Identification of hybrid cholinesterase forms consisting of acetyl- and butyrylcholinesterase subunits in human glioma.

Brain and non-brain tumors contain acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) transcripts and enzyme activity. AChE and BuChE occur in tissues as a set of molecular components, whose distribution in a cyst fluid from a human astrocytoma we investigated. The fluid displayed high BuChE and low AChE activities. Three types of cholinesterase (ChE) tetramers were identified in the fluid by means of sedimentation analyses and assays with specific inhibitors, and their sedimentation coefficients were 11.7S (ChE-I), 11.1S (ChE-II), and 10.5S (ChE-III). ChE-I was unretained, ChE-II was weakly retained and ChE-III was adsorbed to edrophonium-agarose, confirming the AChE nature of the latter. ChE-I and ChE-II tetramers contained BuChE subunits as shown by their binding with an antiserum against BuChE. The ChE activity of the immunocomplexes made with ChE-II and anti-BuChE antibodies decreased with the AChE inhibitor BW284c51, revealing that ChE-II was made of AChE and BuChE subunits, in contrast to ChE-I, which only contained BuChE subunits. The binding of an anti-AChE antibody (AE1) to ChE-II and ChE-III, but not to ChE-I, demonstrated the hybrid composition of ChE-II. A substantial fraction of the AChE tetramers and dimers of astrocytomas and oligodendrogliomas bound both to anti-AChE and anti-BuChE antibodies, which revealed a mixed composition of AChE and BuChE subunits in them. The AChE components of brain, meningiomas and neurinomas were only recognized by AE1. In conclusion, our results demonstrate that aberrant ChE oligomers consisting of AChE and BuChE subunits are generated in astrocytomatous cyst and gliomas but not in brain, meningiomas or neurinomas.

Identification of inactive ecto-5'-nucleotidase in normal mouse muscle and its increased activity in dystrophic Lama2(dy) mice.

Ecto-5'-nucleotidase (eNT) activity and protein in normal (NM) and merosin-deficient dystrophic (DM) Lama2(dy) mice muscle were studied. eNT activity in DM was three- to four-fold that in NM. eNT in NM and DM displayed the same kinetic properties. Slot and Western blotting revealed that the immunoreactive protein was two to three times more abundant in control muscle, when NM and DM samples with the same eNT activity were compared, indicating that mouse muscle contains catalytically inactive eNT components. eNT activity and protein peaks coincided in sedimentation analyses, revealing that inactive eNT occurs as dimers. Most eNT activity and protein of NM bound to Lens culinaris (LCA) or Ricinus communis (RCA) agglutinins, but half of the activity and one-third of the protein bound to wheat germ agglutinin (WGA). Although WGA interaction did not permit full separation of inactive eNT, the results suggest that similar proportions of active species with and without WGA reactivity occur in mouse muscle, whereas a great fraction of the inactive eNT variants lack WGA reactivity. Because the level of eNT protein was little modified in DM, the higher eNT activity in dystrophic than in control muscle may result from misregulation in the synthesis of active and inactive eNT species or from conversion of inactive into active components.

Muscular dystrophy alters the processing of light acetylcholinesterase but not butyrylcholinesterase forms in liver of Lama2(dy) mice.

In order to know whether the histopathological changes of liver, which accompany muscular dystrophy, affect the synthesis of cholinesterases, the distribution and glycosylation of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) forms in normal (NL) and dystrophic Lama2(dy) mouse liver (DL) were investigated. About half of liver AChE, and 25% of BuChE were released with a saline buffer (fraction S(1)), and the rest with a saline-Brij 96 buffer (S(2)). Abundant light (G(2)(A) and G(1)(A)) AChE (87%) and BuChE (93%) forms, and a few G(4)(H) and G(4)(A) ChE species were identified in liver. The dystrophic syndrome had no effect on solubilization or composition of ChE forms. Most of the light AChE and BuChE species (>95%) were bound by octyl-Sepharose, while most light AChE forms (80%), but not BuChE isoforms (15%), were retained in phenyl-agarose. About half of the AChE dimers lost their amphiphilic anchor with phosphatidylinositol-specific phospholipase C (PIPLC), and the fraction of PIPLC-resistant species increased in DL. AChE T and R transcripts were detected by reverse transcriptase-polymerase chain reaction (RT-PCR) of liver RNA. ChE components of liver, erythrocyte, and plasma were distinguished by their amphiphilic properties and interaction with lectins. The dystrophic syndrome increased the liver content of the light AChE forms with Lens culinaris agglutinin (LCA) reactivity. The abundance of ChE tetramers in plasma and their small amount in liver suggest that after their assembly in liver they are rapidly secreted, while the light species remain associated to hepatic membranes.

Characterization of molecular forms of acetyl- and butyrylcholinesterase in human acoustic neurinomas.

Acoustic neurinomas were sequentially extracted with saline and saline-Triton X-100 buffers. Detergent was required to detach the bulk of acetylcholinesterase (AChE), but butyrylcholinesterase (BuChE) was mostly released with saline buffer. Sedimentation analysis and hydrophobic chromatography revealed that neurinomas contain principally amphiphilic AChE tetramers, dimers and monomers, and hydrophilic BuChE tetramers. The AChE dimers and monomers remained amphiphilic after incubation with phosphatidylinositol-specific phospholipase C (PIPLC), after or without prior treatment with alkaline hydroxylamine, which shows that, in contrast to the meningioma AChE dimers and monomers, the neurinoma isoforms are devoid of glycolipid. Neurinoma AChE reacted with the antibodies HR2 and AE1 raised against AChE from human brain or erythrocyte, whereas BuChE bound to a sheep antiserum.

Amphiphilic properties of acetylcholinesterase monomers in mouse plasma.

Mouse plasma acetylcholinesterase (AChE) tetramers (G4) and dimers (G2) were retained by edrophonium-Sepharose, whereas AChE monomers (G1), and G4, G2 and G1 butyrylcholinesterase (BuChE) forms were not. Plasma G4 or G1 AChE did not differ in their affinity for edrophonium. G1 AChE, and G1 and G2 BuChE were retained in octyl-Sepharose, while G4 and G2 AChE, and G4 BuChE eluted freely. The amphiphilic behaviour of G1 AChE remained unmodified after incubation with trypsin. The electrophoretic mobility of the AChE monomers varied with the detergent added to the samples. The results show that mouse plasma G1 AChE possesses hydrophobic regions, which prevent its binding to the affinity matrix, and afford its interaction with octyl-Sepharose. The hydrophobic regions in G1 AChE probably provide conformational stability to disulfide-linked subunits in hydrophilic dimers.