Monodentate, Bidentate and Photocrosslinkable Thiol Ligands for Improving Aqueous Biocompatible Quantum Dots

Water-soluble Quantum Dots (QDs) are highly sensitive fluorescent probes that are often used to study biological species. One of the most common ways to render QDs water-soluble for such applications is to apply hydrophilic thiolated ligands to the QD surface. However, these ligands are labile and can be easily exchanged on the QD surface, which can severely limit their application. As one way to overcome this limitation while maintaining a small colloidal size of QDs, we developed a method to stabilize hydrophilic thiolated ligands on the surface of QDs through the formation of a crosslinked shell using a photocrosslinking approach. This ligand is known to crosslink through ultraviolet (UV) light but, interestingly, our results showed that QD-mediated crosslinking by visible light led to enhanced colloidal stability of the QDs compared to UV light. This was confirmed through spectroscopic, photographic and fluorescence correlation spectroscopy measurements. In order to maximize the biological applications of QDs, it is important to thoroughly investigate the binding and exchange mechanisms of ligands, and especially how these mechanisms affect the ability to control non-specific adsorption of biomolecules. To investigate this, we modified a near-infrared dye to contain a single thiol group to act as a highly sensitive spectroscopic probe for the binding and exchange of thiol groups to monodentate or bidentate ligand-coated QDs. Differences in how monodentate and bidentate ligands control binding of thiolated target (bio)molecules were discovered by fitting the data to the Hill equation. The results highlight how both the coordination geometry and the ligand packing density on the surface of QDs control the binding and exchange mechanisms. The proposed mechanistic scheme was then successfully tested by exposure to a reduced (i.e. -SH containing) antibody. Finally, Förster Resonance Energy Transfer of QD-dye conjugates was studied. At the single molecule level three species were identified: QD without a dye bound, QD with 1 dye attached, and QD with 2 or more dyes attached. The unusual statistical distribution of these different species suggests a highly complex process at the microscopic level. These discoveries will contribute to improving the applications of QDs in biophysical and biomedical studies

Identification of Second Messenger Mediating Signal Transduction in the Olfactory Receptor Cell

One of the biggest controversial issues in the research of olfaction has been the mechanism underlying response generation to odorants that have been shown to fail to produce cAMP when tested by biochemical assays with olfactory ciliary preparations. Such observations are actually the original source proposing a possibility for the presence of multiple and parallel transduction pathways. In this study the activity of transduction channels in the olfactory cilia was recorded in cells that retained their abilities of responding to odorants that have been reported to produce InsP3 (instead of producing cAMP, and therefore tentatively termed “InsP3 odorants”). At the same time, the cytoplasmic cNMP concentration ([cNMP]i) was manipulated through the photolysis of caged compounds to examine their real-time interactions with odorant responses. Properties of responses induced by both InsP3 odorants and cytoplasmic cNMP resembled each other in their unique characteristics. Reversal potentials of currents were 2 mV for InsP3 odorant responses and 3 mV for responses induced by cNMP. Current and voltage (I-V) relations showed slight outward rectification. Both responses showed voltage-dependent adaptation when examined with double pulse protocols. When brief pulses of the InsP3 odorant and cytoplasmic cNMP were applied alternatively, responses expressed cross-adaptation with each other. Furthermore, both responses were additive in a manner as predicted quantitatively by the theory that signal transduction is mediated by the increase in cytoplasmic cAMP. With InsP3 odorants, actually, remarkable responses could be detected in a small fraction of cells (∼2%), explaining the observation for a small production of cAMP in ciliary preparations obtained from the entire epithelium. The data will provide evidence showing that olfactory response generation and adaptation are regulated by a uniform mechanism for a wide variety of odorants

Odorant Inhibition of the Olfactory Cyclic Nucleotide-gated Channel with a Native Molecular Assembly

Human olfaction comprises the opposing actions of excitation and inhibition triggered by odorant molecules. In olfactory receptor neurons, odorant molecules not only trigger a G-protein–coupled signaling cascade but also generate various mechanisms to fine tune the odorant-induced current, including a low-selective odorant inhibition of the olfactory signal. This wide-range olfactory inhibition has been suggested to be at the level of ion channels, but definitive evidence is not available. Here, we report that the cyclic nucleotide-gated (CNG) cation channel, which is a key element that converts odorant stimuli into electrical signals, is inhibited by structurally unrelated odorants, consistent with the expression of wide-range olfactory inhibition. Interestingly, the inhibitory effect was small in the homo-oligomeric CNG channel composed only of the principal channel subunit, CNGA2, but became larger in channels consisting of multiple types of subunits. However, even in the channel containing all native subunits, the potency of the suppression on the cloned CNG channel appeared to be smaller than that previously shown in native olfactory neurons. Nonetheless, our results further showed that odorant suppressions are small in native neurons if the subsequent molecular steps mediated by Ca2+ are removed. Thus, the present work also suggests that CNG channels switch on and off the olfactory signaling pathway, and that the on and off signals may both be amplified by the subsequent olfactory signaling steps

Cross-adaptation between Olfactory Responses Induced by Two Subgroups of Odorant Molecules

