Aleksandra Kubicz

The high molecular weight and the low molecular weight acid phosphatases of the frog liver and their phosphotyrosine activity

1. Two molecular weight classes of non-specific acid phosphatases (AcPases) (3.1.3.2) are present in the frog (Rana esculenta) liver: a higher molecular weight (HMW) of Mr 140,560 and a lower molecular weight (LMW) of Mr 38,180 enzyme. 2. The LMW AcPase was described earlier and the HMW AcPase of optimum pH 4.8 is shown to be a L(+)-tartrate sensitive, thermolabile, dimeric glycoenzyme slightly activated by DTT. 3. The HMW and the LMW AcPases exhibit activity for phosphotyrosine which showed similar sensitivity to various effectors as the p-nitrophenyl phosphatase activity; however, both enzymes differed substantially in this respect suggesting that they might be involved in different metabolic steps.

Multiple molecular forms of the acid phosphatase from Cyprinus carpio liver: Isolation and comparison with those of Rana esculenta

Abstract 1. 1. Acid phosphatase (AcPase) from liver of the carp, Cyprinus carpio, was separated on CM-cellulose into AcPase I, II and III. These are charge isomers with a molecular weight of 123,000 and differ in some biochemical properties. 2. 2. In comparison with the corresponding Rana esculenta enzyme, the carp AcPases differed essentially in terms of substrate requirements, activation and inhibition by some compounds, and thermostability. 3. 3. The carp liver AcPase is a sialoglycoenzyme; different amounts of sialic acid and other carbohydrate components are postulated to be responsible for the enzyme heterogeneity.

THE LOWER MOLECULAR WEIGHT ACID PHOSPHATASE FROM THE FROG LIVER: ISOLATION OF HOMOGENEOUS AcPase III AND IV REPRESENTING GLYCOFORMS WITH DIFFERENT BIOACTIVITY

1. AcPase III and AcPase IV, the major enzyme forms of the LMW AcPase of the frog (Rana esculenta) liver were resolved and purified to homogeneity. 2. AcPase III and IV showed a single protein band on SDS-PAGE corresponding to a mol. wt (Mr) of about 35,000. The Mr of the native enzyme forms were 33,200 (gel electrophoresis) and 38,200 +/- 5000 (gel filtration). This indicates that they are monomeric proteins sharing the same protein molecule. 3. AcPase III and IV differ essentially in thermostability and the activating effect of ConA binding. 4. AcPase III and IV are considerably activated with DTT but they differed markedly by the extent of this activation and the accompanying changes of their pH-activity curves. 5. It is suggested that the frog liver LMW AcPase represents a set of glycoforms whose different bioactivity is determined by the redox states of their essential cysteine residues.

Catfish liver acid phosphatases: Differently glycosylated enzyme molecules with altered kinetic properties

Two forms of catfish liver acid phosphatase (AcPase I and II) were separated and purified to homogeneity and their carbohydrate compositions and some biochemical properties were studied. Evidence is given that AcPase I and II are differently glycosylated forms of the same enzyme. The enzyme forms differ significantly in the size and the composition of their carbohydrate components, sensitivity towards sulfhydryl-blocking and protecting reagents, sensitivity to ferric and ferrous ions, thermostability and ability to hydrolyze some nucleotides. The more highly glycosylated form is more sensitive to thermal denaturation. AcPase I and II behave differently towards ascorbate and changes in its concentration and it is suggested that the concentration of reducing modifiers may regulate AcPase activity at the cellular level. It is hypothesized that the differing extents of glycosylation influence the structure of the enzyme forms. This is expressed in altered conformations of two enzyme forms and results in a different exposure of the essential cysteine residues.

Studies on the heterogeneity of carp liver acid phosphatases: Acid phosphatase—I. Subunit structure and carbohydrate composition

The three molecular forms of the carp liver acid phosphatase (AcPase) were shown to be dimeric proteins, two of them differing in molecular weights. An activating effect of ConA binding on the AcPases has been observed. AcPase I and AcPase II showed a mol. wt of 122,500 and of 58,884 +/- 3000 for their subunits. It is assumed that AcPase I is a sialylated derivative of AcPase II. AcPase III has a mol. wt of 93,132 and the two subunits of 46,556 +/- 4000. A homogeneous AcPase I was obtained and its carbohydrate composition is presented.

