Hydrophilic Dimer Research Articles

Multiple pathways of the reaction of 2,2-diphenyl-1-picrylhydrazyl radical (DPPH [rad]) with (+)-catechin: Evidence for the formation of a covalent adduct between DPPH [rad] and the oxidized form of the polyphenol

The pathways of the reaction of 2,2-diphenyl picrylhydrazyl radicals (DPPH ) with (+)-catechin were studied in alcoholic solvents. The reaction mixtures were analysed by using reversed-phase liquid chromatography (HPLC) and electrospray ionization mass spectrometry (ESI-MS). The intermediate o-quinone of catechin, yellow dimers, trimers and, interestingly, an adduct of the oxidized form of catechin with DPPH radicals were identified. The mass of this adduct was 681 Da, suggesting that one molecule of the DPPH radical complexes with the oxidized form of catechin. It is concluded that once the intermediate o-quinone is formed, the reaction proceeds in two pathways, either the o-quinone reacts with catechin to form a hydrophilic dimer (type B), which is further oxidized to hydrophobic dimers (type A) and consequently to oligomers of higher molecular weights; or the A-ring of the o-quinone is further oxidized by a DPPH radical and that this oxidized intermediate then reacts with another DPPH radical to form the observed adduct. The identification of the latter mechanism could explain the contradictory results reported in the literature for the reaction of polyphenols with DPPH radicals.

Analysis of cholinesterases in human prostate and sperm: Implications in cancer and fertility

Acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) are postulated to play non-cholinergic roles in cellular physiology. The probable implication of cholinesterases (ChEs) in several human pathologies prompted us to study the cholinergic components in the male reproductive system. Surgical pieces of prostatic cancer (PC) and benign prostatic hyperplasia (BPH) were analyzed for AChE and BChE activity. Loosely (S1) and tightly (S2) bound AChE and BChE forms were characterized by sedimentation analysis. The mean AChE activity in BHP samples was 2.38 ± 0.56 mU/mg (nmol of the substrate hydrolysed per minute and per milligram protein) and 2.57 ± 0.61 mU/mg in S1 and S2, respectively. The AChE activity did not vary with cancer, showing 2.46 ± 0.45 mU/mg in S1 and 2.70 ± 0.53 mU/mg in S2 from PC samples. Amphiphilic dimers and monomers and hydrophilic dimers of AChE were identified in BHP and PC tissues. Their contribution was affected by cancer with a great increase in hydrophilic dimers in the cancerous samples. Significant levels of both AChE and BChE activities were found in seminal fluid and homogenates from spermatozoids. Enzymatic activity dropped in samples with abnormal seminal parameters as sperm count and mobility.

Crystal Structures of Hydrophobin HFBII in the Presence of Detergent Implicate the Formation of Fibrils and Monolayer Films

Hydrophobins are small, amphiphilic proteins secreted by filamentous fungi. Their functionality arises from a patch of hydrophobic residues on the protein surface. Spontaneous self-assembly of hydrophobins leads to the formation of an amphiphilic layer that remarkably reduces the surface tension of water. We have determined by x-ray diffraction two new crystal structures of Trichoderma reesei hydrophobin HFBII in the presence of a detergent. The monoclinic crystal structure (2.2A resolution, R = 22, R(free) = 28) is composed of layers of hydrophobin molecules where the hydrophobic surface areas of the molecules are aligned within the layer. Viewed perpendicular to the aligned hydrophobic surface areas, the molecules in the layer pack together to form six-membered rings, thus leaving small pores in the layer. Similar packing has been observed in the atomic force microscopy images of the self-assembled layers of class II hydrophobin, indicating that the crystal structure resembles that of natural hydrophobin film. The orthorhombic crystal structure (1.0 A resolution, R = 13, R(free) = 15) is composed of fiber-like arrays of protein molecules. Rodlet structures have been observed on amphiphilic layers formed by class I hydrophobins; fibrils of class II hydrophobins appear by vigorous shaking. We propose that the structure of the fibrils and/or rodlets is similar to that observed in the crystal structure.

