Proteolysis of <Emphasis Type="Italic">α</Emphasis>-amylase from <Emphasis Type="Italic">Saccharomycopsis fibuligera</Emphasis>: characterization of digestion products

α-Amylase from Saccharomycopsis fibuligera R-64 was successfully purified by butyl Toyopearl hydrophobic interaction chromatography, followed by Sephadex G-25 size exclusion and DEAE Toyopearl anion exchange chromatography. The enzyme has a molecular mass of 54 kDa, as judged by SDS PAGE analysis. Upon tryptic digestion, two major fragments with relative molecular masses of 39 kDa and 10 kDa, which resemble the A/B and C-terminal domains in the homologous Taka-amylase, were obtained and were successfully separated with the Sephadex G-50 size exclusion column. The 39-kDa fragment demonstrated a similar amylolytic activity to that of the undigested enzyme. However, it was found that the K _m value of the 39-kDa fragment was about two-times higher than that of the undigested enzyme. Moreover, thermostability studies showed a lower half-life time for the 39-kDa fragment. These findings suggest that the 39-kDa fragment is the catalytic domain, while the 10-kDa fragment is the C-terminal one, which plays a role in thermostability and starch binding. Although the undigested enzyme is able to act on raw starches at room temperature, with maize starches as the best substrate, neither the undigested enzyme nor the fragments adsorb the tested raw starches. These results propose Saccharomycopsis fibuligera α-amylase as a raw starch-digesting but not adsorbing amylase, with a similar domain organization to that of Taka-amylase A.     

Amylase action pattern on starch polymers

Several decades ago, the first reports on differences in action pattern between amylases from different sources indicated that the starch polymers are not degraded in a completely random manner. We here give an overview of different action patterns of amylases on amylose and amylopectin, focusing on the so-called multiple attack action of the enzymes. Nowadays, the multiple attack action is generally an accepted concept to explain the differences in amylase action pattern. However, the pancreatic α-amylase remains one of the few enzymes known with a considerable level of multiple attack action. Despite some recent studies, the molecular mechanism of the multiple attack action is still largely unclear. Probably, the degree to which the active site architecture and binding properties allow both the reorganization (sliding) of the substrate in the active site and the stabilisation of the productive enzyme/substrate complex mainly determine the multiple attack action of amylases.     

-Amino acid aminotransferase: fragmentation at a flexible loop is an efficient method to generate mutant enzymes with new substrate specificities and elevated activities

-Amino acid aminotransferase ( -AAT) (EC 2.6.1.21) catalyzes the interconversion between various -amino acids and α-keto acids. A subunit of the homodimeric enzyme from a thermophile, Bacillus sp. YM-1, consists of two distinct structural domains connected by one loop. We previously constructed an active fragmentary enzyme whose backbone was cut at the interdomain loop [J. Biochem. 124 (1998) 905]. In this work, we constructed 13 fragmentary -amino acid aminotransferase genes by inserting a termination codon, an SD sequence, and an initiation codon into the specific positions of the gene corresponding to various loop regions and expressed in Escherichia coli cells. We have obtained six genes producing active fragmentary enzymes, one producing an inactive fragmentary enzyme, four producing only large peptide fragment, and another two that gave no products. The six active fragmentary enzymes purified to near-homogeneity showed various substrate specificities and thermostabilities distinct from each other and also from the wild-type enzyme: two exhibited higher catalytic activity towards -alanine, the most efficient substrate, than the wild-type enzyme. These results suggest that cleavage at a loop region is an efficient method for the alteration of enzyme properties.     

Interchange of functional domains switches enzyme specificity: construction of a chimeric pneumococcal-clostridial cell wall lytic enzyme

