Paramagnetic probes in membrane biophysics

The use of paramagnetic probes in membrane research is reviewed. Electron paramagnetic resonance studies on model and biological membranes doped with covalent and non-covalent spin-labels have been discussed with special emphasis on the methodology and the type of information obtainable on several important phenomena like membrane fluidity, lipid flip-flop, lateral diffusion of lipids, lipid phase separation, lipid bilayer phase transitions, lipid-protein interactions and membrane permeability. Nuclear magnetic resonance spectroscopy has also been effectively used to study the conformations of cation mediators across membranes and to analyse in detail the transmembrane ionic motions at the mechanistic level.

Search on a fractal lattice using a quantum random walk

The spatial search problem on regular lattice structures in integer number of dimensions d >= 2 has been studied extensively, using both coined and coinless quantum walks. The relativistic Dirac operator has been a crucial ingredient in these studies. Here, we investigate the spatial search problem on fractals of noninteger dimensions. Although the Dirac operator cannot be defined on a fractal, we construct the quantum walk on a fractal using the flip-flop operator that incorporates a Klein-Gordon mode. We find that the scaling behavior of the spatial search is determined by the spectral (and not the fractal) dimension. Our numerical results have been obtained on the well-known Sierpinski gaskets in two and three dimensions.

Modelling Lipid Competition Dynamics in Heterogeneous Protocell Populations

Recent experimental work in the field of synthetic protocell biology has shown that prebiotic vesicles are able to 'steal' lipids from each other. This phenomenon is driven purely by asymmetries in the physical state or composition of the vesicle membranes, and, when lipid resource is limited, translates directly into competition amongst the vesicles. Such a scenario is interesting from an origins of life perspective because a rudimentary form of cell-level selection emerges. To sharpen intuition about possible mechanisms underlying this behaviour, experimental work must be complemented with theoretical modelling. The aim of this paper is to provide a coarse-grain mathematical model of protocell lipid competition. Our model is capable of reproducing, often quantitatively, results from core experimental papers that reported distinct types vesicle competition. Additionally, we make some predictions untested in the lab, and develop a general numerical method for quickly solving the equilibrium point of a model vesicle population.

Human Endogenous Retrovirus HERV-Fc1 Association with Multiple Sclerosis Susceptibility: A Meta-Analysis

Background: Human endogenous retroviruses (HERVs) are repetitive sequences derived from ancestral germ-line infections by exogenous retroviruses and different HERV families have been integrated in the genome. HERV-Fc1 in chromosome X has been previously associated with multiple sclerosis (MS) in Northern European populations. Additionally, HERV-Fc1 RNA levels of expression have been found increased in plasma of MS patients with active disease. Considering the North-South latitude gradient in MS prevalence, we aimed to evaluate the role of HERV-Fc1on MS risk in three independent Spanish cohorts. Methods: A single nucleotide polymorphism near HERV-Fc1, rs391745, was genotyped by Taqman chemistry in a total of 2473 MS patients and 3031 ethnically matched controls, consecutively recruited from: Northern (569 patients and 980 controls), Central (883 patients and 692 controls) and Southern (1021 patients and 1359 controls) Spain. Our results were pooled in a meta-analysis with previously published data. Results: Significant associations of the HERV-Fc1 polymorphism with MS were observed in two Spanish cohorts and the combined meta-analysis with previous data yielded a significant association [rs391745 C-allele carriers: p(M-H) = 0.0005; ORM-H (95% CI) = 1.27 (1.11-1.45)]. Concordantly to previous findings, when the analysis was restricted to relapsing remitting and secondary progressive MS samples, a slight enhancement in the strength of the association was observed [p(M-H) = 0.0003, ORM-H (95% CI) = 1.32 (1.14-1.53)]. Conclusion: Association of the HERV-Fc1 polymorphism rs391745 with bout-onset MS susceptibility was confirmed in Southern European cohorts.

