Is Butyrylcholinesterase of the Rat CNS a Membrane-Bound Enzyme?

Abstract: The study of Arrhenius plots for acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) activity from the rat brain and spinal cord revealed that in contrast to AChE, which exhibited biphasic Arrhenius plots with a distinct break (transition temperature) at about 16–18°C, BuChE showed no evidence of discontinuity and a higher activation energy in the physiological range of temperature. The results indicate lack of lipid-protein interaction in the case of BuChE of the CNS tissue. It is inferred that BuChE, in contrast to AChE, is not bound in any significant way to cellular membranes of the CNS tissue.     

Cholinesterases: New Roles in Brain Function and in Alzheimer's Disease

The most important therapeutic effect of cholinesterase inhibitors (ChEI) on approximately 50% of Alzheimer's disease (AD) patients is to stabilize cognitive function at a steady level during a 1-year period of treatment as compared to placebo. Recent studies show that in a certain percentage (approximately 20%) of patients this cognitive stabilizing effect can be prolonged up to 24 months. This long-lasting effect suggests a mechanism of action other than symptomatic and cholinergic. In vitro and in vivo studies have consistently demonstrated a link between cholinergic activation and APP metabolism. Lesions of cholinergic nuclei cause a rapid increase in cortical APP and CSF. The effect of such lesions can be reversed by ChEI treatment. Reduction in cholinergic neurotransmission–experimental or pathological, such as in AD–leads to amyloidogenic metabolism and contributes to the neuropathology and cognitive dysfunction. To explain the long-term effect of ChEI, mechanisms based on -amyloid metabolism are postulated. Recent data show that this mechanism may not necessarily be related to cholinesterase inhibition. A second important aspect of brain cholinesterase function is related to enzymatic differences. The brain of mammals contains two major forms of cholinesterases: acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE). The two forms differ genetically, structurally, and for their kinetics. Butyrylcholine is not a physiological substrate in mammalian brain, which makes the function of BuChE of difficult interpretation. In human brain, BuChE is found in neurons and glial cells, as well as in neuritic plaques and tangles in AD patients. Whereas, AChE activity decreases progressively in the brain of AD patients, BuChE activity shows some increase. To study the function of BuChE, we perfused intracortically the rat brain with a selective BuChE inhibitor and found that extracellular acetylcholine increased 15-fold from 5 nM to 75 nM concentrations with little cholinergic side effect in the animal. Based on these data and on clinical data showing a relation between cerebrospinal fluid (CSF) BuChE inhibition and cognitive function in AD patients, we postulated that two pools of cholinesterases may be present in brain, the first mainly neuronal and AChE dependent and the second mainly glial and BuChE dependent. The two pools show different kinetic properties with regard to regulation of ACh concentration in brain and can be separated with selective inhibitors. Within particular conditions, such as in mice nullizygote for AChE or in AD patients at advanced stages of the disease, BuChE may replace AChE in hydrolizing brain acetylcholine.     

Electron microscope localization of acetylcholinesterase and butyrylcholinesterase in the superior cervical ganglion of the cat. I. Normal ganglion

The distributions of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) in the superior cervical ganglion (SCG) of the cat were determined by electron microscopy (EM) with the bis- (thioacetoxy)aurate (I), or Au(TA)2, method. Before the infusion of fixative, one of the enzymes was selectively, irreversibly inactivated in vivo, as confirmed by light microscope (LM) examination of sections of the stellate ganglion stained by the more specific copper thiocholine method. Physostigmine-treated controls, for inhibition of AChE or BuChE, were stained concomitantly with tissue for enzyme localization by the Au(TA)2 method for EM examination in each experiment. It was concluded that most of the AChE of the cat SCG is present in the plasma membranes of the preganglionic axons and their terminals, and in the dendritic and perikaryonal plasma membranes of the postsynaptic ganglion cells. BuChE is confined largely to the postsynaptic neuronal plasma membranes. Reasons for the discrepancies between the localizations found by the present direct EM observations and those deduced earlier from LM comparisons of normal and denervated SCG are discussed. It is proposed that a trophic factor released by the preganglionic terminals is probably required for the synthesis of postsynaptic neuronal AChE, and that BuChE may serve as a precursor of AChE at that site.     

