A new method to evaluate temperature vs. pH activity profiles for biotechnological relevant enzymes.

BACKGROUND: Glycoside hydrolases are important for various industrial and scientific applications. Determination of their temperature as well as pH optima and range is crucial to evaluate whether an enzyme is suitable for application in a biotechnological process. These basic characteristics of enzymes are generally determined by two separate measurements. However, these lead to a two-dimensional assessment of the pH range at one temperature (and vice versa) and do not allow prediction of the relative enzymatic performance at any pH/temperature combination of interest. In this work, we demonstrate a new method that is based on experimental data and visualizes the relationship among pH, temperature, and activity at a glance in a three-dimensional contour plot. RESULTS: In this study, we present a method to determine the relative activity of an enzyme at 96 different combinations of pH and temperature in parallel. For this purpose, we used a gradient PCR cycler and a citrate-phosphate-based buffer system in microtiter plates. The approach was successfully tested with various substrates and diverse assays for glycoside hydrolases. Furthermore, its applicability was demonstrated for single enzymes using the endoglucanase Cel8A from Clostridium thermocellum as well as the commercially available complex enzyme mixture Celluclast®. Thereby, we developed a fast and adaptable method to determine simultaneously both pH and temperature ranges of enzymes over a wide range of conditions, an easy transformation of the experimental data into a contour plot for visualization, and the necessary controls. With our method, the suitability of an enzyme or enzyme mixture for any chosen combination of temperature and pH can easily be assessed at a glance. CONCLUSIONS: We propose a method that offers significant advantages over commonly used methods to determine the pH and temperature ranges of enzymes. The overall relationship among pH, temperature, and activity is visualized. Our method could be applied to evaluate exactly what conditions have to be met for optimal utilization of an enzyme or enzyme mixture for both lab-scale and industrial processes. Adaptation to other enzymes, including proteases, should be possible and the method may also lead to a platform for additional applications, such as inactivation kinetics analysis.

Characterization of the arabinoxylan-degrading machinery of the thermophilic bacterium Herbinix hemicellulosilytica-Six new xylanases, three arabinofuranosidases and one xylosidase.

Herbinix hemicellulosilytica is a newly isolated, gram-positive, anaerobic bacterium with extensive hemicellulose-degrading capabilities obtained from a thermophilic biogas reactor. In order to exploit its potential as a source for new industrial arabinoxylan-degrading enzymes, six new thermophilic xylanases, four from glycoside hydrolase family 10 (GH10) and two from GH11, three arabinofuranosidases (1x GH43, 2x GH51) and one ß-xylosidase (GH43) were selected. The recombinantly produced enzymes were purified and characterized. All enzymes were active on different xylan-based polysaccharides and most of them showed temperature-vs-activity profiles with maxima around 55-65°C. HPAEC-PAD analysis of the hydrolysates of wheat arabinoxylan and of various purified xylooligosaccharides (XOS) and arabinoxylooligosaccharides (AXOS) was used to investigate their substrate and product specificities: among the GH10 xylanases, XynB showed a different product pattern when hydrolysing AXOS compared to XynA, XynC, and XynD. None of the GH11 xylanases was able to degrade any of the tested AXOS. All three arabinofuranosidases, ArfA, ArfB and ArfC, were classified as type AXH-m,d enzymes. None of the arabinofuranosidases was able to degrade the double-arabinosylated xylooligosaccharides XA2+3XX. ß-Xylosidase XylA (GH43) was able to degrade unsubstituted XOS, but showed limited activity to degrade AXOS.

[CHARACTERISTICS OF FUNGAL STRAINS PRODUCING THERMOSTABLE XYLOGLUCANASES FROM THE RUSSIAN NATIONAL COLLECTION OF INDUSTRIAL MICROORGANISMS.]

Fungal strains degrading plant biomass available from the Russian National Collection of Industrial Microorganisms (VKPM) have been screened for the xyloglucanase activity. Under conditions of submerged cultivation, the thermophilic strains Sporotrichum thermophile VKPM F-972, Myceliophthora thermophila VKPM F-244, and Sporotrichum pruinosum VKPM F-235 produced extracellular xyloglucanases with optimal activity at 60°C, pH 5.0. 88-100% of the initial enzyme activity was retained after l-h incubation at 50°C; 79-84% of the activity was retained after l-h incubation at 60°C. S. thermophile VKPM F-972, M. thermophila VKPM F-244, and S. pruinosum VKPM F-235 strains may be used as the gene sources for construction of highly active producers of the thermostable xyloglucanases.

