Changes in synaptic potential properties during acetylcholine receptor accumulation and neurospecific interactions in Xenopus nerve-muscle cell culture

Acetylcholine receptors in the muscle cell membrane accumulate at the nerve contact area in Xenopus cell cultures. The correlation between spontaneous synaptic potential properties and extent of acetylcholine receptor accumulation was studied. Small and infrequent miniature endplate potentials were measured before acetylcholine receptor accumulation which was observed with fluorescence microscopy using tetramethylrhodamine-conjugated α-bungarotoxin. As acetylcholine receptors accumulate at the nerve contact area, these synaptic potentials become larger and their frequency increases dramatically. In nerve-contacted muscle cells where spontaneous synaptic activity could not be detected, extensive acetylcholine receptor accumulation was not found at sites of nerve contact. Furthermore, muscle cells which exhibited extensive acetylcholine receptor accumulation along the nerve always produced miniature endplate potentials. Thus acetylcholine receptor accumulation and the presence of miniature endplate potentials were strongly correlated. Noncholinergic neurons from dorsal root ganglia did not form functional synaptic contacts with muscle cells nor acetylcholine receptor accumulation along the path of contact. Furthermore, explants from tadpole spinal cord formed functional synaptic contacts with muscle cells but rarely caused AChR localization. These data are discussed in terms of developmental processes during neuromuscular junction formation.     

The effect of a moving foveal target on the subjective sensation of motion

In this paper, we report on two experiments concerning the effect of the visual field of fovea on the subjective estimation of angular velocity. Experiment 1 investigates the effect of a slow moving target on the perception of self motion. The result of this experiment can be summarized as follows: a slow moving target seen in the visual field of fovea by a stationary person generates in this person a sensation of self rotation in the same direction as the motion of the target. This phenomenon will be called foveal induced ego motion. Experiment 2 investigates the latency for the detection of a self angular acceleration when the person focusses his fovea on a slowly moving target. From the results of this experiment we conclude that the latency for detection of a small self angular acceleration is shorter if the person sees a small foveal target moving with respect to the person in the direction of self rotation than if that small foveal target is moving (with respect to the person) in the opposite direction. The results of these experiments help us in refining existing models of visual-vestibular interaction, by providing a model which accounts for the phenomenon of oculogyral illusion.This research was conducted while serving as a Visiting Professor at the Man Vehicle Laboratory, Department of Aeronautics and Astronautics, Massachusetts Institute of Technology, Cambridge, MA 02139, USA     

The anti-inflammatory effect of LMWF5A and N-acetyl kynurenine on macrophages: Involvement of aryl hydrocarbon receptor in mechanism of action

After a traumatic insult, macrophages can become activated leading to general inflammation at the site of injury. Activated macrophages are partially regulated by the aryl hydrocarbon receptor (AhR) which when activated suppresses inflammation by limiting the secretion of pro-inflammatory cytokines and promoting the over expression of immuno-modulatory mediators. This study aims to determine whether the low molecular weight fraction of 5% human serum albumin (LMWF5A) and N-acetyl kynurenine (NAK), an N-acetyl tryptophan (NAT) breakdown product in LMWF5A, can regulate inflammation by inhibiting macrophage activation through the AhR since kynurenine is a known AhR agonist. Using LCMS, we demonstrate that NAT is non-enzymatically degraded during accelerated aging of LMWF5A with high heat accelerating degradation. More importantly, NAK is a major degradation product found in LMWF5A. THP-1 monocytes were differentiated into macrophages using phorbol 12-myristate 13-acetate (PMA) and pre-treated with 2-fold dilutions of LMWF5A or synthetic NAK with or without an AhR antagonist (CH223191) prior to overnight stimulation with lipopolysaccharide (LPS). Treatment with LMWF5A caused a 50–70% decrease in IL-6 release throughout the dilution series. A dose-response inhibition of IL-6 release was observed for NAK with maximal inhibition (50%) seen at the highest NAK concentration. Finally, an AhR antagonist partially blocked the anti-inflammatory effect of LMWF5A while completely blocking the effect of NAK. A similar inhibitory effect was observed for CXCL-10, but the AhR antagonist was not effective suggesting additional mechanisms for CXCL-10 release. These preliminary findings suggest that LMWF5A and NAK partially promote the suppression of activated macrophages via the AhR receptor. Therefore, LMWF5A, which contains NAK, is potentially a useful therapeutic in medical conditions where inflammation is prevalent such as trauma, sepsis, and wound healing.     

Excited state vibrational spectroscopy of metal complexes of dipyrido[3,2-a:2′,3′-c]phenazine

The use of vibrational spectroscopic methods to elucidate the states present in metal complexes of dipyrido[3,2-a:2,3-c]phenazine (dppz) are reviewed. The presence of the close lying b₁(ψ) and b₁(phz) molecular orbitals leads to a number of close lying intraligand and MLCT excited states. Using resonance Raman spectroscopy the nature of initial photoexcitation may be established as M→b₁(ψ). For Ru(II) complexes the lowest excited state is ³MLCT(phz) in nature. However, for [Re(CO)₃Cl] complexes the relaxation from the initial excited state may lead to population of a ³MLCT(phen), ³MLCT(phz) state, an state, or an equilibrium between these states. Time-resolved resonance Raman spectroscopy may be used to identify the presence of dppz^·- or the state and has also been used to identify features associated with intercalation of dppz complexes with DNA. The Raman methods are less effective at detecting the short time dynamics between these states. However, this may be accomplished using time-resolved infrared spectroscopy in which all three states may be unambiguously determined. The clearest picture of the dynamics in dppz complexes has been achieved by using a combination of time-resolved resonance Raman, time-resolved infrared and DFT calculations for rhenium(I) complexes.     

Programming an in vitro DNA oscillator using a molecular networking strategy

Living organisms perform and control complex behaviours by using webs of chemical reactions organized in precise networks. This powerful system concept, which is at the very core of biology, has recently become a new foundation for bioengineering. Remarkably, however, it is still extremely difficult to rationally create such network architectures in artificial, non‐living and well‐controlled settings. We introduce here a method for such a purpose, on the basis of standard DNA biochemistry. This approach is demonstrated by assembling de novo an efficient chemical oscillator: we encode the wiring of the corresponding network in the sequence of small DNA templates and obtain the predicted dynamics. Our results show that the rational cascading of standard elements opens the possibility to implement complex behaviours in vitro. Because of the simple and well‐controlled environment, the corresponding chemical network is easily amenable to quantitative mathematical analysis. These synthetic systems may thus accelerate our understanding of the underlying principles of biological dynamic modules.