Characterization of the type of carbohydrate chains of the higher molecular weight (140 kDa) acid phosphatase of the frog liver

1. The higher molecular weight, (HMW, M(r) 140 kDa) acid phosphatase (AcPase) of the frog liver (Rana esculenta) was separated into enzymatically active components by isoelectric focusing in an immobilized pH gradient and their carbohydrate chains were analyzed by specific lectin binding after native blotting. 2. The lectin-binding patterns obtained with ConA, WGA, LcH and PNA as well as with WGA and PNA after desialylation indicate that the frog liver HMW AcPase contains predominantly N-linked complex and/or hybride type carbohydrate chains with terminal sialic acid and fucose residues; O-glycosylated enzyme components with free and sialic acid substituted Gal-GalNAc sequences were also detected.

Studies on the oligosaccharide heterogeneity of the isoelectric forms of the lower molecular weight acid phosphatase of frog liver

1. The lower molecular weight, heterogeneous acid phosphatase (AcPase) from the frog liver (Rana esculenta) containing AcPase I, II, III and IV was separated into enzymatically active components by isoelectric focusing in an immobilized pH gradient. 2. The blotted enzyme bands were characterized by their different binding patterns obtained with the lectins concanavalin A, wheat germ agglutinin (WGA), Lens culinaris hemagglutinin (LcH) and peanut agglutinin (PNA). 3. In situ neuraminidase treatment reduced the staining intensity of some WGA-bands and increased that of PNA-bands. 4. The finding that AcPases I, II, III and IV differ in their carbohydrate chain composition, together with previous results showing different bioactivities of AcPases III and IV, indicates a correlation between the glycosylation state of enzyme forms and their physiological action.

Amino acid composition and immunochemical properties of AcPase III and AcPase IV representing glycoforms of the lower molecular weight, tartrate-resistant acid phosphatase of the frog liver☆

1. Amino acid composition and immunological properties of the frog liver LMW AcPase forms: AcPase III and IV were examined. 2. AcPase III and IV show nearly identical amino acid composition and close immunological similarity. 3. These results indicate protein identity of both the enzyme forms and together with our previous data [Kubicz A., Szalewicz A. and Chrambach A., Int. J. Biochem. 23, 413-419 (1991)] demonstrate that generation of AcPase III and IV is a modification of the same enzyme protein by glycosylation processes. 4. Differences in immunoreactivity between AcPase III and IV were observed and discussed to be due to their altered conformations.

The 102 kDa Chicken Liver Acid Phosphatase: Dimeric Structure, Glycoprotein Nature and Immunological Properties

In this study we isolated a highly purified, homogeneous high molecular weight (HMW) AcPase (Mr 102 kDa) from the chicken liver. This enzyme was shown to be a slightly acidic (pI 5.0-6.1), dimeric sialoglycoenzyme, composed of two equivalent subunits. Its sugar moiety, characterized by interactions with specific lectins, was shown to be composed of hybrid and complex type of carbohydrate chains. Heterogeneity of the high molecular weight AcPase arising from variations of the sugar components was demonstrated by isoelectric focusing, followed by reactions of the isoelectric components with specific lectins on NC membranes. Structural relationship based on immunological similarities was shown between the HMW AcPases from carp, frog, and chicken livers.

The sugar moiety of Tamm-Horsfall protein is affected by the carbohydrate-deficient glycoprotein type I syndrome. A case study.

As the sugar moiety of Tamm-Horsfall protein (THP) is affected by many pathological conditions, the aim of this study was to examine the influence of carbohydrate-deficient glycoprotein syndrome (CDG) on THP glycans. THP was isolated from urine of one patient with CDG type I and N-glycan profiling, analysis of monosaccharide content, determination of THP reactivity with specific lectins and with anti-THP antibodies were performed. THP of the CDG patient showed markedly lower amounts of all monosaccharides. Diminished amounts of lactosamine-type chains, galactose and α2,3 linked sialic acid were expressed in lower reactivity with PHA-L, DSA and MAA, respectively. These modifications were reflected in altered proportions of tetrasialylated and disialylated oligosaccharide chains. THP of the CDG patient reacted slightly more with anti-THP antibodies. Our results indicate that the CDG type I affects the THP sugar moiety and slightly enhances the THP immunoreactivity.