Bacterial autolysins are endogenous enzymes that specifically cleave covalent bonds in the cell wall. These enzymes show both substrate and bond specificities. The former is related to their interaction with the insoluble substrate whereas the latter determine their site of action. The bond specificity allows their classification as muramidases (lysozymes), glucosaminldases, amidases, and endopeptidases. To demonstrate that the autolysin (LYC muramidase) of Clostridium acetobutylicum ATCC824 presents a domainal organization, a chimeric gene (clc) containing the regions coding for the catalytic domain of the LYC muramidase and the choline-binding domain of the pneumococcal phage CPL1 muramidase has been constructed by in vitro recombination of the corresponding gene fragments. This chimeric construction codes for a choline-binding protein (CLC) that has been purified using affinity chromatography on DEAE-cellulose. Several biochemical tests demonstrate that this rearrangement of domains has generated an enzyme with a choline-dependent muramidase activity on pneumococcal cell walls. Since the parental LYC muramidase was cholineindependent and unable to degrade pneumococcal cell walls, the formation of this active chimeric enzyme by exchanging protein domains between two enzymes that specifically hydrolyse cell walls of bacteria belonging to different genera shows that a switch on substrate specificity has been achieved. The chimeric CLC muramidase behaved as an autolytic enzyme when it was adsorbed onto a live autolysin-defective mutant of Streptococcus pneumoniae. The construction described here provides experimental support for the theory of modular evolution which assumes that novel proteins have evolved by the assembly of preexisting polypeptide units.     

Solving the problem of how to eat something as big as yourself: Diverse bacterial strategies for degrading polysaccharides

Polysaccharide digestion by bacteria is an important activity in many ecosystems, and a number of bacterial genera can perform this function. Although many papers have been published about the properties of isolated polysaccharide-degrading enzymes, relatively little is known about how intact bacteria degrade polysaccharides. This review summarizes recent findings suggesting that there are at least three different strategies. the most familiar one is the excretion of extracellular polysaccharidases, which diffuse to and degrade nearby polysaccharides. An example of this type of strategy is provided by the plant pathogen,Erwinia spp. A second strategy is to have the enzyme exposed to the extracellular medium but attached to the surface of the cell. Examples of this strategy are provided by the pullulanase system ofKlebsiella oxytoca and the cellulosomes ofClostridium thermocellum. A strategy that could be seen as a combination of the extracellular enzyme strategy and the surface organelle strategy is provided byVibrio harveyi, which attaches to its substrate, chitin, via proteins that appear to be specialized for attachment and produces extracellular enzymes that attack the chitin. A third strategy is to import the polysaccharide, as appears to be done byBacteroides spp. In this instance, the polysaccharide is bound to an outer membrane receptor, then passes into the periplasm where the degradative enzymes are located. The ecological advantages and disadvantages of these systems are discussed, and areas where further research is needed are defined.     

Crius: A novel fragment‐based algorithm of de novo substrate prediction for enzymes

The study of enzyme substrate specificity is vital for developing potential applications of enzymes. However, the routine experimental procedures require lot of resources in the discovery of novel substrates. This article reports an in silico structure‐based algorithm called Crius, which predicts substrates for enzyme. The results of this fragment‐based algorithm show good agreements between the simulated and experimental substrate specificities, using a lipase from Candida antarctica (CALB), a nitrilase from Cyanobacterium syechocystis sp. PCC6803 (Nit6803), and an aldo‐keto reductase from Gluconobacter oxydans (Gox0644). This opens new prospects of developing computer algorithms that can effectively predict substrates for an enzyme.     

Effect of hydrolytic and oxidative enzymes produced by solid-state fermentation on greige linen fabric

Solid state fermentation (SSF) was applied for production of fungal enzyme preparations from Phanerochaete chrysosporium, Aspergillus oryzae, Aspergillus giganteus and Trichoderma virens using cotton seed-coat fragment waste as a carbon source and enzyme inducer. Lignin-holocellulose matrix of cotton seed coat fragment proved to be effective in inducing production of ligninolytic, cellulolytic and xylanolytic enzymes in solid-state fermentation. The effect of the enzymes produced by SSF on greige linen fabric is discussed and evaluated. In the first experiment the hydrolytic and accompanying oxidative enzymes in the buffer extract of the whole SSF cultures were used for fabric treatment. In the second trial, the enzymes produced in situ (whole SSF material—mixture of fungal biomass, residual substrate and enzymes) were used for the treatment. Weight loss, reducing sugar liberation and removal of colouring materials were measured. The results showed that at equal enzyme charges the intact SSF materials were more efficient than the enzyme extracts. Of the six strains evaluated, Ph. chrysosporium VKM F-1767 was the most effective in removing colouring matters from greige linen fabric.     

