β-Trefoil inhibitors – from the work of Kunitz onward

Renko, M.; Sabotič, Jerica; Turk, Dušan

doi:10.1515/hsz-2012-0159

Cited by 34 publications

(41 citation statements)

References 120 publications

(140 reference statements)

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“…As found in most known Kunitz-type inhibitors [2], EcTI has a single reactive site located on loop L5, between β-strands 4 and 5. An exception is the recently published complex structure of a double-headed serine arrowhead protease inhibitor, API-A complexed with two molecules of trypsin, in which two reactive sites are located in loops L6 and L10 [21].…”

Section: Resultsmentioning

confidence: 85%

“…Members of the superfamily characterized by the β-trefoil fold [1] are structurally similar although their biological functions may be widely different [2]. Such functions may include chlorophyll binding [3], taste modification (miraculin [4]), binding to cytokine receptors (IL-1β [5]), tight binding to ribosomes (ricin [6]) or carbohydrate binding, exemplified by the Clitocybe nebularis lectin, CNL [7].…”

Section: Introductionmentioning

confidence: 99%

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Crystal Structures of a Plant Trypsin Inhibitor from Enterolobium contortisiliquum (EcTI) and of Its Complex with Bovine Trypsin

et al. 2013

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A serine protease inhibitor from Enterolobium contortisiliquum (EcTI) belongs to the Kunitz family of plant inhibitors, common in plant seeds. It was shown that EcTI inhibits the invasion of gastric cancer cells through alterations in integrin-dependent cell signaling pathway. We determined high-resolution crystal structures of free EcTI (at 1.75 Å) and complexed with bovine trypsin (at 2 Å). High quality of the resulting electron density maps and the redundancy of structural information indicated that the sequence of the crystallized isoform contained 176 residues and differed from the one published previously. The structure of the complex confirmed the standard inhibitory mechanism in which the reactive loop of the inhibitor is docked into trypsin active site with the side chains of Arg64 and Ile65 occupying the S1 and S1′ pockets, respectively. The overall conformation of the reactive loop undergoes only minor adjustments upon binding to trypsin. Larger deviations are seen in the vicinity of Arg64, driven by the needs to satisfy specificity requirements. A comparison of the EcTI-trypsin complex with the complexes of related Kunitz inhibitors has shown that rigid body rotation of the inhibitors by as much as 15° is required for accurate juxtaposition of the reactive loop with the active site while preserving its conformation. Modeling of the putative complexes of EcTI with several serine proteases and a comparison with equivalent models for other Kunitz inhibitors elucidated the structural basis for the fine differences in their specificity, providing tools that might allow modification of their potency towards the individual enzymes.

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Section: Resultsmentioning

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Crystal Structures of a Plant Trypsin Inhibitor from Enterolobium contortisiliquum (EcTI) and of Its Complex with Bovine Trypsin

et al. 2013

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“…These inhibitors have a b-trefoil fold, composed of 12 b-strands arranged in threefold pseudo-symmetry units or subdomains with the presence of helices in some cases (Broom et al, 2012;McLachlan, 1979;Murzin et al, 1992;Renko et al, 2012). The pseudo-symmetry units are composed of four b-strands, two of them forming a sixstranded b-barrel with the other subdomains, and the other two of each unit forming a b-hairpin acting like the cap for the bbarrel.…”

Section: Introductionmentioning

confidence: 99%

“…The structural regions reported to be involved in protease-inhibitor interactions are loops connecting the b-strand elements (i.e. loop L4 between b-strands 4 and 5 in STI), which can be highly variable in sequence and length (Renko et al, 2012). The most accepted model for the b-trefoil fold evolution proposes that the fold arose from a duplication and fusion of the monomeric unit from an ancestral trimeric protein (Broom et al, 2012;Ponting and Russell, 2000).…”

Section: Introductionmentioning

confidence: 99%

Structures of a bi-functional Kunitz-type STI family inhibitor of serine and aspartic proteases: Could the aspartic protease inhibition have evolved from a canonical serine protease-binding loop?

