Pelagia benovici sp. nov. (Cnidaria, Scyphozoa): a new jellyfish in the Mediterranean Sea

A bloom of an unknown semaestome jellyfish species was recorded in the North Adriatic Sea from September 2013 to early 2014. Morphological analysis of several specimens showed distinct differences from other known semaestome species in the Mediterranean Sea and unquestionably identified them as belonging to a new pelagiid species within genus Pelagia. The new species is morphologically distinct from P. noctiluca, currently the only recognized valid species in the genus, and from other doubtful Pelagia species recorded from other areas of the world. Molecular analyses of mitochondrial cytochrome c oxidase subunit I (COI) and nuclear 28S ribosomal DNA genes corroborate its specific distinction from P. noctiluca and other pelagiid taxa, supporting the monophyly of Pelagiidae. Thus, we describe Pelagia benovici sp. nov. Piraino, Aglieri, Scorrano & Boero

c-FLIPL regulates endoplasmic reticulum morphology and mitochondria-associated membranes functions

Physical and functional interactions between endoplasmic reticulum (ER) and mitochondria take place at the mitochondria-associated membranes (MAMs), ER subdomains at the interface between the two organelles. Protein complexes at MAMs regulate lipid synthesis, Ca2+ signaling and apoptosis 1. Furthermore, they influence both ER and mitochondrial morphology, as their ablation is frequently associated to the dramatic remodeling of these organelles. Here we show that c-FLIPL (cellular FLICE-inhibitory protein, long isoform), mainly known as inhibitor of caspase-8, can be retrieved at the ER and MAMs. c-FLIP ablation in mouse embryonic fibroblasts (MEFs) impairs ER morphology and luminal contiguity, by inducing the proliferation of ER cisternae to the detriment of tubular ER. Furthermore, c-FLIPL controls the ER-mitochondria apposition, as the depletion of this protein physically uncouples the two organelles. Moreover, functionally, c-FLIP ablation lowers the cytosolic Ca2+-increase evoked either by agonists stimulation or by passive ER discharge and increases the resistance of c-FLIP-/- cells to ER stress-induced apoptosis. We also report that c-FLIP-/- cells show an increased caspase-mediated cleavage of the ER-shaping protein Reticulon-4 (which is a well-known regulator of ER biogenesis and morphology), at both basal level and upon TNFα-dependent apoptosis. In agreement with these findings, we finally show that c-FLIP absence enhances basal caspase-8 activation in c-FLIP-/- MEFs and that caspase-8 inhibition reverts morphological alterations in ER shape observed in c-FLIP-/- cells, suggesting a novel role for caspase-8 and c-FLIPL as regulators of ER functions and ER-mitochondria crosstalk

The influence of invasive jellyfish blooms on the aquatic microbiome in a coastal lagoon (Varano, SE Italy) detected by an Illumina-based deep sequencing strategy

The rapid expansion of multicellular native and alien species outbreaks in aquatic and terrestrial ecosystems (bioinvasions) may produce significant impacts on bacterial community dynamics and nutrient pathways with major ecological implications. In aquatic ecosystems, bioinvasions may cause adverse effects on the water quality resulting from changes in biological, chemical and physical properties linked to significant transformations of the microbial taxonomic and functional diversity. Here we used an effective and highly sensitive experimental strategy, bypassing the efficiency bottleneck of the traditional bacterial isolation and culturing method, to identify changes of the planktonic microbial community inhabiting a marine coastal lagoon (Varano, Adriatic Sea) under the influence of an outbreak-forming alien jellyfish species. Water samples were collected from two areas that differed in their level of confinement inside in the lagoon and jellyfish densities (W, up to 12.4 medusae m−3; E, up to 0.03 medusae m−3) to conduct a snapshot microbiome analysis by a metagenomic approach. After extraction of the genetic material in the environmental water samples, we deep-sequenced metagenomic amplicons of the V5–V6 region of the 16S rRNA bacterial gene by an Illumina MiSeq platform. Experiments were carried out in triplicates, so six libraries of dual indexed amplicons of 420 bp were successfully sequenced on the MiSeq platform using a 2 × 250 bp paired-end sequencing strategy. Approximately 7.5 million paired-end reads (i.e. 15 million total reads) were generated, with an average of 2.5 million reads (1.25 M pairs) per sample replicate. The sequence data, analyzed through a novel bioinformatics pipeline (BioMaS), showed that the structure of the resident bacterial community was significantly affected by the occurrence of jellyfish outbreaks. Clear qualitative and quantitative differences were found between the western and eastern areas (characterized by many or few jellyfish), with 84 families, 153 genera and 324 species in the W samples, and 104 families, 199 genera and 331 species in the E samples. Significant differences between the two sampling areas were particularly detected in the occurrence of 16 families, 22 genera and 61 species of microbial taxa. This is the first time that a NGS platform has been used to screen the impact of jellyfish bioinvasions on the aquatic microbiome, providing a preliminary assessment of jellyfish-driven changes of the functional and structural microbial biodiversity

