Enzyme polymorphism in rat-liver microsomes and plasma membranes. 1. An immunochemical study of multienzyme complexes and other enzyme-active antigens

Crossed-immunoelectrophoretic study on human renal brush border membrane vesicles

The human kidney brush border membrane proteins were studied by crossed-immunoelectrophoresis. An antiserum against membrane vesicles was raised in rabbits and used in establishing a reference immunoelectrophoregram with the antigens released by Triton X-100. Among the precipitates observed, the following hydrolases were identified by zymogram staining: Microvillus aminopeptidase (EC 3..4.11.2), gamma-glutamyltransferase (EC 2.3.2.2), maltase (EC3.2.1.20) and trehalase (EC 3.2.1.28). Depletion of the antiserum with sealed, right-side-out vesicles was performed. No precipitates could be seen when the Triton X-100 extract was electrophoresed in a gel containing the depleted antibody. It is therefore suggested that the precipitation of membrane components by the complete antibody is mainly due to externally-located determinants and that the precipitates of the reference pattern correspond to membrane components pointing, at least in part, towards the tubular lumen. Evidence was also noted for a differential removal of antibodies directed against the different antigens. Such an observation could not be explained by the antigen accessibility nor by its amount in the membrane. Parallel crossed-immunoelectrophoresis of Triton X-100 and papain extracts gave rise to an "identity" pattern for only some antigens, particularly for microvillus aminopeptidase and maltase. It is thus strongly suggested that the papain-released form of these enzymes bears nearly all the antigenicity of the whole molecule.

Immunochemical analysis of inner and outer membranes of Escherichia coli by crossed immunoelectrophoresis

Isolated membrane fractions of Escherichia coli K-12 yielded complex immunoprecipitate patterns when Triton X-100 and sodium dodecyl sulfate extracts were examined by crossed immunoelectrophoresis with antienvelope immunoglobulins. Twelve of the 46 antigens in the immunoprecipitate patterns of inner (plasma) membranes were identified by zymograms and/or by the use of specific antisera. The following enzyme activities were detected in immunoprecipitates: 6-phosphogluconate dehydrogenase (EC 1.1.1.43); adenosine triphosphatase (EC 3.6.1.3); glutamate dehydrogenase (EC 1.4.1.4), two separate components; malate dehydrogenase (EC 1.1.1.37); dihydroorotate dehydrogenase (EC 1.3.3.1); succinate dehydrogenase (EC 1.3.99.1); lactate dehydrogeanse (EC 1.1.1.27); reduced nicotinamide adenine dinucleotide dehydrogenase (EC 1.6.99.3); protease (EC 3.4.21.1); and glycerol 3-phosphate dehydrogenase (EC 1.1.99.5). The corresponding immunoprecipitate pattern for isolated outer membranes consisted of at least 25 discrete antigens and differed strikingly from that obtained with inner membranes. Two major immunogens were identified as lipopolysaccharide and Braun lipoprotein. A protease-active immunoprecipitate was also detected in this fraction, but attempts to identify the Rosenbusch matrix protein in the crossed immunoelectrophoretic profile were unsuccessful.

Crossed immunoelectrophoresis of bovine milk fat globule membrane protein solubilized with non-ionic detergent

Detergent solubilized bovine milk fat globule membrane material studied by crossed immunoelectrophoresis combined with histochemical techniques revealed four major protein complexes. All four were found to bind to concanavalin A and three were identified as sialoglycoproteins. Xanthine oxidase activity was associated with the non-sialoglycoprotein precipitate. Immunoabsorption with intact milk fat globules showed an internal location of the xanthine oxidase, whereas the three other main proteins plus Mg2+-ATPase and 5'-nucleotidase were disposed on the outer membrane surface. The major proteins from milk fat globule membrane and membrane material isolated from skim milk showed immunochemical identity.