Differences in biomass degradation between newly isolated environmental strains of Clostridium thermocellum and heterogeneity in the size of the cellulosomal scaffoldin.

Cellulolytic bacterial strains with high activity were isolated from cellulose degrading enrichment cultures derived from thermophilic biogas plants and environmental samples. The 16S rRNA gene sequences of the strains revealed >99.8% sequence identity and affiliation with the species Clostridium thermocellum. The strains differed in their ability to degrade crystalline cellulose, especially at an elevated temperature of up to 67 °C and at relatively low pH values (pH 6.5). To evaluate the influence of amino acid sequences on the discrepancies in cellulose degradation efficacy, the gene for the major cellulosomal component CelR was sequenced for all strains. The sequences were found to be almost identical (>99%). In contrast, the cellulosomal scaffoldin gene cipA showed more differences in the amino acid sequence and contained 8 or 9 cohesin modules, which indicated a different size of the cellulosome depending on the isolate. Based on MALDI-TOF MS analysis the relative abundance of important cellulosomal enzyme classes was determined. The strains with better biomass degradation properties (BC1 and NB2) had a significantly higher fraction of xylanases.

Isolation of a solventogenic Clostridium sp. strain: fermentation of glycerol to n-butanol, analysis of the bcs operon region and its potential regulatory elements.

A new solventogenic bacterium, strain GT6, was isolated from standing water sediment. 16S-rRNA gene analysis revealed that GT6 belongs to the heterogeneous Clostridium tetanomorphum group of bacteria exhibiting 99% sequence identity with C. tetanomorphum 4474(T). GT6 can utilize a wide range of carbohydrate substrates including glucose, fructose, maltose, xylose and glycerol to produce mainly n-butanol without any acetone. Additional products of GT6 metabolism were ethanol, butyric acid, acetic acid, and trace amounts of 1,3-propanediol. Medium and substrate composition, and culture conditions such as pH and temperature influenced product formation. The major fermentation product from glycerol was n-butanol with a final concentration of up to 11.5 g/L. 3% (v/v) glycerol lead to a total solvent concentration of 14 g/L within 72 h. Growth was not inhibited by glycerol concentrations as high as 15% (v/v). The solventogenesis genes crt, bcd, etfA/B and hbd composing the bcs (butyryl-CoA synthesis) operon of C. tetanomorphum GT6 were sequenced. They occur in a genomic arrangement identical to those in other solventogenic clostridia. Furthermore, the sequence of a potential regulator gene highly similar to that of the NADH-sensing Rex family of regulatory genes was found upstream of the bcs operon. Potential binding sites for Rex have been identified in the promoter region of the bcs operon of solvent producing clostridia as well as upstream of other genes involved in NADH oxidation. This indicates a fundamental role of Rex in the regulation of fermentation products in anaerobic, and especially in solventogenic bacteria.

[The family 28 carbohydrate-binding module of the thermostable endo-1,4-beta-glucanase CelD Caldicellulosiruptor bescii maximizes the enzyme's activity and binds irreversibly to amorphous cellulose].

The nucleotide sequence of a chromosome fragment of the thermophilic anaerobic bacterium Caldicellulosiruptor bescii (syn. Anaerocellum thermophilum) has been determined. The fragment contains four open reading frames with the second one of 749 aa encoding a multimodular endo-1,4-beta-glucanase CelD (85019 Da). N-terminal region of the protein includes the signal peptide and the catalytic module of glycoside hydrolase family 5 (GH5), followed by the substrate-binding module of family 28 (CBM28). The C-terminal region bears three SLH modules. The recombinant endoglucanase and its two separate modules, the catalytic one and CBM28, were produced in E. coli cells and purified to homogeneity. Analysis of the catalytic properties showed CelD to be endo-1,4-beta-glucanase whose maximum activity was exhibited on beta-glucan of barley at pH 6.2 and 70 degrees C. The enzyme was stable at 50 degrees C for 30 days. Upon removal of the C-terminal CBM28, the activity of GH5 decreased on cellulose substrates, and its thermostability was dropped. Binding of CBM28 to amorphous cellulose was almost irreversible as it could not be removed from this substrate in a range of pH 4-11, temperatures--of 0-75 degrees C, and NaCl concentration--of 0-5 M. Only 100% formamide or 1% SDS were able to remove the protein.