Vicia faba chloroplast DNA has only one set of ribosomal RNA genes as shown by partial denaturation mapping and R-loop analysis

Summary Broad-bean (Vicia faba) chloroplast DNA (cpDNA) was isolated and characterized. The intact DNA is circular and has a molecular weight of 79.8x 10⁶ dalton. Electron microscopic analysis of self-annealed intact single-strand circles show that it does not have a large double-stranded inverse repeat as seen in spinach chloroplast DNA. Only one ribosomal RNA gene (one set of 16S and 23S rRNA sequences) was found in preparations of R-loops between the Vicia rRNA and cpDNA circles. A restriction enzyme map for SalI and KpnI was derived by comparing the partial denaturation pattern of the fragments with the pattern of the intact circle. The map was confirmed by gel analysis. The ribosomal RNA gene was localized on the SalI fragment 3b by R-loop analysis. SalI fragment 1a although it contains a G-C rich region did not form R-loops with rRNA. Partial denaturation patterns of spinach cpDNA circles and BglI fragments were determined and from this the position of the fragments mapped. This confirmed the reliability of these methods for the arrangement of restriction enzyme fragments along circular molecules. The structures of the two cpDNAs were compared.     

Aspects of energy-yielding metabolism in the aphid,Schizaphis graminum,and its endosymbiont: Detection of gene fragments potentially coding for the ATP synthaseβ-subunit and glyceraldehyde-3-phosphate dehydrogenase

Specialized cells within the aphid,Schizaphis graminum, contain intracellular, vesicleenclosed eubacterial endosymbionts (Buchnera aphidicola). Using oligonucleotide probes derived from conserved sequences of the ATP synthase -subunit and glyceraldehyde-3-phosphate dehydrogenase, and the polymerase chain reaction (PCR), we have amplified, cloned, and sequenced three DNA fragments. Amino acid sequence similarity indicated that two of these fragments corresponded to endosymbiont and host genes potentially coding for the -subunit of ATP synthase. The host gene fragment contained two putative introns. The third DNA fragment corresponded to a portion of a gene coding for a glyceraldehyde-3-phosphate dehydrogenase that was highly related to one of the enzymes fromEscherichia coli (GapA). These results indicate thatB. aphidicola may have an ATP synthase and consequently could synthesize ATP from a proton motive force generated within the intracellular vesicles of host cells containing the endosymbionts. The detection of a gene fragment coding for a protein similar to glyceraldehyde-3-phosphate dehydrogenase suggests the presence of this glycolytic enzyme in the endosymbiont and its involvement in energy-yielding metabolism.     

Cloning the dapA dapB cluster of the lysine-secreting bacterium Corynebacterium glutamicum

Summary The genes encoding the two successive enzymes of the lysine biosynthetic pathway, dihydrodipicolinate synthase (dapA) and dihydrodipicolinate reductase (dapB), have been isolated from Corynebacterium glutamicum by heterologous complementation of Escherichia coli mutants. The two genes reside on a single 3.8-kb chromosomal fragment. They were subcloned as non overlapping fragments on an E. coli/C. glutamicum shuttle vector and introduced into C. glutamicum. This resulted in overexpression of both enzyme activities which was irrespective of the orientation of the inserts and comparable to that obtained with the large 3.8-kb fragment. Therefore, both genes are located in close proximity to each other on the C. glutamicum chromosome, but are apparently independently transcribed.     

Towards new enzymes for biofuels: lessons from chitinase research

Enzymatic conversion of structural polysaccharides in plant biomass is a key issue in the development of second generation ('lignocellulosic') bioethanol. The efficiency of this process depends in part on the ability of enzymes to disrupt crystalline polysaccharides, thus gaining access to single polymer chains. Recently, new insights into how enzymes accomplish this have been obtained from studies on enzymatic conversion of chitin. First, chitinolytic microorganisms were shown to produce non-hydrolytic accessory proteins that increase enzyme efficiency. Second, it was shown that a processive mechanism, which is generally considered favorable because it improves substrate accessibility, might in fact slow down enzymes. These findings suggest new focal points for the development of enzyme technology for depolymerizing recalcitrant polysaccharide biomass. Improving substrate accessibility should be a key issue because this might reduce the need for using processive enzymes, which are intrinsically slow and abundantly present in current commercial enzyme preparations for biomass conversion. Furthermore, carefully selected substrate-disrupting accessory proteins or domains might provide novel tools to improve substrate accessibility and thus contribute to more efficient enzymatic processes.     

