Dopamine transporter relation to levodopa-derived synaptic dopamine in a rat model of Parkinson's: an in vivo imaging study

Studies showed that the dopamine (DA) transporter (DAT) modulates changes in levodopa-derived synaptic dopamine levels (Δ(DA)) in Parkinson's disease (PD). Here we evaluate the relationship between DAT and Δ(DA) in the 6-hydroxydopamine model of Parkinson's disease to investigate these mechanisms as a function of dopaminergic denervation and in relation to other denervation-induced regulatory changes. 27 rats with a unilateral 6-hydroxydopamine lesion (denervation ∼20–97%) were imaged with ¹¹C-dihydrotetrabenazine (VMAT2 marker), ¹¹C-methylphenidate (DAT marker) and ¹¹C-raclopride (D2-type receptor marker). For denervation <75%Δ(DA) was significantly correlated with a combination of relatively preserved terminal density and lower DAT. For denervation <90%, Δ(DA) was significantly negatively correlated with DAT with a weaker dependence on VMAT2. For the entire data set, no dependence on pre-synaptic markers was observed; Δ(DA) was significantly positively correlated with ¹¹C-raclopride binding-derived estimates of DA loss. These findings parallel observations in humans, and show that (i) regulatory changes attempt to normalize synaptic DA levels (ii) a lesion-induced functional dependence of Δ(DA) on DAT occurs up to ∼ 90% denervation (iii) for denervation < 75% relative lower DAT levels may relate to effective compensation; for higher denervation, lower DAT levels likely contribute to oscillations in synaptic DA associated with dyskinesias.     

Surface structure of the two porcine low-density lipoprotein subclasses — a spin labelling study

Porcine low-density lipoprotein (LDL) subclasses were spin-labelled at both protein and lipid sites. The surface structures of the two subclasses were compared. E.s.r. spectra of stearic acid spin-labels [I(m/n)] and of androstanol spin-label indicated more restricted motion of the labels in LDL₂ (d = 1.063?1.090 g/ml) than in LDL₁ (d = 1.020?1.063 g/ml). Thermotropic change in the surface structure was found in both subclasses by both protein and lipid spin-labels, but at lower temperature in LDl₁, than in LDL₂. These results indicate the relationship between the size and the dynamics of the lipid components in the surface layer of the LDL subclasses.     

Temperature-dependent conformation change in spin-labeled hemoglobin

Hemoglobin was spin labeled at β-93(F9)-cysteine with N-oxy-2,2,6,6-tetramelhylpiperidinylmaleimide. The inward shift of the high-field hyperfine line (ΔH_XXX) position in the ESR spectra of the Spin label was measured aS a function of temperature. One can expect that an abrupt change in the microenvironment around the tightly bound spin label will be reflected in the function ΔH_XXX(T) as a discontinuity (break point). This was shown for aquo-, azido-. nitro- and oxyhemoglobin derivatives. The presented results suggest that the microenvironment around the tightly hound spin label in those methemoglobin derivatives that exhibit the mixed-spin state of the heme iron is prone to an abrupt change above a certain ligand-specific temperature. The change in microenvironment of the spin label is probably due to a temperature-dependent change in the tertiary structure of the protein.     

Adhesion of Acinetobacter venetianus to Diesel Fuel Droplets Studied with In Situ Electrochemical and Molecular Probes

The adhesion of a recently described species, Acinetobacter venetianus VE-C3 (F. Di Cello, M. Pepi, F. Baldi, and R. Fani, Res. Microbiol. 148:237–249, 1997), to diesel fuel (a mixture of C₁₂ to C₂₈ n-alkanes) and n-hexadecane was studied and compared to that of Acinetobacter sp. strain RAG-1, which is known to excrete the emulsifying lipopolysaccharide, emulsan. Oxygen consumption rates, biomass, cell hydrophobicity, electrophoretic mobility, and zeta potential were measured for the two strains. The dropping-mercury electrode (DME) was used as an in situ adhesion sensor. In seawater, RAG-1 was hydrophobic, with an electrophoretic mobility (μ) of −0.38 × 10⁻⁸ m² V⁻¹ s⁻¹ and zeta potential (ζ) of −4.9 mV, while VE-C3 was hydrophilic, with μ of −0.81 × 10⁻⁸ m² V⁻¹ s⁻¹ and ζ of −10.5 mV. The microbial adhesion to hydrocarbon (MATH) test showed that RAG-1 was always hydrophobic whereas the hydrophilic VE-C3 strain became hydrophobic only after exposure to n-alkanes. Adhesion of VE-C3 cells to diesel fuel was partly due to the production of capsular polysaccharides (CPS), which were stained with the lectin concanavalin A (ConA) conjugated to fluorescein isothiocyanate and observed in situ by confocal microscopy. The emulsan from RAG-1, which was negative to ConA, was stained with Nile Red fluorochrome instead. Confocal microscope observations at different times showed that VE-C3 underwent two types of adhesion: (i) cell-to-cell interactions, preceding the cell adhesion to the n-alkane, and (ii) incorporation of nanodroplets of n-alkane into the hydrophilic CPS to form a more hydrophobic polysaccharide–n-alkane matrix surrounding the cell wall. The incorporation of n-alkanes as nanodroplets into the CPS of VE-C3 cells might ensure the partitioning of the bulk apolar phase between the aqueous medium and the outer cell membrane and thus sustain a continuous growth rate over a prolonged period.     

Comparative study of Ca2+ binding to lipoprotein(a) and low density lipoprotein by spin labeling

The effect of Ca2+ binding on the dynamic properties of various spin labeled fatty acids in lipoprotein(a) (Lp(a)) was studied in comparison with low density lipoprotein (LDL) isolated from human plasma. In contrast to LDL, binding of Ca2+ to Lp(a) induced broadening of the lines in the ESR spectra of the spin labeled stearic acids. In 1.6 M NaBr solutions the thermotropic change in the surface structure was observed in both lipoproteins at similar temperatures. Ten millimolar concentration of Ca2+ shifted the temperature of the thermotropic change in the surface structure of Lp(a) to considerably higher values. We conclude that Ca2+ binding to Lp(a) induces changes in the lipid structure of the particle surface.