Oxidative effects of nanosecond pulsed electric field exposure in cells and cell-free media

Nanosecond pulsed electric field (nsPEF) is a novel modality for permeabilization of membranous structures and intracellular delivery of xenobiotics. We hypothesized that oxidative effects of nsPEF could be a separate primary mechanism responsible for bioeffects. ROS production in cultured cells and media exposed to 300-ns PEF (1-13kV/cm) was assessed by oxidation of 2',7'-dichlorodihydrofluoresein (H(2)DCF), dihidroethidium (DHE), or Amplex Red. When a suspension of H(2)DCF-loaded cells was subjected to nsPEF, the yield of fluorescent 2',7'-dichlorofluorescein (DCF) increased proportionally to the pulse number and cell density. DCF emission increased with time after exposure in nsPEF-sensitive Jurkat cells, but remained stable in nsPEF-resistant U937 cells. In cell-free media, nsPEF facilitated the conversion of H(2)DCF into DCF. This effect was not related to heating and was reduced by catalase, but not by mannitol or superoxide dismutase. Formation of H(2)O(2) in nsPEF-treated media was confirmed by increased oxidation of Amplex Red. ROS increase within individual cells exposed to nsPEF was visualized by oxidation of DHE. We conclude that nsPEF can generate both extracellular (electrochemical) and intracellular ROS, including H(2)O(2) and possibly other species. Therefore, bioeffects of nsPEF are not limited to electropermeabilization; concurrent ROS formation may lead to cell stimulation and/or oxidative cell damage.     

Ontogenetic dietary shifts in European common frog (Rana temporaria) revealed by stable isotopes

During migrations and ontogeny amphibians change their habitat and feeding, and thus are important in linking terrestrial and aquatic ecosystems. We measured δ ¹³C and δ ¹⁵N values of early stages (egg, embryo, tadpole) and toes of adult frogs Rana temporaria, collected from a small wetland in Lithuania. We compared the isotopic composition of these tissues with potential food sources, excrements of tadpoles, and filled intestinal tracts. We found that δ ¹³C values in R. temporaria tadpoles were markedly depleted in comparison to adults, eggs or embryos, demonstrating a terrestrial to aquatic shift in energy sources. After the onset of feeding, tadpoles approached isotopic equilibrium with available food (algae and litter). Tadpoles had higher δ ¹⁵N than both algae and litter, differing by 3.6 and 2.4‰, respectively, and similar δ ¹³C to these sources. However, tadpole excrements and body tissue diverged, with mean δ ¹³C values of excrements (−30.3 ± 1.6‰ SD) more similar to litter (−31.7 ± 1.2‰ SD) and body tissue δ ¹³C (−34.8 ± 0.7‰ SD) more similar to algae (−34.2 ± 4.1‰ SD). This suggests that algal resources are critical in early life stages of this anuran, particularly at stages characterized by high growth and low development (stages: 25–35).     

Protein Engineering Allows for Mild Affinity-based Elution of Therapeutic Antibodies

Presented here is an engineered protein domain, based on Protein A, that displays a calcium-dependent binding to antibodies. This protein, Z_Ca, is shown to efficiently function as an affinity ligand for mild purification of antibodies through elution with ethylenediaminetetraacetic acid. Antibodies are commonly used tools in the area of biological sciences and as therapeutics, and the most commonly used approach for antibody purification is based on Protein A using acidic elution. Although this affinity-based method is robust and efficient, the requirement for low pH elution can be detrimental to the protein being purified. By introducing a calcium-binding loop in the Protein A-derived Z domain, it has been re-engineered to provide efficient antibody purification under mild conditions. Through comprehensive analyses of the domain as well as the Z_Ca–Fc complex, the features of this domain are well understood. This novel protein domain provides a very valuable tool for effective and gentle antibody and Fc-fusion protein purification.     

