Kinetic analysis of central [76Br]bromolisuride binding to dopamine D2 receptors studied by PET.

The in vivo kinetic analysis of dopamine D2 receptors was obtained in baboon brain using positron emission tomography (PET) and [76Br]bromolisuride [( 76Br]BLIS) as radioligand. An injection of a trace amount of [76Br]BLIS was followed 3 h later by an injection of a mixture of [76Br]BLIS and BLIS in the same syringe (coinjection experiment). A third injection performed at 6 h was either an excess of unlabeled ligand (displacement experiment) or a second coinjection. This protocol allowed us to evaluate in the striatum of each animal and after a single experiment the quantity of available receptors (B'max) and the kinetic parameters including the association and dissociation rate constants (k + 1VR and k-1, respectively, where VR is the volume of reaction). The cerebellum data were fitted using a model without specific binding. All the parameters were estimated using nonlinear mathematical models of the ligand-receptor interactions including or not including nonspecific binding. The plasma time-concentration curve was used as an input function after correction for the metabolites. An estimate of standard errors was obtained for each PET study and for each identified parameter using the covariance matrix. The average values of B'max and KdVR were 73 +/- 11 pmol/ml tissue and 1.9 +/- 0.9 pmol/ml, respectively. The nonspecific binding was identifiable in the experiment where the last injection corresponded to a second coinjection. We found that approximately 6% of the striatal binding was nonspecific after a tracer injection of [76Br]BLIS. The nonspecific binding appeared to be reversible in the striatum but irreversible in the cerebellum.

[76Br]bromolisuride: a new tool for quantitative in vivo imaging of D-2 dopamine receptors.

Bromolisuride, an ergoline derivative, was labeled with the positron emitter radionuclide, bromine 76. In vitro and in vivo binding and competition studies in rats demonstrated a high affinity (KD = 0.3 nM) and a high specificity of this new radioligand for D-2 dopamine receptors. PET kinetic studies in baboons showed an accumulation of [76Br]bromolisuride in the striatum which reached a maximum 30 min post-injection and which could be displaced by haloperidol. All these results indicated that this new ligand is certainly suitable for the non-invasive in vivo quantitative imaging of D-2 dopamine receptor sites in human brain.

In vivo visualization of central muscarinic receptors using [11C]quinuclidinyl benzilate and positron emission tomography in baboons.

The muscarinic antagonist, quinuclidinyl benzilate (QNB), labeled with carbon 11 was used as a radioligand to visualize in vivo by positron emission tomography (PET) the central muscarinic acetylcholine receptors (mAChR) in baboons (Papio papio). The binding characteristics of [11C]QNB showed its specific binding to central mAChR. [11C]QNB brain uptake was high in cerebral cortex and striatum, areas that are rich in mAChR, whereas it decreased rapidly in cerebellum, evidencing non-specific binding in this structure that is almost devoid of mAChR. These results are consistent with the known cerebral distribution of mAChR in primates. [11C]QNB specific cerebral binding was enhanced by pretreatment with methyl-QNB, a peripherally acting muscarinic antagonist. Specifically labeled binding sites alone were blocked by prior administration of dexetimide, a muscarinic antagonist. Specific radioactivity was driven out from mAChR-rich regions by atropine and dexetimide, drugs with high affinity for mAChR. This competition was stereospecific since only dexetimide, the pharmacologically active isomer of benzetimide, was able to compete with the radioligand on its binding sites. A relationship between the occupancy of [11C]QNB-labeled receptors by atropine or dexetimide and the concomitant induction of a pharmacological effect was also detected by simultaneous PET scanning and electroencephalographic recording. Since mAChR form an important part of choline receptors in the central nervous system, [11C]QNB appears to be a suitable radiotracer to monitor cerebral physiological or pathological phenomena linked to the cholinergic system in living subjects.

"In vivo" visualization by positron emission tomography of the progressive striatal dopamine receptor damage occurring in MPTP-intoxicated non-human primates.

