Solution structure of the Mesorhizobium loti K1 channel cyclic nucleotide‐binding domain in complex with cAMP

Cyclic nucleotide‐sensitive ion channels, known as HCN and CNG channels, are crucial in neuronal excitability and signal transduction of sensory cells. HCN and CNG channels are activated by binding of cyclic nucleotides to their intracellular cyclic nucleotide‐binding domain (CNBD). However, the mechanism by which the binding of cyclic nucleotides opens these channels is not well understood. Here, we report the solution structure of the isolated CNBD of a cyclic nucleotide‐sensitive K⁺ channel from Mesorhizobium loti. The protein consists of a wide anti‐parallel β‐roll topped by a helical bundle comprising five α‐helices and a short 3₁₀‐helix. In contrast to the dimeric arrangement (‘dimer‐of‐dimers’) in the crystal structure, the solution structure clearly shows a monomeric fold. The monomeric structure of the CNBD supports the hypothesis that the CNBDs transmit the binding signal to the channel pore independently of each other.     

Isothermal micro calorimetry - a new method for MIC determinations: results for 12 antibiotics and reference strains of E. coli and S. aureus

Background  

Antimicrobial susceptibility testing of microorganisms is performed by either disc diffusion or broth dilution tests. In clinical use, the tests are often still performed manually although automated systems exist. Most systems, however, are based on turbidometric methods which have well-known drawbacks.     

Interaction of α-conotoxin ImII and its analogs with nicotinic receptors and acetylcholine-binding proteins: additional binding sites on Torpedo receptor

α-Conotoxins interact with nicotinic acetylcholine receptors (nAChRs) and acetylcholine-binding proteins (AChBPs) at the sites for agonists/competitive antagonists. α-Conotoxins blocking muscle-type or α7 nAChRs compete with α-bungarotoxin. However, α-conotoxin ImII, a close homolog of the α7 nAChR-targeting α-conotoxin ImI, blocked α7 and muscle nAChRs without displacing α-bungarotoxin ( Ellison et al. 2003, 2004 ), suggesting binding at a different site. We synthesized α-conotoxin ImII, its ribbon isomer (ImII iso ), 'mutant' ImII(W10Y) and found similar potencies in blocking human α7 and muscle nAChRs in Xenopus oocytes. Both isomers displaced [¹²⁵I]-α-bungarotoxin from human α7 nAChRs in the cell line GH₄C₁ (IC₅₀ 17 and 23 μM, respectively) and from Lymnaea stagnalis and Aplysia californica AChBPs (IC₅₀ 2.0–9.0 μM). According to SPR measurements, both isomers bound to immobilized AChBPs and competed with AChBP for immobilized α-bungarotoxin ( K _d and IC₅₀ 2.5–8.2 μM). On Torpedo nAChR, α-conotoxin [¹²⁵I]-ImII(W10Y) revealed specific binding ( K _d 1.5–6.1 μM) and could be displaced by α-conotoxin ImII, ImII iso and ImII(W10Y) with IC₅₀ 2.7, 2.2 and 3.1 μM, respectively. As α-cobratoxin and α-conotoxin ImI displaced [¹²⁵I]-ImII(W10Y) only at higher concentrations (IC₅₀≥ 90 μM), our results indicate that α-conotoxin ImII and its congeners have an additional binding site on Torpedo nAChR distinct from the site for agonists/competitive antagonists.     

Adaptation of neuronal cells to chronic oxidative stress is associated with altered cholesterol and sphingolipid homeostasis and lysosomal function

Chronic oxidative stress has been causally linked to several neurodegenerative disorders. As sensitivity for oxidative stress greatly differs between brain regions and neuronal cell types, specific cellular mechanisms of adaptation to chronic oxidative stress should exist. Our objective was to identify molecular mechanisms of adaptation of neuronal cells after applying chronic sublethal oxidative stress. We demonstrate that cells resistant to oxidative stress exhibit altered cholesterol and sphingomyelin metabolisms. Stress-resistant cells showed reduced levels of molecules involved in cholesterol trafficking and intracellular accumulation of cholesterol, cholesterol precursors, and metabolites. Moreover, stress-resistant cells exhibited reduced SMase activity. The altered lipid metabolism was associated with enhanced autophagy. Treatment of stress-resistant cells with neutral SMase reversed the stress-resistant phenotype, whereas it could be mimicked by treatment of neuronal cells with a specific inhibitor of neutral SMase. Analysis of hippocampal and cerebellar tissue of mouse brains revealed that the obtained cell culture data reflect the in vivo situation. Stress-resistant cells in vitro showed similar features as the less vulnerable cerebellum in mice, whereas stress-sensitive cells resembled the highly sensitive hippocampal area. These findings suggest an important role of the cell type-specific lipid profile for differential vulnerabilities of different brain areas toward chronic oxidative stress.     

