The effects of long-term administration of rubidium or lithium on reactivity to stress and on dopamine output in the nucleus accumbens in rats

Rubidium and lithium are alkali metals belonging to the same periodic series as sodium, potassium and cesium. In the present report the effects of lithium and rubidium on animal reactivity to stressful stimuli and on dopamine output in the nucleus accumbens were studied. A dose-response curve with rubidium, administered acutely before exposure to unavoidable stress, showed a maximal protective activity on escape deficit development at the dose of 0. 41 mEq/kg. Rubidium injected at doses of 0.008-0.08 mEq/kg 72 h before the unavoidable stress had the same efficacy as the acute 0. 41 mEq/kg dose. Tolerance to the effect of rubidium developed after 9 days of treatment and, on day 15, rats presented a spontaneous escape deficit. The acute effect of lithium, administered for 3.5 days at the dose of 0.8 mEq/kg, i.p. twice a day before the exposure to unavoidable stress, was analogous to that of rubidium, but after repeated treatment a spontaneous escape deficit developed. Rats showing an escape deficit secondary to chronic stress also presented decreased extraneuronal dopamine concentrations in the nucleus accumbens. Accordingly, microdialysis studies showed significantly lower extracellular dopamine levels in rats chronically treated with lithium or rubidium compared to control animals. Cocaine (5 mg/kg i. p.) administered acutely increased extracellular dopamine concentrations in control rats, as well as in rats chronically stressed or chronically treated with lithium or rubidium. However, the dopamine increase was significantly higher in controls compared to the other groups. In conclusion, long-term treatment with lithium or rubidium, or the exposure to chronic stress, produced a condition of behavioral hypo-reactivity accompanied by a decreased dopamine output in the nucleus accumbens.     

Polymer-bound camptothecin: initial biodistribution and antitumour activity studies.

Camptothecin (CPT) is a potent, antitumour drug acting mainly through inhibition of topoisomerase I during the S-phase of the cell cycle. Despite its impressive antitumour activity, clinical development was halted for unpredictable toxic events. Two soluble N-(2-hydroxypropyl) methacrylamide (HPMA) copolymers were synthesised to contain CPT (5 wt.% and 10 wt.%). CPT was covalently linked at its alpha-hydroxyl group to the polymers through a Gly-Phe-Leu-Gly- spacer. In-vitro, CPT-conjugates were fairly resistant to hydrolysis in plasma as in buffer at neutral pH (0.2-0. 4% free CPT/h), while elastase and cysteine-proteases were able to release the active drug. Plasma levels in mice after intravenous administration of CPT-conjugates confirmed the modest hydrolysis in plasma. Plasma levels were approximately 5-fold lower than those observed at the highest tolerated dose of CPT administered in classical vehicles. Biodistribution in HT29 human colon carcinoma bearing mice was carried out after i.v. injection of [3H]CPT-conjugate and free [3H]CPT. Radioactivity uptake in tumour was evident only after [3H]CPT-conjugate treatment. Repeated intravenous administration of CPT-conjugates to HT29-bearing mice gave more than 90% tumour inhibition, some complete tumour regressions and no toxic deaths. The improved pharmacological profile on HT29 human colon carcinoma xenografts of the first poly(HPMA)-CPT conjugates might be ascribed to their prolonged intra-tumour retention and sustained release of the active drug.     

Θ-burst stimulation and striatal plasticity in experimental parkinsonism

Repetitive transcranial magnetic stimulation (rTMS) in humans increases levels of dopamine (DA) in the vicinity of highly active corticostriatal terminals suggesting its use to alleviate symptoms in Parkinson's disease (PD). However, the effects of rTMS on corticostriatal plasticity have not been explored. Here we show that a single-session of cortical rTMS using intermittent theta-burst stimulation (iTBS) pattern increases striatal excitability and rescues corticostriatal long-term depression (LTD) in a significant number of field excitatory postsynaptic potentials (fEPSP) recorded from hemiparkinsonian rats. These data indicate that cortical iTBS affects neuronal activity of subcortical regions, providing experimental evidence for its use in clinical settings.     

Epilepsy-induced abnormal striatal plasticity in Bassoon mutant mice

Recently, the striatum has been implicated in the spread of epileptic seizures. As the absence of functional scaffolding protein Bassoon in mutant mice is associated with the development of pronounced spontaneous seizures, we utilized this new genetic model of epilepsy to investigate seizure-induced changes in striatal synaptic plasticity. Mutant mice showed reduced long-term potentiation in striatal spiny neurons, associated with an altered N -methyl- d -aspartate (NMDA) receptor subunit distribution, whereas GABAergic fast-spiking (FS) interneurons showed NMDA-dependent short-term potentiation that was absent in wild-type animals. Alterations in the dendritic morphology of spiny neurons and in the number of FS interneurons were also observed. Early antiepileptic treatment with valproic acid reduced epileptic attacks and mortality, rescuing physiological striatal synaptic plasticity and NMDA receptor subunit composition. However, morphological alterations were not affected by antiepileptic treatment. Our results indicate that, in Bsn mutant mice, initial morphological alterations seem to reflect a more direct effect of the abnormal genotype, whereas plasticity changes are likely to be caused by the occurrence of repeated cortical seizures.     

Striatum-hippocampus balance: from physiological behavior to interneuronal pathology

In neurological disorders in which the cross-talk between striatal and hippocampal memory systems is affected, such as epilepsy, Down syndrome and Huntington's disease, cell-type specific alterations in synaptic plasticity lead to distinctive patterns causing functional imbalance between the two memory systems. Despite the complex network in which their neuronal activity is likely to be engaged, a common property of striatal and hippocampal neurons is to undergo bidirectional synaptic plasticity that relies on activity of interneurons and correlates with specific learning skills. As interneuronal dysfunction plays a primary role in the pathogenesis of these disorders, interneurons can be viewed as critical elements in neurophysiological substrates of such flexible relationships between these two memory systems.     

mTOR inhibitor rapamycin suppresses striatal post-ischemic LTP

The two complexes of the mammalian target of rapamycin (mTOR), mTORC1 and mTORC2, have central functions in the integration of both extracellular and intracellular signals that are also critical players in the induction of post-ischemic long-term potentiation (i-LTP), a pathological form of plasticity inducible in striatal medium spiny neurons (MSNs) after a brief episode of in vitro ischemia. To evaluate the involvement of mTOR complexes during ischemia we analyzed the time course of i-LTP by intracellular recordings of MSNs from corticostriatal slices incubated with 1 μM mTOR inhibitor rapamycin. Although rapamycin did not affect the amplitude and duration of ischemia-induced membrane depolarization it fully prevented i-LTP, leaving unaffected the capability to undergo activity-dependent LTP following high-frequency stimulation of corticostriatal fibers. The present results argue for a role of mTOR complex in i-LTP and suggest that rapamycin, by selectively blocking i-LTP, represents a promising therapeutic tool to limit cellular damage after ischemic brain insult.