[The properties of four C-terminal carbohydrate-binding modules (CBM4) of laminarinase Lic16A of Clostridium thermocellum].

At the C-terminus of multimodular laminarinase Lic16A Clostridium thermocellum four carbohydrate-binding modules (CBM), belonging to family 4, were found. The isolated CBM - CBM4_1, CBM4_2, CBM4_3, CBM4_4 and the tandem CBM4_(1-4) were obtained. None of the recombinant proteins did have the affinity to soluble beta-1,3-1,4-glucans--laminarin and lihenan--the main specific substrates of Licl6A. All modules, except CBM4_4, had the ability to bind bacterial crystalline cellulose, that was atypical for the family 4 CBMs. We found that all CBMs 4 of Licl6A had affinity for xylan, chitin, beta-glucan from yeast cell wall and Avicel, while CBM4_3 and CBM4_4 had additional affinity to chitosan. The tandem CBM4_(1-4) had the highest affinity to yeast cell wall beta-glucan, avicel and pustulan. The binding constants for these substrates were about 100 times higher than that of the individual modules, suggesting a synergy in the process of absorption to these polysaccharides. This finding helps to explain the evolutionary process of CBM multiplication.

[Substrate-binding properties of family 54 module of laminarinase Lic16A of Clostridium thermocelwnum].

Endo beta-1.3-1.4-glucanase Lic16A of the moderate thermophilic anaerobe Clostridium thermocellum has a complex multimodular structure. In addition to the catalytic module it contains 8 auxiliary modules, 5 of which are substrate binding modules. The new family 54 substrate binding module CBM54 (25.2 kDa), localized at the N-terminus of the enzyme, owns a cleavage site, in its N-terminal part manifested by the appearance of a shortened module CBM54C (17.2 kDa) in vivo and in vito. CBM54C was cloned in Escherichia coli cells and purified to electrophoretic homogeneity. The binding constants of CBM54C to xylan, chitin, insoluble B-glucan of yeast cell wall and bacterial crystalline cellulose were in the same order of magnitude as for CBM54. However CBM54C, unlike CBM54, did not bind pustulan, avicel, and chitosan. Nevertheless the presence of calcium ions restored the ability of CBM54C to bind the latter three carbohydrates. CBM54 substrate binding promiscuity permits to suggest the presence of multiple binding sites, some of them calcium dependent. The collected data allow to localize Ca2+ -independent sites for avicel, pustulan an d chitosan binding inthe spontaneously split-off CBM54 N-terminal area (8 kDa). In this report the localization scheme of Ca2+ -dependent and Ca2+ -independent binding sites for various substrates has been suggested.

[Expression of the genes CelA and XylA isolated from a fragment of metagenomic DNA in Escherichia coli].

The glycosyl hydrolase genes cel5A and xyl3A previously isolated by ourselves within a fragment of DNA from the methagenomic library of cow rumen microflora DNA were sub-cloned and expressed in E. coli. The recombinant proteins Cel5A and Xyl3A were purified and characterized. Cellulase Cel5A belongs to the Family 5 glycosyl hydrolases and is a one-module 38.2 kDa enzyme that hydrolyses the 1,4-glycoside bonds of soluble cellulose substrates and amorphous cellulose, showing its maximal activity (31200 u/mg) on lichenan, a soluble substrate with mixed (beta-1,3-1,4) bonds. The end product of the amorphous cellulose hydrolysis is cellobiose. Cel5A is inactive toward the crystal forms of cellulose. Cel5A is an endoglucanase capable of exohydrolysis. The molecular mass of beta-xylosidase Xyl3A belonging to the Family 3 glycosyl hydrolases is 83.7 kDa. The enzyme is active only on xylooligosaccharides, with the maximal activity shown on xylobiose, the end product of the reaction being xylose. No activity on xylane was hitherto observed. Recombinant Cel5A and Xyl3A are stable over a wide range of pH and temperatures, their maximal activity being observed at pH 6.5 and at 55 degrees C.

