Localization of a gene for human α-galactosidase B (=N-Acetyl-α-D-Galactosaminidase) on chromosome 22

Summary The localization of the structural gene for human -galactosidase B (=N-acetyl--galactosaminidase) was investigated by means of man-Chinese hamster and man-mouse somatic cell hybrids. The hybrid clones were analyzed for chromosomes and for a large number of known enzyme markers. The lysates of the hybrid cells were treated with Sepharose-coupled antihuman -galactosidase B and the activity of the adsorbed enzyme was measured on the Sepharose beads as N-acetyl--galactosominidase. The results show that the structural gene for human -galactosidase B is situated on chromosome 22, and that there is no structural relationship between human -galactosidase A and human -galactosidase B.     

An α-fucosidase pseudogene on human chromosome 2

Summary In Chinese hamster-human hybrids with overlapping translocations, the major site of hybridization of a cDNA clone for the liver form of human -l-fucosidase was 1p36.31p34, consistent with hybridization to the FUCA1 locus. No hybridization to the FUCA2 locus on chromosome 6 was observed. Hybridization to a genomic sequence on chromosome 2 was, however, detected, thus defining a new FUCA-like locus. The restriction map of the -fucosidase cDNA could be exactly superimposed upon its region of homology within a genomic clone containing this FUCA-like locus, suggesting that it is a processed pseudogene.     

Sex-specific selection on the human X chromosome?

Genes involved in major biological functions, such as reproductive or cognitive functions, are choice targets for natural selection. However, the extent to which these genes are affected by selective pressures remains undefined. The apparent clustering of these genes on sex chromosomes makes this genomic region an attractive model system to study the effects of evolutionary forces. In the present study, we analysed the genetic diversity of a X-linked microsatellite in 1410 X-chromosomes from 10 different human populations. Allelic frequency distributions revealed an unexpected discrepancy between the sexes. By evaluating the different scenarios that could have led to this pattern, we show that sex-specific selection on the tightly linked VCX gene could be the most likely cause of such a distortion.     

Immobilization of β-galactosidase on modified polypropilene membranes

A new immobilized system: β-galactosidase-modified polypropylene membrane was created. It was obtained 13 different carriers by chemical modification of polypropylene membranes by two stages. The first stage is treatment with K(2)Cr(2)O(7) to receive carboxylic groups on membrane surface. The second stage is treatment with different modified agents ethylendiamine, hexamethylenediamine, hydrazine dihydrochloride, hydroxylamine, o-phenylenediamine, p-phenylenediamine, N,N'-dibenzyl ethylenediamine diacetate to receive amino groups. The quantity of the amino groups, carboxylic groups and the degree of hydrophilicity of unmodified and modified polypropilene membranes were determined. β-Galactosidase was chemically immobilized on the obtained carries by glutaraldehyde. The highest relative activity of immobilized enzyme was recorded at membrane modified with 10% hexamethylenediamine (Membrane 5) - 92.77%. The properties of immobilized β-galactosidase on different modified membranes - pH optimum, temperature optimum, pH stability and thermal stability were investigated and compared with those of free enzyme. The storage stability of all immobilized systems was studied. It was found that the most stable system is immobilized enzyme on Membrane 5. The system has kept 90% of its initial activity at 300th day (pH=6.8; 4°C). The stability of the free and immobilized β-galactosidase on the modified membrane 5 with 10% HMDA in aqueous solutions of alcohols - mono-, diol and triol was studied. The kinetics of enzymatic reaction of free and immobilized β-galactosidase on the modified membrane 5 at 20°C and 40°C and at the optimal pH for both forms of the enzyme were investigated. It was concluded that the modified agent - hexamethylenediamine, with long aliphatic chain ensures the best immobilized β-galactosidase system.     

Evidence for two β-galactosidase activities inStreptomyces violaceus

The kinetics of β-galactosidase synthesis induced by galactose and lactose inStreptomyces violaceus, as well as the pattern ofo-nitrophenyl-β-d-galactoside-positive bands observed after electrophoresis of both crude extracts, showed the presence of different β-galactosidase activities in the two cellular extracts. It is postulated that the lactase activity induced by lactose is the physiological enzyme responsible for lactose utilization. The possible function of the galactose-induced activity is also discussed.     

A new spin-labeled substrate for β-galactosidase and β-galactoside permease

A spin-labeled β-galactoside has been synthesized. It is a substrate for β-galactosidase and is accumulated by E. coli ML 308-225 and K12-N2244. The accumulation appears to be active transport via the lactose permease since it is inhibited with lactose and the energy poison, amytal. Induction of the K12 strain with isopropylthiogalactoside results in a 100-fold stimulation of uptake of the spin-labeled β-galactoside. Binding of the spin-labeled sugar to membranes derived from the ML strain is inhibited by lactose.     

