Integration of alkaline phosphatase in the intestinal brush border membrane

Alkaline phosphatase has been solubilized from porcine intestinal mucosa by two different methods: treatment of the mucosa by Emulphogen BC 720 and papain hydrolysis of enterocyte brush border membrane vesicles. Two different enzyme forms have been obtained by these methods.The two enzyme forms (‘detergent form’ and ‘papain form’) have been purified to homogeneity by similar techniques and exhibit closely related molecular characteristics. However, the detergent form displays a hydrophobic behaviour and aggregates in media free of detergent. The two forms can be differentiated by their electrophoretic mobility on polyacrylamide gel in the absence of sodium dodecyl sulphate.By electrophoresis on polyacrylamide gel in the presence of sodium dodecyl sulphate, it has been shown that the detergent and papain forms of alkaline phophatase are dimers consisting of two apparently identical subunits whose molecular weights are 64 000 and 61 000, respectively. The difference between these molecular weights has been attributed to the existence of a hydrophobic region in the detergent form which is present on each subunit.     

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).     

SOLUBILIZATION AND PHYSICOCHEMICAL CHARACTERIZATION OF RAT BRAIN ACETYLCHOLINESTERASE: DEVELOPMENT AND MATURATION OF ITS MOLECULAR FORMS

Abstract— We have solubilized two active molecular forms of AChE from rat brain and compared them to the molecular forms solubilized from rat muscle. One of these forms, in muscle, as well as in brain, is easy to solubilize without detergent (ES form–apparent sedimentation coefficient without detergent: 4.6s); the other is hard to solubilize and we obtained a nearly total solubilization only in the presence of detergent (HS form–apparent sedimentation coefficient in presence of detergent: 10.3s). These two molecular forms are glycoprotein in nature. They interact with detergent (Triton X-100), as demonstrated by a comparison of their hydrodynamic parameters (determined by sucrose gradient centrifugation and molecular filtration) in the presence and absence of detergent. In the absence of detergent, their molecular weights are 115,000 for the ES form and 435,000 for the HS form. We did not find the molecular form in brain which seems to be specific to the muscle endplate region. at any stage of its development (EP form–solubilized by detergent–apparent s value in presence of detergent: 16.2s).
During development or maturation of the rat brain, the relative proportion of the HS form to the ES form increases; its absolute amount also increases (by more than a factor of 7 during the first month after birth). The ES form seems to be established at its adult level at the time of birth, before the large increase in the HS form. The proportion of each form in the adult rat brain remains constant: 90% of the total activity is represented by the HS form.     

Existence of two membrane-bound acetylcholinesterases in the honey bee head

Two acetylcholinesterase (EC 3.1.1.7) membrane forms AChE(m1) and AChE(m2), have been characterised in the honey bee head. They can be differentiated by their ionic properties: AChE(m1) is eluted at 220 mM NaCl whereas AChE(m2) is eluted at 350 mM NaCl in anion exchange chromatography. They also present different thermal stabilities. Previous processing such as sedimentation, phase separation, and extraction procedures do not affect the presence of the two forms. Unlike AChE(m1), AChE(m2) presents reversible chromatographic elution properties, with a shift between 350 to 220 mM NaCl, depending on detergent conditions. Purification by affinity chromatography does not abolish the shift of the AChE(m2) elution. The similar chromatographic behaviour of soluble AChE strongly suggests that the occurrence of the two membrane forms is not due to the membrane anchor. The two forms have similar sensitivities to eserine and BW284C51. They exhibit similar electrophoretic mobilities and present molecular masses of 66 kDa in SDS-PAGE and a sensitivity to phosphatidylinositol-specific phospholipase C in non-denaturing conditions, thus revealing the presence of a glycosyl-phosphatidylinositol anchor. We assume that bee AChE occurs in two distinct conformational states whose AChE(m2) apparent state is reversibly modulated by the Triton X-100 detergent into AChE(m1).     

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.     

