Floral structure and pollen morphology of two zinc violets (Viola lutea ssp. calaminaria and V. lutea ssp. westfalica) indicate their taxonomic affinity to Viola lutea

Two zinc violets, the yellow form of the Aachen–Liège area and the blue morph of Blankenrode in western Westphalia, have very restricted occurrence on heavy metal waste heaps. Their taxonomic affinities have not been finally resolved. The flower micromorphological analysis presented here indicates that both zinc violets are closely related to the alpine Viola lutea, in line with our earlier published molecular data, but not with the conclusions of other authors. The zinc violets are classed at the rank of subspecies as V. lutea: ssp. calaminaria for the yellow zinc violet and ssp. westfalica for its blue counterpart. Although the violets examined (V. lutea, V. lutea ssp. calaminaria, V. lutea ssp. westfalica) are closely related, there is no evidence that V. lutea ssp. westfalica is a descendent of V. tricolor. Here we provide the most detailed information on generative organ structure in the four violets studied

Floral structure and pollen morphology are important characters in taxonomy of the genus Viola (Violaceae)

the pistil with stigma, stamen appendages (nectaries) and pollen heteromorphism are important diagnostic features in the genus ViolaL. The style characters were crucial in the very early classifications of this genus (Clausen 1927). We analyzed in details, using scanning electron microscopy (SEM), the microstructural characters of generative organs (style and stigma, stamens with nectaries) and pollen in representatives of three sections (Viola L., Melanium Ging., DischidiumGing.) occurring in Poland to get insights into the relatedness among far-related (different sections) and closely related (sub-sections within section) species. There is a great difference in stigma micromorphology between sections. In the section Violaflowers have style beaked at the apex, glabrous or covered by papillae and/or hairs, depending of subsection. Monotypic section Dischidiumwith one species V. biflora L. characterizes 2-lobed stigma. Cup-shaped stigma with the hole on the top and a lip below, covered with papillae and hairs on its outer surface occurs in pansies of the section Melanium. Pollen is highly heteromorphic (different pollen morphs, from three up to six apertures within one flower or even within one pollen sac) in the Melaniumsection and weakly heteromorphic mainly with three apertures in diploids of Viola and Dischidiumsections. This character is independent of the polyploidy in the Melaniumbut not in Violasection (Dajoz 1999). The flower micromorphological characters are also useful in reconstruction of closely related species origin. Based on stigma and nectaries features, two zinc violets are more similar to the alpineV. lutea, than to V. tricolor, indicated also as the ancestor (Kuta et al.2012)

Evidence for polyploidy in the globally important diazotroph Trichodesmium

Polyploidy is a well-described trait in some prokaryotic organisms; however, it is unusual in marine microbes from oligotrophic environments, which typically display a tendency towards genome streamlining. The biogeochemically significant diazotrophic cyanobacterium Trichodesmium is a potential exception. With a relatively large genome and a comparatively high proportion of non-protein-coding DNA, Trichodesmium appears to allocate relatively more resources to genetic material than closely related organisms and microbes within the same environment. Through simultaneous analysis of gene abundance and direct cell counts, we show for the first time that Trichodesmium spp. can also be highly polyploid, containing as many as 100 genome copies per cell in field-collected samples and >600 copies per cell in laboratory cultures. These findings have implications for the widespread use of the abundance of the nifH gene (encoding a subunit of the N2-fixing enzyme nitrogenase) as an approach for quantifying the abundance and distribution of marine diazotrophs. Moreover, polyploidy may combine with the unusual genomic characteristics of this genus both in reflecting evolutionary dynamics and influencing phenotypic plasticity and ecological resilience

Ubiquitin activation is essential for schizont maturation in Plasmodium falciparum blood-stage development

