Identification of two GH27 bifunctional proteins with β-L-arabinopyranosidase/α-D-galactopyranosidase activities from Fusarium oxysporum

Two distinct extracellular bifunctional proteins with β-L-arabinopyranosidase/α-D-galactopyranosidase activities were purified from the culture filtrate of Fusarium oxysporum 12S. The molecular masses of the enzymes were estimated to be 55 (Fo/AP1) and 73 kDa (Fo/AP2) by SDS-PAGE. They hydrolyzed both p-nitrophenyl β-L-arabinopyranoside and p-nitrophenyl α-D-galactopyranoside with different specificities. Fo/AP1 also showed low activity towards α-D-galactopyranosyl oligosaccharides such as raffinose. Interestingly, both enzymes hydrolyzed larch wood arabinogalactan (releasing arabinose) but not carob galactomannan, which has α-D-galactopyranosyl side chains. When larch wood arabinogalactan was incubated with excess Fo/AP1 or Fo/AP2, both enzymes released approximately 10% of the total arabinose in the substrate. cDNAs encoding Fo/AP1 and Fo/AP2 (Foap1 and Foap2) were isolated by in vitro cloning. The coding sequences of Foap1 and Foap2 genes were 1,647 and 1,620 bp in length and encode polypeptides of 549 and 540 amino acids, respectively. The N-terminal halves of both proteins had high similarity to putative conserved domains of the melibiase superfamily (Pfam account number 02065). The deduced amino acid sequences of the two enzymes indicate that they belong to glycosyl hydrolase family 27. Moreover, the C-terminal regions of both proteins contain a putative family 35 carbohydrate-binding module.     

Evolved β-Galactosidases from Geobacillus stearothermophilus with Improved Transgalactosylation Yield for Galacto-Oligosaccharide Production

A mutagenesis approach was applied to the β-galactosidase BgaB from Geobacillus stearothermophilus KVE39 in order to improve its enzymatic transglycosylation of lactose into oligosaccharides. A simple screening strategy, which was based on the reduction of the hydrolysis of a potential transglycosylation product (lactosucrose), provided mutant enzymes possessing improved synthetic properties for the autocondensation product from nitrophenyl-galactoside and galacto-oligosaccharides (GOS) from lactose. The effects of the mutations on enzyme activity and kinetics were determined. An change of one arginine to lysine (R109K) increased the oligosaccharide yield compared to that for the wild-type BgaB. Subsequently, saturation mutagenesis at this position demonstrated that valine and tryptophan further increased the transglycosylation performance of BgaB. During the transglycosylation reaction with lactose of the evolved β-galactosidases, a major trisaccharide was formed. Its structure was characterized as β-d-galactopyranosyl-(1→3)-β-d-galactopyranosyl-(1→4)-d-glucopyranoside (3′-galactosyl-lactose). At the lactose concentration of 18% (wt/vol), this trisaccharide was obtained in yields of 11.5% (wt/wt) with GP21 (BgaB R109K), 21% with GP637.2 (BgaB R109V), and only 2% with the wild-type BgaB enzyme. GP643.3 (BgaB R109W) was shown to be the most efficient mutant, with a 3′-galactosyl-lactose production of 23%.Galacto-oligosaccharides (GOS) are established prebiotic food ingredients and are used to enhance the growth of bifidobacteria and lactobacilli in the large intestine in order to reduce the growth of pathogenic microorganisms (3, 26, 27). The increased interest in these products by consumers heightened the need for good catalysts. Therefore, the development of an efficient and inexpensive GOS production method is highly desirable. One approach is to use lactose as a substrate for the preparation of prebiotic carbohydrates. Lactose is a low-value sugar comprising up to 75% of the total dry material in whey, and it accumulates in quantities of approximately 6 million tons annually worldwide (29). In several studies, GOS syntheses from lactose using different β-glycosidases had been reported (21). GOS are usually produced by the transglycosylation reaction during enzymatic hydrolysis of lactose. The proportion of transglycosylation to hydrolysis varies, depending on the different sources of enzymes (20, 22, 30, 31). In most cases yields of oligosaccharides are rather low; presumably the products are substrates for the enzyme and undergo hydrolysis.In order to overcome the hydrolysis problem, attempts to transform a glycosidase into a transglycosidase have been made. The generation of glycosynthases, which are mutants of glycosidases with a nonfunctional catalytically acting nucleophile amino acid residue, was one attempt to improve the transglycosylation yield. Many glycosynthases which demonstrated improved glycoside synthesis have been reported (8, 10, 12). However, this approach requires knowledge of the catalytically acting nucleophile residues of the glycosidase studied. Furthermore, activated glycosyl donors (e.g., glycosyl fluoride substrates of the opposite anomeric conformation) are needed for their enzymatic reaction. Therefore, their potential for use in industrial processes for large-scale production of GOS seems low, because of their inactivity on natural substrates (e.g., lactose).In a second approach, directed-evolution strategies have been used to enhance transglycosidase activity. Using random mutagenesis and in vitro recombination, Feng et al. (10) were able to diminish the hydrolytic activity of β-glycosidase from Thermus thermophilus while significantly increasing the transglycosylation activity. This allowed them to synthesize oligosaccharides through transglycosylation reactions with nitrophenyl-β-glycosides as donors and various glycosides as acceptors. The enhancement of the transglycosylation activities of β-glycosidases toward natural substrates such as lactose was achieved by active-site mutagenesis of β-glucosidase from Pyrococcus furiosus (13) or by using a truncated β-galactosidase from Bifidobacterium bifidum (19).The application of thermostable β-galactosidases is of interest in the conversion of lactose, because at higher temperatures higher lactose concentration can be used, favoring GOS synthesis. Thus, we explored the use of the thermophilic β-galactosidase BgaB from Geobacillus stearothermophilus for transglycosylation reaction on lactose to produce specific GOS. BgaB, belonging to glycoside hydrolase family 42 (15), cloned in Escherichia coli is able to hydrolyze lactose, but its GOS productivity is rather low. Thus, we aimed at increasing the synthetic yield of GOS from lactose exerted by the enzyme. Here we applied a random mutagenic approach together with a screening procedure to obtain mutants possessing higher transgalactosylation activity.     