Multiple Molecular Forms of Acetylcholinesterase in the Nematode Caenorhabditis elegans

Abstract: Extracts of the nematode Caenorhabditis elegans contain five molecular forms of acetylcholinesterase (AChE) activity that can be separated by a combination of selective solubilization, velocity sedimentation, and ion-exchange chromatography. These are called form IA (5.2s), form IB (4.9.s), form II (6.7s), form III (11.3s), and form IV (13.0s). All except form III are present in significant amounts in rapidly prepared extracts and are probably native; form III is probably derived autolytically from form IV. Most of forms IA and IB can be solubilized by repeated extractions without detergent, whereas forms II, III, and IV require detergent for effective solubilization and may therefore be membrane-bound. High salt concentrations are not required for, and do not aid in, the solubilization of these forms. For all forms, molecular weights and frictional ratios have been estimated by a combination of gel permeation chromatography and velocity sedimentations in both H₂O and D₂O. The molecular weight estimates range from 83,000 to 357,000 and only form II shows extensive asymmetry. The separated forms have been characterized with respect to substrate affinity, substrate specificity, inhibitor sensitivity, thermal inactivation, and detergent sensitivity. Judging by these properties, C. elegans is like other invertebrates in that none of its cholinesterase forms resembles either the “true” or the “pseudo” cholinesterase of vertebrates. However, internal comparison of the C. elegans forms clearly distinguishes forms IA, III, and IV as a group from forms IB and II; the former are therefore designated “class A” forms, the latter “class B” forms. Genetic evidence indicates that separate genes control class A and class B forms, and that these two classes overlap functionally. Several factors, including kinetic properties, molecular asymmetry, molecular size, and solubility, all suggest that a molecular model of the multiple cholinesterase forms observed in vertebrate electric organs probably does not apply in C. elegans. Potential functional roles and subunit structures of the multiple AChE forms within each C. elegans class are discussed.     

Heterogeneity of Rat Brain Acetylcholinesterase: A Study by Gel Filtration and Gradient Centrifugation

Abstract: According to their solubilization properties, two classes of acetyl-cholinesterases (AChE) can be detected in the adult rat brain: a "soluble" species (easily solubilized without detergent), and a membrane-bound species (solubilized only in the presence of detergent). The latter was found to be homogeneous by gel filtration (Stokes radius 8.05 ± 0.35 nm) and sucrose gradient centrifugation (9.75 ± 0.2 S) in the presence of Triton X-100. The "soluble" AChE gives three stable species in the presence of the same detergent with Stokes radii and sedimentation constants of 10.9 ± 0.5 nm and 16 ± 2 S; 6.75 ± 0.30 nm and 10.7 ± 0.4 S; 5.37 ± 0.35 nm and 4.37 ± 0.1 S. Co-chromatography and co-sedimentation or the reduction and alkylation of disulfide bridges show that all the soluble species are different from the membrane-bound AChE. The possibility that soluble and membrane-bound AChE are completely different molecules is discussed.     

Structure of heparin-derived tetrasaccharides.

Quantitative solubilization of the phospholipid-associated form of acetylcholinesterase (AChE) from Torpedo electric organ can be achieved in the absence of detergent by treatment with phosphatidylinositol-specific phospholipase C (PIPLC) from Staphylococcus aureus [Futerman, Low & Silman (1983) Neurosci. Lett. 40, 85-89]. The sedimentation coefficient on sucrose gradients of AChE solubilized in detergents (DSAChE) varies with the detergent employed. However, the coefficient of AChE directly solubilized by PIPLC is not changed by detergents. Furthermore, PIPLC can abolish the detergent-sensitivity of the sedimentation coefficient of DSAChE purified by affinity chromatography, suggesting that one or more molecules of phosphatidylinositol (PI) are co-solubilized with DSAChE and remain attached throughout purification. DSAChE binds to phospholipid liposomes, whereas PIPLC-solubilized AChE and DSAChE treated with PIPLC do not bind even to liposomes containing PI. Sodium dodecyl sulphate/polyacrylamide-gel electrophoresis shows that PIPLC-solubilized AChE, like unmodified DSAChE, is a catalytic subunit dimer; electrophoresis in the presence of reducing agent reveals no detectable difference in the Mr of the catalytic subunit of unmodified DSAChE, of AChE solubilized by PIPLC and of AChE solubilized by Proteinase K. The results presented suggest that DSAChE is anchored to the plasma membrane by one or more PI molecules which are tightly attached to a short amino acid sequence at one end of the catalytic subunit polypeptide.     

