The sequence of a porcine cDNA encoding α-lactalbumin

A cDNA clone encoding porcine α-lactalbumin (αLA) was isolated and sequenced. The longest clone was 688 nucleotides (nt) long and encoded a preprotein of 141 amino acids (aa) including a leader peptide of 19 aa. The porcine cDNA exhibited a nt similarity of between 72.2%–83.5% to other αLA cDNAs and an aa similarity of between 50.8%–85.2% with other αLA aa sequences. The derived aa sequence varied at three positions from a previously reported sequence for porcine αLA obtained by direct aa sequencing.     

Cloning of a urochordate cDNA featuring mammalian short consensus repeats (SCR) of complement-control protein superfamily

Mammalian tumor necrosis factor (TNF)-α degenerate polymerase chain reaction (PCR) primers were used to amplify a probe from Botryllus schlosseri (colonial ascidian) allogeneic rejection-cDNA library. A PCR product (269 bp) was cloned and sequenced encoding an open reading frame (ORF) of 89 amino acids (aa). This clone, which revealed no similarity to TNF-α, but a substantial similarity to mammalian proteins featuring short consensus repeats (SCRs) of the complement control superfamily, was used to probe the rejection-cDNA library. Two partial cDNA clones were isolated and sequenced (Bs. 1, 846 bp; Bs.2, 712 bp). The longest ORF in clone Bs. 1 (which lacks the 5' end of the cDNA) predicts a protein of 251 aa, which differs from Bs.2 at six nucleotides and four aa. We compare the as similarity (up to 50.5%) of Bs.l with the SCR-region of mammalian complement factor H, apolipoprotein H, selectins, and complement receptors type 1 and type 2. A somatomedin B-like domain at the C-terminus of Bs. 1 deduced protein was also recorded. We propose that this mosaic and polymorphic botryllid sequence, featuring mammalian-like SCRs, might be an ancestral molecule in the evolution of the chordate's complement-control protein superfamily.     

Cloning and expression of a cDNA encoding mouse kidney -amino acid oxidase

A cDNA encoding -amino acid oxidase (DAO;EC 1.4.3.3) has been isolated from a BALB/c mouse kidney cDNA library by hybridization with the cDNA for the porcine enzyme. Analysis of the nucleotide (nt) sequence of the clone revealed that it has a 1647-nt sequence with a 5′-terminal untranslated region of 68 nt that encodes 345 amino acids (aa), and a 3′-terminal untranslated region of 544 nt that contains the polyadenylation signal sequence ATTAAA. The deduced aa sequence showed 77 and 78% aa identity with the porcine and human enzymes, respectively. Two catalytically important aa residues, Tyr²²⁸ and His³⁰⁷, of the porcine enzyme, were both conserved in these three species. RNA blot hybridization analysis indicated that a DAO mRNA, of 2 kb, exists in mouse kidney and brain, but not liver. Synthesis of a functional mouse enzyme in Escherichia coli was achieved through the use of a vector constructed to insert the coding sequence of the mouse DAO cDNA downstream from the tac promoter of plasmid pKK223-3, which was designed so as to contain the lac repressor gene inducible by isopropyl-β- -thiogalactopyranoside. Immunoblot analysis confirmed the synthesis and induction of the mouse DAO protein, and the molecular size of the recombinant mouse DAO was found to be identical to that of the mouse kidney enzyme. Moreover, the maximum activity of the mouse recombinant DAO was estimated to be comparable with that of the porcine DAO synthesized in E. coli cells.     