Butyrylcholinesterase in Human Brain and Acetylcholinesterase in Human Plasma: Trace Enzymes Measured by Two-Site Immunoassay

Enzyme-linked immunosorbent assays for acetylcholinesterase (AChE) and for butyrylcholinesterase (BuChE) were markedly more specific than conventional assays using selective enzyme inhibitors. The new assays were used with blood and brain samples containing traces of one enzyme dominated by large amounts of the other. The results showed that human plasma does contain AChE (8 ng/ml), even though its major cholinesterase is BuChE (3,300 ng/ml). BuChE immunoreactivity was not detected in human red blood cells but occurred in all brain regions. The cerebellum was the richest region tested (540 ng of BuChE/g of tissue), whereas the cerebral cortex was the poorest (240 ng of BuChE/g). However, because of the small local AChE content (99 ng/g), BuChE was the major cortical cholinesterase. The picture was reversed in the putamen, where BuChE immunoreactivity (340 ng/g) was far outweighed by that of AChE (6,100 ng/g).     

Electron microscope localization of acetylcholinesterase and butyrylcholinesterase in the superior cervical ganglion of the cat. II. Preganglionically denervated ganglion

Cat superior cervical ganglia (SCG), denervated preganglionically 6-8 d previously, were stained for acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) by the bis-(thioacetoxy)aurate (I), or Au(TA)2, method and compared by electron microscopy with normal SCG described previously (Davis, R., and G. B. Koelle. 1978. J. Cell Biol. 78:785-809). In confirmation of earlier light microscopic findings by the highly specific copper thiocholine method, there was nearly a total disappearance of AChE from the ganglion; no myelinated or unmyelinated axons with AChE-stained axolemmas were found, and only occasional traces of AChE staining were noted at dendritic and perikaryonal plasma membranes. Considerable staining for BuChE persisted at the latter sites, however. As in the normal SCG, physostigmine-resistant staining, caused by noncholinesterase enzymes plus the possible presence of very low concentrations of AChE or BuChE, was noted at external mitochondrial membranes, elements of the endoplasmic reticulum of neurites and Schwann cells, and also in lysosomes. These findings confirm the previous identification of AChE-stained myelinated fibers in the normal SCG as preganglionic and of the unstained myelinated fibers as postganglionic. It is proposed that the maintenance of AChE at postsynaptic sites in normal ganglia is caused by the release of a trophic factor(s) from presynaptic terminals. The source of the postsynaptic BuChE, which is apparently completely absent from the endoplasmic reticulum of the ganglion cells, remains unexplained.     

The level of butyrylcholinesterase activity increases and the content of the mRNA remains unaffected in brain of senescence-accelerated mouse SAMP8

Looking at cholinesterases (ChEs) changes in age-related mental impairment, the expression of ChEs in brain of senescence accelerated-resistant (SAMR1) and senescence accelerated-prone (SAMP8) mice was studied. Acetylcholinesterase (AChE) activity was unmodified and BuChE activity increased twofold in SAMP8 brain. SAMR1 brain contained many AChE-T mRNAs, less BuChE and PRiMA mRNAs and scant AChE-R and AChE-H mRNAs. Their content unchanged in SAMP8 brain. Amphiphilic (G(4)(A)) and hydrophilic (G(4)(H)) AChE and BuChE tetramers, besides amphiphilic dimers (G(2)(A)) and monomers (G(1)(A)) were identified in SAMR1 brain and their distribution was little modified in SAMP8 brain. Blood plasma does not seem to provide the excess of BuChE activity in SAMP8 brain; it probably arises from glial cell changes owing to astrocytosis.     

Amphiphilic and Nonamphiphilic Forms of Torpedo Cholinesterases: II. Electrophoretic Variants and Phosphatidylinositol Phospholipase C-Sensitive and -Insensitive Forms

We report an electrophoretic analysis of the hydrophobic properties of the globular forms of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) from various Torpedo tissues. In charge-shift electrophoresis, the rate of electrophoretic migration of globular amphiphilic forms (Ga) is increased at least twofold when the anionic detergent deoxycholate is added to Triton X-100, whereas that of globular nonamphiphilic forms (Gna) is not modified. The G2a forms of the first class, as defined by their aggregation properties, are converted to nonamphiphilic derivatives by phosphatidylinositol phospholipase C (PI-PLC) and human serum phospholipase D (PLD). AChE G2a forms from electric organs, nerves, skeletal muscle, and erythrocyte membranes correspond to this type, which also exists in very small quantities in detergent-solubilized extracts of electric lobes and spinal cord. They present different electrophoretic mobilities, so that each of these tissues contains a distinct "electromorph," or two in the case of electric organs. The G2a forms of the second class (AChE in plasma, BuChE in heart), as well as G4a forms of AChE and BuChE, are insensitive to PI-PLC and PLD but may be converted to nonamphiphilic derivatives by Pronase.     

