Acute and chronic changes in kynurenate formation following an intrastriatal quinolinate injection in rats

Summary.

Intrastriatal injection of the endogenous excitotoxin quinolinate in experimental animals causes a lesion which duplicates many features of Huntington's disease (HD). This lesion can be prevented by a related metabolite, kynurenate. Since kynurenate levels are reduced in the HD neostriatum, a deficiency in brain kynurenate may be the cause of neuron loss in HD. In order to investigate the relationship between excitotoxic neurodegeneration and kynurenate formation, effects of a unilateral quinolinate injection on several measures of kynurenate metabolism were studied in the rat striatum and substantia nigra. Within 2 hours, quinolinate caused an approximately 100% increase in striatal kynurenate levels in the absence of changes in its bioprecursor L-kynurenine or its biosynthetic enzymes kynurenine aminotransferases (KATs) I and II. This increase was more dramatic after 2 days (+735%) and was accompanied by an increase in L-kynurenine (+182%). No change or a slight decrease in enzyme activities were detected at this time-point. More chronic excitotoxic lesions produced a substantial increase in kynurenate levels (by approximately 2-, 4- and 4-fold, respectively, after 7 days, 1 and 5 months). Lesion-induced changes in KAT II activity essentially paralleled those seen with kynurenate, whereas KAT I remained slightly decreased at all timepoints. Nigral KAT II activity was increased ipsilaterally 2 days, 1 and 5 months after the striatal quinolinate injection. Kinetic analyses, performed in the striatum 5 months after the quinolinate injection, showed an almost 3-fold decrease in K_m values for KAT II in the absence of v_max changes. These findings indicate that 1) different mechanisms regulate kynurenate production at different stages after an intrastriatal quinolinate injection; 2) an increased substrate affinity to KAT II is responsible for the elevation of kynurenate in the chronically lesioned rat striatum; and 3) qualitative differences in kynurenate metabolism exist between the HD neostriatum and the excitotoxin-lesioned rat striatum, supporting the idea that (a decrease in) kynurenate tone may play a primary role in the pathophysiology of HD.