The laccase/ABTS system oxidizes (+)-catechin to oligomeric products

Laccase (EC 1.10.3.2, p-diphenol dioxygen oxidoreductase)-catalysed (+)-catechin oxidation was investigated, both in the presence and absence of the mediator ABTS. The effect of ascorbic acid, a radical scavenger, on the reaction mechanism was also examined. Using reversed-phase HPLC chromatography, UV–vis and HPLC-ESI-MS spectroscopies, we identified the formation of dimers of the type dehydrocatechin B, which are relatively more hydrophilic than the parent substrate, and hydrophobic dimers of type-A, as well as previously not described oligomers, namely, a trimer, tetramer and their oxidized forms. Evidence is presented for the conversion of a hydrophilic dimer via a quinone intermediate to the hydrophobic dimers. The hydrophobic dimers were further oxidized by laccase to o-quinone, which upon condensation with catechin forms the reduced trimer. Both ABTS and ascorbic acid had effect on the overall rate of (+)-catechin oxidation and the proportions of the final oxidation products. ABTS favoured the formation of the hydrophobic products and decreased the hydrophilic dimers. In contrast, at low concentrations, ascorbic acid favoured the formation of hydrophilic products, whereas at higher concentrations the radical scavenger inhibited the laccase-catalysed catechin oxidation reaction, most probably, by reducing the semiquinone and o-quinone back to the parent polyphenol. A nucleophilic rather than radical mechanism accounts for the product formation.

Structural studies of glucose-6-phosphate and NADP+binding to human glucose-6-phosphate dehydrogenase

Human glucose-6-phosphate dehydrogenase (G6PD) is NADP(+)-dependent and catalyses the first and rate-limiting step of the pentose phosphate shunt. Binary complexes of the human deletion mutant, DeltaG6PD, with glucose-6-phosphate and NADP(+) have been crystallized and their structures solved to 2.9 and 2.5 A, respectively. The structures are compared with the previously determined structure of the Canton variant of human G6PD (G6PD(Canton)) in which NADP(+) is bound at the structural site. Substrate binding in DeltaG6PD is shown to be very similar to that described previously in Leuconostoc mesenteroides G6PD. NADP(+) binding at the coenzyme site is seen to be comparable to NADP(+) binding in L. mesenteroides G6PD, although some differences arise as a result of sequence changes. The tetramer interface varies slightly among the human G6PD complexes, suggesting flexibility in the predominantly hydrophilic dimer-dimer interactions. In both complexes, Pro172 of the conserved peptide EKPxG is in the cis conformation; it is seen to be crucial for close approach of the substrate and coenzyme during the enzymatic reaction. Structural NADP(+) binds in a very similar way in the DeltaG6PD-NADP(+) complex and in G6PD(Canton), while in the substrate complex the structural NADP(+) has low occupancy and the C-terminal tail at the structural NADP(+) site is disordered. The implications of possible interaction between the structural NADP(+) and G6P are considered.

Crystal structure of the receptor-binding domain of human B7-2: insights into organization and signaling.

B7-1 and B7-2 are homologous costimulatory ligands expressed on the surfaces of antigen-presenting cells. Their interactions with CD28/CTLA-4 receptors expressed on T cell surfaces are crucial for the proper regulation of T cell activity. B7-1 and B7-2 display distinct roles in immune regulation, although they are usually considered to have redundant functions. Here, we report the crystal structure of the receptor-binding (Ig V-type) domain of human B7-2 at 2.7-A resolution. Structures of unliganded and liganded B7-1 and B7-2 suggest a physical-chemical basis for the observed functional similarities and differences between these two costimulatory ligands. Of particular note, whereas the majority of the residues mediating B7-1 dimerization are hydrophobic, the B7-2 dimer observed in the B7-2/CTLA-4 complex displays a very hydrophilic dimer interface. These differences provide a mechanism for preventing the formation of B7-1/B7-2 heterodimers. The divergence at the putative dimer interface is also consistent with the lower tendency of B7-2 to dimerize, as shown by the monomeric state of unliganded B7-2 both in solution and crystalline form, and may result in detailed differences in signaling mechanisms associated with B7-1 and B7-2.

