Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:3.4.21.64 (
proteinase K
)
4,071
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Copper (Cu) is believed to be integral in prion biology and the lack of Cu or replacement by other metal ions on prions may be involved in prion diseases. This theory has not been evaluated in the bovine. Thus, mature cows were used to determine the effects of Cu deficiency on brain Cu concentrations and prion functional characteristics. Two Cu states were induced, Cu-adequate (n=4) and Cu-deficient (n=4).
Copper deficiency
resulted in decreased (44%) brain Cu concentrations but had no effect on prion concentrations. Based on Western blot analysis, the molecular weights, glycoform distributions, and elution profiles of brain prions were not affected by Cu status. Importantly, Cu status did not affect prion proteinase degradability as all prions were completely degraded by
proteinase K
. In conclusion, Cu status affected bovine brain Cu concentrations but had no detectable effects on brain prion protein characteristics.
...
PMID:Decreased brain copper due to copper deficiency has no effect on bovine prion proteins. 1715 16
It is now widely accepted that abnormal prion proteins are the likely causative agent in bovine spongiform encephalopathy. Cellular prion proteins (PrP(c)) bind Cu, which appears to be required to maintain functional characteristics of the protein. The replacement of Cu on PrP(c) with Mn has resulted in loss of function and increased protease resistance. Twelve mature cows were used to determine the effects of Cu deficiency, alone and coupled with high dietary Mn, on brain Cu and Mn concentrations and on PrP(c) functional characteristics. Copper-adequate cows were randomly assigned to treatments: 1) control (adequate in Cu and Mn), 2) Cu-deficient (-Cu), and 3) Cu-deficient plus high dietary Mn (-Cu+Mn). Cows assigned to treatments -Cu and -Cu+Mn received no supplemental Cu and were supplemented with Mo to further induce Cu deficiency. After 360 d, Cu-deficient cows (-Cu and -Cu+Mn) tended to have lesser concentrations of Cu (P = 0.09) in the obex region of the brain stem. Brain Mn tended (P = 0.09) to be greater in -Cu+Mn cattle compared with -Cu cattle. Western blots revealed that PrP(c) relative optical densities,
proteinase K
degradability, elution profiles, molecular weights, and glycoform distributions were not different among treatments. The concentration of PrP(c), as determined by ELISA, was similar across treatment groups. Brain tissue (obex) Mn superoxide dismutase activity was greatest (P = 0.04) in cattle receiving -Cu+Mn, whereas immunopurified PrP(c) had similar superoxide dismutase-like activities among treatments. Immunopurified PrP(c) had similar Cu concentrations across treatments, whereas Mn was undetectable. We concluded that Cu deficiency, coupled with excessive Mn intake, in the bovine may decrease brain Cu and increase brain Mn.
Copper deficiency
, alone or coupled with high dietary Mn, did not cause detectable alterations in PrP(c) functional characteristics.
...
PMID:Exposure to low dietary copper or low copper coupled with high dietary manganese for one year does not alter brain prion protein characteristics in the mature cow. 1764 86