Properties of acetylcholinesterase and non-specific cholinesterase in rat superior cervical ganglion and plasma

Amphiphile dependency, solubility in aqueous solutions, and sensitivity to proteolysis of acetylcholinesterase (AChE) and nonspecific cholinesterase (nsChE) in the rat superior cervical ganglion were studied and compared to properties of soluble plasma cholinesterases. Ganglion AChE shows strong amphiphile dependency: an amphyphilic substance must be present in the homogenizing medium in order to obtain maximal apparent enzyme activity. Apparent activity of AChE solubilized in Ringer's solution was also increased after subsequent addition of a detergent. The 4 S molecular form, predominant in this extract (corresponding to the fastest electrophoretic band), is very sensitive to papain proteolysis but can be protected by a detergent. This molecular form therefore carries an important hydrophobic domain and is probably membrane bound in situ. The 10 S form of ganglionic AChE, extracted in Ringer's solution, is probably a soluble enzyme since, like soluble plasma enzymes, it is not amphiphile dependent and is rather resistant to proteolysis. Ganglion nsChE is more water soluble, less amphiphile dependent and more protease resistant than AChE.     

Purification and properties of the membrane-bound form of acetylcholinesterase from chicken brain. Evidence for two distinct polypeptide chains

The major molecular form of acetylcholinesterase (AChE) from chicken brain is a membrane-bound glycoprotein with an apparent sedimentation coefficient of 11.4 S. Analysis of the purified protein by gel filtration, velocity sedimentation, and sodium dodecyl sulfate-gel electrophoresis shows that the solubilized enzyme is a globular tetramer with an apparent Mr = 420,000. This membrane-bound form of AChE is hydrophobic and readily aggregates in the absence of detergent. These aggregates are concentration-dependent, relatively stable in the presence of high salt concentrations, yet readily dissociate upon addition of detergent to the 11.4 S form, indicating that the interactions are hydrophobic. Polyclonal and monoclonal antibodies raised against chicken brain AChE purified by ion exchange chromatography, affinity chromatography, and preparative gel electrophoresis precipitate AChE enzyme activity. However, these antibodies do not cross-react with the enzyme from chicken muscle which preferentially hydrolyses butyrylcholine. Immunoprecipitation of isotopically labeled enzyme molecules from tissue cultured brain cells and analysis by sodium dodecyl sulfate-gel electrophoresis shows that AChE consists of two polypeptide chains with apparent Mr = 105,000 (alpha) and 100,000 (beta) in a 1:1 ratio. Immunoblotting of brain AChE with either the polyclonal or monoclonal antibodies indicates that the alpha and beta chains share antigenic determinants. Furthermore, both polypeptide chains can be labeled with [3H]diisopropyl fluorophosphate, indicating that they each contain a catalytic site. This is the first indication that globular forms of AChE may consist of multiple polypeptide chains.     

STUDIES ON ACETYLCHOLINESTERASE OF RAT BRAIN SYNAPTOSOMAL PLASMA MEMBRANES

Abstract— A fluorimetric assay has been used to examine some kinetic properties of AChE from synaptosomal plasma membranes prepared from rat brain. The AChE bound to the plasma membranes was compared to that solubilized with Triton X-100 and found to be essentially the same with respect to Michaelis constant and inhibitor constants for several AChE inhibitors. The two forms of the enzyme had slightly different pH optima. The kinetic studies revealed no evidence that synaptosomal plasma membrane AChE has allosteric properties. The solubilized enzyme was further purified by affinity chromatography.     