Metabolic Engineering with power-law and linear-logarithmic systems

Metabolic Engineering aims to improve the performance of biotechnological processes through rational manipulation rather than random mutagenesis of the organisms involved. Such a strategy can only succeed when a mathematical model of the target process is available. Simplifying assumptions are often needed to cope with the complexity of such models in an efficient way, and the choice of such assumptions often leads to models that fall within a certain structural template or formalism. The most popular formalisms can be grouped in two categories: power-law and linear-logarithmic. As optimization and analysis of a model strongly depends on its structure, most methods in Metabolic Engineering have been defined within a given formalism and never used in any other.In this work, the four most commonly used formalisms (two power-law and two linear-logarithmic) are placed in a common framework defined within Biochemical Systems Theory. This framework defines every model as matrix equations in terms of the same parameters, enabling the formulation of a common steady state analysis and providing means for translating models and methods from one formalism to another. Several Metabolic Engineering methods are analysed here and shown to be variants of a single equation. Particularly, two problem solving philosophies are compared: the application of the design equation and the solution of constrained optimization problems. Generalizing the design equation to all the formalisms shows it to be interchangeable with the direct solution of the rate law in matrix form. Furthermore, optimization approaches are concluded to be preferable since they speed the exploration of the feasible space, implement a better specification of the problem and exclude unrealistic results.Beyond consolidating existing knowledge and enabling comparison, the systematic approach adopted here can fill the gaps between the different methods and combine their strengths.     

Expression of parasite virulence at different host population densities under natural conditions

It has recently been suggested that the expression of parasite virulence depends on host population density, such that infected hosts have a higher sensitivity to density, and thus reach their carrying capacity earlier than uninfected hosts. In this scenario, parasite-induced reduction in fitness (i.e., virulence) increases with host density. We tested this hypothesis experimentally, using outdoor mesocosm populations of Daphnia magna infected by the microsporidian Octosporea bayeri. Contrary to the prediction, virulence was independent of host density. In a competition experiment with initial prevalence of 50%, O. bayeri reduced the competitive ability of infected Daphnia within the asexual growth phase independent of initial host population density. In an additional experiment we set up populations with 100% and 0% prevalence and followed their population dynamics over the whole season. Consistent with the competition experiment, we found no difference in population dynamics within the asexual growth phase of the host, suggesting that infected hosts are not more sensitive to density than uninfected hosts. The additional experiment, however, included more than the initial growth phase as did the competition experiment. Eventually, after 100 days, 100% infected populations assumed a reduced carrying capacity compared to uninfected populations. We identify and discuss three reasons for the discrepancy between our experiment and the predictions.     