Chemical characterization of sialyl oligosaccharides in milk of the Japanese black bear, Ursus thibetanus japonicus

Sialyl oligosaccharides were separated from two samples of Japanese black bear milk by extraction with chloroform/methanol, gel filtration on Bio Gel P-2, ion exchange chromatography on DEAE-Sephadex A-50 and high-performance liquid chromatography (HPLC) on a TSK gel Amido-80 column. They were characterized by ¹H-NMR spectroscopy. The structures of four sialyl oligosaccharides separated from the milk were the following:

Neu5Ac(α2-3)Gal(β1-4)Glc

Neu5Ac(α2-6)Gal(β1-4)GlcNAc(β1-3) Gal(α1-3)Gal(β1-4)[Fuc(α1-3)]GlcNAc(β1-6) Gal(β1-4)Glc

Neu5Ac(α2-6)Gal(β1-4)GlcNAc(β1-3) Gal(α1-3)[Fuc(α1-2)]Gal(β1-4)[Fuc(α1-3)]GlcNAc(β1-6) Gal(β1-4)Glc

Neu5Ac(α2-6)Gal(β1-4)GlcNAc(β1-3)[Neu5Ac(α2-6)Gal(β1-4)GlcNAc(β1-6)]Gal(β1-4)Glc

Differences in oligosaccharide pattern of a sample of polar bear colostrum and mid-lactation milk

Although the concentrations of carbohydrate in the colostrum and in the mid-lactation milk of polar bear (Ursus maritimus) were similar, the oligosaccharide patterns differed. The colostrum sample contained Neu5Ac(α2-3)Gal(β1-4)Glc (3′-N-acetylneuraminyllactose), GalNAc(α1-3)[Fuc(α1-2)]Gal(β1-4)Glc (A-tetrasaccharide), Fuc(α1-2)Gal(β1-4)Glc (2′-fucosyllactose) and Gal(β1-4)Glc (lactose). The mid-lactation milk contained Gal(α1-3)[Fuc(α1-2)]Gal(β1-4)[Fuc(α1-3)]Glc (B-pentasaccharide), GalNAc(α1-3)[Fuc(α1-2)]Gal(β1-4)[Fuc(α1-3)]Glc (A-pentasaccharide), Gal(α1-3)[Fuc(α1-2)]Gal(β1-4)Glc (B-tetrasaccharide), A-tetrasaccharide, Gal(α1-3)Gal(β1-4)[Fuc(α1-3)]Glc (3-fucosylisoglobotriose), Gal(α1-3)Gal(β1-4)Glc (isoglobotriose) and lactose. The dominant saccharides in the colostrum were 3′-N-Acetylneuraminyllactose and lactose, whereas isoglobotriose was the dominant saccharide in the mid-lactation milk in which lactose was only a minor component. Isoglobotriose, which had previously been found to be a dominant saccharide in mature milk from the Ezo brown bear, the Japanese black bear and the polar bear, was not found in the polar bear colostrum.     

Rheological properties of mixtures of κ-carrageenan from Hypnea musciformis and galactomannan from Cassia javanica

Mixed gels of κ-carrageenan (κ-car) from Hypnea musciformis and galactomannans (Gal) from Cassia javanica (CJ) and locust bean gum (LBG) were compared using dynamic viscoelastic measurements and compression tests. Mixed gels at 5 g/l of total polymer concentration in 0.1 M KCl showed a synergistic maximum in viscoelastic measurements for κ-car/CJ and κ-car/LBG at 2:1 and 4:1 ratios, respectively. The synergistic maximum obtained from compression tests carried out for mixed gels at 10 g/l of total polymer concentration in 0.25 M KCl was the same for both κ-car/CJ and κ-car/LBG gels. An enhancement in the storage modulus (G′) and the loss modulus (G″) was observed in the mechanical spectra for the mixtures in relation to κ-car. The proportionally higher increase in G″ compared with G′, as indicated by the values of the loss tangent (tan δ), suggests that the Gal adhere non-specifically to the κ-car network.     

