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.     

Enzyme genomics: Application of general enzymatic screens to discover new enzymes

In all sequenced genomes, a large fraction of predicted genes encodes proteins of unknown biochemical function and up to 15% of the genes with "known" function are mis-annotated. Several global approaches are routinely employed to predict function, including sophisticated sequence analysis, gene expression, protein interaction, and protein structure. In the first coupling of genomics and enzymology, Phizicky and colleagues undertook a screen for specific enzymes using large pools of partially purified proteins and specific enzymatic assays. Here we present an overview of the further developments of this approach, which involve the use of general enzymatic assays to screen individually purified proteins for enzymatic activity. The assays have relaxed substrate specificity and are designed to identify the subclass or sub-subclasses of enzymes (phosphatase, phosphodiesterase/nuclease, protease, esterase, dehydrogenase, and oxidase) to which the unknown protein belongs. Further biochemical characterization of proteins can be facilitated by the application of secondary screens with natural substrates (substrate profiling). We demonstrate here the feasibility and merits of this approach for hydrolases and oxidoreductases, two very broad and important classes of enzymes. Application of general enzymatic screens and substrate profiling can greatly speed up the identification of biochemical function of unknown proteins and the experimental verification of functional predictions produced by other functional genomics approaches.     

High-throughput screening assays for the identification of chemical probes

High-throughput screening (HTS) assays enable the testing of large numbers of chemical substances for activity in diverse areas of biology. The biological responses measured in HTS assays span isolated biochemical systems containing purified receptors or enzymes to signal transduction pathways and complex networks functioning in cellular environments. This Review addresses factors that need to be considered when implementing assays for HTS and is aimed particularly at investigators new to this field. We discuss assay design strategies, the major detection technologies and examples of HTS assays for common target classes, cellular pathways and simple cellular phenotypes. We conclude with special considerations for configuring sensitive, robust, informative and economically feasible HTS assays.     

Soluble chromogenic substrates for the assay of endo-1,4-beta-xylanases and endo-1,4-beta-glucanases

New soluble chromogenic substrates were prepared for specific and rapid assays of endo-1,4-beta-xylanases and endo-1,4-beta-glucanases. A soluble beechwood 4-O-methyl-D-glucurono-D-xylan was dyed with Remazol brilliant blue R, and hydroxyethylcellulose was coupled to Ostazin brilliant red H-3B. The assays are based on photometric measurements of the enzyme-released dyed fragments soluble in the presence of organic solvents which precipitate the original substrates and their high-molecular-weight fractions. The assays are advantageous for rapid analyses of large amount of samples and also permit evaluation of the activities of both enzymes in the presence of exo-beta-glycanases and beta-glycosidases, at a high level of reducing compounds and viable cells, on the cell surface and on cell membranes and organelles.     

An improved method for the large-scale isolation of chromaffin granules from bovine adrenal medulla

Chromaffin granules essentially free of contamination from mitochondria, lysosomes and fragments of endoplasmic reticulum have been isolated in a large scale from bovine adrenal medulla. The homogeneity was judged by electron microscopy and assays of various ‘marker’ enzymes.     

Cleavage of mispaired heteroduplex DNA substrates by numerous restriction enzymes

The utility of restriction endonucleases as a tool in molecular biology is in large part due to the high degree of specificity with which they cleave well-characterized DNA recognition sequences. The specificity of restriction endonucleases is not absolute, yet many commonly used assays of biological phenomena and contemporary molecular biology techniques rely on the premise that restriction enzymes will cleave only perfect cognate recognition sites. In vitro, mispaired heteroduplex DNAs are commonly formed, especially subsequent to polymerase chain reaction amplification. We investigated a panel of restriction endonucleases to determine their ability to cleave mispaired heteroduplex DNA substrates. Two straightforward, non-radioactive assays are used to evaluate mispaired heteroduplex DNA cleavage: a PCR amplification method and an oligonucleotide-based assay. These assays demonstrated that most restriction endonucleases are capable of site-specific double-strand cleavage with heteroduplex mispaired DNA substrates, however, certain mispaired substrates do effectively abrogate cleavage to undetectable levels. These data are consistent with mispaired substrate cleavage previously reported for Eco RI and, importantly, extend our knowledge of mispaired heteroduplex substrate cleavage to 13 additional enzymes.     

Labeled proteinase inhibitors: versatile tools for the characterization of serine proteinases in solid-phase assays.