The yeast FET5 gene encodes a FET3 -related multicopper oxidase implicated in iron transport

The yeast FET3 gene encodes an integral membrane multicopper oxidase required for high-affinity iron uptake. The FET4 gene encodes an Fe(II) transporter required for low-affinity uptake. To identify other yeast genes involved in iron uptake, we isolated genes that could, when overexpressed, suppress the iron-limited growth defect of a fet3 fet4 mutant. The FET5 gene was isolated in this screen and it encodes a multicopper oxidase closely related to Fet3p. Several observations indicate that Fet5p plays a role analogous to Fet3p in iron transport. Suppression of the fet3 fet4 mutant phenotype by FET5 overexpression required the putative FTR1 transporter subunit of the high-affinity system. Fet5p is an integral membrane protein whose oxidase domain is located on the cell surface or within an intracellular compartment. Oxidase activity measured in cells with altered levels of FET5 expression suggested that Fet5p is a functional oxidase. FET5 overexpression increased the rate of iron uptake by a novel uptake system. Finally, FET5 mRNA levels are regulated by iron and are increased in cells grown in iron-limited media. These results suggest that Fet5p normally plays a role in the transport of iron.     

The use of a thermostable β-glucanase gene from Clostridium thermocellum as a reporter gene in plants

In order to take advantage of the high thermostability of its product, β-1,3;1,4-glucanase (lichenase), we used a modified version of the licB gene from Clostridium thermocellum as a reporter gene for the analysis of gene expression in transformed plants. The coding region of the licB gene was truncated at both ends. The truncated enzyme retained its activity and thermostability. The modified gene (m-licB), with and without a plant leader peptide-encoding sequence, was expressed in tobacco plants under control of either the Agrobacterium octopine T_R-DNA 2′ gene promoter or the promoter of the gene for the small subunit of ribulose-1,5-bisphosphate carboxylase. Expression of licB can be measured quantitatively and accurately, the assay is sensitive and simple enough to be used for analysis of various gene fusion systems or for screening of transformants. The enzyme is very stable and remains active in tissue extracts even after storage for 1 year and survives many thawing-freezing cycles. The lichenase-encoding gene was expressed at high levels in transformed tobacco plants without any apparent detrimental effects on vegetative growth or flowering. Received: 4 March 1997 / Accepted: 8 October 1997     

The Schizosaccharomyces pombe cdc6 gene encodes the catalytic subunit of DNA polymerase δ

The cdc6 mutants of Schizosaccharomyces pombe have been classified as being defective in progression through the G2 phase of the cell cycle. We cloned an S. pombe gene that could complement the temperature-sensitive growth of the cdc6-23 mutant. Unexpectedly, the cloned gene was allelic to pol3, which encodes the catalytic subunit of DNA polymerase δ. Integration mapping confirmed that cdc6 and pol3 are identical. The cdc6-23 mutant carries one amino acid substitution in the conserved N3 region of Pol3.     