Cloning and High-Level Expression of α-Galactosidase cDNA from Penicillium purpurogenum

The cDNA coding for Penicillium purpurogenum α-galactosidase (αGal) was cloned and sequenced. The deduced amino acid sequence of the α-Gal cDNA showed that the mature enzyme consisted of 419 amino acid residues with a molecular mass of 46,334 Da. The derived amino acid sequence of the enzyme showed similarity to eukaryotic αGals from plants, animals, yeasts, and filamentous fungi. The highest similarity observed (57% identity) was to Trichoderma reesei AGLI. The cDNA was expressed in Saccharomyces cerevisiae under the control of the yeast GAL10 promoter. Almost all of the enzyme produced was secreted into the culture medium, and the expression level reached was approximately 0.2 g/liter. The recombinant enzyme purified to homogeneity was highly glycosylated, showed slightly higher specific activity, and exhibited properties almost identical to those of the native enzyme from P. purpurogenum in terms of the N-terminal amino acid sequence, thermoactivity, pH profile, and mode of action on galacto-oligosaccharides.α-Galactosidase (αGal) (EC 3.2.1.22) is of particular interest in view of its biotechnological applications. αGal from coffee beans demonstrates a relatively broad substrate specificity, cleaving a variety of terminal α-galactosyl residues, including blood group B antigens on the erythrocyte surface. Treatment of type B erythrocytes with coffee bean αGal results in specific removal of the terminal α-galactosyl residues, thus generating serological type O erythrocytes (8). Cyamopsis tetragonoloba (guar) αGal effectively liberates the α-galactosyl residue of galactomannan. Removal of a quantitative proportion of galactose moieties from guar gum by αGal improves the gelling properties of the polysaccharide and makes them comparable to those of locust bean gum (18). In the sugar beet industry, αGal has been used to increase the sucrose yield by eliminating raffinose, which prevents normal crystallization of beet sugar (28). Raffinose and stachyose in beans are known to cause flatulence. αGal has the potential to alleviate these symptoms, for instance, in the treatment of soybean milk (16).αGals are also known to occur widely in microorganisms, plants, and animals, and some of them have been purified and characterized (5). Dey et al. showed that αGals are classified into two groups based on their substrate specificity. One group is specific for low-M_r α-galactosides such as pNPGal (p-nitrophenyl-α-d-galactopyranoside), melibiose, and the raffinose family of oligosaccharides. The other group of αGals acts on galactomannans and also hydrolyzes low-M_r substrates to various extents (6).We have studied the substrate specificity of αGals by using galactomanno-oligosaccharides such as Gal³Man₃ (6³-mono-α-d-galactopyranosyl-β-1,4-mannotriose) and Gal³Man₄ (6³-mono-α-d-galactopyranosyl-β-1,4-mannotetraose). The structures of these galactomanno-oligosaccharides are shown in Fig. ​Fig.1.1. Mortierella vinacea αGal I (11) and yeast αGals (29) are specific for the Gal³Man₃ having an α-galactosyl residue (designated the terminal α-galactosyl residue) attached to the O-6 position of the nonreducing end mannose of β-1,4-mannotriose. On the other hand, Aspergillus niger 5-16 αGal (12) and Penicillium purpurogenum αGal (25) show a preference for the Gal³Man₄ having an α-galactosyl residue (designated the stubbed α-galactosyl residue) attached to the O-6 position of the third mannose from the reducing end of β-1,4-mannotetraose. The M. vinacea αGal II (26) acts on both substrates to almost equal extents. The difference in specificity may be ascribed to the tertiary structures of these enzymes. Open in a separate windowFIG. 1Structures of galactomanno-oligosaccharides.Genes encoding αGals have been cloned from various sources, including humans (3), plants (20, 32), yeasts (27), filamentous fungi (4, 17, 24, 26), and bacteria (1, 2, 15). αGals from eukaryotes show a considerable degree of similarity and are grouped into family 27 (10).Here we describe the cloning of P. purpurogenum αGal cDNA, its expression in Saccharomyces cerevisiae, and the purification and characterization of the recombinant enzyme.     