Intravenous administration of 1-methyl-4-phenyl-1,2,3,6,-tetrahydropyridine (MPTP) leads to the progressive development of a model of Parkinson's disease in the primate. The development of damage occurring in the striatal area during MPTP-treatment was followed "in vivo" in a baboon by positron emission tomography (PET). Spiperone labelled with a positron emitter 76Br (76Br-BSP) was used for the quantitative "in vivo" imaging of D2 dopamine receptors. The decrease in the striatal binding of 76Br-BSP measured "in vivo", after three series of MPTP injections, paralleled the increase in the severity of behavioral symptoms seen immediately after administration of the neurotoxin. At the end of the MPTP-treatment when neurological symptoms were the most important, a 36% decrease in the 76Br-BSP specific binding was measured. Between the series of MPTP injections a partial recovery in the quantitative measurement of the 76Br-BSP specific binding occurring in the striatum was well correlated with the disappearance of the neurological syndrome. Post-mortem histological and biochemical studies in nigro-striatal anatomical structures of MPTP-intoxicated primates compared with control animals showed a 80% loss of neuronal cell bodies in the substantia nigra compacta and a 42% decrease in the density (Bmax) of D2 receptors (in vitro 3H-spiperone binding). All these results showed that the use of PET and 76Br-BSP allow to follow in a noninvasive way both the degenerative processes and the subsequent partial recovery which occur in dopaminergic striatal receptor function during MPTP-treatment.

Binding and exchange of nucleotides on the chloroplast coupling factor CF1. The role of magnesium.

On the soluble part of the coupling factor (CF1), extracted from spinach chloroplasts, three nucleotide-binding sites are identified. Three ADP are bound per CF1 when the enzyme is incubated with ADP either with or without Mg2+. Two ADP and one ATP are bound per CF1 when the enzyme is incubated with a limiting concentration of ATP, in the presence of Mg2+. At high ATP concentration, in the presence of Mg2+, one free ATP exchanges with one bound ADP and two ATP and one ADP remain bound per CF1. When Mg2+ is omitted from the incubation medium of ATP and CF1, only two ADP and around 0.5 ATP are bound per CF1. The three nucleotide binding sites of CF1 fall into two different and independent categories according to the ability of the bound nucleotides to be exchanged with free nucleotides. On one site the bound ADP is difficult to exchange. On the other two sites, the bound nucleotides. ADP or ATP, are readily exchangable. We propose that the two exchangeable sites form the catalytic part of the enzyme where ATP is hydrolyzed. When ATP concentration is high enough, in the presence of Mg2+, one ATP displaces one bound ADP and allows the ATP hydrolysis to proceed. We propose too that the site where ADP is difficult to exchange may represent the 'tight' ADP-binding site, different from the catalytic ones, which becomes exchangeable on the CF1 in vivo when the thylakoid membranes are energized by light, as stressed by Bickel-Sandkötter and Strotman [(1976) FEBS Lett. 65, 102-106].

[55Co]- and [64Cu]DTPA: new radiopharmaceuticals for quantitative tomocisternography.

The diethylenetriaminepentaacetic acid (DTPA) complexes of the convenient half-life positron emitters 55Co and 64Cu have been prepared for quantitation of cerebrospinal fluid (CSF) kinetics in different areas of the brain using positron emission tomography. The radionuclides are prepared by proton bombardment of natural nickel (58Ni(p, alpha)55 Co and 64Ni (p,n)64Cu reactions). The chemical separation of the radionuclides from the target is described, and the production yields, radionuclidic purities and specific activities are given.

Synthesis, tissue distribution in rats and PET studies in baboon brain of no-carrier-added [18F]RU 52461: in vivo evaluation as a brain glucocorticoid receptor radioligand.

11,17 beta-Dihydroxy-6-methyl-17 alpha-(3-[18F]fluoro-prop-1- ynyl)androsta-1,4,6-trien-3-one [( 18F]RU 52461), an 18F-analog of RU 28362, was synthesized by bromide displacement with [18F]fluoride in 12-30% overall radiochemical yield (decay-corrected) within 140 min from end of bombardment (EOB). The specific activity was 900-1500 mCi/mumol (33.3-55.5 GBq/mumol) at the end of synthesis (EOS). Biodistribution studies indicated high adrenal and pituitary retention, and uniformly low uptake of [18F]RU 52461 in all other brain regions of the rat. Except for the pituitary, no specific receptor-mediated uptake of [18F]RU 52461 could be demonstrated using saturating doses of unlabeled RU 52461 in rat brain. While no change was observed throughout the brain areas in adrenalectomized rats and in animals coinjected with dexamethasone, when compared to controls. PET studies revealed extremely low levels of radioactivity in baboon brain. Therefore, [18F]RU 52461 does not appear to cross the blood-brain barrier, suggesting that this radiopharmaceutical is not suitable to visualize the brain glucocorticoid binding sites by PET.