Two Glass Transitions Associated to Different Dynamic Disorders in the Nematic Glassy State of a Non-Symmetric Liquid Crystal Dimer Dopped with gamma-Alumina Nanoparticles

In the present work, the nematic glassy state of the non-symmetric LC dimer -(4-cyanobiphenyl-4-yloxy)--(1-pyrenimine-benzylidene-4-oxy) undecane is studied by means of calorimetric and dielectric measurements. The most striking result of the work is the presence of two different glass transition temperatures: one due to the freezing of the flip-flop motions of the bulkier unit of the dimer and the other, at a lower temperature, related to the freezing of the flip-flop and precessional motions of the cyanobiphenyl unit. This result shows the fact that glass transition is the consequence of the freezing of one or more coupled dynamic disorders and not of the disordered phase itself. In order to avoid crystallization when the bulk sample is cooled down, the LC dimer has been confined via the dispersion of -alumina nanoparticles, in several concentrations.

Fabrication and characterization of active and sequential circuits utilizing Schottky-wrap-gate-controlled GaAs hexagonal nanowire network structures

For realization of hexagonal BDD-based digital systems, active and sequential circuits including inverters, flip flops and ring oscillators are designed and fabricated on GaAs-based hexagonal nanowire networks controlled by Schottky wrap gates (WPGs), and their operations are characterized. Fabricated inverters show comparatively high transfer gain of more than 10. Clear and correct operation of hexagonal set-reset flip flops (SR-FFs) is obtained at room temperature. Fabricated hexagonal D-type flip flop (D-FF) circuits integrating twelve WPG field effect transistors (FETs) show capturing input signal by triggering although the output swing is small. Oscillatory output is successfully obtained in a fabricated 7-stage hexagonal ring oscillator. Obtained results confirm that a good possibility to realize practical digital systems can be implemented by the present circuit approach.

Design of a Frequency Divider with Reduced Complexity Based on a Resonant Tunneling Diode

A novel edge-triggered D-flip-flop based on a resonant tunneling diode (RTD) is proposed and used to construct a binary frequency divider. The design is discussed in detail and the performance of the circuit is verified using SPICE. Relying on the nonlinear characteristics of RTD, we reduced the number of components used in our DFF circuit to only half of that required using conventional CMOS SCFL technology.

Effectiveness of Loss labeling in Improving TCP Performance in Wired/Wireless Networks

The current congestion-oriented design of TCP hinders its ability to perform well in hybrid wireless/wired networks. We propose a new improvement on TCP NewReno (NewReno-FF) using a new loss labeling technique to discriminate wireless from congestion losses. The proposed technique is based on the estimation of average and variance of the round trip time using a filter cal led Flip Flop filter that is augmented with history information. We show the comparative performance of TCP NewReno, NewReno-FF, and TCP Westwood through extensive simulations. We study the fundamental gains and limits using TCP NewReno with varying Loss Labeling accuracy (NewReno-LL) as a benchmark. Lastly our investigation opens up important research directions. First, there is a need for a finer grained classification of losses (even within congestion and wireless losses) for TCP in heterogeneous networks. Second, it is essential to develop an appropriate control strategy for recovery after the correct classification of a packet loss.

A unique and robust single slice FPGA identification generator

In this paper, a new field-programmable gate array (FPGA) identification generator circuit is introduced based on physically unclonable function (PUF) technology. The new identification generator is able to convert flip-flop delay path variations to unique n-bit digital identifiers (IDs), while requiring only a single slice per ID bit by using 1-bit ID cells formed as hard-macros. An exemplary 128-bit identification generator is implemented on ten Xilinx Spartan-6 FPGA devices. Experimental results show an uniqueness of 48.52%, and reliability of 92.41% over a 25°C to 70°C temperature range and 10% fluctuation in supply voltage

Power performance with gated clocks of a pipelined Cordic Core

This paper presents the evaluation in power consumption of gated clocks pipelined circuits with different register configurations in Virtex-based FPGA devices. Power impact of a gated clock circuitry aimed at reducing flip-flops output rate at the bit level is studied. Power performance is also given for pipeline stages based on the implementation of a double edge-triggered flip-flop. Using a pipelined Cordic Core circuit as an example, this study did not find evidence in power benefits either when gated clock at the bit-level or double-edge triggered flip-flops used when synthesized with FPGA logic resources.

