Investigation of the Substrate-Binding Site of Trypsin by the Aid of Tripeptidyl-p-nitroanilide Substrates

Pozsgay, Marianne; Szabó, Gabriella Cs.; Elödi, P; Gáspár, R.; Bajusz, Sindor; Simonsson, Roger

doi:10.1111/j.1432-1033.1981.tb06230.x

Cited by 30 publications

(9 citation statements)

References 16 publications

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“…Substrate specificity studies progressed faster after the development of peptides having a chromophore or a fluorophore bound at the carboxyl side of a C-terminal Arg (Pozsgay et al, 1981;Juliano and Juliano, 1985;Schellenberger et al, 1991). These studies led to the discovery that most trypsins prefer substrates with Pro and Phe at P2 and P3, respectively.…”

Section: Introductionmentioning

confidence: 97%

Substrate specificity of insect trypsins and the role of their subsites in catalysis

Lopes

Juliano

Marana

et al. 2006

Insect Biochemistry and Molecular Biology

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Section: Introductionmentioning

confidence: 97%

Substrate specificity of insect trypsins and the role of their subsites in catalysis

Lopes

Juliano

Marana

et al. 2006

Insect Biochemistry and Molecular Biology

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“…In contrast the inhibition by methyl or ethyl guanidines is 20–30 times more effective than inhibition by the corresponding amines [38] . Likewise k cat / K M for the trypsin catalysed hydrolysis of Bz-Phe-Val-Arg-pna is ~20 times greater than that observed when the arginine residue is replaced by a lysine residue [39] . The fact that the binding of Z-Arg-COOH is not ~20 tighter than Z-Lys-COOH ensures that the better binding and catalytic efficiency of arginine substrates is not cancelled out by more effective product inhibition by Z-Arg-COOH compared to Z-Lys-COOH.…”

Section: Discussionmentioning

confidence: 75%

A new lysine derived glyoxal inhibitor of trypsin, its properties and utilization for studying the stabilization of tetrahedral adducts by trypsin

Cleary

Malthouse

2016

Biochemistry and Biophysics Reports

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New trypsin inhibitors Z-Lys-COCHO and Z-Lys-H have been synthesised. Ki values for Z-Lys-COCHO, Z-Lys-COOH, Z-Lys-H and Z-Arg-COOH have been determined. The glyoxal group (–COCHO) of Z-Lys-COCHO increases binding ~300 fold compared to Z-Lys-H. The α-carboxylate of Z-Lys-COOH has no significant effect on inhibitor binding. Z-Arg-COOH is shown to bind ~2 times more tightly than Z-Lys-COOH. Both Z-Lys-13COCHO and Z-Lys-CO13CHO have been synthesized. Using Z-Lys-13COCHO we have observed a signal at 107.4 ppm by 13C NMR which is assigned to a terahedral adduct formed between the hydroxyl group of the catalytic serine residue and the 13C-enriched keto-carbon of the inhibitor glyoxal group. Z-Lys-CO13CHO has been used to show that in this tetrahedral adduct the glyoxal aldehyde carbon is not hydrated and has a chemical shift of 205.3 ppm. Hemiketal stabilization is similar for trypsin, chymotrypsin and subtilisin Carlsberg. For trypsin hemiketal formation is optimal at pH 7.2 but decreases at pHs 5.0 and 10.3. The effective molarity of the active site serine hydroxyl group of trypsin is shown to be 25300 M. At pH 10.3 the free glyoxal inhibitor rapidly (t1/2=0.15 h) forms a Schiff base while at pH 7 Schiff base formation is much slower (t1/2=23 h). Subsequently a free enol species is formed which breaks down to form an alcohol product. These reactions are prevented in the presence of trypsin and when the inhibitor is bound to trypsin it undergoes an internal Cannizzaro reaction via a C2 to C1 alkyl shift producing an α-hydroxycarboxylic acid.

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“…A direct relationship between polypeptide chain length and hydrolysis rate has been long proposed. 41,42 Further, according to the K m estimates, the affinity of trypsin towards smaller structures seems to be higher, with the BSA pepsin-hydrolysate (AHP) having lower K m compared to the intact protein (AnH(P) and nAnH). In this case, affinity might be a reflection of the poorer accessibility of larger structures to the active site of trypsin.…”

Section: 32mentioning

confidence: 99%

Protein acidification and hydrolysis by pepsin ensure efficient trypsin-catalyzed hydrolysis

et al. 2021

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show abstract

Investigation of the Substrate-Binding Site of Trypsin by the Aid of Tripeptidyl-p-nitroanilide Substrates

Cited by 30 publications

References 16 publications

Substrate specificity of insect trypsins and the role of their subsites in catalysis

Substrate specificity of insect trypsins and the role of their subsites in catalysis

A new lysine derived glyoxal inhibitor of trypsin, its properties and utilization for studying the stabilization of tetrahedral adducts by trypsin

Protein acidification and hydrolysis by pepsin ensure efficient trypsin-catalyzed hydrolysis

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