Hydrolysis of GM1-ganglioside by human liver β-galactosidase isoenzymes

1. GM(1)-ganglioside, specifically tritiated in the terminal galactose, was hydrolysed by two forms of ;acid' methylumbelliferyl beta-galactosidase isolated on gel filtration. 2. Identification of GM(1)-ganglioside beta-galactosidase activity with the ;acid' methyl-umbelliferyl beta-galactosidases was based on the following: coincident elution profiles on gel filtration; simultaneous inactivation by heat and other treatments; stabilization of both activities by chloride ions; mutual inhibition of hydrolysis by the two substrates. 3. The two isoenzymes (I) and (II) showed general requirements for a mixture of anionic and nonionic detergents in the hydrolysis of the natural substrate. 4. Isoenzyme (I) differed from (II) in molecular size, pH-activity profile, relative resistance to dilution and in sensitivity to various inhibitors. 5. The most significant difference between the isoenzymes is in substrate saturation kinetics: (I) was hyperbolic whereas (II) was sigmoid. The apparent Michaelis constants were 28mum for (I) and 77mum for (II). Isoenzyme (I) was insensitive to GM(2)-ganglioside whereas (II) was inhibited, consistent with the hypothesis that GM(1)-ganglioside (and its analogue) acts as modifier in isoenzyme (II) but not in (I). 6. Isoenzyme (I) was membrane-bound whereas (II) was soluble; the former probably represents isoenzyme (II) bound to membrane components, thereby becoming activated. 7. Membranes may serve a dual role in enzyme catalysis involving lipids: as a medium where both enzyme and substrate are effectively concentrated, and as actual activator of enzymes through binding of the latter to specific membrane components.     

Effects of the Bgs locus on mouse β-galactosidase

The Bgs locus determines tissue levels of β-galactosidase in the mouse, so that enzyme levels are twice as high in mice carrying the Bgs ^hallele as in mice carrying the Bgs ^dallele (Felton et al., 1974). By immunotitration with antiserum to purified β-galactosidase, we have found that the Bgs locus influences the amount of enzyme protein present in the tissues. We have utilized recombinant inbred lines derived from a cross between C57BL/6J and DBA/2J mice to confirm the location of the Bgs locus on chromosome 9. The inhibition of mouse β-galactosidase by the active-site-directed reagent N-bromoacetyl-β-d-galactosylamine has been investigated. β-Galactosidase from the high and low Bgs strains has identical affinity for this inhibitor.     

Histochemical methods for acid β-galactosidase: Technics for semipermeable membranes

Summary Indigogenic and azocoupling reactions for the detection of acid -galctosidase in unfixed cold microtome sections adherent to semipermeable membranes are described. The indigogenic method is the method of choice. The described procedure prevents the leakage of the enzyme activity of sections (the diffusion is limited to the closest surroundings of the actual localization of enzyme activity) and is recommended as a routine method in studies concerning acid -galactosidase.     

Assignment of the gene for cystathionine β-synthase to human chromosome 21 in somatic cell hybrids

Summary Among several established mouse, rat, and Chinese hamster cell lines that were screened for cystathionine -synthase (CBS) activity, mouse 3T3 and Chinese hamster Don fibroblasts were found to contain no detectable activity. Somatic cell hybrids between human fibroblasts KG-7 with normal CBS activity and Don/a23TK^- cells (series XXI) were examined for CBS activity and for human chromosome content. Only chromosome 21 cosegregated with CBS activity. Because the activities measured could represent either Chinese hamster or human gene products, we have prepared a new series of hybrids between Don/a23TK^- cells and mutant human fibroblasts from a patient with homocystinuria due to deficiency of functional CBS mRNA. None of these (series XXV) hybrids contained detectable CBS activity, although collectively all human chromosomes were represented. Our results suggest that the human gene for CBS, called CBS, and thus for the most common form of homocystinuria, is located on chromosome 21.     

Premature chromosome condensation —studies on human metastatic carcinoma cells

Summary Utilizing the phenomenon of premature chromosome condensation (PCC) studies were carried out on inter-phase chromatin of metastatic cells from 52 cancerous effusions obtained from 45 patients presenting with various solid carcinomas. A highly individual pattern of distribution of the various interphase stages was detected, reflecting the heterogeneity of human solid tumors in an advanced stage. Nevertheless a variety of clinical, biologic, and tecnical factors were examined for their possible influence on these PCC patterns. The duration in culture was one of the influencing factors, as were the time lapse between the first diagnosis and the sampling of the respective effusion, or the nature of cytostatic therapy. Cytogenetic equevalents of gene amplification, as represented by double minutes, could be found in the prematurely interphase chromatin of 35 of the 52 effusions. Gl-PCC proved to be most reliable with regard to screening of double minutes. In addition, an adequate quality of Giemsa banding was achieved in PCC of 21 out of 24 effusions yielding a sufficient number of well-spread PCC. In six of these 21 cases PCC was superior to metaphase analysis in obtaining karyotypes, while the same was true for 14 of the 52 effusions screened for double minutes. Thus the PCC technique was shown to be an indispensable additional source of cytogenetic information in cells of human solid tumors.     

