Structure of the LpxC deacetylase with a bound substrate-analog inhibitor

The zinc-dependent UDP-3-O-acyl-N-acetylglucosamine deacetylase (LpxC) catalyzes the first committed step in the biosynthesis of lipid A, the hydrophobic anchor of lipopolysaccharide (LPS) that constitutes the outermost monolayer of Gram-negative bacteria. As LpxC is crucial for the survival of Gram-negative organisms and has no sequence homology to known mammalian deacetylases or amidases, it is an excellent target for the design of new antibiotics. The solution structure of LpxC from Aquifex aeolicus in complex with a substrate-analog inhibitor, TU-514, reveals a novel alpha/beta fold, a unique zinc-binding motif and a hydrophobic passage that captures the acyl chain of the inhibitor. On the basis of biochemical and structural studies, we propose a catalytic mechanism for LpxC, suggest a model for substrate binding and provide evidence that mobility and dynamics in structural motifs close to the active site have key roles in the capture of the substrate.     

PEGDA hydrogels with patterned elasticity: Novel tools for the study of cell response to substrate rigidity

The ability of cells to migrate in response to mechanical gradients (durotaxis) and differential cell behavior in adhesion, spreading, and proliferation in response to substrate rigidity are key factors both in tissue engineering, in which materials must be selected to provide the appropriate mechanical signals, and in studies of mechanisms of diseases such as cancer and atherosclerosis, in which changes in tissue stiffness may inform cell behavior. Using poly(ethylene glycol) diacrylate hydrogels with varying polymer chain length and photolithographic patterning techniques, we are able to provide substrates with spatially patterned, tunable mechanical properties in both gradients and distinct patterns. The hydrogels can be patterned to produce anisotropic structures and exhibit patterned strain under mechanical loading. These hydrogels may be used to study cell response to substrate rigidity in both two and three dimensions and can also be used as a scaffold in tissue‐engineering applications. Biotechnol. Bioeng. 2010; 105: 636–644. © 2009 Wiley Periodicals, Inc.     

A chromogenic substrate for a beta-xylosidase-coupled assay of alpha-glucuronidase

4-Nitrophenyl 2-(4-O-methyl-alpha-d-glucopyranuronosyl)-beta-d-xylopyranoside obtained on deesterification of 4-nitrophenyl 2-O-(methyl 4-O-methyl-alpha-d-glucopyranosyluronate)-beta-d-xylopyranoside (Hirsch et al., Carbohydr. Res. 310, 145-149, 1998) was found to be an excellent substrate for the measurement of hemicellulolytic alpha-glucuronidase activity. A new precise alpha-glucuronidase assay was developed by coupling the alpha-glucuronidase-catalyzed formation of 4-nitrophenyl beta-d-xylopyranoside with its efficient hydrolysis by beta-xylosidase. A recombinant strain of Saccharomyces cerevisiae, harboring and expressing the beta-xylosidase gene xlnD of Aspergillus niger under control of the alcohol dehydrogenase II promoter on a multicopy plasmid, was used as a source of beta-xylosidase. The activity values of beta-xylosidase in the assay required to achieve a steady-state rate of 4-nitrophenol formation shortly after starting the alpha-glucuronidase reaction were obtained both experimentally and by calculation using the kinetics of coupled enzyme reactions.     

Study on a new chromogenic substrate for the prothrombin time determination

The aim of our study was to evaluate the possibility of using a chromogenic substrate for the prothrombin time determination. The reagent used by us (Chromoquick) is composed of a human placenta thromboplastin and chromogenic substrate (Tos-Gly-Pro-Arg-5-amino-2-nitrobenzoic acid-isopropylamide), calcium chloride and a buffer. Normal subjects, patients with liver disease, patients on oral anticoagulant therapy, patients on heparin therapy, heterozygous and homozygous patients for prothrombin complex defects and other miscellaneous conditions have been investigated. The results of chromoquick have been related with standard prothrombin time obtained using a human placenta thromboplastin (Thromborel) and rabbit brain and lung thromboplastin (Simplastin). The normal range was 18-23 s for chromoquick and 13.5-15.5 s for the standard prothrombin times using Thromborel and Simplastin. In all groups of patients examined we noticed a significant correlation between the chromogenic and the classic prothrombin times with r values varying between +0.505 and +0.947. The statistical significance resulted from p values varying between less than 0.05 and less than 0.001. Only in the case of some heterozygotes for prothrombin complex factor defects the values obtained have not been unequivocal in the sense that in a few instances the heterozygotes seemed to escape detection. Therefore, it seems that the introduction of chromogenic substrates in laboratory practice for the prothrombin time determination is possible and can offer considerable advantages like standardization and automation. The only disadvantage may be caused by costs involved.     