Purification and properties of hydrophilic dimers of acetylcholinesterase from mouse erythrocytes

Differences in the glycosylation of acetylcholinesterase (AChE) subunits which form the dimers of mouse erythrocyte and a suitable procedure to purify the enzyme by affinity chromatography in edrophonium-Sepharose are described. AChE was extracted (∼80%) from erythrocytes with Triton X-100 and sedimentation analyses showed the existence of amphiphilic AChE dimers in the extract. The AChE dimers were converted into monomers by reducing the disulfide bond which links the enzyme subunits. Lectin interaction studies revealed that most of the dimers were bound by concanavalin A (Con A) (90–95%), Lens culinaris agglutinin (LCA) (90–95%), and wheat germ ( Triticum vulgaris) agglutinin (WGA) (70–75%), and a small fraction by Ricinus communis agglutinin (RCA 120) (25–30%). The lower level of binding of the AChE monomers with WGA (55–60%), and especially with RCA (10–15%), with respect to the dimers, reflected heterogeneity in the sugar composition of the glycans linked to each AChE subunit in dimers. Forty per cent of the amphiphilic AChE dimers lost the glycosylphosphatidylinositol (GPI) and, therefore, were converted into hydrophilic forms, by incubation with phosphatidylinositol-specific phospholipase C (PIPLC), which permitted their separation from the amphiphilic variants in octyl-Sepharose. Only the hydrophilic dimers, either isolated or mixed with the amphiphilic forms, were bound by edrophonium-Sepharose, which allowed their purification (4800-fold) with a specific activity of 7700 U/mg protein. The identification of a single protein band of 66 kDa in gel electrophoresis demonstrates that the procedure can be used for the purification of GPI-anchored AChE, providing that the attached glycolipid domain is susceptible to PIPLC.

Amphiphilic properties of acetylcholinesterase monomers in mouse plasma

Mouse plasma acetylcholinesterase (AChE) tetramers (G 4) and dimers (G 2) were retained by edrophonium-Sepharose, whereas AChE monomers (G 1), and G 4, G 2 and G 1 butyrylcholinesterase (BuChE) forms were not. Plasma G 4 or G 1 AChE did not differ in their affinity for edrophonium. G 1 AChE, and G 1 and G 2 BuChE were retained in octyl-Sepharose, while G 4 and G 2 AChE, and G 4 BuChE eluted freely. The amphiphilic behaviour of G 1 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 G 1 AChE possesses hydrophobic regions, which prevent its binding to the affinity matrix, and afford its interaction with octyl-Sepharose. The hydrophobic regions in G 1 AChE probably provide conformational stability to disulfide-linked subunits in hydrophilic dimers.

Biochemical properties of 5′-nucleotidase from mouse skeletal muscle

Ecto-5′-nucleotidase (eNT) from mouse muscle has been purified after extraction with detergent followed by chromatography on concanavalin A- and AMP-Sepharose. Three fractions were recovered: UF was NT non-retained in immobilised AMP; F-I was bound enzyme eluted with β-glycerophosphate, and F-II was bound NT released with AMP. eNT was 80 000-fold purified in F-II, this fraction showing proteins of 74, 68 and 51 kDa after immunoblotting. NT in UF migrated at 6.7S after centrifugation in sucrose gradients with Triton X-100, the peak being split into two of 6.7S and 4.4S in gradients with Brij 96. Ecto-NT in F-I or F-II migrated at 5.8S in Triton X-100-, or 4.4S in Brij 96-containing gradients. The hydrodynamic behaviour, concentration in Triton X-114, binding to phenyl-agarose, and sensitivity to phosphatidylinositol-specific phospholipase C revealed that enzyme forms in F-I or F-II were amphiphilic dimers with linked phosphatidylinositol residues, whilst most of NT forms in UF were hydrophilic dimers. A zinc/protein molar ratio of 2.2 was determined for eNT in F-II. NT activity was decreased in assays made in imidazole buffer, and was partly restored with 10 μM Zn 2+ or 100 μM Mn 2+. In assays with Tris buffer, NT showed a K m for AMP of 12 μM, and was competitively inhibited by ATP or ADP.

