Two homologous fungal carbonyl reductases with different substrate specificities

Two homologous fungal short-chain dehydrogenase/reductase (SDR) proteins have been cloned from the fungus Curvularia lunata (teleomorph: Cochliobolus lunatus) and expressed in Escherichia coli: trihydroxynaphthalene reductase (3HNR), an enzyme of the melanin biosynthetic pathway that catalyzes the conversion of 1,3,8-trihydroxynaphthalene to vermelone, and 17beta-hydroxysteroid dehydrogenase (17beta-HSDcl), which acts on androgens and estrogens, although its physiological substrate remains to be defined. In the present study, we have compared the structures, specificities to substrates and inhibitors, temperature and pH optima of 3HNR and 17beta-HSDcl. Sequence analysis and homology-built models revealed that these enzymes are highly similar. Both of these enzymes are NADP(H)-preferring reductases and act on steroids at position 17; however, 17beta-HSDcl presented considerably higher initial rates than 3HNR. In vitro, 17beta-HSDcl preferably catalyzed the reduction of 4-estrene-3,17-dione, while the best steroid substrate for 3HNR was 5alpha-androstane-3,17-dione. On the other hand, 2,3-dihydro-2,5-dihydroxy-4H-benzopyran-4-one (DDBO), an artificial substrate of 3HNR, was oxidized rapidly by 3HNR, while it was not a substrate for 17beta-HSDcl. Additionally, our data show that tricyclazole, a specific inhibitor of 3HNR, is 100-fold less effective for 17beta-HSDcl inhibition, while flavonoids can inhibit both 3HNR and 17beta-HSDcl. We have also examined the effects of temperature and pH on the oxidation of DDBO by 3HNR and the oxidation of 4-estrene-17beta-ol-3-one by 17beta-HSDcl. The apparent optimal temperature for 3HNR activity was between 25 and 30 degrees C, while it was between 40 and 45 degrees C for 17beta-HSDcl activity. The pH optimum of 3HNR activity was between 8 and 9, and for 17beta-HSDcl, between 7 and 8. Our data show that in spite of high homology and similar backbone structure, differences between 3HNR and 17beta-HSDcl were not only in substrate specificities, but also in temperature and pH optima.     

Geotrichum candidum produces several lipases with markedly different substrate specificities.

We have purified and examined the substrate specificity of four lipases from two strains of the mould Geotrichum candidum, ATCC 34614 and CMICC 335426. We have designated the lipases I and II (ATCC 34614), and A and B (CMICC 335426). The enzymes are monomeric and have similar molecular masses and pI. Thus, lipases I and II have native molecular masses of 50.1 kDa and 55.5 kDa, and pI of 4.61 and 4.47, respectively. Lipases A and B are very similar to lipases I and II with native molecular masses of 53.7 kDa and 48.9 kDa, and pI of 4.71 and 4.50, respectively. Treatment with endo-beta-N-acetylglucosaminidase caused a reduction in molecular mass of approximately 4.5 kDa for all four lipases, indicating that these enzymes are glycosylated. Western blotting shows that the lipases are related. However, lipase B from CMICC 335426 shows a remarkable specificity for unsaturated substrates with a double bond at position 9 (cis configuration), and this specificity is not exhibited by the other three lipases. No lipase of this unique specificity has previously been purified to homogeneity. Structural studies using these four lipases should allow insight into the molecular basis of this remarkable specificity.     

Effects of Triton X-100 on acid phosphatases with different substrate specificities

Summary The effect of Triton X-100 on the activities of acid phosphatases from wheat germ, potato and human prostate was tested using -glycerophosphate, p-nitro-phenyl phosphate and naphthol AS BI phosphate as substrates. There was little effect on -glycerophosphatase activity at the concentrations of Triton X-100 tested. However at low concen trations of the detergent there was a stimulation of the activities of p-nitrophenyl phosphatase and naphthol phosphatase which were inhibited with the higher concentrations. Triton X-100 was found to enhance colour production between naphthol AS BI and fast red violet LB.Further evidence is presented confirming the presence of more than one acid phosphatase from each of the sources employed.     