Solubilization and partial characterization of acetylcholinesterase from the sarcotubular system of skeletal muscle

Attempts were made to solubilize acetylcholinesterase (AChE) from microsomal membranes isolated from rabbit white muscle. The preparative procedure included a step in which the microsomes were incubated in a solution containing high salt concentration (0.6 M KCl). About 15% of the total enzyme activity could be solubilized with dilute buffer. Addition of EDTA (1 mM), EGTA (1 mM) or NaCl (0.5 and 1 M) to the extraction buffer did not improve the solubilization yield. Several non-ionic detergents and biliary salts were then used to bring the enzyme into solution. Triton X-100, C₁₂E₉ (dodecylnonaethylenglycol monoether) and biliary salt, above their critical micellar concentration, proved to be very effective as solubilizing agents. The occurrence of multiple molecular forms in detergent-soluble AChE was investigated by means of molecular sieving, centrifugation analysis, and slab gel electrophoresis. Experiments on gel filtration showed that, during the process, half of the enzyme was transformed into aggregates, the rest of the activity appearing as peaks with Stokes radii ranging from 3.7 to 7.9 nm. Both ionic strength and detergent nature modify the number and relative proportion of these peaks. Centrifugation analysis of Triton-saline-soluble AChE yielded molecular forms of 4.8S, 10–11S, and 13.5S, whereas deoxycholate extracts revealed species of 4.8S, 10S, and 15S, providing that gradients were prepared with 0.5 M NaCl. In the absence of salt, forms of 6.5–7.5S, 10S, and 15S were measured. The lightest species was always the predominant form. Slab gel electrophoresis showed several bands (68,000–445,000). The 4.8S component only yielded bands of 65,000–70,000. The results suggest that the monomeric form of AChE (4.8S), the most abundant species in muscle microsomes, has a Stokes radius of 3.3 nm and a molecular weight in the range of 70,000.     

Amphiphilic Detergent-Soluble Acetylcholinesterase from Torpedo marmorata: Characterization and Conversion by Proteolysis to a Hydrophilic Form

The membrane-bound acetylcholinesterase (AChE) from the electric organ of Torpedo marmorata was solubilized by Triton X-100 or by treatment with proteinase K and purified to apparent homogeneity by affinity chromatography. Although the two forms differed only slightly in their subunit molecular weight (66,000 and 65,000 daltons, respectively), considerable differences existed between native and digested detergent-soluble AChE. The native enzyme sedimented at 6.5 S in the presence of Triton X-100 and formed aggregates in the absence of detergent. The digested enzyme sedimented at 7.5 S in the absence and in the presence of detergent. In contrast to the detergent-solubilized AChE, the proteolytically derived form neither bound detergent nor required amphiphilic molecules for the expression of catalytic activity. This led to the conclusion that limited digestion of detergent-soluble AChE results in the removal of a small hydrophobic peptide which in vivo is responsible for anchoring the protein to the lipid bilayer.     

Association of tailed acetylcholinesterase to lipidic membranes in mammalian skeletal muscle

Tailed acetylcholinesterase (AChE) was studied in three subcellular membrane fractions of mouse skeletal muscle: a fraction enriched in isolated motor endplates (C), an extrasynaptic membrane fraction (A) and a microsomal fraction (S). In the (C) fraction, tailed asymmetric 16S AChE required high salt conditions to be extracted, while in (A) and (S) microsomal membranes, a collagenase sensitive 16S form, was extracted by detergent alone. This apparent “hydrophobic” property suggests that there is a pool of 16S AChE which is probably bound to lipidic membranes. The detergent extractable (DE) 16S AChE was not concentrated in motor endplate-rich regions and differential inhibition of external and internal AChE demonstrated that it could have both intra- and extracellular locations in the adult differentiated muscle fibres.     