Excision Repair of 2,5-Diaziridinyl-1,4-Benzoquinone (DZQ)-DNA Adduct by Bacterial and Mammalian 3-Methyladenine-DNA Glycosylases

The mechanisms of anticancer activity of 2,5-diaziridinyl-1,4-benzoquinone (DZQ) are believed to involve the alkylation of guanine and adenine bases. In this study, it has been investigated whether bacterial and mammalian 3-methyladenine-DNA glycosylases are able to excise DZQ-DNA adduct with a differential substrate specificity. DZQ-induced DNA adduct was first formed in the radiolabeled restriction enzyme DNA fragment, and excision of the DNA adduct was analyzed following treatment with homogeneous 3-methyladenine-DNA glycosylase from E. coli, rat, and human, respectively. Abasic sites generated by DNA glycosylases were cleaved by the associated lyase activity of the E. coli formami-dopyrimidine-DNA glycosylase. Resolution of cleaved DNA on a sequencing gel with Maxam-Gilbert sequencing reactions showed that DZQ-induced adenine and guanine adducts were very good substrates for bacterial and mammalian enzymes. The E. coli enzyme excises DZQ-induced adenine and guanine adducts with similar efficiency. The rat and human enzymes, however, excise the adenine adduct more efficiently than the guanine adduct. These results suggest that the 3-methyladenine-DNA glycosylases from different origins have differential substrate specificity to release DZQ-DNA lesions. The use of 3-methyladenine-DNA glycosylase incision analysis could possibly be applied to quantify a variety of DNA adducts at the nucleotide level.     

Analysis of DNA from a Beta procumbens chromosome fragment in sugar beet carrying a gene for nematode resistance

Summary We have begun to apply techniques for the preparation and anaylsis of large DNA segments from sugar beet (Beta vulgaris) addition lines carrying a mitotically stable chromosome fragment from B. procumbens that confers monogenic resistance to the nematode Heterodera schachtii, with a view towards isolating the resistance gene. DNA probes specific for this chromosome fragment were selected, and various methods for cloning genome-specific fragments, including probes from megabase DNA separated in pulsed-field slab gels, are compared. Probes that display high homology to B. procumbens have been used for hybridization of a representative genomic library and for initial step in mapping the chromosome fragment via pulsed-field gel electrophoresis after restriction with infrequently cutting enzymes. Our data indicate that DNA molecules from the entire chomosome fragment can be separated from protoplast DNA lysates.     

How is it that microsatellites and random oligonucleotides uncover DNA fingerprint patterns?

Minisatellites, microsatellites, and short random oligonucleotides all uncover highly polymorphic DNA fingerprint patterns in Southern analysis of genomic DNA that has been digested with a restriction enzyme having a 4-bp specificity. The polymorphic nature of the fragments is attributed to tandem repeat number variation of embedded minisatellite sequences. This explains why DNA fingerprint fragments are uncovered by minisatellite probes, but does not explain how it is that they are also uncovered by microsatellite and random oligonucleotide probes. To clarify this phenomenon, we sequenced a large bovine genomic BamHI restriction fragment hybridizing to the Jeffreys 33.6 minisatellite probe and consisting of small and large Sau3A-resistant subfragments. The large Sau3A subfragment was found to have a complex architecture, consisting of two different minisatellites, flanked and separated by stretches of unique DNA. The three unique sequences were characterized by sequence simplicity, that is, a higher than chance occurrence of tandem or dispersed repetition of simple sequence motifs. This complex repetitive structure explains the absence of Sau3A restriction sites in the large Sau3A subfragment, yet provides this subfragment with the ability to hybridize to a variety of probe sequences. It is proposed that a large class of interspered tracts sharing this complex yet simplified sequence structure is found in the genome. Each such tract would have a broad ability to hybridize to a variety of probes, yet would exhibit a dearth of restriction sites. For each restriction enzyme having 4-bp specificity, a subclass of such tracts, completely lacking the corresponding restriction sites, will be present. On digestion with the given restriction enzyme, each such tract would form a large fragment. The largest fragments would be those that contained one or more long minisatellite tracts. Some of these large fragments would be highly polymorphic by virtue of the included minisatellite sequences; by virtue of their complex structure, all would be capable of hybridizing to a wide variety of probes, uncovering a DNA fingerprint pattern.     