Levels of glucose dehydrogenases with different substrate specificities in rat and beef livers

The relative substrate specificities of glucose dehydrogenases (E.C. 1.1.1.47) from beef liver and rat liver are very different. The beef enzyme oxidizes glucose more rapidly than either glucose-6-phosphate or galactose-6-phosphate. On the other hand, the dehydrogenase from rat liver prefers the hexose phosphates to glucose.A procedure for estimating the level of glucose dehydrogenase in rat and beef liver is described. The glucose-6-phosphate dehydrogenase activity attributed to glucose dehydrogenases is estimated to be about one-fifth and one-third that of cytoplasmic glucose-6-phosphate dehydrogenase (E.C. 1.1.1.49) in female and male rat liver respectively.A fluorometric adaptation of the less sensitive spectrophotometric assay for glucose dehydrogenase is described.     

The white-rot fungus Pleurotus ostreatus secretes laccase isozymes with different substrate specificities

Four laccase isozymes (LCC1, LCC2, LCC3 and LCC4) synthesized by Pleurotus ostreatus strain V-184 were purified and characterized. LCC1 and LCC2 have molecular masses of about 60 and 65 kDa and exhibited the same pI value (3.0). Their N termini were sequenced, revealing the same amino acid sequence and homology with laccases from other microorganisms. Laccases LCC3 and LCC4 were characterized by SDS-PAGE, estimating their molecular masses around 80 and 82 kDa, respectively. By native isoelectrofocusing, their pI values were 4.7 and 4.5, respectively. When staining with ABTS and guaiacol in native polyacrilamide gels, different specificities were observed for LCC1/LCC2 and LCC3/LCC4 isozymes.     

Sodium-dependent nucleoside transport in mouse intestinal epithelial cells. Two transport systems with differing substrate specificities

Nucleoside transport was examined in freshly isolated mouse intestinal epithelial cells. The uptake of formycin B, the C nucleoside analog of inosine, was concentrative and required extracellular sodium. The initial rate of sodium-dependent formycin B transport was saturable with a Km of 45 +/- 3 microM. The purine nucleosides adenosine, inosine, guanosine, and deoxyadenosine were all good inhibitors of sodium-dependent formycin B transport with 50% inhibition (IC50) observed at concentrations less than 30 microM. Of the pyrimidine nucleosides examined, only uridine (IC50, 41 +/- 9 microM) was a good inhibitor. Thymidine and cytidine were poor inhibitors with IC50 values greater than 300 microM. Direct measurements of [3H]thymidine transport revealed, however, that the uptake of this nucleoside was also mediated by a sodium-dependent mechanism. Thymidine transport was inhibited by low concentrations of cytidine, uridine, adenosine, and deoxyadenosine (IC50 values less than 25 microM), but not by formycin B, inosine, or guanosine (IC50 values greater than 600 microM). These data indicate that there are two sodium-dependent mechanisms for nucleoside transport in mouse intestinal epithelial cells, and that formycin B and thymidine may serve as model substrates to distinguish between these transporters. Neither of these sodium-dependent transport mechanisms was inhibited by nitrobenzylmercaptopurine riboside (10 microM), a potent inhibitor of one of the equilibrative (facilitated diffusion) nucleoside transporters found in many cells.     

Arabidopsis AtcwINV3 and 6 are not invertases but are fructan exohydrolases (FEHs) with different substrate specificities

The genome of Arabidopsis thaliana contains six putative cell-wall type invertase genes (AtcwINV1-6). Heterologous expression of AtcwINV1, 3 and 6 cDNAs in Pichia pastoris revealed that the enzymes encoded by AtcwINV3 and 6 did not show invertase activity. Instead, AtcwINV3 is a 6-FEH and AtcwINV6 is a fructan exohydrolase (FEH) that can degrade both inulin and levan-type fructans. For AtcwINV6 it is proposed to use the term (6&1) FEH. In contrast, AtcwINV1 is a typical invertase. FEH activity was also detected in crude extracts of different parts of Arabidopsis. To verify that the FEH activity of AtcwINV3 and 6 were not artefacts of the heterologous expression system, the protein corresponding to AtcwINV3 was isolated from whole Arabidopsis plants and indeed showed only 6-FEH activity and no invertase activity. Although no fructans can be detected in Arabidopsis plants, it is shown that kestoses (trimers) can be synthesized in crude leaf extracts. The putative physiological significance of FEH in so-called non-fructan plants is discussed.     