Arylamidases of rat liver and chemically induced hepatomas. 1. Subcellular distribution of L-leucine. 2. Naphthylamidase-active antigens

The subcellular distribution of arylamidase-active antigens in rat liver and in two chemically induced hepatomas (D23 and D33) was investigated. Soluble antigens or detergent-solubilized membrane antigens from isolated subcellular fractions were tested in fused rocket immunoelectrophoresis against antisera prepared against each of the fractions. The arylamidase active antigens were identified by means of a zymogram technique using L-leucine 2-naphthylamide as substrate. Two arylamidase-active antigens were shown to be shared between plasma membranes, microsomes, lysosomal membranes and lysosomal content of the hepatocytes. One of these occurred predominantly in the plasma membranes (the plasma membrane arylamidase) while the other was preferentially found in the lysosomal content (the lysosomal content arylamidase). Also a third arylamidase-active antigen was identified and was shown to be restricted to the microsomes and the lysosomal membranes (the microsomal/lysosomal arylamidase). The rat liver plasma membrane arylamidase-active antigen was also present in plasma membrane, microsomal and cell-sap fractions of both the hepatomas. However, in the hepatomas this antigen occurred predominantly in the microsomal fraction. The plasma membrane arylamidase was the only arylamidase-active antigen found in the hepatoma D33 while the plasma membrane and microsomal fractions of hepatoma D23 also contained another antigen with this activity. Neither the lysosomal content arylamidase nor the microsomal/lysosomal arylamidase could be detected in any of the hepatoma fractions.

Arylamidases of rat liver and chemically induced hepatomas. II. Preparation and characterization of monospecific antisera against two distinct arylamidase-active antigens

Monospecific antisera were prepared against the most prominent arylamidase (alpha-aminoacyl-peptide hydrolase (microsomal), EC 3.4.11.2) active antigen in plasma membranes (the plasma membrane arylamidase) and lysomal content (the lysosomal content arylamidase), respectively. Plasma membrane extract and lysosomal content were allowed to react in crossed immunoelectrophoresis against their homologous antisera. The electrophoretic plates were washed extensively, dried and subsequently stained for arylamidase activity. The particular immunoprecipitates were thus identified and could be excised to be used for immunizations. The two resulting antisera precipitated the arylamidase used for immunization, but failed to be monospecific as they precipitated additional antigens. These antisera with restricted specificity against some plasma membrane and lysosomal content antigens, respectively, were used to produce immunoprecipitates intended for new attempts to prepare monospecific antisera by a second cycle of immunizations. A monospecific antiserum against the plasma membrane arylamidase was thus obtained, while a third cycle of immunizations was needed to get a monospecific anti-lysosomal content antiserum. The plasma membrane arylamidase showed ATPase activity also after precipitation with the monospecific antiserum, thus still retaining its characteristics as a multienzyme complex.

The immunochemical approach to the characterization of membrane proteins. Human erythrocyte membrane proteins analysed as a model system

1. Crossed immunoelectrophoresis was used for extensive characterization of individual proteins of human erythrocyte membranes solubilized in non-ionic detergent. 2. The precipitates were assigned to extrinsic or intrinsic proteins. 3. Four glycoproteins were identified by their lectin binding behaviour, whilst five proteins were affected by neuraminidase, indicating them to be sialoglycoproteins. 4. Enzymatic activity is retained in the solubilized system and the presence of acetylcholinesterase and an ATPase was demonstrated. The formation of phosphorylated membrane proteins on incubation with [32P]ATP was demonstrated by autoradiography on the immunoelectrophoresis plates. 5. Five proteins located on the outer cell surface were identified by antibody binding to intact cells. These same proteins were degraded by proteolytic enzymes in intact cells but only three of them were labelled by lactoperoxidase-catalysed 125I-iodination. 6. Analysis of erythrocyte membrane proteins using quantitive immunoelectrophoresis yields results concordant with those obtained by dodecyl sulfate-polyacrylamide gel electrophoresis.