Cross-Homologies and Structural Differences Between Human Cholinesterases Revealed by Antibodies Against cDNA-Produced Human Butyrylcholinesterase Peptides

To study the polymorphism of human cholinesterases (ChEs) at the levels of primary sequence and three-dimensional structure, a fragment of human butyrylcholinesterase (BuChE) cDNA was subcloned into the pEX bacterial expression vector and its polypeptide product analyzed. Immunoblot analysis revealed that the clone-produced BuChE peptides interact specifically with antibodies against human and Torpedo acetylcholinesterase (AChE). Rabbit polyclonal antibodies prepared against the purified clone-produced BuChE polypeptides interacted in immunoblots with denatured serum BuChE as well as with purified and denatured erythrocyte AChE. In contrast, native BuChE tetramers from human serum, but not AChE dimers from erythrocytes, interacted with these antibodies in solution to produce antibody-enzyme complexes that could be precipitated by second antibodies and that sedimented faster than the native enzyme in sucrose gradient centrifugation. Furthermore, both AChE and BuChE dimers from muscle extracts, but not BuChE tetramers from muscle, interacted with these antibodies. To reveal further whether the anti-cloned BuChE antibodies would interact in situ with ChEs in the neuromuscular junction, bundles of muscle fibers were microscopically dissected from the region in fetal human diaphragm that is innervated by the phrenic nerve. Muscle fibers incubated with the antibodies and with 125I-Protein A were subjected to emulsion autoradiography, followed by cytochemical ChE staining. The anti-cloned BuChE antibodies, as well as anti-Torpedo AChE antibodies, created patches of silver grains in the muscle endplate region stained for ChE, under conditions where control sera did not. These findings demonstrate that the various forms of human AChE and BuChE in blood and in neuromuscular junctions share sequence homologies, but also display structural differences between distinct molecular forms within particular tissues, as well as between similarly sedimenting molecular forms from different tissues.     

Differential effect of pressure and temperature on the catalytic behaviour of wild-type human butyrylcholinesterase and its D70G mutant.

The combined action of temperature (10-35 degrees C) and pressure (0. 001-2 kbar) on the catalytic activity of wild-type human butyrylcholinesterase (BuChE) and its D70G mutant was investigated at pH 7.0 using butyrylthiocholine as the substrate. The residue D70, located at the mouth of the active site gorge, is an essential component of the peripheral substrate binding site of BuChE. Results showed a break in Arrhenius plots of wild-type BuChE (at Tt approximately 22 degrees C) whatever the pressure (dTt/dP = 1.6 +/- 1.5 degrees C.kbar-1), whereas no break was observed in Arrhenius plots of the D70G mutant. These results suggested a temperature-induced conformational change of the wild-type BuChE which did not occur for the D70G mutant. For the wild-type BuChE, at around a pressure of 1 kbar, an intermediate state, whose affinity for substrate was increased, appeared. This intermediate state was not seen for the mutant enzyme. The wild-type BuChE remained active up to a pressure of 2 kbar whatever the temperature, whereas the D70G mutant was found to be more sensitive to pressure inactivation (at pressures higher than 1.5 kbar the mutant enzyme lost its activity at temperatures lower than 25 degrees C). The results indicate that the residue D70 controls the conformational plasticity of the active site gorge of BuChE, and is involved in regulation of the catalytic activity as a function of temperature.     

EFFECTS OF INACTIVATION OF BUTYRYLCHOLINESTERASE ON STEADY STATE AND REGENERATING LEVELS OF GANGLIONIC ACETYLCHOLINESTERASE

