTBE and ethanol as sole carbon sources. Based on microarray high scores and protein similarity analysis, an MTBE regulon located on the megaplasmid was identified for further investigation. Putative functions for enzymes encoded in this regulon are described with relevance to the predicted MTBE degradation pathway. A new unique dioxygenase enzyme system that carries out the hydroxylation of tert-butyl alcohol to 2-methyl-2-hydroxy-1-propanol in M. petroleiphilum PM1 was discovered. Hypotheses regarding the acquisition and evolution of MTBE genes as well as the involvement of IS elements in these complex processes were formulated. The pathways for toluene, phenol, and alkane oxidation via toluene monooxygenase, phenol hydroxylase, and propane monooxygenase, respectively, were upregulated in MTBE-grown cells compared to ethanol-grown cells. Four out of nine putative cyclohexanone monooxygenases were also upregulated in MTBE-grown cells. The expression data allowed prediction of several hitherto-unknown enzymes of the upper MTBE degradation pathway in M. petroleiphilum PM1 and aided our understanding of the regulation of metabolic processes that may occur in response to pollutant mixtures and perturbations in the environment.     

The moss genes <Emphasis Type="Italic">PpSKI1</Emphasis> and <Emphasis Type="Italic">PpSKI2</Emphasis> encode nuclear SnRK1 interacting proteins with homologues in vascular plants

The yeast Snf1, animal AMPK, and plant SnRK1 protein kinases constitute a family of related proteins that have been proposed to serve as metabolic sensors of the eukaryotic cell. We have previously reported the characterization of two redundant SnRK1 encoding genes (PpSNF1a and PpSNF1b) in the moss Physcomitrella patens. Phenotypic analysis of the snf1a snf1b double knockout mutant suggested that SnRK1 is important for the plant’s ability to recognize and adapt to conditions of limited energy supply, and also suggested a possible role of SnRK1 in the control of plant development. We have now used a yeast two-hybrid system to screen for PpSnf1a interacting proteins. Two new moss genes were found, PpSKI1 and PpSKI2, which encode highly similar proteins with homologues in vascular plants. Fusions of the two encoded proteins to the green fluorescent protein localize to the nucleus. Knockout mutants for either gene have an excess of gametophores under low light conditions, and exhibit reduced gametophore stem lengths. Possible functions of the new proteins and their connection to the SnRK1 kinase are discussed.