The apolipoprotein(a) gene resides on human chromosome 6q26–27, in close proximity to the homologous gene for plasminogen

Summary Apolipoprotein(a) [apo(a)], the glycoprotein associated with the lipoprotein(a) [Lp(a)] subfraction of plasma lipoproteins, has been shown to exhibit heritable molecular weight isoforms ranging from 400–700 kDa. Increased serum concentrations of Lp(a) correlate positively with the risk of atherosclerosis. Variations in Lp(a) plasma levels among individuals are inherited as a codominant quantitative trait. As part of an effect to define the basis of these variations and further clarify the expression of the protein, we have determined the chromosomal location of the human apo(a) gene. Blot hybridization analysis of DNA from a panel of mouse-human somatic cell hybrids with an apo(a) cDNA probe revealed a complex pattern of bands, all of which segregated with chromosome 6. In situ hybridization yielded a single peak of grain density located on chromosome 6q26–27. Apo(a) cDNA sequences exhibit striking homology to those of the plasma protease plasminogen, and, therefore, we have reexamined the chromosome assignment of the plasminogen gene. We conclude that both the apo(a) and plasminogen genes reside on human chromosome 6q22–27, consistent with a gene duplication mechanism for their evolutionary origin. The results are of significance for the genetic control of apo(a) expression and genetic influences predisposing to atherosclerosis.     

Geobacillus stearothermophilus LV cadA gene mediates resistance to cadmium, lead and zinc in zntA mutants of Salmonella entérica serovar Typhimurium

Salmonella entérica serovar Typhimurium cells expressing the cadA gene of Geobacillus stearothermophilus LV exhibit a hypersensitive phenotype to cadmium chloride. Deletion of the ORF STM3576 from the Salmonella genome resulted in cadmium, lead and zinc sensitivity, confirming that this ORF is a homologue of the zntA gene. The observed sensitivity was reverted upon expression of the G. stearothermophilus LV cadA gene. These results indicate that the cadA gene product is involved in Cd, Pb and Zn resistance as a classical P-type ATPase and strongly suggest that the observed hypersensitive phenotype to these metals can be related to the function of the host .zntA gene product.     

The Sjögren-Larsson syndrome gene encodes a hexadecenal dehydrogenase of the sphingosine 1-phosphate degradation pathway

Sphingosine 1-phosphate (S1P) functions not only as a bioactive lipid molecule, but also as an important intermediate of the sole sphingolipid-to-glycerolipid metabolic pathway. However, the precise reactions and the enzymes involved in this pathway remain unresolved. We report here that yeast HFD1 and the?Sj?gren-Larsson syndrome (SLS)-causative mammalian gene ALDH3A2 are responsible for conversion of?the S1P degradation product hexadecenal to hexadecenoic acid. The absence of ALDH3A2 in CHO-K1 mutant cells caused abnormal metabolism of S1P/hexadecenal to ether-linked glycerolipids. Moreover, we demonstrate that yeast Faa1 and Faa4 and mammalian ACSL family members are acyl-CoA synthetases involved in the sphingolipid-to-glycerolipid metabolic pathway and that hexadecenoic acid accumulates in Δfaa1 Δfaa4 mutant cells.?These results unveil the entire S1P metabolic pathway: S1P is metabolized to glycerolipids via hexadecenal, hexadecenoic acid, hexadecenoyl-CoA, and palmitoyl-CoA. From our results we propose a possibility that accumulation of the S1P metabolite hexadecenal contributes to the pathogenesis of SLS.     

A Chlamydomonas gene encodes a G protein β subunit-like polypeptide

Summary A Chlamydomonas gene encodes a protein that shows sequence similarity with the subunit of guanine nucleotide binding proteins from mammals, fruit fly and yeast. In addition to amino acid sequences similarity, each of these proteins contains a segmented repeat structure in which certain amino acids form a consensus sequence. Thus this gene product has been designated a Chlamydomonas subunit-like polypeptide (Cblp). The mRNA is constitutively expressed during the cell cycle and during flagellar regeneration.     

The regulatory network controlling β-globin gene switching

Molecular Biology Reports - The human globin gene cluster, which represents a prototypical eukaryotic multigene locus, has been investigated for more than two decades and is classic model for...     

Expression of a β-galactosidase gene from Lactobacillus sake in Escherichia coli

Summary A -galactosidase gene from Lactobacillus sake coding for lactose hydrolysis was cloned and expressed in Escherichia coli. Chromosomal DNA from L. sake was partially digested with the restriction enzyme Sau3AI, and the 3–6 Kb fragment was ligated to the cloning vector pSP72 digested with BamHI. One E. coli transformant expressing -galactosidase was isolated on X-gal plates. It contained a plasmid with an insertion of approx. 4 Kb. The restriction map of the recombinant plasmid was constructed. The characteristics of the recombinant -galactosidase were compared with those of the wild type. The optima pH and temperature for both enzymes was 6.5 and 50°C, respectively. Stability of the enzymes at different temperatures and activity on lactose were determined.     