Ubiquitylation is a common post translational modification of eukaryotic proteins and in the human malaria parasite, Plasmodium falciparum (Pf) overall ubiquitylation increases in the transition from intracellular schizont to extracellular merozoite stages in the asexual blood stage cycle. Here, we identify specific ubiquitylation sites of protein substrates in three intraerythrocytic parasite stages and extracellular merozoites; a total of 1464 sites in 546 proteins were identified (data available via ProteomeXchange with identifier PXD014998). 469 ubiquitylated proteins were identified in merozoites compared with only 160 in the preceding intracellular schizont stage, suggesting a large increase in protein ubiquitylation associated with merozoite maturation. Following merozoite invasion of erythrocytes, few ubiquitylated proteins were detected in the first intracellular ring stage but as parasites matured through trophozoite to schizont stages the apparent extent of ubiquitylation increased. We identified commonly used ubiquitylation motifs and groups of ubiquitylated proteins in specific areas of cellular function, for example merozoite pellicle proteins involved in erythrocyte invasion, exported proteins, and histones. To investigate the importance of ubiquitylation we screened ubiquitin pathway inhibitors in a parasite growth assay and identified the ubiquitin activating enzyme (UBA1 or E1) inhibitor MLN7243 (TAK-243) to be particularly effective. This small molecule was shown to be a potent inhibitor of recombinant PfUBA1, and a structural homology model of MLN7243 bound to the parasite enzyme highlights avenues for the development of P. falciparum specific inhibitors. We created a genetically modified parasite with a rapamycin-inducible functional deletion of uba1; addition of either MLN7243 or rapamycin to the recombinant parasite line resulted in the same phenotype, with parasite development blocked at the schizont stage. Nuclear division and formation of intracellular structures was interrupted. These results indicate that the intracellular target of MLN7243 is UBA1, and this activity is essential for the final differentiation of schizonts to merozoites

Arbuscular mycorrhiza and salt tolerance of plants

Although salt has detrimental effects on spore germination of arbuscular mycorrhizal fungi (AMF), their hyphal growth and the colonization rate of plants under laboratory conditions, many salt tolerant plants (the halophytes) are strongly colonized by AMF in their natural habitats. AMF spores in several saline soils consist of to up to 80 % of one single species, Glomus geosporum. In contrast, roots of halophytes are mostly colonized by fungi of the Glomus intraradices group, of which many are as yet uncultured. Salt stress is intimately related to drought in saline habitats. Molecular analyses of genes expressed upon salt stress indicate that aquaporins which facilitate the transfer of water across membranes play a major role in alleviating salt stress in plants. In AMF, genes serving to scavenge reactive oxygen species (ROS) are expressed upon exposure to salt, indicating that fungi have to develop an enhanced oxidative defence. The development of AMF inocula that confer sustained salt tolerance to plants would have enormous practical applications. Many positive reports on salt stress alleviation by AMF exist. However, the state of the art has not yet reached field applications. In contrast to other recent reviews, the present article focuses on ecological aspects of the symbiosis between AMF and halophytes. It also emphasizes the complexity of the interactions between salt and drought stress as well as the role of AMF in alleviating salt stress

The lime-silicate question

Hikers passing through nature easily recognize that the vegetation on limestone (calcareous soils) and silicate (acidic soils) is very different. This is not so much the case with trees but with herbs, particularly in grasslands. These differences in the vegetation on both soil types, referred to as the lime silicate question, were recognized as early as the 18th century. Even so, fairly little is known about why this occurs. The current paucity of information exists mainly because the determinants that govern the formation of plant communities on either lime or acid soils mainly reside below-ground, in the root-surface area, and these complex below-ground interactions are almost impossible to explore through experimental approaches and direct measurements. Element availability or toxicity and interactions with microorganisms are both equally important. The calcium cation, for example, is not only an essential growth component but can be severely toxic to plants in unbalanced concentrations. Plants also vary in their ability to acquire iron and phosphorus. Aluminium toxicity affects plant growth, particularly in acid soils, and acid-tolerant plants have acquired the capability to cope with high levels of Al in soils. Mainly saprophytic fungi serve to degrade litter in acid soils and liberate nutrients for plant growth. In calcareous soils, bacteria and small animals, such as earthworms and their inhabitant bacteria, are the main decomposers of litter and contribute significantly to the fertility of the soils. Arbuscular mycorrhizal fungi (AMF) have a particularly significant role in calcareous soils, where they are believed to determine the competitiveness of plants in lime meadows. Physical factors also impact the different composition of plant communities in acid and calcareous soils. (C) 2015 Elsevier Ltd. All rights reserved