Proton flux induced by free fatty acids across phospholipid bilayers: New evidences based on short-circuit measurements in planar lipid membranes

Free fatty acids (FFA) are important mediators of proton transport across membranes. However, information concerning the influence of the Structural features of both FFA and the membrane environment on the proton translocation mechanisms across phospholipid membranes is relatively scant. The effects of FFA chain length, unsaturation and membrane composition on proton transport have been addressed in this study by means of electrical measurements in planar lipid bilayers. Proton conductance (G(H)(+)) was calculated from open-circuit voltage and short-circuit current density measurements. We found that cis-unsaturated FFA caused a more pronounced effect on proton transport as compared to Saturated and trans-unsaturated FFA. Cholesterol and cardiolipin decreased membrane leak conductance. Cardiolipin also decreased proton conductance. These effects indicate a dual modulation of protein-independent proton transport by FFA: through a flip-flop mechanism and by modifying a proton diffusional pathway. Moreover the membrane phospholipid composition was shown to importantly affect both processes. (C) 2009 Elsevier Inc. All rights reserved.

A multisampling time-domain CMOS imager with synchronous readout circuit

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

A multisampling time-domain CMOS imager with synchronous readout circuit

A novel multisampling time-domain architecture for CMOS imagers with synchronous readout and wide dynamic range is proposed. The architecture was implemented in a prototype of imager with 32x32 pixel array fabricated in AMS CMOS 0.35νm and was characterized for sensitivity and color response. The pixel is composed of an n+/psub photodiode, a comparator and a D flip-flop having 16% fill-factor and 30νmx26νm dimensions. The multisampling architecture requires only a 1 bit per pixel memory instead of 8 bits which is typical for time-domain active pixel architectures. The advantage is that the number of transistors in the pixel is low, saving area and providing higher fill-factor. The maximum frame rate is analyzed as a function of number of bits and array size. The analysis shows that it is possible to achieve high frame rates and operation in video mode with 10 bits. Also, we present analysis for the impact of comparator offset voltage in the fixed pattern noise. Copyright 2007 ACM.

Glukose-konjugierte Hemmstoffe als Strategie der gezielten Hemmung des DNA-Reparaturproteins O 6 -Methylguanin-DNA-Methyltransferase in Tumorzellen und der Einfluss von ATP-binding cassette Transportern