The effects of single and repeated injections of tetramonoisopropyl pyrophosphortetramide (iso-OMPA), a selective inactivator of butyrylcholinesterase (BuChE), were studied on the ganglionic and muscular levels of BuChE and acetylcholinesterase (AChE) in cats during the steady state and following the irreversible inactivation of both enzymes by isopropylmethylphosphonofluoridate (sarin). Single intravenous injections of iso-OMPA, 3.0 or 6.0 μmol/kg, produced nearly total inactivation of BuChE with no immediate effect on the AChE of the superior cervical (SCG), stellate (StG), and ciliary (CG) ganglia and inferior oblique (10) muscle; regeneration of BuChE occurred at approximately the same rate in the three ganglia, and at 4–6 days the AChE levels were significantly elevated. When single doses of iso-OMPA were given 1 h following sarin, 2.0 μmol/kg, intravenously, there was a slight increase in the rate of AChE regeneration during the ensuing 2 days. With the repeated injection of iso-OMPA, 3.0 μmol/kg every 48 h, there was a consistent but not statistically significant reduction in AChE regeneration at 4, 6, 12, and 18 days following sarin in all 3 ganglia. Similar treatment with iso-OMPA alone produced significant increases in ganglionic AChE at all these periods excepting the longest. The daily injection of iso-OMPA for 6 days, which maintained ganglionic BuChE at approx 2% of the control values, produced significant reductions in AChE regeneration, but again significant increases in ganglionic AChE levels in cats that did not receive sarin. The IO muscle did not exhibit these effects. A working hypothesis is proposed, that BuChE is a precursor of ganglionic AChE, and that the level of BuChE participates in the regulation of AChE synthesis by inhibition of a preceding rate-limiting step.     

Butyrylcholinesterase-Mediated enhancement of the enzymatic activity of trypsin

1. Acetylcholinesterase (AChE, EC 3.1.1.7) and butyrylcholinesterase (BuChE, EC 3.1.1.8) are enzymes that catalyze the hydrolysis of esters of choline.2. Both AChE and BuChE have been shown to copurify with peptidases.3. BuChE has also been shown to copurify with other proteins such as transferrin, with which it forms a stable complex. In addition, BuChE is found in association with -amyloid protein in Alzheimer brain tissues.4. Since BuChE copurifies with peptidases, we hypothesized that BuChE interacts with these enzymes and that this association had an influence on their catalytic activities. One of the peptidases that copurifies with cholinesterases has specificity similar to trypsin, hence, this enzyme was used as a model to test this hypothesis.5. Purified BuChE causes a concentration-dependent enhancement of the catalytic activity of trypsin while trypsin does not influence the catalytic activity of BuChE.6. We suggest that, in addition to its esterase activity, BuChE may assume a regulatory role by interacting with other proteins.     

Amphiphilic and Nonamphiphilic Forms of Torpedo Cholinesterases: I. Solubility and Aggregation Properties

We report an analysis of the solubility and hydrophobic properties of the globular forms of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) from various Torpedo tissues. We distinguish globular nonamphiphilic forms (Gna) from globular amphiphilic forms (Ga). The Ga forms bind micelles of detergent, as indicated by the following properties. They are converted by mild proteolysis into nonamphiphilic derivatives. Their Stokes radius in the presence of Triton X-100 is approximately 2 nm greater than that of their lytic derivatives. The G2a forms fall in two classes. Class I contains molecules that aggregate in the absence of detergent, when mixed with an AChE-depleted Triton X-100 extract from electric organ. AChE G2a forms from electric organs, nerves, skeletal muscle, and erythrocyte membranes correspond to this type, which is also detectable in detergent-soluble (DS) extracts of electric lobes and spinal cord. Class II forms never aggregate but only present a slight shift in sedimentation coefficient, in the presence or absence of detergent. This class contains the AChE G2a forms of plasma and of the low-salt-soluble (LSS) fractions from spinal cord and electric lobes. The heart possesses a BuChE G2a form of class II in LSS extracts, as well as a similar G1a form. G4a forms of AChE, which are solubilized only in the presence of detergent and aggregate in the absence of detergent, represent a large proportion of cholinesterase in DS extracts of nerves and spinal cord, together with a smaller component of G4a BuChE. These forms may be converted to nonamphiphilic derivatives by Pronase. Nonaggregating G4a forms exist at low levels in the plasma (BuChE) and in LSS extracts of nerves (BuChE) and spinal cord (AChE).     

Altered Levels of Acetylcholinesterase in Alzheimer Plasma

Background

Many studies have been conducted in an extensive effort to identify alterations in blood cholinesterase levels as a consequence of disease, including the analysis of acetylcholinesterase (AChE) in plasma. Conventional assays using selective cholinesterase inhibitors have not been particularly successful as excess amounts of butyrylcholinesterase (BuChE) pose a major problem.