[Cloning and characterization of a large metagenomic DNA fragment containing glycosyl-hydrolase genes].

The problem of search for and characterization of enzymes synthesized by non-cultivated microorganisms is presently being settled by creating metagenomic libraries. A 6000-clone library with the average size of its inserts amounting to 15 bp has been constructed on the basis of total DNA isolated from cow rumen microorganisms. As the result of the screening of the library on plates with different substrates, a clone was selected that efficiently hydrolyzed lichenan and carboxymethylcellulose. The clone contained the recombinant plasmid pBlue-13 bearing a 12071 bp.-long metagenomic fragment carrying ten open reading frames, two of them being identified as glycosyl hydrolase genes. No homology of the metagenomic DNA with any known microorganism genomes was revealed. The amino acid sequence, deduced on the basis of frame 4 and denoted by Xyl3A, bears resemblance with beta-xylosidases of glycosyl hydrolase Family 3. Frame 6 encodes polypeptide Cel5A homologous to cellulases of glycosyl hydrolase Family 5. The amino acid sequences deduced on the basis of seven out of ten open reading frames were homologous to proteins of microorganisms belonging to the Bacteroides sp. family, the bacteria inhabiting mammalian intestines.

[Extracellular glycosyl hydrolase activity of the clostridia producing acetone, butanol, and ethanol].

Production of acetone, butanol, ethanol, acetic acid, and butyric acid by three strains of anaerobic bacteria, which we identified as Clostridium acetobutylicum, was studied. The yield of acetone and alcohols in 6% flour medium amounted to 12.7-15 g/l with butanol constituting 51.0-55.6%. Activities of these strains towards xylan, beta-glucan, carboxymethylcellulose, and crystalline and amorphous celluloses were studied. C. acertobutylicum 6, C. acetoburylicum 7, and C. acertobutylicum VKPM B-4786 produced larger amounts of acetone and alcohols and displayed higher cellulase and hemicellulase activities than the type strain C. acetobutylicum ATCC 824. It was demonstrated that starch in the medium could be partially substituted with plant biomass.

Bacterial acetone and butanol production by industrial fermentation in the Soviet Union: use of hydrolyzed agricultural waste for biorefinery.

Clostridial acetone-butanol fermentation from renewable carbohydrates used to be the largest biotechnological process second only to yeast ethanol fermentation and the largest process ever run under sterile conditions. With the rising prices for mineral oil, it has now the economical and technological potential to replace petrochemistry for the production of fuels from renewable resources. Various methods for using non-food biomass such as cellulose and hemicellulose in agricultural products and wastes have been developed at laboratory scale. To our knowledge, the AB plants in Russia were the only full-scale industrial plants which used hydrolyzates of lignocellosic waste for butanol fermentation. These plants were further developed into the 1980s, and the process was finally run in a continual mode different from plants in Western countries. A biorefinery concept for the use of all by-products has been elaborated and was partially put into practice. The experience gained in the Soviet Union forms a promising basis for the development of modern large-scale processes to replace a considerable fraction of the current chemical production of fuel for our future needs on a sustainable basis.

[Thermoanaerobacter ethanolicus gene cluster containing the alpha- and beta-galactosidases genes melA and lacA, and properties of recombinant lacA].

The nucleotide sequence of a 4936 bp Thermoanaerobacter ethanolicus genomic DNA fragment containing the thermostable beta-galactosidase gene lacA and two incomplete open reading frames has been determined. The product of the first frame is highly homologous to alpha-galactosidases (melibiases), the product of the third frame is homologous to the alpha-D-mannosidases. The terminal area of the lacA, immediately following the stop-codon, harbors presumably a transcription termination site. Based on the location of the putative alpha-galactosidase gene melA and of the beta-galactosidase gene lacA on the T. ethanolicus chromosome, their combined transcription could be presumed. The calculated molecular mass of LacA is 86 kDa. LacA belongs to GH family 2 (GH2). Maximal activity of the purified recombinant enzyme was observed between pH values of 5.7 and 6.0 and temperatures of 75-80 degrees C. The highest activity, 480 units mg(-1), was found on lactose (Km 30 mM), the activities on pNPhGal and oNPhGal amounting to 330 and 420 units mg(-1), respectively. Immobilization on aldehyde silochrome increases the thermostability of the enzyme and keeps its high activity.