Existence of Two Acetylcholinesterases in the Mosquito Culex pipiens (Diptera: Culicidae)

Two acetylcholinesterases (AChEs), AChE1 and AChE2, differing in substrate specificity and in some aspects of inhibitor sensitivity, have been characterized in the mosquito Culex pipiens. The results of ultracentrifugation in sucrose gradients and nondenaturing gel electrophoresis of AChE activity peak fractions show that each AChE is present as two molecular forms: one amphiphilic dimer possessing a glycolipid anchor and one hydrophilic dimer that does not interact with nondenaturing detergents. Treatment by phosphatidylinositol-specific phospholipase C converts each type of amphiphilic dimer into the corresponding hydrophilic dimer. Molecular forms of AChE1 have a lower electrophoretic mobility than those of AChE2. However, amphiphilic dimers and hydrophilic dimers have similar sedimentation coefficients (5.5S and 6.5S, respectively). AChE1 and AChE2 dimers, amphiphilic or hydrophilic, resist dithiothreitol reduction under conditions that allow reduction of Drosophila AChE dimers. In the insecticide-susceptible strain S-LAB, AChE1 is inhibited by 5 x 10(-4) M propoxur (a carbamate insecticide), whereas AChE2 is resistant. All animals are killed by this concentration of propoxur, indicating that only AChE1 fulfills the physiological function of neurotransmitter hydrolysis at synapses. In the insecticide-resistant strain, MSE, there is no mortality after exposure to 5 x 10(-4) M propoxur: AChE2 sensitivity to propoxur is unchanged, whereas AChE1 is now resistant to 5 x 10(-4) M propoxur. The possibility that AChE1 and AChE2 are products of tissue-specific posttranslational modifications of a single gene is discussed, but we suggest, based on recent results obtained at the molecular level in mosquitoes, that they are encoded by two different genes.

From iodide to iotrolan: history and argument

The history of iodinated contrast agents is reviewed, demonstrating the evolution toward contrast agents of increasingly better tolerance, predicated upon stability hydrophilicity and lower osmolality. These properties were best approximated by iotrolan, 5,5′-(N,N′-dimethylmalonyl-dimino)-bis-(N,N′-bis[1RS, 2SR)-2, 3-dihydroxy-1-hydroxymethyl-propyl]-2,4,6-triidoisophthalamide], anon-ionic, highly hydrophilic dimer which at 300 mg I/ml is isotonic with body fluids and as proved to be preclinically and clinically well tolerated in all body compartments and cavities, including the subarachnoid space.

Purification and characterization of acetyl-cholinesterase from the Colorado potato beetle, Leptinotarsa decemlineata (say)

Acetylcholinesterase (AChE) was purified from an insecticide-susceptible strain of Colorado potato beetle by affinity chromatography following extraction with Triton X-100. The purification factor and yield were 39,000-fold and 51%, respectively. AChE activity was significantly inhibited by higher concentrations of acetylthiocholine (ATC) and acetyl-β-methylthiocholine (AβMTC), and moderately inhibited by propionylthiocholine (PTC). AChE activity was not inhibited by S-butyrylthiocholine (BTC). Substrate specificity constants ( κ cat K m ) of AChE for ATC, AβMTC and PTC were 21-, 25- and 13-fold, respectively, higher than that for BTC. Turnover numbers ( κ cat) of the native AChE were 23,000 min −1 for ATC, 14,000 for AβMTC, 8000 for PTC and 700 for BTC. AChE activity was effectively inhibited by 0.1 μM concentrations of eserine and BW284C51, but not by ethopropazine. The purified AChE consisted of two different molecular forms. The major form (92%) was a hydrophilic dimer, whereas the minor form (8%) was an amphiphilic dimer. Both molecular forms had virtually identical molecular weights (130,000 for native AChE and 65,000 for subunits) and isoelectric points (pI 7.3). The amphiphilic form of the AChE was insensitive to the action of phospholipase C, suggesting that this form has a hydrophobic domain that has been structurally modified. Amino acid analysis indicated that the mole percentages of amino acids of the enzyme were highly comparable to those of the previously reported AChE from Drosophila.