Principal Findings

Here we have estimated the levels of AChE activity in human plasma by first immunoprecipitating BuChE and measuring AChE activity in the immunodepleted plasma. Human plasma AChE activity levels were ∼20 nmol/min/mL, about 160 times lower than BuChE. The majority of AChE species are the light G₁+G₂ forms and not G₄ tetramers. The levels and pattern of the molecular forms are similar to that observed in individuals with silent BuChE. We have also compared plasma AChE with the enzyme pattern obtained from human liver, red blood cells, cerebrospinal fluid (CSF) and brain, by sedimentation analysis, Western blotting and lectin-binding analysis. Finally, a selective increase of AChE activity was detected in plasma from Alzheimer''s disease (AD) patients compared to age and gender-matched controls. This increase correlates with an increase in the G₁+G₂ forms, the subset of AChE species which are increased in Alzheimer''s brain. Western blot analysis demonstrated that a 78 kDa immunoreactive AChE protein band was also increased in Alzheimer''s plasma, attributed in part to AChE-T subunits common in brain and CSF.

Conclusion

Plasma AChE might have potential as an indicator of disease progress and prognosis in AD and warrants further investigation.     

Divergent Regulation of Acetylcholinesterase and Butyrylcholinesterase in Tissues of the Rat

Abstract: Investigating the possibility that acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) are regulated in a coordinated manner, we have examined the natural variation in activity of these two enzymes in several tissues of adult male Sprague-Dawley, Fischer-344, and Wistar-Furth rats. Both enzymes varied greatly in mean activity among brain, diaphragm, atria, serum, superior cervical ganglia, and liver. In Sprague-Dawley rats there were also large individual variations with up to a fivefold range of AChE activities and up to a 100-fold range of BuChE activities in a given tissue. Individual variations in cholinesterase activities appeared to be smaller in the inbred Fischer-344 or Wistar-Furth rats. Experiments with internal standards of partially purified AChE and BuChE indicated that the individual variations probably reflected differences in the intrinsic content or specific activity of the tissue enzymes. Comparison of the AChE activities in different tissues of a given group of rats failed to reveal statistically significant correlations in any strain (i.e., the relative activity of any one tissue was no guide to the relative activity of any other tissue in the same rat). This result indicates that the regulation of AChE is tissue-specific. By contrast, BuChE activity showed highly significant correlations among the majority of the tissues examined in the Sprague-Dawley rats, implying that widely dispersed factors can affect the regulation of this enzyme. Body-wide regulation is not necessarily the rule, however, since only a single tissue pair in the inbred Fischer rats and none of the pairs in the Wistar-Furth rats showed significant correlations of BuChE activity. In general, AChE and BuChE activities were not correlated with each other to a statistically significant degree. We conclude that the control of these enzymes normally involves different mechanisms and is strongly affected by the genetic background of the sample population.     

Potencies and selectivities of inhibitors of acetylcholinesterase and its molecular forms in normal and Alzheimer's disease brain

Eight inhibitors of acetylcholinesterase (AChE), tacrine, bis-tacrine, donepezil, rivastigmine, galantamine, heptyl-physostigmine, TAK-147 and metrifonate, were compared with regard to their effects on AChE and butyrylcholinesterase (BuChE) in normal human brain cortex. Additionally, the IC50 values of different molecular forms of AChE (monomeric, G1, and tetrameric, G4) were determined in the cerebral cortex in both normal and Alzheimer's human brains. The most selective AChE inhibitors, in decreasing sequence, were in order: TAK-147, donepezil and galantamine. For BuChE, the most specific was rivastigmine. However, none of these inhibitors was absolutely specific for AChE or BuChE. Among these inhibitors, tacrine, bis-tacrine, TAK-147, metrifonate and galantamine inhibited both the G1 and G4 AChE forms equally well. Interestingly, the AChE molecular forms in Alzheimer samples were more sensitive to some of the inhibitors as compared with the normal samples. Only one inhibitor, rivastigmine, displayed preferential inhibition for the G1 form of AChE. We conclude that a molecular form-specific inhibitor may have therapeutic applications in inhibiting the G1 form, which is relatively unchanged in Alzheimer's brain.     