Virtual fragment screening for novel inhibitors of 6-phosphogluconate dehydrogenase

The enzyme 6-phosphogluconate dehydrogenase is a potential drug target for the parasitic protozoan Trypanosoma brucei, the causative organism of human African trypanosomiasis. This enzyme has a polar active site to accommodate the phosphate, hydroxyl and carboxylate groups of the substrate, 6-phosphogluconate. A virtual fragment screen was undertaken of the enzyme to discover starting points for the development of inhibitors which are likely to have appropriate physicochemical properties for an orally bioavailable compound. A virtual screening library was developed, consisting of compounds with functional groups that could mimic the phosphate group of the substrate, but which have a higher pK_a. Following docking, hits were clustered and appropriate compounds purchased and assayed against the enzyme. Three fragments were identified that had IC₅₀ values in the low micromolar range and good ligand efficiencies. Based on these initial hits, analogues were procured and further active compounds were identified. Some of the fragments identified represent potential starting points for a medicinal chemistry programme to develop potent drug-like inhibitors of the enzyme.     

Applications of PCR-RFLPs for differentiating two freshwater sponges: <Emphasis Type="Italic">Ephydatia </Emphasis><Emphasis Type="Italic">fluviatilis</Emphasis> and <Emphasis Type="Italic">Ephydatia mülleri</Emphasis>

The two freshwater sponges Ephydatia fluviatilis and Ephydatia mülleri belong to the widespread Spongillidae family. Their morphological tracts are very similar and can be distinguished mainly on the basis of their gemmuloscleres. However, when gemmules are absent it is essential to have an unambiguous species attribution for a population genetic study based on fresh tissues and historical collections. This article reports a simple Polymerase Chain Reaction-Restriction Fragment Length Polymorphism (PCR-RFLP) analysis, applied to DNA extracted from both gemmules and fresh tissues in order to discriminate between the two congeneric E. fluviatilis and E. mülleri. Such a biomolecular method is based on the discriminative enzymes’ digestion of each of the three amplified fragments 5.8S-ITS2-28S, D3 domain of the 28S subunit and COI. Two restriction enzymes were tested for a 620–642 bp fragment of 5.8S-ITS2-28S and for a 342 bp fragment of the D3 domain of the 28S, one restriction enzyme was tested for a 681 bp fragment codifying for COI. Obtained digestion patterns were diagnostic for each of the two species, providing a relatively simple, fast and cheap method for species attribution compared to sequencing. Handling editor: C. Sturmbauer     

Localization of flagellin genes on the physical map of Methanococcus voltae

Methanococcus voltae DNA, digested individually with the restriction enzymes ApaI, SacII, BamHI, or EagI, was resolved by pulsed-field gel electrophoresis reproducing the previously published digestion patterns. Hybridization of a flagellin gene-specific probe to such gels dried down (unblots) resulted in the identification of one band per enzyme harboring the flagellin genes. These bands all overlapped, revealing that an approximately 15-kb BamHI/EagI DNA fragment should harbor the flagellin genes. Double digestion with BamHI and EagI resulted in the resolution of two bands in the 15-kb region of the gel. Separation of these two fragments prior to blotting and probing with a flagellar gene-specific probe revealed that one of these fragments possessed the flagellar sequences. The presence of an EagI restriction site in flaB3 localized the flagellin genes precisely at the junction of EagI fragments Ea2 and Ea5 at approximately the 1800-kb position of the physical map.     

The Source for the Difference Between Sulfhydryl and Hydroxyl Anions in Their Nucleophilic Addition Reaction to a Carbonyl Group: A DFT Approach.