Human liver plasma membranes contain an enzyme activity that removes membrane anchor from alkaline phosphatase and converts it to a plasma-like form

Treatment of liver plasma membranes with Triton X-100 allowed an endogenous alkaline phosphatase-converting activity to convert amphiphilic alkaline phosphatase (membrane anchor covalently attached) to hydrophilic dimers that resemble the enzyme found in normal plasma. The Triton-solubilized activity was unaffected by protease inhibitors. Amphiphilic alkaline phosphatase purified from human liver and placenta were both substrates. The Triton-solubilized enzyme would not hydrolyze l-3-phosphatidy(2- 3H)-inositol or p-nitrophenylphosphoryl choline, nor would it cleave endogenous alkaline phosphatase from intact plasma membranes. These observations and the analysis of the protein product of the hydrolysis of placental alkaline phosphatase, following treatment with the converting activity, indicated that the enzyme has the specificity of a glycosyl-phosphatidylinositol phospholipase d. Further characterization of the enzyme activity suggests additional similarities with the glycosyl-phosphatidylinositol phospholipase d found in mammalian plasma. Alkaline phosphatase-converting activity in plasma membranes represented the same percent of total protein as it did in whole liver, whereas serum contained 3- to 10-times this amount. Endogenous converting activity in plasma membranes was not solubilized by salt washes, sonication, or repeated freeze-thaw treatments. We believe it is unlikely that the alkaline phosphatase-converting activity in liver plasma membranes resulted from adsorption of the enzyme present in plasma.

Acetylcholinesterases of the nematode Steinernema carpocapsae. Characterization of two types of amphiphilic forms differing in their mode of membrane association.

We analyzed the molecular forms of acetylcholinesterase (AChE) in the nematode Steinernema carpocapsae. Two major AChEs are involved in acetylcholine hydrolysis. The first class of AChE is highly sensitive to eserine (IC50 = 0.05 microM). The corresponding molecular forms are: an amphiphilic 14S form converted into a hydrophilic 14.5S form by mild proteolysis and two hydrophilic 12S and 7S forms. Reduction of the amphiphilic 14S form with 10 mM dithiothreitol produces hydrophilic 7S and 4S forms, indicating that it is an oligomer of hydrophilic catalytic subunits linked by disulfide bond(s) to a hydrophobic structural element that confers the amphiphilicity to the complex. Sedimentation coefficients suggest that 4S, 7S, 12S forms correspond to hydrophilic monomer, dimer, tetramer and that the 14S form is also a tetramer linked to one structural element. The second class of AChE is less sensitive to eserine (IC50 = 0.1 mM). Corresponding molecular forms are hydrophilic and amphiphilic 4S forms (monomers) and a major amphiphilic 7S form converted into a hydrophilic dimer by Bacillus thuringiensis phosphatidylinositol-specific phospholipase C. This amphiphilic 7S form thus possesses a glycolipid anchor. It appears that Steinernema (a very primitive invertebrate) presents AChEs with two types of membrane association that closely resemble those described for amphiphilic G2 and G4 forms of AChE in more evolved animals.