Peptidyl chloromethyl ketones were used for the specific labeling of proteinases by attaching a biotin group to the N-terminal end of the peptide. Such labeled peptide inhibitors allowed the detection and quantitation of proteolytic enzymes immobilized on the plastic surface of a microtiter plate, as well as on nitrocellulose. The validity of these solid-phase assays was demonstrated using subtilisin Carlsberg as a model enzyme and biotinyl-epsilon-aminocaproyl-L-alanyl-L-alanyl-L-propyl-L-phenylal++ + anyl- chloromethyl ketone as a specific reagent. In addition to being usable for the screening of a particular proteinase in a large number of samples, these assays can be adapted for the analysis of specific proteolytic enzyme present in complex mixtures.     

alpha-1 Antitrypsin phenotypes determined by isoelectric focusing of the cysteine-antitrypsin mixed disulfide in serum.

The methods available for analysis of sugar kinase activity are usually either complicated or time consuming. Coupled assays, aside from the added cost of coupling enzymes and substrates, present problems due to the pH optima, activators, and inhibitors of the coupling enzymes. Direct separation of the product requires either ion exchange (1) or paper chromatography (2,3). The former requires constant attention and the latter usually takes either overnight for the completion of a chromatogram or a great deal of elution solvent (200 ml) for DEAE paper discs (3).Those enzymes which form phosphorylated products from nonionic substrates (hexokinases, glycerol kinase, phosphoribosyl-transferases, etc.) may be conveniently assayed by chromatograhic separation of a radioactive phosphorylated product from the radioactive nonionic substrate, where the product remains at the origin. In such assays, no interfering coupling enzymes are used and the product can be directly and sensitively measured. The only current limitation with such methods is the time required for the separation of the phosphorylated product. It would be advantageous to obtain the enzyme's activity in as short a time as possible.We present here a method of paper chromatographic separation of phosphorylated product from nonionic substrate which requires only approximately two hours, uses a large petri dish, very little chromatographic grade paper, and almost no attention.     

Detection of activities that interfere with the enzymatic assay of deoxyribonucleoside 5'-triphosphates

Several enzymes that interfere with the enzymatic assay of deoxyribonucleoside 5'-triphosphates (dNTP's) are present as contaminants when nucleotides are extracted from HeLa cells with 60% methanol. These activities include a nuclease, nucleoside diphosphokinase, and deoxyribonucleoside monophosphokinases which phosphorylate dAMP, dGMP, and dCMP. Collectively, these enzymes are able to degrade and reutilize the DNA template which is used together with DNA polymerase for dNTP assays. This process introduces large errors when dNTP assays are performed in this manner. Attempts to block the enzymatic conversion of deoxyribonucleoside diphosphates to triphosphates by inhibition of nucleoside diphosphokinase were unsuccessful because of the inability to block completely the kinase activity. Acid extraction of nucleotides also results in the presence of an activity that interferes with the enzymatic dNTP assay. The error introduced by this interfering activity is much smaller than that arising from the enzymes present in methanol extracts. All of these interfering activities are removed when cells are first extracted with 60% methanol and the resulting extract is subsequently treated with perchloric acid.     

Diminished activities of fatty acid synthesis enzymes in insulin-resistant adipocytes from spontaneously obese rats.

Acetyl coenzyme A carboxylase and fatty acid synthetase activities were studied to determine the biochemical basis of the markedly impaired capacity of fat cells from spontaneously obese, old rats to convert glucose to fatty acids relative to cells from lean, young rats. Michaelis constants for the substrates of both enzymes were similar in large and small adipocyte homogenates. In contrast, Vmax values were over 80% less in homogenates from large relative to small cells on a per cell basis. Long-term dialysis or the presence of albumin during the assays failed to restore the activities of these enzymes in homogenates of large fat cells. The combination of equal volumes of homogenates from the two cell types resulted in carboxylase and synthetase activities intermediate between activities found in the two homogenates alone. Therefore, the presence of endogenous allosteric inhibitors does not appear to account for the markedly blunted fatty acid synthesis enzyme activities in large fat cells. These results suggest that the fatty acid synthesis impairment, which is a primary defect in the insulin resistance of the large cells, is at least partly due to diminished cellular contents of acetyl coenzyme A carboxylase and fatty acid synthetase.     