The Michaelis constants of a nonchromogenic substrate may be determined using a chromogenic substrate

A general method is presented for the determination of the KM and Vmax for a nonchromogenic substrate in an experimental system where a chromogenic and a nonchromogenic substrate compete for the active site of a single enzyme. Entire progress curves of absorbance versus time for the transformation of the chromogenic substrate must be obtained in the absence and presence of the nonchromgenic substrate. Two quantities may then be extracted from the entire kinetic curves: the value of a delta Area, the area bounded by the kinetic traces of absorbance versus time in the presence and absence of the nonchromogenic substrate; and the value of delta t(5%), the time required to transform 5% of the chromogenic substrate in the presence of the nonchromogenic substrate minus the corresponding time required in its absence. The values of KM and Vmax for the nonchromogenic substrate may be obtained from the dependencies of delta Area and delta t(5%) upon the concentration of the nonchromogenic substrate. The ability of this procedure to yield the correct values of KM and Vmax was demonstrated using beta-lactamase, beta-galactosidase, alkaline phosphatase, and 19 chromogenic/nonchromogenic substrate pairs. This method is equally valid in the absence or presence of competitive product inhibition and should be applicable to any enzyme-catalyzed, strongly exergonic reaction.     

A new chromogenic substrate for assay and detection of alpha-amylase

A new soluble chromogenic substrate for alpha-amylase was prepared by coupling partially hydrolyzed starch with a dye, Ostazin brilliant red H-3B. The substrate is precipitable from buffered solutions with ethanol and is equally suitable for assay of alpha-amylase, detection of separated alpha-amylase isoenzymes in gels, and selection of microbial producers of the enzyme.     

Requirement for a different hydrophobic moiety and reliable chromogenic substrate for endo-type glycosylceramidases.

A series of synthetic lactosides with aglycones that differed in length and structure were used to determine the substrate specificity of endo-type glycosylceramidases. Endoglycoceramidases (EGCase) from bacteria preferred lactosides with an acylamide structure over simple n-alkyl lactosides. While ceramide glycanase (CGase) from leech did not show preference. N -Acylaminoethyl beta-lactosides and n -alkyl lactosides were substrates for both EGCase and CGase, but N-acylaminobutyl beta-lactosides, whose acylamide residue differs from that in ceramide, were not hydrolyzed by EGCases. Thus, EGCases, but not CGase, appear to require an N-acyl group at the same position as that of intact glycosphingolipid for substrate recognition. A p-nitrophenyl lactoside derivative possessing an N-acyl chain was degraded by both EGCases and CGase and this chromogenic substrate may be an alternative substrate for endo-type glycosylceramidase activity. Km of the chromogenic lactoside for CGase and Rhodococcus EGCase were 28 microM and 2.9 mM, respectively.     

Development of a dual fluorogenic and chromogenic dipeptidyl peptidase IV substrate

A new far-red dual fluorogenic and chromogenic substrate, 5-glycylprolylglycylprolyl-9-di-3-sulfonyl-propylaminobenza[a]phenoxazonium perchlorate (GPGP-2SBPO), was developed for dipeptidyl peptidase IV (DPP-IV) sensing. The glycylprolylglycylprolyl tetrapeptide was chosen as the recognition sequence due to its stability under physiological conditions. In contrast, the truncated substrate, GP-2SBPO, containing only a glycylprolyl peptide, is unstable. Proteolysis of GPGP-2SBPO was assayed by monitoring the absorbance and fluorescence signals from the released fluorochrome, 2SBPO, at 625 and 670nm, respectively.     

An inexpensive insoluble chromogenic substrate for the determination of proteolytic activity

Summary A new insoluble chromogenic substrate for the determination of proteolytic activity was developed. This substrate was prepared by incorporating black drawing ink into casein and heating this complex at 200°C for 4 h. It is especially suitable for determining the activity of alkaline bacterial proteinases.     