It has long been believed that vertebrate olfactory signal transduction is mediated by independent multiple pathways (using cAMP and InsP3 as second messengers). However, the dual presence of parallel pathways in the olfactory receptor cell is still controversial, mainly because of the lack of information regarding the single-cell response induced by odorants that have been shown to produce InsP3 exclusively (but not cAMP) in the olfactory cilia. In this study, we recorded activities of transduction channels of single olfactory receptor cells to InsP3-producing odorants. When the membrane potential was held at −54 mV, application of InsP3-producing odorants to the ciliary region caused an inward current. The reversal potential was 0 ± 7 mV (mean ± SD, n = 10). Actually, InsP3-producing odorants generated responses in a smaller fraction of cells (lilial, 3.4%; lyral, 1.7%) than the cAMP-producing odorant (cineole, 26%). But, fundamental properties of responses were surprisingly homologous; namely, spatial distribution of the sensitivity, waveforms, I-V relation, and reversal potential, dose dependence, time integration of stimulus period, adaptation, and recovery. By applying both types of odorants alternatively to the same cell, furthermore, we observed cells to exhibit symmetrical cross-adaptation. It seems likely that even with odorants with different modalities adaptation occurs completely depending on the amount of current flow. The data will also provide evidence showing that olfactory response generation and adaptation are regulated by a uniform mechanism for a wide variety of odorants

High Time-Resolution Monitoring of Free-Tropospheric Sulfur Dioxide and Nitric Acid at the Summit of Mt. Fuji, Japan

This is the first paper that describes the atmospheric sulfur dioxide (SO2) and nitric acid (HNO3) monitored with a good time-resolution at the summit (3,776 m a.s.l.), which is located in the free troposphere, and southeastern foot (1,284 m a.s.l.) of Mt. Fuji. Japan. During the summer of 2012, two analytical systems consisting mainly of a parallel-plate wet denuder and ion chromatograph operated simultaneously at both the sampling sites. All the samples collected at both the sampling sites contained detectable levels of sulfate from gas-phase SO2 while the nitrate from gas-phase HNO3 was detectable in 97.8% of air samples at the southeastern foot and 88.4% at the summit. The average concentrations of SO2 and HNO3 were, respectively, 0.061 ± 0.071 and 0.031 ± 0.020 ppbv at the summit (n = 672), and 0.347 ± 0.425 and 0.146 ± 0.070 ppbv at the southeastern foot (n = 1344) of Mt. Fuji. Both the acidic gases at the southeastern foot and the HNO3 at the summit showed a diurnal pattern with daytime maxima and nighttime minima. Meanwhile, the SO2 at the summit did not show a distinct shift, which indicates the SO2 concentrations at the summit would be principally controlled by the advection of air parcel in the free troposphere

Macroeconomic Implications of Declines in Nominal Exchange Rate Pass-through Rates (Japanese)

Several studies have found that there have been declines in nominal exchange rate pass-through rates in recent years. In this paper we theoretically analyze the macroeconomic implications of such changes. A special feature of the analysis in the paper is that it builds a dynamic general equilibrium model that consists of two countries for this purpose. In the model there are two types of producers of tradable goods: those that set prices in their own currency and those that set prices in foreign currencies. The pass-through rate in this model is determined by the relative proportions of these two types. By conducting a simulation analysis using this model, we show how macroeconomic performance differs depending on the pass-through rate. Specifically, we derive the responses of prices of domestic import and export goods, inflation rates, GDP, and other indices in response to shocks such as fluctuations in exchange rates and changes in monetary policies in foreign countries, both in a high pass-through rate environment and in a low pass-through rate environment. This exercise reveals that reactions of an economy to external shocks depend in crucial ways on the degree of pass-through.

Very low-density lipoprotein-apoprotein CI is increased in diabetic nephropathy: Comparison with apoprotein CIII

Very low-density lipoprotein-apoprotein CI is increased in diabetic nephropathy: Comparison with apoprotein CIII.BackgroundRecent studies have suggested that apoprotein (apo) CI in very low-density lipoprotein (VLDL) plays an important role in causing hypertriglyceridemia independent of apo CIII, which is associated with coronary heart disease (CHD). Because the incidence of CHD is increased in diabetic patients and is even higher when diabetic nephropathy is developed, we measured apo CI levels in VLDL from type 2 diabetic patients, with various degree of nephropathy, and compared the results with those for healthy controls or nondiabetic patients with chronic renal failure (CRF).MethodsThis study enrolled healthy control subjects, type 2 diabetic patients with normoalbuminuria, microalbuminuria, overt proteinuria, and CRF on hemodialysis and nondiabetic hemodialyis patients. VLDL (density <1.006) was separated by ultracentrifugation. Then the apo CI, CIII, and B concentrations in VLDL were measured by enzyme-linked immunosorbent assay (ELISA).ResultsThe apo CI, CIII, and B concentrations in VLDL were respectively 3-, 2-, and 2-fold higher, respectively, in diabetic patients with overt proteinuria than in controls. Hemodialysis patients with diabetic nephropathy had levels of apo CI, CIII, and B in VLDL that were 2.6-, 2.7- and 2-fold higher, respectively, than those in controls. Nondiabetic hemodialysis patients also had a 2.7-fold higher level of VLDL apo CIII, whereas VLDL apo CI and VLDL apo B were not significantly increased. VLDL apo CI was significantly correlated with VLDL apo B independently of VLDL apo CIII level.ConclusionAn increase of VLDL apo CIII is a prominent feature of dyslipidemia in CRF patients, regardless of whether they are diabetic or nondiabetic, whereas an increase of VLDL apo CI is more specific to diabetic nephropathy and is closely associated with an increase of VLDL particle numbers, a new risk factor for CHD