Sinapoyltransferases in the light of molecular evolution

Acylation is a prevalent chemical modification that to a significant extent accounts for the tremendous diversity of plant metabolites. To catalyze acyl transfer reactions, higher plants have evolved acyltransferases that accept β-acetal esters, typically 1-O-glucose esters, as an alternative to the ubiquitously occurring CoA-thioester-dependent enzymes. Shared homology indicates that the β-acetal ester-dependent acyltransferases are derived from a common hydrolytic ancestor of the Serine CarboxyPeptidase (SCP) type, giving rise to the name Serine CarboxyPeptidase-Like (SCPL) acyltransferases. We have analyzed structure–function relationships, reaction mechanism and sequence evolution of Arabidopsis 1-O-sinapoyl-β-glucose:l-malate sinapoyltransferase (AtSMT) and related enzymes to investigate molecular changes required to impart acyltransferase activity to hydrolytic enzymes. AtSMT has maintained the catalytic triad of the hydrolytic ancestor as well as part of the H-bond network for substrate recognition to bind the acyl acceptor l-malate. A Glu/Asp substitution at the amino acid position preceding the catalytic Ser supports binding of the acyl donor 1-O-sinapoyl-β-glucose and was found highly conserved among SCPL acyltransferases. The AtSMT-catalyzed acyl transfer reaction follows a random sequential bi-bi mechanism that requires both substrates 1-O-sinapoyl-β-glucose and l-malate bound in an enzyme donor–acceptor complex to initiate acyl transfer. Together with the strong fixation of the acyl acceptor l-malate, the acquisition of this reaction mechanism favours transacylation over hydrolysis in AtSMT catalysis. The model structure and enzymatic side activities reveal that the AtSMT-mediated acyl transfer proceeds via a short-lived acyl enzyme complex. With regard to evolution, the SCPL acyltransferase clade most likely represents a recent development. The encoding genes are organized in a tandem-arranged cluster with partly overlapping functions. With other enzymes encoded by the respective gene cluster on Arabidopsis chromosome 2, AtSMT shares the enzymatic side activity to disproportionate 1-O-sinapoyl-β-glucoses to produce 1,2-di-O-sinapoyl-β-glucose. In the absence of the acyl acceptor l-malate, a residual esterase activity became obvious as a remnant of the hydrolytic ancestor. With regard to the evolution of Arabidopsis SCPL acyltransferases, our results suggest early neofunctionalization of the hydrolytic ancestor toward acyltransferase activity and acyl donor specificity for 1-O-sinapoyl-β-glucose followed by subfunctionalization to recognize different acyl acceptors.     

The genus Taxodium (Cupressaceae) in the Palaeogene and Neogene of Central Europe

Fossil remains of Taxodium from upper Eocene to lower Miocene localities in Germany, the Czech Republic and Russia are investigated to reconsider taxonomic concepts. It is demonstrated that all material belongs to one species which is named Taxodium dubium (Sternberg) Heer emend. Using the whole-plant concept, T. dubium is considered as a synthetic species comprising foliage, seed cones, seeds, and male cones with pollen in situ. Shared identity of T. dubium and the wood morpho-taxon Taxodioxylon taxodii Gothan is assumed. Taxodium dubium underwent evolutionary changes through the Oligocene expressed mainly in changes of the cone scale ornamentation. To designate this intraspecific variation taxonomically two morpho-formae are distinguished: T. dubium forma heerii (Dorofeev) Kunzmann, Kva?ek, Mai et Walther stat. nov. et emend. and T. dubium forma dubium. Simultaneous intraspecific variations in leaf morphology and leaf epidermal anatomy are missing. Taxodium dubium occurs from the late Eocene to late Miocene in the (Atlantic-) Boreal province sensu Mai of Central Europe and from the late Oligocene to late Pliocene in the Transeuropean Paratethys province sensu Mai.     

Morphological, physiological and behavioural evaluation of a ‘Mice in Space’ housing system

Environmental conditions likely affect physiology and behaviour of mice used for life sciences research on Earth or in Space. Here, we analysed the effects of cage confinement on the weightbearing musculoskeletal system, behaviour and stress of wild-type mice (C57BL/6JRj, 30 g b.wt., total n = 24) housed for 25 days in a prototypical ground-based and fully automated life support habitat device called “Mice in Space” (MIS). Compared with control housing (individually ventilated cages) the MIS mice revealed no significant changes in soleus muscle size and myofiber distribution (type I vs. II) and quality of bone (3-D microarchitecture and mineralisation of calvaria, spine and femur) determined by confocal and micro-computed tomography. Corticosterone metabolism measured non-invasively (faeces) monitored elevated adrenocortical activity at only start of the MIS cage confinement (day 1). Behavioural tests (i.e., grip strength, rotarod, L/D box, elevated plus-maze, open field, aggressiveness) performed subsequently revealed only minor changes in motor performance (MIS vs. controls). The MIS habitat will not, on its own, produce major effects that could confound interpretation of data induced by microgravity exposure during spaceflight. Our results may be even more helpful in developing multidisciplinary protocols with adequate scenarios addressing molecular to systems levels using mice of various genetic phenotypes in many laboratories. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.