Enzymic and structural studies on processed proteins from the vacuolar (lutoid-body) fraction of latex of Hevea brasiliensis

The lutoid-body (bottom) fraction of latex from the rubber tree (Hevea brasiliensis) contains a limited number of major proteins. These are the chitin-binding protein hevein, its precursor and C-terminal fragment of the precursor, a basic chitinase/lysozyme, and a β-1,3-glucanase. The content and properties of the latter enzyme differ between lutoid-body fractions from four different rubber clones (cultivars). While the enzyme from clone GT.1 is a glycoprotein with carbohydrate attached to two glycosylation sites, the enzymes from other clones contain little or no carbohydrate. Latex from clone GT.1 has a higher β-1,3-glucanase content than those from the other three clones, but with a significantly lower specific activity. The enzyme exhibits a pH optimum at 4.5, but there is a second one at 6.7. Peptides isolated from β-1,3-glucanase of clone GT.1 showed that the enzyme is heterogeneous at the C-terminus, probably as a result of removal of a vacuolar targeting sequence by an endopeptidase, followed by further removal of C-terminal residues by a carboxypeptidase-like activity. This incomplete digestion can be related to glycosylation at the extreme C-terminus of the mature enzyme. Non-glycosylated Hevea β-1,3-glucanases exhibit less C-terminal heterogeneity. A homologue of the antifungal protein osmotin was isolated from rubber clones which are less susceptible to fungal diseases. Another identified protein is identical to a citrate binding protein (CBP), already sequenced as cDNA, but with cleaved-off N-terminal signal and C-terminal vacuolar targeting peptides. Four C-terminal propeptides of vacuolar proteins in Hevea are positively identified, which is a valuable contribution to previously known examples of this type of processing.     

Expression of 5α-reductase in bacteria as a trp E fusion protein and its use in the production of antibodies for immunocytochemical localization of 5α-reductase

A cDNA encoding a full-length rat 5α-reductase was isolated using female rat liver mRNA and the polymerase chain reaction, and fused to the Escherichia coli trp E gene in a pATH expression vector. The trp E-5α-reductase fusion protein expressed in bacteria and a synthetic oligopeptide corresponding to the C-terminus of rat 5α-reductase were used as antigens to produce rabbit polyclonal antibodies to 5α-reductase. Antibodies to the 5α-reductase portion of the fusion protein and to the peptide were purified by affinity chromatography. Antibodies against the 5α-reductase fusion protein reacted with a single component of rat liver microsomes with M_r 26,000 on Western blots, consistent with the size of 5α-reductase predicted from its cDNA, and with a M_r 23,000 component on Western blots of detergent extracts of rat ventral prostate nuclei; other rat ventral prostate cellular fractions (mitochondrial, microsomal, cytosol) bound little or no antibody. Antibody against the synthetic peptide reacted with a M_r 26,000 component of rat liver microsomes as well as with several components in various cellular fractions of rat ventral prostate. With anti-5α-reductase fusion protein antibodies, specific immunocytochemical staining was observed in the epithelial cell nuclei of the rat ventral prostate, seminal vesicle, epididymis and other accessory sex glands. This nuclear staining was specific, since antibodies from non-immunized rabbits did not give nuclear staining and preincubation of the anti-5α-reductase fusion protein antibodies with the trp E-5α-reductase fusion protein eliminated nuclear staining. Incubation of antibodies with trp E (without the 5α-reductase fusion) had no effect on nuclear staining. Specific staining was not detected in the cytoplasm of these epithelial cells. Little or no specific staining was observed in stromal cells in these rat tissuess. Human prostate was also immunocytochemically stained with this antibody. Specific staining was found in both epithelial and stromal cell nuclei.     

Characterisation of the gene encoding a protective antigen from Babesia microti identified it as η subunit of chaperonin containing T-complex protein 1

Passive immunisations with a monoclonal antibody termed 1-5H showed a partial but significant inhibition of parasitaemia against Babesia microti challenge infection. By immunoscreening with 1-5H, a clone (termed p58 gene) was obtained from a cDNA expression library of B. microti and the complete nucleotide sequence was determined. A protein homology search showed significant amino acid identities to the η subunit of the chaperonin containing T-complex protein 1 (CCT) of human (59%), mouse (58%) and Plasmodium falciparum (62%). Genomic analyses indicated that the p58 gene is present as a single copy gene and contains a total of approximately 400-bp introns in the genome of B. microti. The mAb 1-5H recognised a 58-kDa protein of B. microti and was found to cross-react with a 60-kDa protein of Babesia rodhaini. These results suggest the possibility that the p58 protein is the CCT η subunit of B. microti and functions as a chaperonin.     