Unmasking Aurelia species in the Mediterranean Sea: an integrative morphometric and molecular approach

Molecular analyses have led to an increased knowledge of the number and distribution of morphologically cryptic species in the world's oceans and, concomitantly, to the identification of non-indigenous species (NIS). Traditional taxonomy and accurate delimitation of species’ life histories and autecology lag far behind, however, even for the most widely distributed taxa, such as the moon jellyfish Aurelia (Cnidaria, Scyphozoa) species complex. Here we analysed mitochondrial cytochrome c oxidase subunit I (COI) and nuclear 28S ribosomal RNA (28S) gene sequences to assign polyps, ephyrae, and medusae collected in the Mediterranean Sea to different phylogenetic species. We find evidence for three Aurelia species, none of which are referable to the type species of the genus, Aurelia aurita (Linnaeus, 1758), and describe the anatomical, morphometric, and developmental variation within and between them. We identify Aurelia coerulea von Lendenfeld, 1884 and Aurelia solida Browne, 1905 as established non-indigenous species in the Mediterranean Sea. We describe Aurelia relicta sp. nov., an endemic species currently unique to a population in the marine lake of Mljet (Croatia). These results demonstrate the usefulness of integrative approaches in resolving taxonomic uncertainty surrounding cryptic species complexes, identifying patterns of marine biodiversity, and recognizing non-indigenous species in marine ecosystems

Solvent-Dependent Intramolecular Electron Transfer in a Peptide-Linked [Ru(bpy)3]2+−C60 Dyad

A novel peptide-linked [Ru(bpy)3]2+−C60 dyad is shown to undergo an intramolecular photoinduced electron transfer in chlorinated hydrocarbons that causes quenching of the emission associated to the ruthenium metal-to-ligand charge-transfer excited state. Addition of a strong protic solvent, such as hexafluoro-2-propanol, leads to deactivation of the electron-transfer process with concomitant recovery of the emission to the extent recorded for a solution of a reference ruthenium complex lacking the fullerene moiety. This behavior is associated with a direct effect of the protic solvent on the secondary structure of the peptide spacer, whose preferred conformations in solution have been assessed by FT-IR and 2D NMR spectroscopy. Chlorinated hydrocarbons favor the peptide 310-helical conformation, which provides efficient interactions between the ruthenium and C60 chromophores, whereas the presence of a protic solvent produces helix unfolding, which hampers suitable spatial orientations of the chromophores for electron transfer. The reversibility of the phenomenon is also demonstrated and discussed

A new macromedusa from the coast of Mozambique: Aurelia mozambica sp. nov. (Scyphozoa: Ulmaridae)

A new species of the cosmopolitan jellyfish genus Aurelia is described from the coastal waters of Mozambique using a combination of morphological, meristic and genetic information (COI and 18S). The species can be separated from congeners that have been recently described by a combination of bell shape, number of canal origins and anastomoses, and the shape of the manubrium and oral arms. Three types of nematocysts are present in the tissues of both the bell margin and oral arms, and this description of the cnidome will allow for future comparison. Pairwise genetic comparisons showed a mean COI divergence of 4.8% within the group, and a mean divergence ranging between 15% and 22% with all other species of Aurelia

Pelagia benovici sp. nov. (Cnidaria, Scyphozoa): a new jellyfish in the Mediterranean Sea

A bloom of an unknown semaestome jellyfish species was recorded in the North Adriatic Sea from September 2013 to early 2014. Morphological analysis of several specimens showed distinct differences from other known semaestome species in the Mediterranean Sea and unquestionably identified them as belonging to a new pelagiid species within genus Pelagia. The new species is morphologically distinct from P. noctiluca, currently the only recognized valid species in the genus, and from other doubtful Pelagia species recorded from other areas of the world. Molecular analyses of mitochondrial cytochrome c oxidase subunit I (COI) and nuclear 28S ribosomal DNA genes corroborate its specific distinction from P. noctiluca and other pelagiid taxa, supporting the monophyly of Pelagiidae. Thus, we describe Pelagia benovici sp. nov. Piraino, Aglieri, Scorrano & Boero