Covalent modification of subtilisin Bacillus lentus cysteine mutants with enantiomerically pure chiral auxiliaries causes remarkable changes in activity

Methanethiosulfonate reagents may be used to introduce virtually unlimited structural modifications in enzymes via reaction with the thiol group of cysteine. The covalent coupling of enantiomerically pure (R) and (S) chiral auxiliary methanethiosulfonate ligands to cysteine mutants of subtilisin Bacillus lentus induces spectacular changes in catalytic activity between diastereomeric enzymes. Amidase and esterase kinetic assays using a low substrate approximation were used to establish kcat/KM values for the chemically modified mutants, and up to 3-fold differences in activity were found between diastereomeric enzymes. Changing the length of the carbon chain linking the phenyl or benzyl oxazolidinone ligand to the mutant N62C by a methylene unit reverses which diastereomeric enzyme is more active. Similarly, changing from a phenyl to benzyl oxazolidinone ligand at S166C reverses which diastereomeric enzyme is more active. Chiral modifications at S166C and L217C give CMMs having both high esterase kcat/KM's and high esterase to amidase ratios with large differences between diastereomeric enzymes.     

Assay of apical membrane enzymes based on fluorogenic substrates.

A series of enzymatic rate assays are described. The assays are based on coumarin derivatives that are fluorogenic substrates for the enzymes dipeptidase IV, aminopeptidase N, alkaline phosphatase, and gamma-glutamyltransferase. These simple assays are rapid and offer improved sensitivity over established colorimetric methods. The substrates have apparent affinities for the enzymes of 5-250 microM. L-Glutamic acid gamma-(7-amido-4-methylcoumarin) is characterized as a substrate of gamma-glutamyltransferase on the basis of inhibition of enzymatic cleavage when the glycylglycine acceptor molecule is omitted and inhibition of the enzymatic reaction by addition of glycine. Assay conditions for the four enzymes are established such that less than 0.6% of the substrate is consumed, fluorescence is proportional to enzymatic product, and results may be directly compared to established colorimetric assays. Intestinal epithelial cells are used both to establish appropriate assay conditions and to demonstrate the utility of the assays.     

Quantitative detection of blood-brain barrier-associated enzymes in cultured endothelial cells of procine brain microvessels

Summary The present study deals with a rapid and convenient assay for blood-brain barrier (BBB)-associated enzymes, γ-glutamyl transpeptidase (γ-GTP) and alkaline phosphatase (ALP), in cultured endothelial cells and other cells. These enzyme activities in cultured cells could be efficiently measured by direct incubation of each substrate in the culture plates without pretreatment of the cells. This new direct in situ-in plate assay was more rapid and convenient than conventional ex-plate assays, and these assays gave similar values for specific enzyme activities. γ-GTP and ALP activities could be detected by this in situ method in primary-cultured endothelial cells of porcine brain microvessels, but their levels were lower than those before culture. The degree of loss due to culture differed, between γ-GTP and ALP; a relatively large amount of ALP remained but the γ-GTP level decreased greatly In this direct in situ-in plate assay, cultured porcine aortic endothelial cells exhibited negligibly small activities for both enzymes, whereas cultured astroglial cells of neonatal porcine brain showed moderate γ-GTP activity and a trace of ALP activity. This direct in situ-in plate assay can be used for microculture and automatic measurement and offers a convenient means for studying the possible regulatory mechanisms of the expression of the BBB-associated enzymes.     

Subcellular localization of the pyoverdine biogenesis machinery of Pseudomonas aeruginosa: A membrane-associated “siderosome”

The peptidic siderophore pyoverdine is the primary iron uptake system of fluorescent pseudomonads, and a virulence factor in the opportunistic pathogen Pseudomonas aeruginosa. Pyoverdine biogenesis is a co-ordinate process requiring several precursor-generating enzymes and large nonribosomal peptide synthetases (NRPSs) in the cytoplasm, followed by extracytoplasmic maturation. By using cell fractionation, protein–protein interaction, and in vivo labeling assays we obtained evidence that, in P. aeruginosa, pyoverdine NRPSs assemble with precursor-generating enzymes into a membrane-bound multi-enzymatic complex, for which we propose the name “siderosome”. The pyoverdine biogenetic complex represents a novel example of subcellular compartmentalization of a secondary metabolic pathway in prokaryotes.     

Quantifying enzymatic lysis: estimating the combined effects of chemistry, physiology and physics

The number of microbial pathogens resistant to antibiotics continues to increase even as the rate of discovery and approval of new antibiotic therapeutics steadily decreases. Many researchers have begun to investigate the therapeutic potential of naturally occurring lytic enzymes as an alternative to traditional antibiotics. However, direct characterization of lytic enzymes using techniques based on synthetic substrates is often difficult because lytic enzymes bind to the complex superstructure of intact cell walls. Here we present a new standard for the analysis of lytic enzymes based on turbidity assays which allow us to probe the dynamics of lysis without preparing a synthetic substrate. The challenge in the analysis of these assays is to infer the microscopic details of lysis from macroscopic turbidity data. We propose a model of enzymatic lysis that integrates the chemistry responsible for bond cleavage with the physical mechanisms leading to cell wall failure. We then present a solution to an inverse problem in which we estimate reaction rate constants and the heterogeneous susceptibility to lysis among target cells. We validate our model given simulated and experimental turbidity assays. The ability to estimate reaction rate constants for lytic enzymes will facilitate their biochemical characterization and development as antimicrobial therapeutics.     