[Thermotoga neopolitina gene cluster, participating in degradation of starch and maltodextrins: expression of aglB and aglA gene in Escherichia coli, properties of recombinant enzymes]. / Klaster genov Thermotoga neapolitana, uchastvuiushchikh v degradatsii krakhmala i mal'todekstrinov: éksptressiia genov aglB i aglA v Escherichia coli, svoistva rekombinantykh fermentov.

The aglB and aglA genes from the starch/maltodextrin utilization gene cluster of Thermotoga neapolitana were subcloned into pQE vectors for expression in Escherichia coli. The recombinant proteins AglB and AglA were purified to homogeneity and characterized. Both enzymes are hyperthermostable, the highest activity was observed at 85 degrees C. AglB is an oligomer of identical 55-kDa subunits capable of aggregation. This protein hydrolyses cyclodextrins and linear maltodextrins to glucose and maltose by liberating glucose from the reducing end of the molecules, and it is a cyclodextrinase with alpha-glucosidase activity. The pseudo-tetrasaccharide acarbose, a potent alpha-amylase and alpha-glucosidase inhibitor, does not inhibit AglB but, on the contrary, acarbose is degraded quantitatively by AglB. Recombinant AglB is activated in the presence of CaCl2, KCl, and EDTA, as well as after heating of the enzyme. AglA is a dimer of two identical 54-kDa subunits, and it hydrolyses the alpha-glycoside bonds of disaccharides and short maltooligosaccharides, acting on the substrate from the non-reducing end of the chain. It is a cofactor-dependent alpha-glucosidase with a wide action range, hydrolysing both oligoglucosides and galactosides with alpha-link. Thereby, the enzyme is not specific with respect to the configuration at the C4 position of its substrate. For the enzyme to be active, the presence of NAD+, DTT, and Mn2+ is required. Enzymes AglB and AglA supplement one another in substrate specificity and ensure complete hydrolysis to glucose for the intermediate products of starch degradation.

[Thermotoga neapolitana gene clusters participating in degradation of starch and maltodextins: molecular structure of the locus]. / Klaster genov Thermotoga neapolitana, uchastvuiushchikh v degradatsii krakhmala i mal'todekstrinov: molekuliarnaia struktura lokusa.

A 5451-bp genome fragment of the hyperthermophilic anaerobic eubacterium Thermotoga neapolitana has been cloned and sequenced. The fragment contains one truncated and three complete open reading frames highly homologous to the starch/maltodextrin utilization gene cluster from Thermotoga maritima whose genome sequence is known. The incomplete product of the first frame is highly homologous to MalG, the E. coli protein of starch and maltodextrin transport. The product of the second frame, AglB, is highly homologous to cyclomaltodextrinase with the alpha-glucosidase activity TMG belonging to family 13 of glycosyl hydrolases (GH13). The product of the third frame, AglA, is homologous to the Thermotoga maritima cofactor-dependent alpha-glucosidase from the GH4 family. The two enzymes form a separate branch on the phylogenetic tree of the family. The AglA and AglB proteins supplement each other in substrate specificity and can ensure complete hydrolysis to glucose of cyclic and linear maltodextrins, the intermediate products of starch degradation. The product of the fourth reading frame has sequence similarity with the riboflavin-specific deaminase RibD from T. maritima. The homologous locus of this bacterium, between the aglA and ribD genes, has five open reading frames missing in T. neapolitana. The nucleotide sequences of two frames are homologous to transposase genes. The deletion size is 2.9 kb.

The thermostable alpha-L-rhamnosidase RamA of Clostridium stercorarium: biochemical characterization and primary structure of a bacterial alpha-L-rhamnoside hydrolase, a new type of inverting glycoside hydrolase.

