Effect of aging on vulnerability of striatal D1 and D2 dopamine receptor-containing neurons to kainic acid

Enkephalinergic striatal projection neurons become less affected by quinolinic acid than substance P-containing striatal projection neurons as rats age

While the excitotoxic vulnerability of striatal neurons is known to be greater in juvenile than adult animals, it is uncertain if striatal neuron types decline differentially in their vulnerability with age. To examine this issue, we unilaterally injected quinolinic acid (QA), an N-methyl-d-aspartate (NMDA) receptor agonist, into the striatum of juvenile and adult rats, and used in situ hybridization histochemistry with oligonucleotide probes for preproenkephalin and preprotachykinin mRNA to label surviving enkephalinergic (ENK) and substance P-containing (SP) neurons in adjacent sections through the injection center. The results confirmed that the region of severe damage is greater in young than adult animals, but revealed that at the very center of the QA injection, labeled neuron abundance was lower in adult than juvenile striatum. In juvenile rats, the vulnerability of the ENK neurons at all distances from the injection center was the same as that of the SP neurons. By contrast, in adult rats, the ENK neuron survival was greater than the SP neuron survival at all distances beyond the lesion center. The SP neuron survival outside the injection center in the adult rats was similar to that in juvenile rats, while the ENK neuron survival beyond the injection center was better in adult than juvenile rats. These data indicate that there is an age-dependent decrease in the vulnerability of ENK but not SP striatal projection neurons to QA-mediated injury in rats. The results also raise the possibility that, if an excitotoxic process is involved in HD pathogenesis, a differential age-related decline in the sensitivity of striatal projection neuron types to this process may contribute to the more uniform striatal neuron loss in juvenile-onset Huntington's disease (HD) and the more differential loss in adult-onset HD.

Adenosine A2A receptor imaging with [11C]KF18446 PET in the rat brain after quinolinic acid lesion: comparison with the dopamine receptor imaging

We proposed [11C]KF18446 as a selective radioligand for mapping the adenosine A2A receptors being highly enriched in the striatum by positron emission tomography (PET). In the present study, we investigated whether [11C]KF18446 PET can detect the change in the striatal adenosine A2A receptors in the rat after unilateral injection of an excitotoxin quinolinic acid into the striatum, a Huntington's disease model, to demonstrate the usefulness of [11C]KF18446. The extent of the striatal lesion was identified based on MRI, to which the PET was co-registered. The binding potential of [11C]KF18446 significantly decreased in the quinolinic acid-lesioned striatum. The decrease was comparable to the decrease in the potential of [11C]raclopride binding to dopamine D2 receptors in the lesioned striatum, but seemed to be larger than the decrease in the potential of [11C]SCH 23390 binding to dopamine D1 receptors. Ex vivo and in vitro autoradiography validated the PET signals. We concluded that [11C]KF18446 PET can detect change in the adenosine A2A receptors in the rat model, and will provide a new diagnostic tool for characterizing post-synaptic striatopallidal neurons in the stratum.

Positron emission tomography and ex vivo and in vitro autoradiography studies on dopamine D2-like receptor degeneration in the quinolinic acid-lesioned rat striatum: comparison of [11C]raclopride, [11C]nemonapride and [11C]N-methylspiperone

With [11C]raclopride,[11C]nemonapride and [11C]N-methylspiperone, degeneration of dopamine D2-like receptors in the unilaterally quinolinic acid-lesioned rats was evaluated by positron emission tomography (PET) and ex vivo and in vitro autoradiography. PET showed a decreased uptake of [11C]raclopride in the lesioned striatum, but an increased uptake of [11C]nemonapride and [11C]N-methylspiperone despite a decreased binding in vitro. Ex vivo autoradiography showed an increased accumulation of the three ligands in the cortical region overlying the injured striatum, probably enlarging PET signals. PET has the limited potential for evaluating the receptor degeneration in the present animal model.

Long-term dietary strawberry, spinach, or vitamin E supplementation retards the onset of age-related neuronal signal-transduction and cognitive behavioral deficits

Recent research has indicated that increased vulnerability to oxidative stress may be the major factor involved in CNS functional declines in aging and age-related neurodegenerative diseases, and that antioxidants, e.g., vitamin E, may ameliorate or prevent these declines. Present studies examined whether long-term feeding of Fischer 344 rats, beginning when the rats were 6 months of age and continuing for 8 months, with diets supplemented with a fruit or vegetable extract identified as being high in antioxidant activity, could prevent the age-related induction of receptor-mediated signal transduction deficits that might have a behavioral component. Thus, the following parameters were examined: (1) oxotremorine-enhanced striatal dopamine release (OX-K+-ERDA), (2) cerebellar beta receptor augmentation of GABA responding, (3) striatal synaptosomal 45Ca2+ clearance, (4) carbachol-stimulated GTPase activity, and (5) Morris water maze performance. The rats were given control diets or those supplemented with strawberry extracts (SE), 9.5 gm/kg dried aqueous extract (DAE), spinach (SPN 6.4 gm/kg DAE), or vitamin E (500 IU/kg). Results indicated that SPN-fed rats demonstrated the greatest retardation of age-effects on all parameters except GTPase activity, on which SE had the greatest effect, whereas SE and vitamin E showed significant but equal protection against these age-induced deficits on the other parameters. For example, OX-K+-ERDA enhancement was four times greater in the SPN group than in controls. Thus, phytochemicals present in antioxidant-rich foods such as spinach may be beneficial in retarding functional age-related CNS and cognitive behavioral deficits and, perhaps, may have some benefit in neurodegenerative disease.