Two bacterial collagenolytic serine proteases have different topological specificities

From among 2000 soil isolates, we purified a secreted serine protease from Streptomyces omiyaensis (SOT), which has extremely high gelatinolytic activity. Using sequence analysis, the primary structure of SOT showed 77% identity with that of S. griseus trypsin (SGT). We constructed recombinants SOT and SGT using S. lividans. They indicated similar properties on optimum pH and temperature, thermostability, and substrate preference using fluorescence energy transfer combinatorial libraries. SOT greatly hydrolyzed both type I and type IV collagens, but SGT has poor ability to hydrolyze type IV collagen. Furthermore, SOT exhibits higher hydrolytic activities toward other protein substrate such as gelatin and casein than SGT. These results suggest that these two enzymes have different topological specificities in spite of their similar primary structures. We also constructed chimeras between SOT and SGT to investigate which domain is associated with differences in their substrate specificity. In comparison to substrate specificities of chimeras, we found that the N-terminal domain contributes to the determination of topological specificity.     

Non-poisson analysis of endonucleases with substrate sequence specificities

Endonucleases with substrate-sequence specificities, such as restriction enzymes, usually cleave small, defined nucleic acid molecules used in enzyme assays at one or only a few sites. The methods in common use for analysis of endonucleases are based on the Poisson distribution. A critical, but usually unstated, assumption of this distribution, however, is that there is a large number of possible reactive sites on each substrate molecule. Thus use of the Poisson distribution may introduce large errors into analysis of such assays. Here we develop a series of appropriate expressions for use in analyzing endonucleases with substrate-sequence specificities.     

Distinct substrate specificities of Arabidopsis DCL3 and DCL4

In Arabidopsis thaliana, Dicer-like 3 (DCL3) and Dicer-like 4 (DCL4) cleave long, perfect double-stranded RNAs (dsRNAs) into 24 and 21 nucleotides (nt) small interfering RNAs, respectively, which in turn function in RNA-directed DNA methylation and RNA interference, respectively. To reveal how DCL3 and DCL4 individually recognize long perfect dsRNAs as substrates, we biochemically characterized DCL3 and DCL4 and compared their enzymatic properties. DCL3 preferentially cleaves short dsRNAs with 5′ phosphorylated adenosine or uridine and a 1 nt 3′ overhang, whereas DCL4 cleaves long dsRNAs with blunt ends or with a 1 or 2 nt 3′ overhang with similar efficiency. DCL3 produces 24 nt RNA duplexes with 2 nt 3′ overhangs by the 5′ counting rule. Inorganic phosphate, NaCl and KCl enhance DCL3 activity but inhibit DCL4 activity. These results indicate that plants use DCLs with distinct catalytic profiles to ensure each dsRNA substrate generates only a specific length of siRNAs that trigger a unique siRNA-mediated response.     

Immunochemical studies on dextrans. Two distinct alpha 1 linked to 3 specificities of rabbit anti-dextran B1355

Rabbit anti-dextran B1355 sera prepared by injecting rabbits with Leuconostoc mesenteroides NRRL B1355 were separated on a Sephadex G75 column into two fractions, one binding and the other not binding to the column. Oligosaccharide inhibition of precipitation of the two fractions with dextran B1355 indicated that both fractions had alpha 1 linked to 3 specificity. However, antibodies in the non-binding fraction were shown to be directed against O-alpha-D-glucopyranosyl-(1 linked to 3)-O-alpha-D-glucopyranosyl-(1 linked to 6)-D-glucose, while those in the binding fraction were directed against O-alpha-D-glucopyranosyl-(1 linked to 6)-O-alpha-D-glucopyranosyl-(1 linked to 3)-D-glucose. These results are consistent with the proposal of Bhoopalam et al. (Proc. Soc. Exp. Biol. Med. (1979(=) 161, 430-434) that there are different epitopic groups on this dextran.     