Microplate quantification of enzymes of the plant ascorbate-glutathione cycle

Here, we describe microplate assays for determining the specific activities of four enzymes that constitute the ascorbate-glutathione cycle: APX, MDHAR, DHAR, and GR. In plants, these enzymes play a major role in detoxifying reactive oxygen species produced in cells under environmental stress. This work presents the development of plate reader assays to allow rapid analysis of the ascorbate-glutathione cycle activity using tomato fruits subjected to salt stress as a model. With this method, it is possible to analyze easily in one day the activities of the four enzymes for 30 experimental samples, all in triplicate and with blanks.     

Rapid isolation, purification and characterisation of type II restriction enzymes from Lactococcus spp.

An inexpensive procedure that uses small volumes (5–10 ml) of cell culture for the rapid isolation of restriction enzymes, sufficiently pure to allow preliminary characterisation, is presented. The method was designed initially to screen for Type II restriction enzymes, but different assays can be devised to screen for other types of restriction enzymes. Although initially optimised in Lacotococcus lactis subsp. cremoris LC17-1, this method potentially holds wider applications in other lactococcal species as was shown by its successful application to Lactococcus lactis subp. lactis. Without the necessity for chromatographic techniques that are often expensive and time consuming, the convenience of the technique makes it suitable for rapid, routine screening of a large number of lactic acid bacterial strains, or restriction and modification systems cloned into them, for restriction enzyme activity.     

A general procedure for screening inhibitory antibodies: application for identifying anti-protein kinase C antibodies

In this communication we describe a microfiltration assay to identify monoclonal antibodies that interfere with the activity of enzymes. This method is quick and sensitive to small changes in the activity of the enzyme and does not require highly purified enzyme or large quantities of antibodies. It has been applied to identify anti-protein kinase C antibodies which would have been impossible to identify by classical assays such as enzyme-linked immunosorbent assay.     

Fluorogenic substrates with single fluorophores for nucleic acid-modifying enzymes: design principles and new applications

Nucleic acid-modifying enzymes are widely used in numerous applications. Many of these proteins are also important drug targets. Thus, better assays for the evaluation of their activities are always needed and are continuously being developed. Recently, I reported on a set of assays for several DNA-modifying enzymes (polymerases, endonucleases, and ligase) based on simple, hairpin-type oligonucleotide substrates labeled with a single fluorophore (Anal. Biochem. 412 (2011) 229-236). The present paper reports further studies on the mechanism of action of these substrates. It was assumed that the single fluorophore of these substrates is substantially quenched by stacking onto the terminal base(s) of the duplex, and that any perturbation of that stacking causes an increase in fluorescence. Based on this assumption, substrates of the same type for a variety of additional enzymes were developed and tested. The new assays described herein are for T4 polynucleotide kinase, the DNA repair enzymes uracil-DNA glycosylase (UDG) and formamido-pyrimidine-DNA glycosylase (FPG), 3'-5' exonucleases, and enzymes with template-independent terminal transferase activity such as Taq polymerase. All of these molecules are easy to synthesize, and similar substrates for other enzymes can rapidly be designed based on the principles outlined in this work.     

Colorimetric Assays for Quantitative Analysis and Screening of Epoxide Hydrolase Activity

Focusing on directed evolution to tailor enzymes as usable biocatalysts for fine chemistry, we have studied in detail several colorimetric assays for quantitative analysis of epoxide hydrolase (EH) activity. In particular, two assays have been optimized to characterize variants issued from the directed evolution of the EH from Aspergillus niger. Assays described in this paper are sufficiently reliable for quantitative screening of EH activity in microtiter plates and are low cost alternatives to GC or MS analysis. Moreover, they are usable for various epoxides and not restricted to a type of substrate, such as those amenable to assay by UV absorbancy. They can be used to assay EH activity on any epoxide and to directly assay enantioselectivity when both (R) and (S) substrates are available. The advantages and drawbacks of these two methods to assay EH activity of a large number of natural samples are summarized.