High-Molecular-Weight Alkaline Phosphatase in Serum Has Properties Similar to the Enzyme in Plasma Membranes of the Liver

Partially purified high-molecular-weight alkaline phosphatase from serum was compared with two other forms of the enzyme from the human liver, enzyme in native plasma membranes and purified alkaline phosphatase as a hydrophilic dimer. In a high-molecular-weight form from serum and plasma membranes, and when treated with 1% (v/v) Triton X-100, alkaline phosphatase showed a major band on gradient gel electrophoresis with a mobility equivalent to 400 kD. Nondetergent-treated material from both sources did not enter the gel and was in the voided volume of a gel permeation column. Stimulation of catalytic activity by four different phospholipids and by albumin yielded similar results for high-molecular-weight alkaline phosphatase and for the enzyme in plasma membranes, but these were different from the hydrophilic form. Inhibitors of alkaline phosphatase had similar effects on all forms. Of the three forms of the enzyme, only the hydrophilic dimer did not become incorporated into liposomes or adsorb to octyl-Sepharose after solubilization with Triton X-100 and removal of the detergent. Km (substrate concentration to give half maximal velocity) values with p-nitrophenylphosphate and heat and sodium dodecyl sulfate stabilities were similar for all forms. In the high-molecular-weight form from serum and in plasma membranes, alkaline phosphatase and 5'-nucleotidase showed similar rates of release by phosphatidylinositol phospholipase C. Three preparations of phospholipase D failed to release alkaline phosphatase from either the high-molecular-weight form or from plasma membranes. Based on these similarities, it is probable that the complex of high-molecular-weight alkaline phosphatase in serum most often originates from fragments of hepatic plasma membranes.

Molecular forms of acetylcholinesterase in two sublines of human erythroleukemia K562 cells

Acetylcholinesterase (AChE) in K562 cells exists in two molecular forms. The major form, an amphiphilic dimer (G2a) which sediments at 5.3 S, and the minor form, an amphiphilic monomer (G1a) which sediments at 3.5 S. Extraction in the presence of the sulfhydryl alkylating agent N-ethylmaleimide was required to preserve the G2a form. In Triton X-100 extracts of the subline K562-243, phosphatidylinositol-specific phospholipase C (PtdIns-PLC) from Bacillus thuringiensis converted most of the G2a AChE into a hydrophilic dimer (G2h), indicating that the G2a form possessed a hydrophobic glycoinositol phospholipid that mediated its attachment to the membrane. Treatment of intact K562-243 cells with PtdIns-PLC released approximately 60% of the total AChE activity and provided an estimate of the externally exposed AChE. The direct conversion from an amphiphilic to a hydrophilic dimeric form by PtdIns-PLC was not obtained in extracts or intact cells of the subline K562-48. Instead, pretreatment with alkaline hydroxylamine was necessary to render the amphiphilic G2 form of this subline susceptible to digestion by the phospholipase. In this respect, the amphiphilic dimer of K562-48 AChE resembles the G2a form of human erythrocyte AChE, which is resistant to PtdIns-PLC because of the direct palmitoylation of an inositol hydroxyl group in the anchor [Roberts et al. (1988) J. Biol. Chem. 263, 18766-18775]. Release of this acyl chain by hydroxylamine renders the enzyme susceptible to PtdIns-PLC [Toutant et al. (1989) Eur. J. Biochem. 180, 503-508]. In both K562 sublines, sialidase decreased the migration of the G2a form but not of the G1a form of AChE. G1a forms thus appear to represent an intracellular pool of newly synthesized molecules residing in a compartment proximal to the trans-Golgi apparatus. The sialidase-resistant G1a molecules were also resistant to PtdIns-PLC digestion; possible explanations for this resistance are presented.

The solubilization of tetrameric alkaline phosphatase from human liver and its conversion into various forms by phosphatidylinositol phospholipase C or proteolysis.

