Effect of fasting on hypogean (<Emphasis Type="Italic">Niphargus stygius</Emphasis>) and epigean (<Emphasis Type="Italic">Gammarus fossarum</Emphasis>) amphipods: a laboratory study

Two amphipods, the hypogean Niphargus stygius and epigean Gammarus fossarum, were analyzed for fatty acid (FA) composition, electron transport system (ETS) activity and respiration (R) during a laboratory fasting experiment. In agreement with ETS and R measurements (and the ETS/R ratio), the hypogean N. stygius utilized FA more slowly than the epigean G. fossarum. Inter-specific differences in the utilization of certain FA during fasting were also revealed. While N. stygius tended to preserve all of its FA during the experimental fasting period, G. fossarum showed a tendency to utilize MUFA (monounsaturated FA) and SAFA (saturated FA) and preferentially retain PUFA (polyunsaturated FA). The significant correlations between ETS activity and composition of specific FA during fasting can be linked to R. During the fasting, both ETS activity and respiration rate of G. fossarum decreased, however, ETS/R ratio increased. In contrast, N. stygius did not show significant changes in these parameters. This is the first report, which connects ETS activity with changes in concentrations of specific FA during fasting. Such evolutionary adaptations of hypogean species enables them to better survive chronically low and/or discontinuous food supplies compared to epigean species, which live in environments where food shortages are much less frequent.     

Overexpressing AtCKX1 in Potato Plants grown In Vitro: The Effects on Cytokinin Composition and Tuberization

Journal of Plant Growth Regulation - Over the last years, cytokinin deficiency has been studied in a variety of plant species, using transgenic expression of cytokinin oxidase/dehydrogenase genes...     

Molecular detection of Babesia canis in Dermacentor reticulatus ticks collected in Slovakia

Dermacentor reticulatus ticks are recognized as the most important vectors of Babesia canis, the aetiological agent of canine babesiosis occurring throughout Europe. Vector competence of D. reticulatus for B. canis is well described and experimentally determined; however, by using molecular analysis it was proven so by one recent study in Russia. Herein, the additional molecular evidence of B. canis infection in D. reticulatus ticks collected in Slovakia is provided. Using PCR followed by sequencing of distinctive amplicons we determined the presence of Babesia canis canis in one of 100 tested adult ticks. Two zoonotic pathogens, Francisella tularensis and Coxiella burnetii, were previously isolated from D. reticulatus ticks in Slovakia. In our samples, we detected only the presence of F. tularensis.     

A locus conferring tolerance to Theileria infection in African cattle

East Coast fever, a tick-borne cattle disease caused by the Theileria parva parasite, is among the biggest natural killers of cattle in East Africa, leading to over 1 million deaths annually. Here we report on the genetic analysis of a cohort of Bos indicus (Boran) cattle demonstrating heritable tolerance to infection with T. parva (h² = 0.65, s.e. 0.57). Through a linkage analysis we identify a 6 Mb genomic region on bovine chromosome 15 that is significantly associated with survival outcome following T. parva exposure. Testing this locus in an independent cohort of animals replicates this association with survival following T. parva infection. A stop gained variant in a paralogue of the FAF1 gene in this region was found to be highly associated with survival across both related and unrelated animals, with only one of the 20 homozygote carriers (T/T) of this change succumbing to the disease in contrast to 44 out of 97 animals homozygote for the reference allele (C/C). Consequently, we present a genetic locus linked to tolerance of one of Africa’s most important cattle diseases, raising the promise of marker-assisted selection for cattle that are less susceptible to infection by T. parva.     