Guerra

Valiente

Pons

et al. 2016

Journal of Structural Biology

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Bi-functional inhibitors from the Kunitz-type soybean trypsin inhibitor (STI) family are glycosylated proteins able to inhibit serine and aspartic proteases. Here we report six crystal structures of the wild-type and a non-glycosylated mutant of the bifunctional inhibitor E3Ad obtained at different pH values and space groups. The crystal structures show that E3Ad adopts the typical β-trefoil fold of the STI family exhibiting some conformational changes due to pH variations and crystal packing. Despite the high sequence identity with a recently reported potato cathepsin D inhibitor (PDI), three-dimensional structures obtained in this work show a significant conformational change in the protease-binding loop proposed for aspartic protease inhibition. The E3Ad binding loop for serine protease inhibition is also proposed, based on structural similarity with a novel non-canonical conformation described for the double-headed inhibitor API-A from the Kunitz-type STI family. In addition, structural and sequence analyses suggest that bifunctional inhibitors of serine and aspartic proteases from the Kunitz-type STI family are more similar to double-headed inhibitor API-A than other inhibitors with a canonical protease-binding loop.

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“…Members of this superfamily share structural features but not necessarily other properties and their biological role may be widely different [2]. Prominent among them are plant protease inhibitors of the Kunitz type, called Kunitz-P or Kunitz-STI inhibitors [2], [3]. These proteins primarily inhibit serine proteases, although some also inhibit cysteine and aspartic proteases [4].…”

Section: Introductionmentioning

confidence: 99%

Crystal Structure of Crataeva tapia Bark Protein (CrataBL) and Its Effect in Human Prostate Cancer Cell Lines

et al. 2013

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A protein isolated from the bark of Crataeva tapia (CrataBL) is both a Kunitz-type plant protease inhibitor and a lectin. We have determined the amino acid sequence and three-dimensional structure of CrataBL, as well as characterized its selected biochemical and biological properties. We found two different isoforms of CrataBL isolated from the original source, differing in positions 31 (Pro/Leu); 92 (Ser/Leu); 93 (Ile/Thr); 95 (Arg/Gly) and 97 (Leu/Ser). CrataBL showed relatively weak inhibitory activity against trypsin (Kiapp = 43 µM) and was more potent against Factor Xa (Kiapp = 8.6 µM), but was not active against a number of other proteases. We have confirmed that CrataBL contains two glycosylation sites and forms a dimer at high concentration. The high-resolution crystal structures of two different crystal forms of isoform II verified the β-trefoil fold of CrataBL and have shown the presence of dimers consisting of two almost identical molecules making extensive contacts (∼645 Å2). The structure differs from those of the most closely related proteins by the lack of the N-terminal β-hairpin. In experiments aimed at investigating the biological properties of CrataBL, we have shown that addition of 40 µM of the protein for 48 h caused maximum growth inhibition in MTT assay (47% of DU145 cells and 43% of PC3 cells). The apoptosis of DU145 and PC3 cell lines was confirmed by flow cytometry using Annexin V/FITC and propidium iodide staining. Treatment with CrataBL resulted in the release of mitochondrial cytochrome c and in the activation of caspase-3 in DU145 and PC3 cells.

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β-Trefoil inhibitors – from the work of Kunitz onward

Cited by 34 publications

References 120 publications

Crystal Structures of a Plant Trypsin Inhibitor from Enterolobium contortisiliquum (EcTI) and of Its Complex with Bovine Trypsin

Crystal Structures of a Plant Trypsin Inhibitor from Enterolobium contortisiliquum (EcTI) and of Its Complex with Bovine Trypsin

Structures of a bi-functional Kunitz-type STI family inhibitor of serine and aspartic proteases: Could the aspartic protease inhibition have evolved from a canonical serine protease-binding loop?

Crystal Structure of Crataeva tapia Bark Protein (CrataBL) and Its Effect in Human Prostate Cancer Cell Lines

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