Differential inhibition of soluble and membrane-bound acetylcholinesterase forms from mouse brain by choline esters with an acyl moiety of an intermediate size

Differential inhibitions of soluble and membrane-bound acetylcholinesterase forms purified from mouse brain were examined by the comparison of kinetic constants such as a K _m value, a K_ss value (substrate inhibition constant), and IC₅₀ values of active site-selective ligands including choline esters. Membrane-bound acetylcholinesterase form (solubilized only in the presence of detergent) showed lower K_m and K_ss values than soluble acetylcholinesterase form (easily solubilized without detergent). Edrophonium expressed a slightly but significantly (p<0.01) higher inhibition of detergent-soluble acetylcholinesterase form than aqueous-soluble acetylcholinesterase form, while physostigmine inhibited both forms with a similar potency. A remarkable difference in inhibition was observed using choline esters; although choline esters with acyl chain of a short size (acetyl-to butyrylcholine) or a long size (heptanoyl- to decanoylcholine) showed a similar inhibitory potency for two forms of acetylcholinesterase, pentanoylcholine and hexanoylcholine inhibited more strongly aqueous-soluble acetylcholinesterase than detergent-soluble acetylcholinesterase. Thus, it is suggested that the two forms of AChE may be distinguished kinetically by pentanoyl- or hexanoylcholine.This work was supported in part by Agency for Defense Development.     

THE EFFECTS OF SOLUBILIZATION PROCEDURES ON THE RELEASE AND MOLECULAR STATE OF ACETYLCHOLINESTERASE FROM ELECTRIC ORGAN TISSUE

Abstract— A study was made of the effect of various solubilization procedures on the release of AChE from electric organ tissue of the electric eel and on the molecular state of the enzyme. The procedures employed included homogenization in different ionic media or in the presence of detergents, etuymic treatment and chemical modification. Studies were performed on intact electroplax, tissue homogenates and membrane fractions. The apparent AChE activity of intact cells, homogenates and membrane fractions was shown to be governed by diffusion-controlled substrate and hydrogen ion gradients, generated by AChE-catalyscd hydrolysis, leading to a lower substrate concentration and a lower pH in the vicinity of the particulate enzyme.
Treatment of homogenates with NaCl solutions or with NaCl solutions containing the nonionic detergent Triton X-100 causes release of the native'molecular forms of the enzyme (primarily the 18 S species) which aggregate at low ionic strength. For optimal extraction both high ionic strength (e.g. 1 M-NaCl) and the detergent are needed AChE is also solubilized by treatment of tissue homogenates with trypsin, bacterial protease or collagenase. The first two enzymes caused its release as an 11 S non-aggregating form, while collagenase also produces a minor non-aggregating - 16 S component. Treatment of tissue homogenates with maleic anhydride causes release of AChE as a non-aggregating 18 S species. On the basis of the solubilization experiments it is concluded that the interaction of AChE with the excitable membrane is primarily electrostatic. The possible orientation of the enzyme within the synaptic gap is discussed.     

THE DISSOCIATION OF RAT BRAIN MEMBRANES BEARING ACETYLCHOLINESTERASE BY THE NON-IONIC DETERGENT TRITON X-100 AND AN EXAMINATION OF THE PRODUCT

Abstract— The action of Triton X-100 on a membrane preparation from rat brain was studied with reference to the solubilization of acetylcholinesterase and the product was characterized by exclusion chromatography. The AChE and membrane protein were readily solubilized to form particles corresponding to a mol. wt. of about 5 × 10⁵. The solubility of these particles depended on the continued presence of the detergent. It was concluded that these soluble particles formed an intermediate stage in organization between membrane-bound AChE and the soluble protein enzyme, and perhaps represented preexisting lipoprotein subunits of the membranes.     

Cellular Localization of the Molecular Forms of Acetylcholinesterase in Primary Cultures of Rat Sympathetic Neurons and Analysis of the Secreted Enzyme