An alpha-L-rhamnosidase clone was isolated from a genomic library of the thermophilic anaerobic bacterium Clostridium stercorarium and its primary structure was determined. The recombinant gene product, RamA, was expressed in Escherichia coli, purified to homogeneity and characterized. It is a dimer of two identical subunits with a monomeric molecular mass of 95 kDa in SDS polyacrylamide gel electrophoresis. At pH 7.5 it is optimally active at 60 degrees C and insensitive to moderate concentrations of Triton X100, ethanol and EDTA. It hydrolysed p-nitrophenyl-alpha-L-rhamnopyranoside, naringin and hesperidin with a specific activity of 82, 1.5 and 0.46 U mg-1 respectively. Hydrolysis occurs by inversion of the anomeric configuration as detected using 1H-NMR, indicating a single displacement mechanism. Naringin was hydrolysed to rhamnose and prunin, which could further be degraded by incubation with a thermostable beta-glucosidase. The secondary structure of RamA consists of 27% alpha-helices and 50% beta-sheets, as detected by circular dichroism. The primary structure of the ramA gene has no similarity to other glycoside hydrolase sequences and possibly is the first member of a new enzyme family.

Duplicated Clostridium thermocellum cellobiohydrolase gene encoding cellulosomal subunits S3 and S5.

The upstream region of the cellobiohydrolase gene cbhA of Clostridium thermocellum F7 was sequenced. It was found that this region contains the previously sequenced gene celK encoding an enzyme closely related to CbhA (cellulosomal subunit S3). The presence of a putative transcription terminator in the 524-bp intergenic region indicates that celK and cbhA are not cotranscribed as an operon. Sequence comparison between the two cellobiohydrolases revealed high sequence conservation in the catalytic domain and in the N-terminal cellulose-binding domain (CBD) homologous to CBD family IV, which binds specifically to amorphous cellulose and soluble cellooligosaccharides. In contrast to CbhA, CelK lacks a family III CBD capable of binding to crystalline cellulose. By partial amino acid sequence determination CelK was shown to be identical to cellulosomal subunit S5. CelK and CbhA were found to be members of subfamily E1 of cellulase family E (glycosylhydrolase family 9). Sequence comparison of catalytic domains of family E1 cellulases with C. thermocellum CelD, a family E1 endoglucanase of known three-dimensional structure, revealed a significant variation in the lengths of substrate-binding loops connecting the helices of the (alpha/alpha)6 barrel fold. The extended loops of CelK and CbhA might form an active-site tunnel, as found in the catalytic domains of fungal cellobiohydrolases.

Organization of the chromosomal region containing the genes lexA and topA in Thermotoga neapolitana. Primary structure of LexA reveals phylogenetic relevance.

The chromosomal region of Thermotoga neapolitana surrounding the gene lexA (4283 bp) was sequenced. In addition to the topoisomerase gene top2A it contained five open reading frames. A part of the cloned region showed high sequence homology with a previously published sequence of Th. maritima and indicated an identical arrangement of genes in both microorganisms. Structural analysis of the LexA protein showed significant, but relatively low overall homology with LexA proteins of other bacteria, especially in the DNA binding region. However, key amino acids for processing and secondary structure elements like the helix-turn-helix motif are well conserved. Sequence alignment analysis of the whole protein and the DNA-binding sites of all known LexA sequences uncovers groups of similarity reminding the phylogenetic tree of the Bacteria. A consensus sequence with the SOS- or Cheo-box upstream of the lexA gene of Th. maritima and Th. neapolitana was absent. Together with the phylogenetic distance of the Thermotogales from other bacteria this suggests the presence of a new operator target sequence specific for the Thermotogales, in analogy to the SOS-box for the gamma-group Proteobacteria and the Cheo-box for low- and high-GC Gram-positive bacteria.

Nucleotide sequence of arfB of Clostridium stercorarium, and prediction of catalytic residues of alpha-L-arabinofuranosidases based on local similarity with several families of glycosyl hydrolases.

The nucleotide sequence of the alpha-L-arabinofuranosidase gene arfB from Clostridium stercorarium was determined. The deduced protein has a molecular mass of 56.2 kDa with an amino terminus identical to the N-terminal sequence of the purified mature enzyme from C. stercorarium. Its sequence is homologous to arabinofuranosidases of glycosyl hydrolase family 51. Sequence alignment and cluster analysis reveal three new members of glycosyl hydrolase family 51, allowing for the definition of highly conserved regions. Two of these regions are remarkably similar to the most conserved regions within several other families of glycosyl hydrolases, which have in common a (beta/alpha)8-barrel as the core super-secondary structure, and allow to predict the acid/base catalyst and the nucleophile of the active site.