Ganglioside GM1 metabolism in living human fibroblasts with β-galactosidase deficiency

Summary The uptake and catabolism of [³H-ceramide]-G_M1 was followed in living fibroblasts from patient with different forms of -galactosidase deficiency. Gangliosides are identified according to the nomenclature of Svennerholm (1963). A total inability to metabolize the ingested substrate was found in infantile G_M1-gangliosidosis whereas cells from an adult G_M1-gangliosidosis variant showed a slower rate of degradation, compared with controls. Morquio B fibroblasts had a comparable catabolism of G_M1 as controls. Fibroblasts from different types of galactosialidosis, a recessive disease associated with a coexistent -galactosidase/neuraminidase deficiency all showed degradation of ingested G_M1. In view of the molecular defect in this disease, this catabolism must be due to the 10–20% of monomeric -galactosidase molecules present in the lysosomes. Unexpectedly, in these cells an impaired metabolism of G_M3 was found. The same finding was observed when cells with an isolated neuraminidase deficiency (mucolipidosis I) were loated with G_M1. A hypothesis is presented to explain these results.     

The genetic defect in the various types of human β-galactosidase deficiency

Summary Gene localization studies revealed the presence of two structural -galactosidase (GAL) loci on the human chromosomes 3 and 22 (de Wit et al., 1979). To determine the function of these genes, proliferating hybrid cell lines were isolated following fusion of fibroblasts from two different patients with a GAL deficiency and Chinese hamster cells. The hybrids were analyzed electrophoretically and immunologically.Fibroblasts from a patient with an adult type of GAL deficiency associated with a neuraminidase deficiency were used for the first fusion. No evidence for a structural GAL mutation was found in these hybrids. The absence of a structural GAL mutation is consistent with a primary defect in neuraminidase in this adult patient.Fibroblasts from a patient with the infantile type 1 G_M1-gangliosidosis were used for the second fusion. It is concluded that the human determinants present in the isolated hybrid lines occur in heteropolymeric man-Chinese hamster molecules. The heteropolymeric isoenzyme in (+3–22) hybrids is very labile and is sensitive to neuraminidase treatment. Therefore it is concluded that the infantile type 1 patient is mutated in the structural GAL gene on chromosome 3. Because this patient has a primary defect in G_M1-GAL, the GAL gene on chromosome 3 is apparently a G _M1-GAL gene. Interaction of the two GAL loci results in an additional band of GAL activity on electrophoresis. This suggests that the gene on chromosome 22 is also a structural G _M1-GAL gene.     

Characteristics of yeast β-galactosidase immobilized on calcium alginate gels

Summary Saccharomyces anamensis having -galactosidase activity, has been immobilized in calcium alginate gel matrix that retained 78.6% enzyme activity to that of native cells. Optimum pH(7.0) was negligibly affected by immobilization. K_m values for immobilized and native cells were 119 mM and 102 mM respectively. Protective agents like dithioerythritol, bovine serum albumin, enhance the enzyme activity when added prior to immobilization. Immobilized cells can be stored in refrigeration(4°C) for 42 days without a significant loss of enzyme activity.     

Assignment of structural β-galactosidase loci to human chromosomes 3 and 22

Summary Hybrid cell lines isolated after fusions between Chinese hamster E36 cells and normal human white blood cells were analyzed for human -galactosidase isoenzymes and for human chromosomes, especially 3, 12, and 22, the candidates for bearing a -galactosidase locus. Results of neuraminidase treatment of the cell lysates and immunological studies showed that in man two structural -galactosidase loci are present and can be assigned to chromosomes 3 and 22. No correlation was found between the expression of human -galactosidase and the presence of human chromosome 12.     

Aqueous two-phase partition coefficients for Escherichia coli β-galactosidase fusions

The partition of native Escherichia coli -galactosidase and of two different fusion proteins comprised mainly of -galactosidase from E. coli was studied in aqueous two-phase systems composed of polyethylene glycol (PEG) and dextran. These fusions contain an amino-terminal segment from the E. coli outer membrane protein F (OmpF) and a linker peptide. Differences in the partition pattern could be observed for the three enzymes despite their similarity. Decreased polymer concentrations in the phase system increased the partition coefficient for all three -galactosidases.     