When membrane-bound human liver alkaline phosphatase was treated with a phosphatidylinositol (PI) phospholipase C obtained from Bacillus cereus, or with the proteases ficin and bromelain, the enzyme released was dimeric. Butanol extraction of the plasma membranes at pH 7.6 yielded a water-soluble, aggregated form that PI phospholipase C could also convert to dimers. When the membrane-bound enzyme was solubilized with a non-ionic detergent (Nonidet P-40), it had the Mr of a tetramer; this, too, was convertible to dimers with PI phospholipase C or a protease. Butanol extraction of whole liver tissue at pH 6.6 and subsequent purification yielded a dimeric enzyme on electrophoresis under nondenaturing conditions, whereas butanol extraction at pH values of 7.6 or above and subsequent purification by immunoaffinity chromatography yielded an enzyme with a native Mr twice that of the dimeric form. This high molecular weight form showed a single Coomassie-stained band (Mr = 83,000) on electrophoresis under denaturing conditions in sodium dodecyl sulfate, as did its PI phospholipase C cleaved product; this Mr was the same as that obtained with the enzyme purified from whole liver using butanol extraction at pH 6.6. These results are highly suggestive of the presence of a butanol-activated endogenous enzyme activity (possibly a phospholipase) that is optimally active at an acidic pH. Inhibition of this activity by maintaining an alkaline pH during extraction and purification results in a tetrameric enzyme. Alkaline phosphatase, whether released by phosphatidylinositol (PI) phospholipase C or protease treatment of intact plasma membranes, or purified in a dimeric form, would not adsorb to a hydrophobic medium. PI phospholipase C treatment of alkaline phosphatase solubilized from plasma membranes by either detergent or butanol at pH 7.6 yielded a dimeric enzyme that did not absorb to the hydrophobic medium, whereas the untreated preparations did. This adsorbed activity was readily released by detergent. Likewise, alkaline phosphatase solubilized from plasma membranes by butanol extraction at pH 7.6 would incorporate into phosphatidylcholine liposomes, whereas the enzyme released from the membranes by PI phospholipase C would not incorporate. The dimeric enzyme purified from a butanol extract of whole liver tissue carried out at pH 6.6 did not incorporate. We conclude that PI phospholipase C converts a hydrophobic tetramer of alkaline phosphatase into hydrophilic dimers through removal of the 1,2-diacylglycerol moiety of phosphatidylinositol. Based on these and others' findings, we devised a model of alkaline phosphatase's conversion into its various forms.

Native molecular forms of head acetylcholinesterase from adult Drosophila melanogaster: quaternary structure and hydrophobic character.

The native molecular forms of acetylcholinesterase (AChE) present in adult Drosophila heads were characterized by sedimentation analysis in sucrose gradients and by nondenaturing electrophoresis. The hydrophobic properties of AChE forms were studied by comparing their migration in the presence of Triton X100, 10-oleyl ether, or sodium deoxycholate, or in the absence of detergent. We examined the polymeric structure of AChE forms by disulfide bridge reduction. We found that the major native molecular form is an amphiphilic dimer which is converted into hydrophilic dimer and monomer on autolysis of the extracts, or into a catalytically active amphiphilic monomer by partial reduction. The latter component exists only as trace amounts in the native enzyme. Two additional minor native forms were identified as hydrophilic dimer and monomer. Although a significant proportion of AChE was only solubilized in high salt, following extractions in low salt, this high salt-soluble fraction contained the same molecular forms as the low salt-soluble fractions: thus, we did not detect any molecular form resembling the asymmetric forms of vertebrate cholinesterases.

Analysis of acetylcholinesterase molecular forms during the development of Drosophila melanogaster. Evidence for the existence of an amphiphilic monomer

Acetylcholinesterase (AChE, EC 3.1.1.7) was studied during the development of Drosophila melanogaster with particular regard to the hydrophobic interactions of the molecular forms of the enzyme. Amphiphilic forms were defined as those which interacted directly with non-denaturing detergents, whereas non-interacting molecules were referred to as hydrophilic components. 1. 1. The total AChE activity showed a transient peak at the first larval stage and was maximal in the adult. 2. 2. At all developmental stages, the major molecular form of AChE was an amphiphilic, membranebound, dimer of catalytic subunits. 3. 3. In larvae and young pupae, we also observed a significant proportion of a native amphiphilic monomer which could represent the precursor of the mature dimer of the enzyme. 4. 4. Two other minor forms, identified as hydrophilic dimer and monomer, were present in all extracts.