# Analysis of Protein Inhibitors of Trypsin in Quinoa, Amaranth and Lupine Seeds. Selection and Deep Structure–Function Characterization of the Amaranthus caudatus Species

**Authors:** Martha Hernández de la Torre, Giovanni Covaleda-Cortés, Laura Montesinos, Daniela Covaleda, Juan C. Ortiz, Jaume Piñol, José M. Bautista, J. Patricio Castillo, David Reverter, Francesc Xavier Avilés

PMC · DOI: 10.3390/ijms26031150 · 2025-01-28

## TL;DR

This study identifies a potent trypsin inhibitor in amaranth seeds, characterizes its structure, and explores its potential for agricultural and biotechnological applications.

## Contribution

The study presents a novel trypsin inhibitor from amaranth with a resolved 3D structure and evaluates its functional role.

## Key findings

- Amaranth seeds contain a highly active trypsin inhibitor with a molecular weight of 7889.1 Da and a Ki of 1.2 nM.
- The inhibitor's 3D structure reveals a substrate-like interaction and a key disulfide bond constraining its binding loop.
- The inhibitor does not affect microbial pathogens but may serve as an agricultural insect deterrent.

## Abstract

Protease inhibitors are biomolecules with growing biotechnological and biomedical relevance, including those derived from plants. This study investigated strong trypsin inhibitors in quinoa, amaranth, and lupine seeds, plant grains traditionally used in Andean South America. Amaranth seeds displayed the highest trypsin inhibitory activity, despite having the lowest content of aqueous soluble and thermostable protein material. This activity, directly identified by enzymatic assay, HPLC, intensity-fading mass spectrometry (IF-MS), and MS/MS, was attributed to a single protein of 7889.1 Da, identified as identical in Amaranthus caudatus and A. hybridus, with a Ki of 1.2 nM for the canonical bovine trypsin. This form of the inhibitor, which is highly homogeneous and scalable, was selected, purified, and structurally–functionally characterized due to the high nutritional quality of amaranth seeds as well as its promising agriculture–biotech–biomed applicability. The protein was crystallized in complex with bovine trypsin, and its 3D crystal structure resolved at 2.85 Å, revealing a substrate-like transition state interaction. This verified its classification within the potato I inhibitor family. It also evidenced that the single disulfide bond of the inhibitor constrains its binding loop, which is a key feature. Cell culture assays showed that the inhibitor did not affect the growth of distinct plant microbial pathogen models, including diverse bacteria, fungi, and parasite models, such as Mycoplasma genitalium and Plasmodium falciparum. These findings disfavour the notion that the inhibitor plays an antimicrobial role, favouring its potential as an agricultural insect deterrent and prompting a redirection of its functional research.

## Linked entities

- **Proteins:** prss1.L (serine protease 1 L homeolog)
- **Species:** Amaranthus caudatus (taxon 3567), Plasmodium falciparum (taxon 5833)

## Full-text entities

- **Diseases:** potato I (MESH:C538354)
- **Species:** Amaranthus hybridus (green amaranth, species) [taxon 3565], Amaranthus caudatus (amaranth, species) [taxon 3567], Bos taurus (bovine, species) [taxon 9913], Chenopodium quinoa (quinoa, species) [taxon 63459], Plasmodium falciparum (malaria parasite P. falciparum, species) [taxon 5833], Mycoplasmoides genitalium (species) [taxon 2097]

## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11817793/full.md

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Source: https://tomesphere.com/paper/PMC11817793