Transpeptidation reactions of a specific substrate catalyzed by the streptomyces R61 DD-peptidase: characterization of a chromogenic substrate and acyl acceptor design

The Streptomyces R61 dd-peptidase, a functional model for penicillin-binding proteins, catalyzes the hydrolysis and aminolysis of d-alanyl-d-alanine-terminating peptides by specific amines. In vivo, this reaction completes bacterial cell wall biosynthesis. For in vitro studies of this enzyme to date, various nonspecific acyl-donor substrates have been employed. Recently, however, a peptidoglycan-mimetic peptide substrate, glycyl-l-alpha-amino-epsilon-pimelyl-d-alanyl-d-alanine, has been described that is much more specific for this enzyme. In this paper, we describe the synthesis and kinetic characterization of an analogous thiolester substrate, 3-(N-glycyl-l-cysteinyl)-propanoyl-d-alanyl-d-thiolactate, that the enzyme hydrolyzes and aminolyzes very efficiently (k(cat)/K(m) = 1.0 x 10(7) s(-)(1) M(-)(1)). Direct or indirect, by means of a thiol trap, spectrophotometric monitoring of the reactions of this substrate is readily achieved. Deacylation of the enzyme is rate-determining under substrate saturation conditions, and therefore the aminolysis reaction can be directly studied. The results show that d-amino acids and certain Gly-l-Xaa dipeptides and tripeptides may act as acyl acceptors at the active site of the enzyme. d-Phenylalanine and Gly-l-Phe were the most effective d-amino acid and dipeptide acceptors, respectively. On the basis of the dual specificity of the active site for acceptors (d-amino acids and Gly-l-Xaa peptides), "dual function" acceptors were designed and synthesized. Two of these, aminomalon-(N-ethyl)amide and aminomalon-(N-phenethyl)amide, were particularly effective. It did seem, however, that the observed rates of reaction of these very effective acceptors may be limited by some common, possibly physical, step. More extended, peptidoglycan-like, acceptors were found to be essentially unreactive. The reasons for this counterintuitive behavior are discussed.     

Phe5(4-nitro)-bradykinin: a chromogenic substrate for assay and kinetics of the metalloendopeptidase meprin

Phe5(4-nitro)-bradykinin has been identified as a good synthetic substrate to study the kinetics and mechanism of action of the metalloendopeptidase meprin. No convenient substrate for kinetic analysis of the enzyme had been previously described. HPLC analyses indicated that meprin cleaved bradykinin and nitrobradykinin between Phe5 (or Phe5(NO2)) and Ser6. Reaction rates for bradykinin were determined by quantitative HPLC analyses, whereas rates for nitrobradykinin were measured by continuous monitoring of the spectral change that occurs at 310 nm when the Phe(NO2)-Ser bond is hydrolyzed. For nitrobradykinin and unmodified bradykinin, respectively, Km values were 281 and 425 microM, kcat values were 28 and 22 s-1, and kcat/Km values were 9.7 x 10(4) and 5.1 x 10(4)M-1. The two products of bradykinin hydrolysis were not substrates for the enzyme, but they were inhibitors. The initial rates of hydrolysis of nitrobradykinin increased linearly with enzyme concentration (0.09-2.2 micrograms/ml), and increased linearly with temperature in the range from 15 to 55 degrees C. Hydrolysis of the substrate was optimal at alkaline pH values. The cysteine endopeptidases papain and cathepsin L and the metalloproteases thermolysin, angiotensin-converting enzyme, and neutral endopeptidase (EC 3.4.24.11) also cleaved nitrobradykinin, but at different peptide bonds than meprin. The single cleavage of nitrobradykinin at the Phe(NO2)-Ser bond and the concomitant spectral shift that occurs at alkaline pH makes this a particularly suitable substrate for meprin.     

Novel inhibitor for prolyl aminopeptidase from Serratia marcescens and studies on the mechanism of substrate recognition of the enzyme using the inhibitor

Prolyl aminopeptidase from Serratia marcescens hydrolyzed x-beta-naphthylamides (x=prolyl, alanyl, sarcosinyl, L-alpha-aminobutylyl, and norvalyl), which suggested that the enzyme has a pocket for a five-member ring. Based on the substrate specificity, novel inhibitors of Pro, Ala, and Sar having 2-tert-butyl-[1,3,4]oxadiazole (TBODA) were synthesized. The K(i) value of Pro-TBODA, Ala-TBODA, and Sar-TBODA was 0.5 microM, 1.6 microM, and 12mM, respectively. The crystal structure of enzyme-Pro-TBODA complex was determined. Pro-TBODA was located at the active site. Four electrostatic interactions were located between the enzyme and the amino group of Pro inhibitors (Glu204:0E1-N:Inh, Glu204:0E2-N:Inh, Glu232:0E1-N:Inh, and Gly46:O-N:Inh), and the residue of the inhibitors was inserted into the hydrophobic pocket composed of Phe139, Leu141, Leu146, Tyr149, Tyr150, and Phe236. The roles of Phe139, Tyr149, and Phe236 in the hydrophobic pocket and Glu204 and Glu232 in the electrostatic interactions were confirmed by site-directed mutagenesis, which indicated that the molecular recognition of proline is achieved through four electrostatic interactions and an insertion in the hydrophobic pocket of the enzyme.     