Localization of enzymes in specialized regions of the microsomal membrane

Microsomal vesicles were centrifuged through sucrose density gradients containing deoxycholate. With 0.15% detergent electron transport enzymes and phosphatases could be separated. Increasing the deoxycholate concentration to 0.19% resulted in separation of the microsomal material into five bands containing (in order from the top of the gradient) adenosine monophosphatase, inosine diphosphatase and some glucose-6-phosphatase (band 1); NADH-linked (band 2) and NADH-linked (band 3) electron transport enzymes; and glucose-6-phosphatase (bands 4 and 5). It appears that enzymes are arranged in specialized patches in the microsomal membrane.

Epinephrine-binding plasma-membrane antigens in rat liver

Detergent extracts of isolated rat liver plasma membranes were analysed in two-dimensional immunoelectrophoresis against antiserum to plasma membranes. Enzyme staining of the immunoprecipitates revealed the presence of about ten antigens with nucleoside di- and triphosphatase activity. Most of these were earlier shown also to be NADH-neotetrazolium reductase active. In addition, two of these antigens exhibited L-leucyl-beta-naphthylamidase activity. As judged from autoradiography these plasma membrane antigens earlier characterized as multienzyme complexes bound [14C]epinephrine, and the same antigens were labelled regardless of whether membranes or membrane extracts were incubated with the radioactive hormone. The specificity of this binding was established in displacement experiments with unlabelled hormones or their analogues. Another hormone-binding antigen, also identified in the plasma membrane extract did not exhibit any known enzyme activity while three antigens with different enzyme activities had no epinephrine-binding capacity. [14C]Epinephrine-labelled plasma membrane extracts were chromatographed on Sepharose 4B and the fractions obtained were analysed in two-dimensional immunoelectrophoresis combined with autoradiography. Nucleoside di- and triphosphatases of high molecular weights (5000000) were associated with L-leucyl-beta-naphthylamidase activity, while no such associations were detected in a lower molecular weight region (70000). Further immunological studies on the various fractionated antigens provided evidence that at least two of them occurred in both low and high molecular weight fractions. Hormone-binding membrane components in varying concentrations were found throughout the eluted extract.

Soluble and membrane-bound enzyme-active antigens of rat-liver lysosomes

Secondary lysosomes were isolated from rat liver and separated into a soluble and a membrane fraction. Plasma membranes and microsomes were also isolated and antisera against the various fractions were prepared in rabbits. Lysosomal content and detergent-solubilized membrane fractions were analysed in two-dimensional immunoelectrophoresis (crossed immunoelectrophoresis). The immunoprecipitates were stained by histochemical procedures for different enzyme activities such as phosphatases, non-specific esterase, arylsulphatase, glycosidases and L-leucyl-beta-naphthylamidase. When lysosomal content was tested against its corresponding antiserum, 17 different precipitates could be seen. Most of the enzyme activities tested were shown to reside separately in one or a few precipitates each. In contrast, when the membrane extracts were investigated, a more polymorphic pattern of enzyme-active precipitates appeared. Thus, when lysosomal membrane extracts were reacted with homologous antiserum 11 precipitates with acid phosphatase activity were obtained. Several of the antigens were electrophoretically different and immunologically non-identical. As expected from the biology of secondary lysosomes, many of their antigens were also found in microsomes and/or plasma membranes, but several antigens unique for lysosomes were detected concomitantly. Closer analysis of these results indicated that several seemingly identical enzyme-active proteins occurred both in soluble and membrane-associated forms. However, while many of the membrane antigens expressed 2-4 different enzyme activities, only one activity was detected in individual precipitates of the lysosomal content. Thus, acid phosphatase activity was found together with esterase activity in three membrane-associated antigens. The precipitates formed by two of these also stained for arylsulphatase and nucleoside tri-, di- and monophosphatase activities. L-Leucyl-beta-naphthylamidase activity was found in one additional acid-phosphatase-active precipitate.