Intensity of mineralization in the hyporheic zone of the prealpine river Bača (West Slovenia)

Respiratory electron transport system (ETS) activity and oxygen consumption in the interstitial water, and in the fine (i.e. silt) and coarse (sand) sediment fractions from the hyporheic zone of the prealpine river Bača (W Slovenia) have been measured in order to estimate the intensity of potential and actual carbon mineralization through microbial communities. Hyporheic samples from the river bed (RB) and gravel bars (GB) were compared. ETS activity and oxygen consumption of all fractions from the RB did not differ significantly from those from the GB. ETS activity and oxygen consumption of biofilm attached to 1 g of the silt were higher than of that attached to the same mass of the sand. A significant correlation between ETS activity and oxygen consumption indicated that the former should be a good indicator of intensity of bioactivity in hyporheic sediments. The ratio of ETS activity to oxygen consumption (ETS/R ratio) revealed that the oxygen consumption of microorganisms is responsible for approximately 60% of the metabolic potential in the hyporheic sediments. The contributions of different fractions of sediment to the total ETS activity differed between RB and GB. The contribution of microorganisms in the interstitial water and silt was higher in GB than in the RB, but the sand fraction contributed less to potential carbon loss in GB than in the RB. Average total respiratory carbon loss per volume through the hyporheic zone was higher in the RB than in GB. The main reasons suggested are the different intensity of exchange of surface water with the hyporheic zone, and the rate of consolidation of sediments, which is primarily a function of river hydrology and geomorphology. Handling editor: J. Padisak     

Somatodendritic serotonin release and re-uptake in mouse embryonic stem cell-derived serotonergic neurons

Serotonergic neurotransmission plays an important role during neural development. Serotonergic dysfunction is observed in various psychiatric disorders and many psychoactive drugs target proteins on serotonergic neurons. Serotonergic neurons are located in the raphé nuclei and densely innervate the whole brain. The low number and the intricate accessibility of these neurons do not allow to culture them and therefore to date it was impossible to study drug-target interactions on bona fide serotonergic neurons. In order to circumvent such problems we have developed a protocol that allows the rapid and efficient generation of serotonergic neurons from mouse embryonic stem cells. Neuronal precursors were obtained by neuronal stem sphere formation in floating culture in the presence of various mitogens. Differentiation into neurons was induced by withdrawal of the mitogens. About 90% of the resulting neurons exhibited a serotonergic phenotype as judged by immunostaining against serotonin, its synthesising enzyme tryptophan hydroxylase 2, the serotonin transporter as well as 5-HT1(A) and 5-HT1(B) autoreceptors. In addition, we found expression of the vesicular monoamine transporter vMAT2 and the presynaptic protein Bassoon, which is involved in organizing the assembly of the presynaptic active zone. Depolarisation-induced calcium influx was visualised by Fluo-4, and accompanying exocytotic events by FM dye staining. Proteins involved in 5-HT release and re-uptake as well as depolarisation evoked exocytosis were evenly co-distributed on neurites and cell bodies suggesting that ES cell-derived serotonergic neurons also exhibit somatodendritic release comparable to serotonergic neurons in the raphé nuclei.     

Plasmalogen synthesis is regulated via alkyl-dihydroxyacetonephosphate-synthase by amyloid precursor protein processing and is affected in Alzheimer's disease

Lipids play an important role as risk or protective factors in Alzheimer's disease, which is characterized by amyloid plaques composed of aggregated amyloid-beta. Plasmalogens are major brain lipids and controversially discussed to be altered in Alzheimer's disease (AD) and whether changes in plasmalogens are cause or consequence of AD pathology. Here, we reveal a new physiological function of the amyloid precursor protein (APP) in plasmalogen metabolism. The APP intracellular domain was found in vivo and in vitro to increase the expression of the alkyl-dihydroxyacetonephosphate-synthase (AGPS), a rate limiting enzyme in plasmalogen synthesis. Alterations in APP dependent changes of AGPS expression result in reduced protein and plasmalogen levels. Under the pathological situation of AD, increased amyloid-beta level lead to increased reactive oxidative species production, reduced AGPS protein and plasmalogen level. Accordingly, phosphatidylethanol plasmalogen was decreased in the frontal cortex of AD compared to age matched controls. Our findings elucidate that plasmalogens are decreased as a consequence of AD and regulated by APP processing under physiological conditions.