Enzymatic syntheses of T antigen-containing glycolipid mimicry using the transglycosylation activity of endo-α-N-acetylgalactosaminidase

Thomsen–Friedenreich antigen (T antigen) disaccharide, β- -galactose-(1→3)-α-N-acetyl- -galactosamine (β- -Gal-(1→3)-α- -GalNAc), containing glycolipid mimicry was synthesized using the transglycosylation activity of endo-α-N-acetylgalactosaminidase from Bacillus sp. This enzyme could transfer the disaccharide from a p-nitrophenyl substrate to water-soluble 1-alkanols and other alcohols at a transfer ratio of 70% or more. Although the transfer ratios were lower for water-insoluble than water-soluble alcohols, they were shown to increase by adding sodium cholate to the reaction mixtures. The enzyme also transferred the disaccharide directly from asialofetuin to 1-alkanols. The anomeric bond between the disaccharide and 1-alkanols of the transglycosylation product is in the α configuration as determined by sequential digestion of jack bean β-galactosidase and Acremonium α-N-acetylgalactosaminidase. Since the transglycosylation product, β- -Gal-(1→3)-α- -GalNAc-(1→O)-hexyl, efficiently inhibits the binding of anti-T antigen monoclonal antibody to asialofetuin, it has potential as an agent for blocking T antigen-mediated cancer metastasis.     

The Cytochrome b5 Tail Anchors and Stabilizes Subdomains of Human DNA Topoisomerase IIα in the Cytoplasm of Retrovirally Infected Mammalian Cells

DNA topoisomerase II (topo II) is the target of many anticancer drugs and is often altered in drug-resistant cell lines. In some tumor cell lines truncated isoforms of topo IIα are localized to the cytoplasm. To study the localization and function of individual enzyme domains, we have epitope-tagged several fragments of human topo IIα and expressed them by retroviral infection of rodent and human cells. We find that fusion of the topo II fragments to the hydrophobic tail of human liver cytochrome b₅ anchors the fusion protein to the outer face of cytoplasmic membranes, as determined by colocalization with calnexin and selective detergent permeabilization. Moreover, whereas the minimal ATPase domain (aa 1–266) is weakly and diffusely expressed, addition of the cytb₅ anchor (1–266-b₅) increases its steady-state level 16-fold with no apparent toxicity. Similar results are obtained with the complete ATPase domain (aa 1–426). A C-terminal domain (aa 1030–1504) of human topo IIα containing an intact dimerization motif is stably expressed and accumulates in the nucleus. Fusion to the cytb₅ anchor counteracts the nuclear localization signal and relocalizes the protein to cytoplasmic membranes. In conclusion, we describe a technique that stabilizes and targets retrovirally expressed proteins such that they are exposed on the cytoplasmic surface of cellular membranes. This approach may be of general use for regulating the nuclear accumulation of drugs or proteins in living cells.     

Molecular cloning and expression analysis of phospholipase Cdelta from mud loach, Misgurnus mizolepis

A gene encoding phosphoinositide-specific phospholipase C (PLC), designated ML-PLCδ, was cloned from mud loach (Misgurnus mizolepis) liver. A complete cDNA encoding ML-PLCδ was isolated by screening the cDNA library of mud loach liver and using the 5′-rapid amplification of cDNA ends (RACE) method. The full-length ML-PLCδ gene contains an open reading frame of 2325 base pairs encoding a 774 amino acid protein with a molecular mass of 88,072 Da; this corresponds to the size of the protein expressed in Escherichia coli BL21 (DE3) using pET28a vector. It contains all of the characteristic domains found in mammalian PLCδ isozymes (PH domain, EF-hands, X–Y catalytic region, and a C2 domain). A homology search revealed that ML-PLCδ shares relatively high sequence identity with mammalian PLCδ1 (51–52%) and catfish PLCδ (64%). The recombinant ML-PLCδ protein expressed as a histidine-tagged fusion protein in E. coli was purified to apparent homogeneity by Ni²⁺-NTA affinity chromatography. The recombinant ML-PLCδ showed a concentration-dependent PLC activity to phosphatidylinositol 4,5-bis-phosphate (PIP₂) and its activity was Ca²⁺-dependent, which was similar to mammalian PLCδ isozymes.     