The secretion and cellular localization of the molecular forms of acetylcholinesterase (AChE) were studied in primary cultures of rat sympathetic neurons. When cultured under conditions favoring a noradrenergic phenotype, these neurons synthesized and secreted large quantities of the tetrameric G4, and the dodecameric A12 forms, and minor amounts of the G1 and G2 forms. When these neurons adopted the cholinergic phenotype, i.e., in the presence of muscle-conditioned medium, the development of the cellular A12 form was completely inhibited. These neurons secreted only globular, mainly G4, AChE. Both cellular and secreted A12 AChE in adrenergic cultures aggregated at an ionic strength similar to that of the culture medium, raising the hypothesis that this form was associated with a polyanionic component of basal lamina. In noradrenergic neurons, 60-80% of the catalytic sites were exposed at the cell surface. In particular, 80% of G4 form, but only 60% of the A12 form, was external, demonstrating for the A12 form a sizeable intracellular pool. The hydrophobic character of the molecular forms was studied in relation to their cellular localization. As in muscle cells, most of the G4 form was membrane-bound. Whereas 76% of the cell surface A12 form was solubilized in the aqueous phase by high salt concentrations, only 50% of the intracellular A12 form was solubilized under these conditions. The rest of intracellular A12 could be solubilized by detergents and was thus either membrane-bound or entrapped in vesicles originating from, e.g., the Golgi apparatus.     

Proteins of the kidney microvillar membrane. The amphipathic form of dipeptidyl peptidase IV.

Dipeptidyl peptidase IV was solubilized from the microvillar membrane of pig kidney by Triton X-100. The purified enzyme was homogeneous on polyacrylamide-gel electrophoresis and ultracentrifugation, although immunoelectrophoresis indicated that amino-peptidase M was a minor contaminant. A comparison of the detergent-solubilized and proteinase (autolysis)-solubilized forms of the enzyme was undertaken to elucidate the structure and function of the hydrophobic domain that serves to anchor the protein to the membrane. No differences in catalytic properties, nor in sensitivity to inhibition by di-isopropyl phosphorofluoridate were found. On the other hand, several structural differences could be demonstrated. Both forms were about 130,000 subunit mol.wt., but the detergent form appeared to be larger by no more than about 4,000. Electron microscopy showed both forms to be dimers, and gel filtration revealed a difference in the dimeric mol.wt. of about 38 000, mainly attributable to detergent molecules bound to the hydrophobic domain. Papain converted the detergent form into a hydrophilic form that could not be distinguished in properties from the autolysis form. A hydrophobic peptide of about 3500 mol.wt. was identified as a product of papain treatment. The detergent and proteinase forms differed in primary structure. Partial N-terminal amino acid sequences were shown to be different, and the pattern of release of amino acids from the C-terminus by carboxypeptidase Y was essentially similar. The results are consistent with a model in which the protein is anchored to the microvillar membrane by a small hydrophobic domain located within the N-terminal amino acid sequence of the polypeptide chain. The significance of these results in relation to biosynthesis of the enzyme and assembly in the membrane is discussed.     

Characterization of the folate-binding proteins associated with the plasma membrane of rat liver

Unsaturated folate-binding proteins (i.e., apo forms) have been identified with the plasma membranes of rat liver by the binding of [3H]pteroylglutamic acid. Normal rat liver contains very little of the folate-binding apoproteins, but the folate-binding capacity increases substantially when the rats are made folate-deficient. This increase appears to be due to unsaturation of the folate-binding holoproteins rather than to synthesis of additional protein, because the binding capacity of the plasma membranes from normal rat liver following dissociation of the bound folate is equivalent to the binding capacity of the preparation from folate-deficient liver. Two molecular forms of folate-binding protein were identified by gel filtration of the solubilized plasma membrane fraction, a high-molecular-weight form (Mr less than 100,000), representing 25% of the binding capacity, and a smaller protein (Mr approximately equal to 55,000), representing 75% of the binding capacity. Whereas the larger species can be solubilized only with a detergent, the smaller form appears to be hydrophilic and dissociates spontaneously from the membrane preparation. The binding of [3H]pteroylglutamic acid by the membrane preparation was specific, saturable, and pH- and temperature-dependent. Scatchard analysis of the binding could be fitted to a curvo-linear plot, indicating at least two orders of binding sites which probably correspond to the two molecular forms identified by gel filtration. Competitive inhibition by folate analogues demonstrated that the apoproteins have higher affinity for oxidized folate than for N5-methyltetrahydrofolate and virtually no affinity for N5-formyltetrahydrofolate or methotrexate.