Methionine-alpha-naphthyl ester, a useful chromogenic substrate for esterproteases of the mouse submandibular gland.

The two aminoacid esters, N-acetyl-l-methionine α-naphthyl ester and N-acetyl-l-alanine α-naphthyl ester have been found to be suitable chromogenic substrates for the demonstration of mouse submandibular esterproteases. Using these substrates, a complex banding pattern of esterproteases was demonstrated by disc electrophoresis of mouse submandibular gland. Of these, protease A, epidermal growth factor binding protein, and the γ-subunits of 7 S nerve growth factor could be identified.     

Complementary substrate specificities of class I and class II collagenases from Clostridium histolyticum

The substrate specificities of three class I (beta, gamma, and eta) and three class II (sigma, epsilon, and zeta) collagenases from Clostridium histolyticum have been investigated by quantitating the kcat/KM values for the hydrolysis of 53 synthetic peptides with collagen-like sequences covering the P3 through P3 subsites of the substrate. For both classes of collagenases, there is a strong preference for Gly in subsites P1' and P3. All six enzymes also prefer substrates that contain Pro and Ala in subsites P2 and P2' and Hyp, Ala, or Arg in subsite P3'. This agrees well with the occupancies of these sites by these residues in type I collagen. However, peptides with Glu in subsites P2 or P2' are not good substrates, even though Glu occurs frequently in these positions in collagen. Conversely, all six enzymes prefer aromatic amino acids in subsite P1, even though such residues do not occur in this position in type I collagen. In general, the class II enzymes have a broader specificity than the class I enzymes. However, they are much less active toward sequences containing Hyp in subsites P1 and P3'. Thus, the two classes of collagenases have similar but complementary sequence specificities. This accounts for the ability of the two classes of enzymes to synergistically digest collagen.     

Synaptophysin and synapsin I as tools for the study of the exo-endocytotic cycle

Synaptophysin, an integral protein of the synaptic vesicle membrane, and synapsin I, a phosphoprotein associated with the cytoplasmic side of synaptic vesicles, represent useful markers that allow to follow the movements of the vesicle membrane during recycling. The use of antibodies against these proteins to label nerve terminals during experimental treatments which stimulate secretion has provided evidence that during the exo-endocytotic cycle synaptic vesicles transiently fuse with the axolemma, from which they are specifically recovered. When recycling is blocked, exocytosis leads to the permanent incorporation of the synaptic vesicle membrane into the axolemma and to diffusion of the vesicle components in the plane of the membrane.     

N-acetyl-(L-Ala) 3 -p-nitroanilide as a new chromogenic substrate for elastase

The introduction of a useful new chromogenic substrate for the determination of elastase (EC 3.4.4.7) activity is described. N-acetyl-L-Ala-L-Ala-L-Ala-$\text{p}$-nitroanilide (AcAla₃NA) is a new specific elastase substrate whose hydrolysis can be followed spectrophotometrically at 410 nm in a wide pH range. Its rate of hydrolysis by α-chymotrypsin (EC 3.4.4.5) and trypsin (EC 3.4.4.4.) is 0.02% and 0.001% respectively compared to its rate of hydrolysis by elastase. As little as 0.1 μg elastase/ml can be satisfactorily determined. At pH 8, K_m = 0.88 mM and k_cat = 11.9 sec^?1.     

U-3''-BCIP: a chromogenic substrate for the detection of RNase A in recombinant DNA expression systems.

The synthesis of the bovine pancreatic ribonuclease A (RNase A, EC 3.1.27.5) chromogenic substrate uridine-3'-(5-bromo-4-chloroindol-3-yl)-phosphate (U-3'-BCIP) is described. RNase A catalyzes the hydrolysis of U-3'-BCIP to release a halogenated indol-3-ol that undergoes rapid aerobic oxidation to the dark blue 5,5'-dibromo-4,4'-dichloroindigo. Preliminary kinetic studies indicate that this compound may have practical use for assaying RNase A activity both in vitro and in vivo, e.g. in screening bacterial colonies for RNase A produced by recombinant DNA methods.