Binding site and interlobe interactions of the ionotropic glutamate receptor GluK3 ligand binding domain revealed by high resolution crystal structure in complex with (S)-glutamate

Ionotropic glutamate receptors (iGluRs) are involved in excitatory signal transmission throughout the central nervous system and their malfunction is associated with various health disorders. GluK3 is a subunit of iGluRs, belonging to the subfamily of kainate receptors (GluK1–5). Several crystal structures of GluK1 and GluK2 ligand binding domains have been determined in complex with agonists and antagonists. However, little is known about the molecular mechanisms underlying GluK3 ligand binding properties and no compounds displaying reasonable selectivity towards GluK3 are available today. Here, we present the first X-ray crystal structure of the ligand binding domain of GluK3 in complex with glutamate, determined to 1.6 Å resolution. The structure reveals a conserved glutamate binding mode, characteristic for iGluRs, and a water molecule network in the glutamate binding site similar to that seen in GluK1. In GluK3, a slightly lower degree of domain closure around glutamate is observed compared to most other kainate receptor structures with glutamate. The volume of the GluK3 glutamate binding cavity was found to be of intermediate size between those of GluK1 and GluK2. The residues in GluK3 contributing to the subfamily differences in the binding sites are primarily: Thr520, Ala691, Asn722, Leu736 and Thr742. The GluK3 ligand binding domain seems to be less stabilized through interlobe interactions than GluK1 and this may contribute to the faster desensitization kinetics of GluK3.     

Resource partitioning confirmed by isotopic signatures allows small mammals to share seasonally flooded meadows

Meadows in river deltas are characterized by a high diversity and abundance of small mammals. However, neither their spatial arrangement nor differences in their use of microhabitat can necessarily explain the dense co‐occurrence of sympatric species. We investigated how several small mammal species share a seasonally flooded meadow of limited size, testing predictions (P1) that herbivore, granivore, insectivore, and omnivore species are separated in time (dominant in different years), (P2) that sympatric species undergo isotopic partitioning, and (P3) that there are intraspecific differences in diet. Stable carbon and nitrogen isotope signatures in the hair of seven synantropic shrew, vole, and mice species were used as a proxy for their diet. We found that the three most abundant species in eight of the nine years were from different diet groups. However, based on the number of species in the functional groups, the state of small mammal community was considered unfavored in five out of the nine investigation years. In years with the greatest dominance of Apodemus agrarius, the small mammal community was characterized by decreased diversity and Micromys minutus was either in low abundance or absent. In 2014 and 2016, years of low abundance or absence of M. oeconomus, M. agrestis, and M. glareolus were both recorded in high numbers. Differences in the isotopic signatures of the three most abundant small mammal species in the community were clearly expressed and core areas in the isotopic space were separated, showing their dependence on different dietary resources. Intraspecific dietary separation between young and adult animals was observed only in M. oeconomus. Thus, the high species diversity of small mammals and the formation of their community in this investigated flooded meadow are maintained by isotopic partitioning (segregation in dietary space) and by changes in their number over time (shifting dominance).     

Kainate induces various domain closures in AMPA and kainate receptors

Ionotropic glutamate receptors are key players in fast excitatory synaptic transmission within the central nervous system. These receptors have been divided into three subfamilies: the N-methyl-d-aspartic acid (NMDA), 2-amino-3-(3-hydroxy-5-methyl-4-isoxazolyl)propionic acid (AMPA) and kainate receptors. Kainate has previously been crystallized with the ligand binding domain (LBD) of AMPA receptors (GluA2 and GluA4) and kainate receptors (GluK1 and GluK2). Here, we report the structures of the kainate receptor GluK3 LBD in complex with kainate and GluK1 LBD in complex with kainate in the absence of glycerol. Kainate introduces a conformational change in GluK3 LBD comparable to that of GluK2, but different from the conformational changes induced in GluA2 and GluK1. Compared to their domain closures in a glutamate bound state, GluA2 and GluK1 become more open and kainate induces a domain closure of 60% and 62%, respectively, relative to glutamate (100%). In GluK2 and GluK3 with kainate, the domain closure is 88% and 83%, respectively. In previously determined structures of GluK1 LBD in complex with kainate, glycerol is present in the binding site where it bridges interlobe residues and thus, might contribute to the large domain opening. However, the structure of GluK1 LBD with kainate in the absence of glycerol confirms that the observed domain closure is not an artifact of crystallization conditions. Comparison of the LBD structures with glutamate and kainate reveals that contacts are lost upon binding of kainate in the three kainate receptors, which is in contrast to the AMPA receptors where similar contacts are seen. It was revealed by patch clamp electrophysiology studies that kainate is a partial agonist at GluK1 with 36% efficacy compared to glutamate, which is in between the published efficacies of kainate at GluK2 and AMPA receptors. The ranking of efficacies seems to correlate with LBD domain closures.