The use of fluorescein-conjugated Bandeiraea simplicifolia B4-isolectin as a histochemical reagent for the detection of α- -galactopyranosyl groups : Their occurrence in basement membranes

The Bandeiraea simplicifolia B₄-isolectin, which combines specifically with α- -galactopyranosyl groups, has been conjugated with fluorescein isothiocyanate and demonstrated to be a reliable histochemical probe for the detection of these groups in normal tissues of mouse, rabbit, rat and man. Specificity of binding of the fluorescein-conjugated B. simplicifolia B₄-isolectin to native cryostat tissue sections was demonstrated in two ways:

1. 1. The hapten inhibitor methyl α- -galactopyranoside prevented the binding of the lectin to tissues whereas the non-hapten methyl α- -glucopyranoside did not.

2. 2. Pretreatment of tissue sections with coffee bean α-galactoside abolished lectin binding whereas pretreatment with A. niger or E. coli β-galactosidase did not. The fluorescein-conjugated isolectin visualized α- -galactopyranosyl groups in basement membranes and on the surface of certain epithelial cells of mouse, rat, rabbit, and on the surface of the TA3 murine mammary carcinoma. These studies suggest that the B. simplicifolia B₄-isolectin may be of great utility in studying the family of α- -galactosyl-containing glycoconjugates of basement membranes in pathological states accompanied by basement membrane changes, such as diabetes mellitus, and in neoplasms that secrete basement membrane.

     

In vivo modification of Na,K-ATPase activity in Drosophila

We have constructed and characterized transgenic Drosophila lines with modified Na⁺,K⁺-ATPase activity. Using a temperature dependent promoter from the hsp70 gene to drive expression of wild-type α subunit cDNA, we can conditionally rescue bang-sensitive paralysis and ouabain sensitivity of a Drosophila Na⁺,K⁺-ATPase α subunit hypomorphic mutant, 2206. In contrast, a mutant α subunit (α^D369N) leads to increased bang-sensitive paralysis and ouabain sensitivity. We can also generate temperature dependent phenotypes in wild-type Drosophila using the same hsp70 controlled α transgenes. Ouabain sensitivity was as expected, however, both bang sensitive paralysis or locomotor phenotypes became more severe regardless of the type of α subunit transgene. Using the Gal4-UAS system we have limited expression of α transgenes to cell types that normally express a particular Drosophila Na⁺,K⁺-ATPase β (Nervana) subunit isoform (Nrv1 or 2). The Nrv1-Gal4 driver results in lethality while the Nrv2-Gal4 driver shows reduced viability, locomotor function and uncontrolled wing beating. These transgenic lines will be useful for disrupting function in a broad range of cell types.     

Re-examination of the anomeric configuration of the galactose-(1–3)-galactose linkages in the asparagine-linked sugar chains of subcomponent C1q of bovine complement and calf thymocyte plasma membrane glycoproteins

The anomeric configuration of the terminal Gal1–3Gal linkages found in the asparagine-linked sugar chains of subcomponent C1q of bovine complement and of calf thymocyte plasma membrane glycoproteins were re-examined, and confirmed to be alpha by coffee bean -galactosidase digestion. This contradictory result compared to the previous assignment could be explained by the finding that even very trace amounts (0.06 mU) of -galactosidase contaminating the preparation of jack bean -galactosidase were able to cleave the Gal1–3Gal linkage.