Faculty Bibliography

In recent studies we found that cytoplasmic tubulin from brain was rapidly split by brain cathepsin D. Two pools could be established; the major portion was split at 18%/h, a minor portion at 2%/h, under our experimental circumstances. In the present work these experiments were extended to membrane-bound tubulin from brain. The membrane-bound form, in contrast to the cytoplasmic tubulin, was not degraded by cerebral cathepsin D under similar experimental conditions. This was not due to the presence of an inhibitory protein since added cytoplasmic tubulin was degraded. Several other protein components of membrane fractions (synaptosomal, mitochondrial) were degraded by cathepsin D, as measured on two-dimensional electropherograms. Thrombin degraded cytoplasmic tubulin, but the degradation products differed from those of cathepsin D degradation. Thrombin also hydrolyzed membrane-bound tubulin, but at a lower rate than the cytoplasmic form. Our results indicate great differences in the breakdown rate of a protein, which depend on its localization, in accord with the differences found in in vivo turnover rates

The breakdown of cytoplasmic tubulin from brain (purified by ammonium sulfate fractionation and DEAE cellulose chromatography) by cathepsin D from brain (purified by ammonium sulfate fractionation and pepstatin Sepharose chromatography) was studied; changes in the intensity of tubulin gel bands were determined. The pH optimum of hemoglobin breakdown by cathepsin D was 3.2; the pH optimum for tubulin breakdown was 5.8; at pH 5.8 there was no significant hemoglobin breakdown by the enzyme. Tubulin breakdown had an apparent K(m) of 1.8 x 10(?5)M and a V(max) of 0.56 ?g tubulin (?g enzyme per min). The rate of breakdown was heterogeneous and studied on length of incubation; the major portion of tubulin was rapidly broken down and a smaller portion was more stable. The rate under our experimental conditions was 18%/h in the 1-4 h period and 2%/h after 4 h. This was not due to enzyme instability: after 4 h of inhibition freshly added tubulin was rapidly broken down, whereas freshly added enzyme did not increase the rate of breakdown. Thus breakdown heterogeneity was due to substrate (tubulin) heterogeneity. Pepstatin inhibited cathepsin D breakdown of tubulin at acid pH; at pH 7.6 it had no effect. Leupeptin was not inhibitory. We calculated that the cathepsin D content in brain, if fully active, could break down cytoplasmic tubulin with a half-life of 24 h, but it is likely that under in vivo conditions enzyme activity is greatly modified

Taurine, aspartic acid, glutamic acid, glycine, and GABA were administered either intragastrically or in liquid diets to mice and rats. This resulted in a great increase in the plasma concentration of the administered amino acid, with plasma levels remaining elevated for several days. The prolonged increase in plasma levels resulted in significant increases in brain levels. Under these experimental conditions, taurine, aspartic acid, and glutamic acid were increased 30-60%; glycine and GABA 100%. During these experiments, plasma levels of taurine, aspartate, and glutamate were below brain levels; those of glycine and GABA were above. The findings show that even slowly penetrating amino acid levels can be increased in brain after parenteral administration of large doses

Various opiate ligands were bound to brain membranes of mice of the Recombinant Inbred System. The specific binding of low levels of [3H]naloxone, [3H]dihydromorphine and [3H]ethylketocyclazocine was disturbed in a similar fashion among the inbred strains, and in a pattern different from that observed for [3H](D-Ala2,D-Leu5)-enkephalin. The results indicate that the inbred strains differ in mu- and delta-type binding and support the concept of multiple opiate receptors in mouse brain