Muscarinic cholinergic receptor in the human heart evidenced under physiological conditions by positron emission tomography.

The muscarinic receptor was studied in vivo in the human heart by a noninvasive method, positron emission tomography (PET). The study showed that the binding sites of 11C-labeled methiodide quinuclidinyl benzilate [( 11C]-MQNB), a muscarinic antagonist, were mainly distributed in the ventricular septum (98 pmol/cm3 of heart) and in the left ventricular wall (89 pmol/cm3), while the atria were not visualized. A few minutes after a bolus intravenous injection, the concentration of [11C]MQNB in blood fell to a negligible level (less than 100th of the concentration measured in the ventricular septum). When injected at high specific radioactivity, the concentration of [11C]MQNB in the septum rapidly increased and then remained constant with time. This result was explained by rebinding of the ligand to receptors. It was the major difference observed between the kinetics of binding of [11C]MQNB to receptor sites after intravenous injection in vivo and that of [3H]MQNB to heart homogenates in vitro. The MQNB concentrations in the ventricular septum of different individuals were found to be highest when the heart rate at the time of injection was slow. This result suggests that the antagonist binding site is related to a low-affinity conformational state of the receptor under predominant vagal stimulation. Thus, positron emission tomography might be the ideal method to study the physiologically active form of the muscarinic acetylcholine receptor in man.

Synthesis, affinity and specificity of 18F-setoperone, a potential ligand for in-vivo imaging of cortical serotonin receptors.

Setoperone, a piperidine derivative known for its potent serotonin and moderate dopamine receptor blocking properties was labelled with the positron emitter 18F using a nucleophilic substitution on the nitro derivative. The general pattern of the in-vivo and in-vitro rat brain distribution of this new radioligand was consistent with the mapping of serotonin (5HT2) and dopamine (D2) receptors. The cortical binding of 18F-setoperone was selectively inhibited by ketanserin and not by sulpiride. The affinity of the radiofluorinated ligand for the serotonin receptors was in the nanomolar range (Kd = 0.7 nM).

6-[18F]fluoro-L-dopa uptake and [76Br]bromolisuride binding in the excitotoxically lesioned caudate-putamen of nonhuman primates studied using positron emission tomography.

The functional status of the dopaminergic system following striatal excitotoxic lesions was studied in living baboons by positron emission tomography (PET) using 6-[18F]fluoro-L-dopa as specific tracer for the presynaptic dopaminergic terminals and [76Br]bromolisuride as selective dopamine D2-receptor marker. The glutamate receptor agonist ibotenic acid (IA) was injected into the right caudate-putamen of six baboons to induce a neuropathological and behavioral model of Huntington's disease (HD). In vivo PET studies performed 3 to 6 months after the IA injections showed that subtotal excitotoxic lesions of the CP were accompanied by changes in the kinetic of [76Br]bromolisuride binding indicating a dose-dependent reduction in binding sites in the lesioned striatum of all IA-injected animals. In the most severely lesioned animals, there was also a decrease in the uptake of the nigrostriatal dopaminergic marker. The loss of D2-receptors and decrease in striatal dopamine uptake are consistent with clinical and postmortem findings in HD. In addition, the decrease in 6-[18F]fluoro-L-dopa uptake confirms previous studies performed in a rat model of HD suggesting a continuous decline of nigral dopamine cell function following destruction of their intrinsic striatal target neurons. The results of our experience to date in PET studies of 6-[18F]fluoro-L-dopa and [76Br]bromolisuride binding in IA-lesioned primates indicate that PET can identify effects of cell loss on markers of pre- and postsynaptic function in the striatum of living subjects.