Das DNA-Reparaturprotein O6-Methylguanin-DNA-Methyltransferase [MGMT] ist der Hauptresistenzfaktor gegenüber der zytotoxischen Wirkung von SN1-alkylierenden Zytostatika in der Tumortherapie. Die Verwendung der MGMT-Hemmstoffe O6-Benzylguanin [O6BG] und O6-(4-Bromothenyl)guanin [O6BTG] führte zu einer Sensibilisierung des Normalgewebes, was eine Dosis-Reduktion der Zytostatika erforderlich machte und die erhoffte Therapieverbesserung verhinderte. Aus diesem Grund ist eine Strategie der selektiven Hemmung des MGMT-Proteins (Targeting-Strategie) erforderlich, um die systemische Toxizität in der Kombinationsbehandlung zu reduzieren. In dieser Arbeit wurde die Anwendbarkeit der Glukose-Konjugation als Targeting-Strategie untersucht, da Tumorzellen einen erhöhten Glukoseverbrauch aufweisen und demzufolge Glukosetransporter überexprimieren. Die Glukose-Konjugate O6BG-Glu und O6BTG-Glu inhibierten MGMT in Tumorzellen und sensibilisierten die Zellen gegenüber den alkylierenden Agenzien Temozolomid [TMZ] und Lomustin [CCNU]. Des Weiteren inaktivierten die Glukose-Konjugate die MGMT-Aktivität im Tumor eines Xenograft-Mausmodells und reduzierten das Tumorwachstum nach einer TMZ-Behandlung im gleichen Ausmass wie die Inhibitoren O6BG und O6BTG. Trotzdem war auch mit den Glukose-Konjugaten keine Steigerung der Zytostatika-Dosis im Mausmodell möglich. Die Untersuchungen der Aufnahme von O6BG-Glu und O6BTG-Glu wiederlegten eine Involvierung der Glukosetransporter. Der Einsatz von spezifischen Glukosetransporter-Inhibitoren und Kompetitions-Experimenten führte zu keiner Verminderung der MGMT-Hemmung oder Aufnahme vom radioaktiven H3-O6BTG-Glu in die Zelle. Dies legt nahe, dass die Glukose-Konjugate über einen unspezifischen Mechanismus (aktiv) in die Zellen gelangen. Der Grund für eine mögliche unselektive Aufnahme könnte im hydrophoben Alkyllinker, der für die Konjugation des Glukosemoleküls verwendet wurde, begründet sein. Dies führt zur Generierung von amphipathischen Konjugaten, die eine initiale Bindung an die Plasmamembran aufweisen und eine Aufnahme über den Flip-Flop-Mechanismus (transbilayer transport) wahrscheinlich machen. Die amphipathische Molekülstruktur der Glukose-Konjugate führte zu einer Partikelbildung in wässrigen Lösungen, die eine Reduktion der Menge an aktiven Monomeren von O6BG-Glu und O6BTG-Glu bewirken, die zur Hemmung von MGMT zur Verfügung stehen. Der zweite Teil der Arbeit befasste sich mit der Rolle von ABC-Transportern hinsichtlich einer Targeting-Strategie von MGMT-Hemmstoffen. Obwohl eine hohe Expression dieser ABC-Transporter in Tumoren zur Resistenzentwicklung gegenüber Zytostatika führt, wurde ihr Einfluss auf MGMT-Hemmstoffe oder einer MGMT-Targeting-Strategie niemals untersucht. In dieser Arbeit wurde zum ersten Mal ein aktiver Efflux von MGMT-Hemmstoffen durch ABC-Transporter nachgewiesen. Die Inhibition von ABC-Transportern bewirkte eine schnellere Inaktivierung von MGMT durch die Glukose-Konjugate. Des Weiteren zeigten Kompetitions-Experimente mit den MGMT-Hemmstoffen eine verminderte Efflux-Rate von Fluoreszenzfarbstoffen, die spezifisch von ABC-Transportern exportiert werden. ABC-Transporter reduzieren die wirksame Konzentration des Hemmstoffes in der Zelle und beeinträchtigen somit die Effektivität der MGMT-Inhibition. Eine simultane Hemmung der ABC-Transporter P-glycoprotein (P-gp), multi resistance protein 1 (MRP1) and breast cancer resistance protein (BCRP) erhöhte die Effektivität der MGMT-Hemmstoffe (O6BG, O6BTG, O6BG-Glu, O6BTG-Glu) und verstärkte auf diese Weise die TMZ-induzierte Toxizität in Tumorzelllinien. Die Involvierung von ABC-Transportern in der intrazellulären Speicherung von MGMT-Hemmstoffen ist wahrscheinlich die Ursache für die beobachteten Unterschiede in der Sensibilisierung verschiedener Tumorzelllinien gegenüber Zytostatika durch das Glukose-Konjugat O6BG-Glu. Eine Strategie, den Einfluss von ABC-Transportern zu reduzieren und zukünftliche MGMT-Targeting-Strategien effizienter umzusetzen, ist die Verwendung von O6BTG als Ausgangssubstanz. Die höhere Inhibitionsfähigkeit der Bromthiophenmoleküle vermindert die erforderliche intrazelluläre Konzentration für eine vollständige MGMT-Hemmung und reduziert auf diese Weise den Einfluss von ABC-Transportern.

pH-dependent distribution of chlorin e6 derivatives across phospholipid bilayers probed by NMR spectroscopy

The pH-dependent membrane adsorption and distribution of three chlorin derivatives, chlorin e6 (CE), rhodin G7 (RG), and monoaspartyl-chlorin e6 (MACE), in the physiological pH range (pH 6-8) were probed by NMR spectroscopy. Unilamellar vesicles consisting of dioleoyl-phosphatidyl-choline (DOPC) were used as membrane models. The chlorin derivatives were characterized with respect to their aggregation behavior, the pK(a) values of individual carboxylate groups, the extent of membrane adsorption, and their flip-flop rates across the bilayer membrane for pH 6-8. External membrane adsorption was found to be lower for RG than for CE and MACE. Both electrostatic interactions and the extent of aggregation seemed to be the main determinants of membrane adsorption. Rate constants for chlorin transfer across the membrane were found to correlate strongly with the pH of the surrounding medium, in particular, for CE and RG. In acidic solution, CE and RG transfer across the membrane was strongly accelerated, and in basic solution, all compounds were retained, mostly in the outer monolayer. In contrast, MACE flip-flop across the membrane remained very low even at pH 6. The protonation of ionizable groups is suggested to be a major determinant of chlorin transfer rates across the bilayer. pK(a) values of CE and RG were found to be between 6 and 8, and two of the carboxylate groups in MACE had pK(a) values below 6. For CE and RG, the kinetic profiles at acidic pH indicated that the initial fast membrane distribution was followed by secondary steps that are discussed in this article.