Age-related changes in acetylcholinesterase and its molecular forms in various brain areas of rats

A previous study conducted in this laboratory revealed a decrease in total cholinesterase (total ChE) in the cerebral cortex, hippocampus and striatum in aged rats (24 months) of various strains, as compared with young animals (3 months). The purpose of the present experiments was to extend the study to other brain areas (hypothalamus, medulla-pons and cerebellum) and to assess whether this decrease was dependent on the reduction of either specific acetylcholinesterase (AChE) or butyrylcholinesterase (BuChE) or both. By using ultracentrifugation on a sucrose gradient, the molecular forms of AChE were evaluated in all the brain areas of young and aged Sprague-Dawley rats. In young rats the regional distribution of total ChE and AChE varied considerably with respect to BuChE. The age-related loss of total ChE was seen in all areas. Although there was a reduction of AChE and, to somewhat lesser extent, of BuChE in the cerebral cortex, hippocampus, striatum, and hypothalamus (but not in the medulla-pons or the cerebellum), the ratio AChE/BuChE was not substantially modified by age. Two molecular forms of AChE, namely G4 (globular tetrameric) and G1 (monomeric), were detected in all the brain areas. Their distribution, expressed as G4/G1 ratio, varied in young rats from about 7.5 for the striatum to about 2.0 for the medulla-pons and cerebellum. The age-related changes consisted in a significant and selective loss of the enzymatic activity of G4 forms in the cerebral cortex, hippocampus, striatum, and hypothalamus, which resulted in a significant decrease of the G4/G1 ratio. No such changes were found in the medullapons or the cerebellum. Since G4 forms have been proposed to be present presynaptically, their age-related loss in those brain areas where acetylcholine plays an important role in neurotransmission may indicate an impairment of presynaptic mechanisms.     

Immunochemistry of mammalian cholinesterases

Advances in the study of cholinesterase biology have been facilitated by the development of polyclonal and monoclonal antibodies to acetylcholinesterase (AChE) (EC 3.1.1.7) and butyrylcholinesterase (BuChE) (EC 3.1.1.8) in several laboratories. Our work has focused on murine monoclonal antibodies to the mammalian enzymes. Two dozen antibodies are now in hand, with primary specificity for the AChE of human red blood cells, rabbit brain, and rat brain, and for the BuChE of human plasma. These antibodies exhibit a restricted but useful range of affinities for other mammalian cholinesterases of corresponding types. Several applications are described, including an analysis of BuChE phylogeny within the higher primates, an immunodisplacement assay of AChE in normal human red blood cells and cells from patients with paroxysmal nocturnal hemoglobinuria, a study of immunochemical differences between membrane-associated and soluble AChE of rabbit brain, and initial work on the immunofluorescence cytochemistry of the rat brain.     

人脑和人血清胆碱酯酶三维结构的计算机模拟研究

本文以同源的电鳐胆碱酯酶（Ｔ．ＡＣｈＥ）的三维结构为模板,模拟预测了人脑和血清胆碱酯酶（Ｈ。ＡＣｈＥ和Ｈ．ＢｕＣｈＥ）的三维结构和活力中心的组成。指Ｔ．ＡＣｈＥ,Ｈ．ＡＣｈＥ和Ｈ．ＢｕＣｈＥ宁间结构差异,并讨论了ＡＣｈ和Ｈ。ＡＣｈＥ的对接（ｄｏｃｋｉｎｇ）。Ｈ。ＡＣｈＥ和Ｈ．ＢｕＣｈＥ三维结构的确定将为进一步深入研究它的中毒机理和合理药物设计提供靶子。     

The expression of cholinesterases in human renal tumours varies according to their histological types

The change in the expression of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) activities in neoplastic colon and lung prompted us to study the possible effect of cancer on the expression of cholinesterases (ChEs) in kidney. Samples of papillary renal cell carcinoma (pRCC), conventional RCC (cRCC), chromophobe RCC (chRCC) and renal oncocytoma (RON), beside adjacent non-cancerous tissues, were analyzed. In pRCC both AChE and BuChE activities were statistically increased; in cRCC and chRCC only AChE activity increased and in RON neither AChE nor BuChE activities were affected. Abundant amphiphilic AChE dimers (G(2)(A)) and fewer monomers (G(1)(A)) were identified in healthy kidney as well as in all tumour classes. Incubation with PIPLC revealed glycosylphosphatidylinositol in AChE forms. BuChE is distributed between principal G(4)(H), fewer G(1)(H), and much fewer G(4)(A) and G(1)(A) species. RT-PCR showed similar amounts of AChE-H, AChE-T and BuChE mRNAs in healthy kidney. Their levels increased in pRCC but not in the other tumour types. The data support the idea that, as in lung tumours, in renal carcinomas expression of ChE mRNAs, biosynthesis of molecular components and level of enzyme activity change according to the specific kind of cell from which tumours arise.