Ab initio calculations show that sulfhydryl anion has a significantly lower potential than the hydroxide anion for stabilizing the products of its attack on carbonyl moieties - the tetrahedral complexes (TC). In this paper we analyze the factors that contribute to this phenomenon. Quantum mechanical MO ab initio calculations were used for studies of two reaction series, one for the attack of hydroxyl and one for the attack of sulfhydryl anion on different carbonyl compounds and their analogs. All of the anionic TCs formed by HS^- are characterized by higher charge transfer, but are significantly less stable than the relevant TC of HO^-. To explain the phenomenon we used a simple qualitative model based on Density Functional Theory (DFT). The crucial role of the occupied valence MOs is demonstrated in the process of electronegativity equalization between the donor and acceptor fragments in the final TC product. The sulfhydryl anion has significantly lower potential to stabilize TC products in comparison with the hydroxide anion because of the larger extent of electron back-donation from the electrophiles HOMO_A to the nucleophiles LUMO_D. This electron back-donation thus reduces the stability of the anionic TC in the case of HS^- and may account for the calculational results. Applications of this work to enzyme reactions help in understanding the differences in mechanisms of serine and cysteine proteases and may be used to guide the design of inhibitors for these enzymes. In perspective, the back-donation phenomenon discussed here may be applied to the study of electron transfer processes involving oxidation-reduction enzymes.     

Biopreparation of cotton fabric with enzymes produced by solid-state fermentation

Fungal enzyme preparations from Phanerochaete chrysosporium, Aspergillus oryzae, Aspergillus giganteus and Trichoderma virens, produced by solid-state fermentation (SSF) on cotton seed-coat fragment waste as substrate and enzyme inducer were investigated in biopreparation of cotton fabric. Cotton seed-coat fragment is rich in lignin, cellulose and hemicelluloses, therefore enzyme complexes produced by target fungi on such a substrate can be used effectively to degrade impurities in cotton fabrics during biopreparation. Activities of extracellular hydrolytic and ligninolytic enzymes were determined from the SSF extract materials. The potential of the hydrolytic and accompanying oxidative enzymes in the whole SSF cultures was exploited in degradation of seed-coat fragments and other coloring materials of greige cotton fabric. Enzyme assays indicated that many extracellular enzymes have been produced under these conditions including both hydrolytic and oxidative enzymes. A. oryzae NRRL 3485 produced significantly higher amounts of both hydrolytic and oxidative enzymes than other tested fungi. Best results in removal of seed-coat fragments from cotton fabric were obtained by P. chrysosporium NCAIM (=ATCC 34541), P. chrysosporium VKM F-1767 and A. oryzae NRRL 3485 SSF enzyme complexes.     

The phosphoenolpyruvate-dependent carbohydrate: Phosphotransferase system enzymes II as chemoreceptors in chemotaxis of Escherichia coli K12

Summary In Escherichia coli K12, eight substrate-specific, membrane-bound enzymes II of the PEP-dependent carbohydrate: phosphotransferase system (PTS), specific for hexoses, hexosamines and hexitols, have been characterised in a series of isogenic and constitutive strains. In such mutants, lacking all but one enzyme II, the transport and vectorial phosphorylation activities as well as the chemotactical response in capillary tube assays have been compared. According to the data obtained, all enzymes II not only are directly involved in the transport and vectorial phosphorylation of their substrates, but they have also a primary role as the chemoreceptors for these substrates: (1) Metabolism of the attractant beyond the phosphorylation step is not a pre-requisite to eliciting positive chemotaxis. (2) Mutants, having only one enzyme II react in the capillary tube assay only to substrates of this enzyme II, but not to substrates of the missing enzymes II. This holds for enzymes II consisting of one membrane-bound protein as well as for systems containing a soluble factor III (FIII). (3) The substrate specificities or affinities, whether tested by transport and chemotaxis assays in vivo or by phosphorylation tests in vitro, are in correpondence. (4) The activities of enzymes II, regulated in a complex way at the level of enzyme synthesis and activity and tested as above, are also in agreement. (5) Mutants lacking the soluble proteins enzyme I or HPr of the PTS no longer respond chemotactically to any substrate taken up and phosphorylated by enzymes II. It is concluded that in PTS enzymes II some functions required for transport and chemotaxis are identical. It is suggested furthermore, that the alternation of intrinsic membrane-bound proteins between a phosphorylated and a dephosphorylated state, rather than binding of the substrate to the enzyme II, is the decisive stimulus in the chemotaxis toward carbohydrates taken up by these transport systems.