• Title of article

    Spatial Learning and Memory Deficits Induced by Dopamine Administration with Decreased Glutathione

  • Author/Authors

    Barbara Shukitt-Hale، نويسنده , , Steven A. Erat، نويسنده , , James A. Joseph، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 1998
  • Pages
    10
  • From page
    1149
  • To page
    1158
  • Abstract
    Administration of buthionine sulfoximine (BSO) selectively inhibits glutathione (GSH) biosynthesis and induces a GSH deficiency. Decreased GSH levels in the brain may result in less oxidative stress (OS) protection, because GSH contributes substantially to intracellular antioxidant defense. Under these conditions, administration of the pro-oxidant, dopamine (DA), which rapidly oxidizes to form reactive oxygen species, may increase OS. To test the cognitive behavioral consequences of decreased GSH, BSO (3.2 mg in 30 μl, intracerebroventricularly) was administered to male Fischer 344 rats every other day for 4 days. In addition, DA (15 μl of 500 μM) was administered every day [either 1h after BSO (BSO + DA group) or 1h before BSO (DA + BSO group), when given on the same day as BSO] and spatial learning and memory assessed (Morris water maze, six trials/day). BSO + DA rats, but not DA + BSO rats, demonstrated cognitive impairment compared to a vehicle group, as evidenced by increased latencies to find the hidden platform, particularly on the first trial each day. Also, the BSO + DA group utilized non-spatial strategies during the probe trials (swim with no platform): i.e., less time spent in the platform quadrant, fewer crossings and longer latencies to the previous platform location, and more time spent around the edge of the pool rather than in the platform zone. Therefore, the cognitive behavioral consequences of decreasing GSH brain levels with BSO in conjunction with DA administration depends on the order of administration. These findings are similar to those seen previously on rod and plank walking performance, as well as to those seen in aged rats, suggesting that the oxidation of DA coupled with a reduced capacity to respond to oxidative stress may be responsible for the induction of age-related cognitive deficits.
  • Keywords
    glutathione , Dopamine , oxidative stress , Cognitive performance , Morris water maze , aging , free radicals , buthionine sulfoximine
  • Journal title
    Free Radical Biology and Medicine
  • Serial Year
    1998
  • Journal title
    Free Radical Biology and Medicine
  • Record number

    517861