eatment to reduce the nucleic acid content and recently suggested that nucleic acids do not contribute to the conversion activity of mouse adapted prion strains. To determine if this is true of all mouse prion strains the CAA was performed using the M1000 strain of mouse adapted human prions. The effect of MgCl2 concentration, a divalent cation required for the efficient activity of the nucleic acid digesting enzyme, Benzonase was first investigated to ensure that the effect of the treatment was enzyme specific. It was found that concentrations of MgCl2 required for optimal activity of Benzonase did not significantly affect conversion activity, while concentrations at or over 5mM significantly decreased conversion activity. Benzonase treatment of the mouse derived August 2010 | Volume 5 | Issue 8 | e12351 Prion Protein Misfolding UBH, significantly decreased conversion activity, relative to the buffer control, whereas pre-treatment of the IBH seed of the CAA had no effect. This suggests that nucleic acids present in the UBH substrate, but not the IBH seed, can act as catalysts or scaffolds for PrPres formation. Familial prion disease mutations affect sGAG binding and conversion activity of PrPC in the CAA Mutations associated with familial prion disease located in the C-terminal region of PrP do not reduce the stability of PrP. However, the proline to leucine mutation at residue 101 of full length mouse PrP has been reported to alter the alpha-helical content of full length PrP and this and other familial mutations have been reported to increase the GAG binding capacity of PrP. Expression of endogenous levels of 101L mutation are not sufficient to induce spontaneous disease in knock-in 11325787 mice, although the mutation does alter the susceptibility of mice to prion infection. To investigate how GAGs may affect the susceptibility of the 101L mutation to undergo seeded misfolding we developed a CAA model using mouse PrPC exogenously expressed in RK13 cells as the substrate. RK13 cells do not express detectable levels of PrP, but become susceptible to infection by mouse adapted prion strains through exogenous expression of mouse PrP. When lysates of mouse PrPC expressing cells were used as the substrate in the CAA a significant increase in PrPres was detected relative to RK-13 cells that had been transfected with the empty expression vector. This exogenous expression system also enabled the investigation of the conversion activity of moPrP harbouring a P101L mutation. The conversion activity of reactions containing mutant 101L-moPrP was significantly greater than those of wild-type 101P-moPrP, despite detection of lower 101L-moPrP levels. To investigate whether the association of sGAG with PrPC affects the conversion process wild-type 101P-moPrP and mutant 101L-moPrP cells were treated with chlorate, a general inhibitor of GAG sulphation, and PrPC formed in the presence of modified GAG sulphation used as substrate in the CAA. The conversion activity of wildtype 101P-moPrP was not significantly affected by chlorate treatment of the cells. In contrast the conversion activity of mutant 101L-moPrP was significantly increased MedChemExpress 62717-42-4 following chlorate treatment. To understand the different response of 101P and 101L moPrP to chlorate treatment we investigated their relative GAG binding capacities. The heparin binding capacity of 101L-moPrP was significantly greater than that of 101P-moPrP. An N-terminally truncated form of PrP does not appreciably bind to sG