Effects of α-galactosidase digestion on lectin staining in human pancreas

Summary Effects of -galactosidase (from green coffee beans) digestion on lectin staining were examined in formalin-fixed, paraffin-embedded human pancreatic tissues from individuals of blood-group B and AB. Digestion with the enzyme resulted in almost complete loss of Griffonia simplicifolia agglutinin I-B₄(GSAI-B₄) staining in the acinar cells with concomitant appearance of Ulex europaeus agglutinin-I(UEA-I) staining in the corresponding cells. In addition, reactivity with soybean agglutinin(SBA) was also imparted by the enzyme digestion in GSAI-B₄ positive acinar cells. -Galactosidase digestion following -galactosidase digestion neither reduced the reactivity with SBA nor induced the reactivity with Griffonia simplicifolia agglutinin-II(GSA-II) in GSAI-B₄ positive cells, while in UEA-I positive cells, both reduction of SBA reactivity and appearance of GSA-II reactivity occurred after simple -galactosidase digestion as well as sequential digestion with - and -galactosidase. However, when -l-fucosidase digestion procedure was inserted between - and -galactosidase digestion, UEA-I staining imparted by -galactosidase digestion was markedly decreased in intensity and GSA-II reactivity was appeared in GSAI-B₄ positive acinar cells. Furthermore, after sequential digestion with -galactosidase and fucosidase, reactivity with peanut agglutinin(PNA) was revealed in GSAI-B₄ positive acinar cells as well as UEA-I positive cells in secretors. In non-secretors, strong PNA staining was usually observed in the acinar cells throughout the glands without enzyme digestion. These results confirmed that the -galactosidase induced GSA-II reactivity and the fucosidase induced PNA reactivity are due to precursors of different kinds of blood-group determinants and suggest that at least two kinds of B antigen determinants, i.e. Gal(1-3)[Fuc(1-2)]Gal(1-3,4)GlcNac and Gal(1-3)-[Fuc(1-2)]Gal(1-3)GalNAc are produced in GSAI-B₄ positive acinar cells. The synthesis of the latter type of B antigen is assumed to be controlled under the secretory gene in human pancreas.Abbreviation GalNAc N-acetyl-d-galactosamine - Gal d-galactose - GlcNAc N-acetyl-d-glucosamine - Fuc l-fucose - NeuNAc N-acetylneuraminic acid (sialic acid)     

Latent β-galactosidase inEscherichia coli

Incubation of washedEscherichia coli cells with crystalline RNase lead to increased β-galactosidase activity. The height of the increase depended on the type of strain and the conditions of cultivation. RNase only raised the level of the β-galactosidase which was bound to the relatively easily sedimenting cellular particles. It had no effect on the activity of β-galactosidase present in soluble form in the supernatant after the disruption of cells or on the activity of purified β-galactosidase in solution. Another basic protein, histone, was found to have a similar effect to that of RNase.     

Covalent immobilization of Kluyveromyces fragilis β-galactosidase on magnetic nanosized epoxy support for synthesis of galacto-oligosaccharide

The novel magnetic nanobeads with epoxy groups on the surface were prepared from glycidyl methacrylate (GMA), ethylene glycol dimethacrylate (EGDMA) and hydroxyethyl methacrylate (HEMA) via emulsifier-free emulsion polymerisation, and they were characterized by scanning electron microscopy and vibrating sample magnetometer. The magnetic poly(GMA-EDGMA-HEMA) nanobeads were used as support for covalent immobilization of Kluyveromyces fragilis β-galactosidase, the maximum amount enzyme attached onto the support was 145.6?mg/g with activity recovery of 72.6%. The loading capacity of this novel support for K. fragilis β-galactosidase was improved 2.6-folds compared with Eupergit(?) C (commercial epoxy support). The immobilized K. fragilis β-galactosidase exhibited high catalytic activity for the reaction of galacto-oligosaccharide (GOS) synthesis, and a total of 2,240?g GOS were produced per gram of immobilized enzyme during consecutive batch reaction of 10 times. The immobilized biocatalyst retained 81.5% of its original activity after 10 reaction cycles.     

The human genes for the α and γ subunits of the mast cell receptor for immunoglobulin E are located on human chromosome band 1823

The receptor with high affinity for immunoglobulin E (FcERI) is a key molecule in triggering the allergic reaction. It is tetrameric complex of one subunit, one subunit, and two disulfide-linked subunits. This receptor is present exclusively on mast cells and basophils. Molecules identical to the subunit of FcRI also form cell surface complex with other Fc receptors such as mouse FcRIIa in macrophages and most probably with human FcRIII (CD16) in natural killer (NK) cells. Here we show by in situ hybridization that the human genes for the (FCER1A) and subunits (FCER1 G) of FcERI and the gene for FcRIII (FCGR3, CD16) are located on human chromosome band 1823.