Structural determinants of the substrate specificities of xylanases from different glycoside hydrolase families

Xylanases are of widespread importance in several food and non-food biotechnological applications. They degrade heteroxylans, a structurally heterogeneous group of plant cell wall polysaccharides, and other important components in various industrial processes. Because of the highly complex structures of heteroxylans, efficient utilization of xylanases in these processes requires an in-depth knowledge of their substrate specificity. A significant number of studies on the three-dimensional structures of xylanases from different glycoside hydrolase (GH) families in complex with the substrate provided insight into the different mechanisms and strategies by which xylanases bind and hydrolyze structurally different heteroxylans and xylo-oligosaccharides (XOS). Combined with reports on the hydrolytic activities of xylanases on decorated XOS and heteroxylans, major advances have been made in our understanding of the link between the three-dimensional structures and the substrate specificities of these enzymes. In this review, authors gave a concise overview of the structure–function relationship of xylanases from GH5, 8, 10, and 11. The structural basis for inter- and intrafamily variation in xylanase substrate specificity was discussed as are the implications for heteroxylan degradation.     

Highly active and selective endopeptidases with programmed substrate specificities

A family of engineered endopeptidases has been created that is capable of cleaving a diverse array of peptide sequences with high selectivity and catalytic efficiency (kcat/KM > 10(40 M(- 1) s(- 1)). By screening libraries with a selection-counterselection substrate method, protease variants were programmed to recognize amino acids having altered charge, size and hydrophobicity properties adjacent to the scissile bond of the substrate, including GluArg, a specificity that to our knowledge has not been observed among natural proteases. Members of this artificial protease family resulted from a relatively small number of amino acid substitutions that (at least in one case) proved to be epistatic.     

Fusarium graminearum xylanases show different functional stabilities,substrate specificities and inhibition sensitivities

When grown on arabinoxylan as the sole carbon source, the cereal phytopathogen Fusarium graminearum expresses four xylanases. Cloning and heterologous expression of the corresponding xylanase encoding genes and analysis of general biochemical properties, substrate specificities and inhibition sensitivities revealed some marked differences. XylA and XylB are glycoside hydrolase family (GH) 11 xylanases, while XylC and XylD belong to GH10. pH and temperature for optimal activity of the enzymes were between 6.0 and 7.0 and 40 °C, respectively. Interestingly, XylC displayed remarkable pH stability as it retained most of its activity even after pre-incubation at pH 1.0 and 13.0 for 120 min at room temperature. All xylanases hydrolysed xylotetraose, xylopentaose and xylohexaose, but to different extents, while only XylC and XylD hydrolysed xylotriose. The two GH10 xylanases released a higher percentage of smaller products from xylan and xylo-oligosaccharides than did their GH11 counterparts. Analysis of kinetic properties revealed that wheat arabinoxylan is the favoured XylC substrate while XylA and XylB prefer sparsely substituted oat spelt xylan. XylC and XylD were inhibited by xylanase inhibiting protein (XIP), while XylA and XylB were sensitive to Triticum aestivum xylanase inhibitor (TAXI). Because of its pH stability and preference for arabinoxylan, XylC is a valuable candidate for use in biotechnological applications.     

Two anaerobic polychlorinated biphenyl-dehalogenating enrichments that exhibit different para-dechlorination specificities.