Phytohormone-regulated β-amylase gene expression in rice

The expression of -amylase genes in rice (Oryza sativa) and its regulation by phytohormones gibberellic acid (GA) and abscisic acid (ABA) were examined. Upon germination -amylase is synthesizedde novo in aleurone cells and (GA) is not required. Exogenous addition of GA does not enhance the -amylase activity, while ABA inhibits the -amylase activity, mRNA accumulation, and the germination of rice seeds. GA can reverse ABA inhibition of -amylase expression, but not ABA inhibition of seed germination. Such regulation represents a new interaction of ABA and GA.     

The open reading frame TTC1157 of Thermus thermophilus HB27 encodes the methyltransferase forming N²-methylguanosine at position 6 in tRNA

N(2)-methylguanosine (m(2)G) is found at position 6 in the acceptor stem of Thermus thermophilus tRNA(Phe). In this article, we describe the cloning, expression, and characterization of the T. thermophilus HB27 methyltransferase (MTase) encoded by the TTC1157 open reading frame that catalyzes the formation of this modified nucleoside. S-adenosyl-L-methionine is used as donor of the methyl group. The enzyme behaves as a monomer in solution. It contains an N-terminal THUMP domain predicted to bind RNA and contains a C-terminal Rossmann-fold methyltransferase (RFM) domain predicted to be responsible for catalysis. We propose to rename the TTC1157 gene trmN and the corresponding protein TrmN, according to the bacterial nomenclature of tRNA methyltransferases. Inactivation of the trmN gene in the T. thermophilus HB27 chromosome led to a total absence of m(2)G in tRNA but did not affect cell growth or the formation of other modified nucleosides in tRNA(Phe). Archaeal homologs of TrmN were identified and characterized. These proteins catalyze the same reaction as TrmN from T. thermophilus. Individual THUMP and RFM domains of PF1002 from Pyrococcus furiosus were produced. These separate domains were inactive and did not bind tRNA, reinforcing the idea that the THUMP domain acts in concert with the catalytic domain to target a particular position of the tRNA molecule.     

A β-thalassemia mutant caused by a 300-bp deletion in the human β-globin gene

Summary Larger deletions are a rare cause of -thalassemia. We report a further instance of a deletion comprising about 300 bp in a female heterozygote. Exon 1, part of IVS-1 and the 5 -globin gene promoter region are lost.     

The wciN gene encodes an α-1,3-galactosyltransferase involved in the biosynthesis of the capsule repeating unit of Streptococcus pneumoniae serotype 6B

Almost all Streptococcus pneumoniae (pneumococcus) capsule serotypes employ the Wzy-dependent pathway for their capsular polysaccharide (CPS) biosynthesis. The assembly of the CPS repeating unit (RU) is the first committed step in this pathway. The wciN gene was predicted to encode a galactosyltransferase involved in the RU assembly of pneumococcus type 6B CPS. Herein, we provide the unambiguous in vitro biochemical evidence that wciN encodes an α-1,3-galactosyltransferase catalyzing the transfer of galactosyl from UDP-Gal onto the Glcα-pyrophosphate-lipid (Glcα-PP-lipid) acceptor to form Galα(1-3)Glcα-PP-lipid. A chemically synthesized acceptor (Glcα-PP-O(CH(2))(10)CH(3)) was used to characterize the WciN activity. The disaccharide product, i.e., Galα(1-3)Glcα-PP-O(CH(2))(10)CH(3), was characterized by mass and NMR spectroscopy. Substrate specificity study indicated that the acceptor structural region composed of pyrophosphate and lipid moieties may play an important role in the enzyme-acceptor recognition. Furthermore, divalent metal cations were found indispensable to the WciN activity, suggesting that this glycosyltransferase (GT) belongs to the GT-A superfamily. By analyzing the activities of six WciN mutants, a DXD motif involved in the coordination of a divalent metal cation was identified. This work provides a chemical biology approach to characterize the activities of pneumococcal CPS GTs in vitro and will help to better understand the pneumococcal CPS biosynthetic pathway.     

The use of β-galactosidase as a tracer in immunocytochemistry

Summary A new immunocytochemical method using -galactosidase as a tracer is described. The positive staining appears blue on an unstained background. The present method has the high sensitivity and specificity of the immunoperoxidase method and appears to be a practical alternative. The substrate has no carcinogenic activity. Staining is permanent and the sections can be dehydrated and mounted in synthetic media. Enzyme and substrate solutions are stable for several months.