Fluorescent nucleotide triphosphate substrates for snake venom phosphodiesterase

A fluorescent oligopeptide energy transfer assay with broad applications for neutral proteases

A fluorescent peptide substrate to explore the protease specificity for the amino acid regions C- and N-terminal to the cleavage site has been designed. Intramolecular quenching of indole fluorescence by an N-terminal dansyl group separated by six amino acid residues forms the basis of this assay. For a particular enzyme, specificity can be designed into the peptide sequence by means of the number of residues that separate the two chromophores. In the present instance, the heptapeptide Dns-Gly-Lys-Tyr-Ala-Pro-Trp-Val is used to assay angiotensin converting enzyme (ACE), Astacus protease, carboxypeptidase A, alpha-chymotrypsin, and trypsin, all of which cleave the peptide in accord with their known specificity: Trypsin and Astacus protease hydrolyze only the Lys-Tyr and Tyr-Ala bonds, respectively. alpha-Chymotrypsin primarily cleaves the Tyr-Ala bond while ACE makes three successive dipeptidyl cleavages from the C-terminus. Carboxypeptidase rapidly hydrolyzes first the Trp-Val and then the Pro-Trp bond. For all of the enzymes, catalytic activity (kcat/Km) is in the range from 10(5) to 10(6) M-1 s-1. Hydrolysis causes a fluorescence increase in the 310 to 410 nm region of 8.6- to 13.6-fold depending on the enzyme that is assayed. Assays can be designed based on the increase in tryptophan fluorescence or by individual product analyses using thin-layer or high-performance liquid chromatography. The specificity and sensitivity of such internally quenched fluorescent oligopeptides would seem to be ideal for the assay of specific endoproteases.

Direct observation of enzyme substrate complexes by stopped-flow fluorescence: mathematical analyses

The fluorescence changes which occur upon the interaction of enzyme and substrate under stopped-flow conditions can provide a sensitive means to directly observe ES complexes. The interconversion of the intermediates during catalysis causes changes in fluorescence, signaling directly their existence, and allowing their quantitation. We have studied extensively an approach which measures radiationless energy transfer (RET) between enzyme tryptophanyl residues and a fluorescent peptide or ester substrate. Our studies of a number of proteolytic enzymes have validated the approach, which is sensitive and applicable to a variety of enzymes under a wide range of experimental conditions, including subzero temperatures. Direct excitation of fluorescent substrates can also be used to observe ES complex formation and breakdown and is complementary to the RET approach. Here we review both the RET and direct excitation kinetic approaches, with particular emphasis on the mathematical foundations we have developed which are critical to the successful interpretation of these or any other spectroscopic approach which yields a signal that is unique to the ES complex.

Preparation of analogues of NAD+ as substrates for a sensitive fluorimetric assay of nucleotide pyrophosphatase

1,N6-Etheno derivatives of pyridine analogues of NAD+ were synthesized, characterized and tested as substrates for a fluorimetric assay of nucleotide pyrophosphatase (EC 3.6.1.9). Upon cleavage of their pyrophosphate bond, the fluorescence of pyridine-1,N6-ethenoadenine dinucleotide (epsilon PdAD+) and of 4-hydrazinocarbonyl-pyridine-1,N6-ethenoadenine dinucleotide (epsilon hy4PdAD+) increased respectively 15-and 73-fold, at pH 7.4. This property allows a convenient steady-state assay of nucleotide pyrophosphatase by continuous monitoring of reaction progress. Both compounds were good substrates of this class of enzyme. The relative insensitivity of the fluorescence of epsilon PdAD+ and epsilon hy4PdAD+ to pH changes allowed assays under conditions preserving cellular integrity. epsilon PdAD+ is useful as a substrate for measuring nucleotide pyrophosphatase activity on the outside of mammalian cells because it is not a substrate for the external NAD+ glycohydrolase. epsilon Hy4PdAD+ proved useful when high sensitivity was needed.