ABSTRACT
Membrane introduction mass spectrometry has been applied to on-line monitoring of the reaction of monochloramine with hydrogen chloride. The detection limit for monochloramine introduced by a sheet-membrane direct-insertion probe and measured by electron impact ionization and selected ion detection was found to be 0.7 mg/l. Formation of dichloramine, trichloramine and molecular chlorine in response to the addition of hydrogen chloride to the monochloramine solution was measured on-line. The flow-through membrane introduction mass spectrometry method for detection of chloramines and characterization of their chemistry has minimal memory effects, high molecular specificity, high speed of analysis owing to fast response times, and low detection limits.
ABSTRACT
Human serum butyrylcholinesterase (EC 3.1.1.8) loses 100% of its activity toward butyrylthiocholine in 60 min at pH 3.0. This deactivation is retarded by 1.37 M ammonium sulfate to a loss of 40% after 60 min at pH 3.0. Reneutralization experiments suggest that the mechanism for this acid inactivation does not exclusively involve hydrolysis of peptide bonds or protonation of the enzyme's active site. Studies with different anions and cations demonstrate that the order of their effectiveness as protective agents against acid inactivation closely follows the Hofmeister series. No relationship was found between catalytic activation or inhibition by salt and protection from acid inactivation. Ultraviolet difference studies at 288 nm with enzyme brought to pH 2.7 from pH 8.0 in the presence and absence of 1.37 M ammonium sulfate demonstrated no change in UV absorbance with ammonium sulfate present and approximately a 0.15 ODU rise in absorbance in the absence of ammonium sulfate. These results suggest that acidic pH conditions result in deactivating stereochemical changes in the active site of butyrylcholinesterase and that certain anions and cations, according to the Hofmeister series, are able to protect the enzyme from acid inactivation by stabilizing the active conformation of its active site.