Two anaerobic polychlorinated biphenyl (PCB)-dechlorinating enrichments with distinct substrate specificities were obtained: a 2,3,4,6-tetrachlorobiphenyl (2346-CB) para-dechlorinating enrichment derived from Aroclor 1260-contaminated Woods Pond (Lenox, Mass.) sediment and a 2,4,6-trichlorobiphenyl (246-CB) unflanked para-dechlorinating enrichment derived from PCB-free Sandy Creek Nature Center (Athens, Ga.) sediment. The enrichments have been successfully transferred to autoclaved soil slurries over 20 times by using 300 to 350 microM 2346-CB or 246-CB. Both enrichments required soil for successful transfer of dechlorination activity. The 2346-CB enrichment para dehalogenated, in the absence or presence of 2346-CB, only 4 of 25 tested para halogen-containing congeners: 234-CB, 2345-CB, 2346-CB, and 2,4,6-tribromobiphenyl (246-BrB). In the presence of 246-CB, the 246-CB enrichment para dehalogenated 23 of the 25 tested congeners. However, only three congeners (34-CB, 2346-CB, and 246-BrB) were dehalogenated in the absence of 246-CB, indicating that these specific congeners initiate dehalogenation in this enrichment culture. The addition of the 2346-CB (para)-dechlorinating enrichment did not further stimulate the 2346-CB-primed dechlorination of the Aroclor 1260 residue in Woods Pond sediment samples. Compared to the addition of the primer 246-CB or the 246-CB unflanked para-dechlorinating enrichment alone, the addition of both 246-CB (300 microM) and the 246-CB enrichment stimulated the unflanked para dechlorination of the Aroclor 1260 residue in Woods Pond sediments. These results indicate that the two enrichments contain different PCB-dechlorinating organisms, each with high substrate specificities. Furthermore, bioaugmentation with the enrichment alone did not stimulate the desired dechlorination in PCB-contaminated Woods Pond sediment.     

The three desulfoglucosinolate sulfotransferase proteins in Arabidopsis have different substrate specificities and are differentially expressed

Sulfotransferases (SOTs) catalyse the transfer of a sulfate group from 3'-phosphoadenosine 5'-phosphosulfate (PAPS) to an appropriate hydroxy group of various substrates with the parallel formation of 3'-phosphoadenosine 5'-phosphate. In Arabidopsis thaliana, 18 SOT proteins (AtSOT) have been identified. Three of them, AtSOT16, AtSOT17 and AtSOT18, catalyse the sulfation of desulfoglucosinolates. The proteins were expressed in Escherichia coli, purified by affinity chromatography and used for enzyme kinetic studies. By establishing two types of enzyme assay using both 35S-labelled and unlabelled PAPS, separation of the products by HPLC, and detection of the products by monitoring radioactivity or UV absorption, the substrate specificities of the three AtSOT proteins were determined. They show different maximum velocities with several desulfoglucosinolates as substrates and differ in their affinity for desulfobenzylglucosinolate and PAPS. The sequences encoding AtSOT18 were amplified from Arabidopsis ecotypes C24 and Col0; the two expressed proteins differ in two out of 350 amino acids. These amino-acid variations led to different substrate specificities. Exchange of one of the two amino acids in AtSOT18 from C24 to the respective amino acid in AtSOT18 from Col0 gave the C24 protein the same substrate specificity as the wild-type AtSOT18 protein from Col0. All three desulfoglucosinolate AtSOT proteins are localized in the cytoplasm, as demonstrated by transient expression of fusion constructs with the green fluorescent protein in Arabidopsis protoplasts. Northern blot analysis indicated differential expression of the three AtSOT genes in plant organs and tissues at different developmental stages and during a light/darkness cycle. High (500 microM) and low (50 microM) sulfate concentrations in the medium did not influence the levels of expression.     

Stage-specific expression of Caenorhabditis elegans ribonuclease H1 enzymes with different substrate specificities and bivalent cation requirements

Ribonuclease H1 (RNase H1) is a widespread enzyme found in a range of organisms from viruses to humans. It is capable of degrading the RNA moiety of DNA-RNA hybrids and requires a bivalent ion for activity. In contrast with most eukaryotes, which have one gene encoding RNase H1, the activity of which depends on Mg(2+) ions, Caenorhabditis elegans has four RNase H1-related genes, and one of them has an isoform produced by alternative splicing. However, little is known about the enzymatic features of the proteins encoded by these genes. To determine the differences between these enzymes, we compared the expression patterns of each RNase H1-related gene throughout the development of the nematode and the RNase H activities of their recombinant proteins. We found gene-specific expression patterns and different enzymatic features. In particular, besides the enzyme that displays the highest activity in the presence of Mg(2+) ions, C. elegans has another enzyme that shows preference for Mn(2+) ion as a cofactor. We characterized this Mn(2+)-dependent RNase H1 for the first time in eukaryotes. These results suggest that there are at least two types of RNase H1 in C. elegans depending on the developmental stage of the organism.