# Thrombolytic proteins profiling: High‐throughput activity, selectivity, and resistance assays

**Authors:** Martin Toul, Alan Strunga, Jiri Damborsky, Zbynek Prokop

PMC · DOI: 10.1002/2211-5463.70132 · 2025-10-04

## TL;DR

The paper introduces optimized biochemical methods to evaluate clot-dissolving proteins, helping develop safer and more effective treatments for conditions like stroke and heart attack.

## Contribution

The study provides a comprehensive profiling system for thrombolytic proteins, integrating multiple assays to assess activity, selectivity, and resistance.

## Key findings

- Tenecteplase shows higher fibrin selectivity and inhibition resistance compared to alteplase.
- The assays can predict clinical outcomes like biological half-life and bleeding risk.
- The methodology supports rapid screening of thrombolytic biomolecules for therapeutic potential.

## Abstract

Cardiovascular diseases, including thrombotic events such as ischemic stroke, pulmonary embolism, and myocardial infarction, are among the leading causes of morbidity and disability worldwide. The application of clot‐dissolving thrombolytic enzymes is a cost‐effective therapeutic intervention for these life‐threatening conditions. However, the effectiveness and safety profiles of current drugs are suboptimal, necessitating the discovery of new medicines or the engineering and enhancement of the existing ones. Here, we present a set of optimized biochemical protocols that allow robust screening and the therapeutic potential assessment of thrombolytic biomolecules. The assays provide information on multiple characteristics such as enzymatic activity, fibrinolysis rate, fibrin and fibrinogen stimulation, fibrin selectivity, clot binding affinity, and inhibition resistance. Such detailed characterization enables a rapid and reliable evaluation of candidate effectiveness and provides an indication of biological half‐life, associated bleeding complications, and other side effects. We demonstrate the credibility of the methodology by applying it to the two most widely used thrombolytic drugs: alteplase (Activase®/Actilyse®) and tenecteplase (Metalyse®/TNKase®). Consistent with previous studies, tenecteplase exhibited increased fibrin selectivity and inhibition resistance, which explains its extended half‐life. Our findings reinforce the growing consensus that tenecteplase may be a superior alternative to alteplase for thrombolytic treatment.

We present optimized biochemical protocols for evaluating thrombolytic proteins, enabling rapid and robust screening of enzymatic activity, inhibition resistance, and fibrin affinity, stimulation, and selectivity. The outcome translates to key clinical indicators such as biological half‐life and bleeding risk. These assays streamline the development of safer and more effective clot‐dissolving therapies by guiding the design and engineering of next‐generation thrombolytics.

## Linked entities

- **Diseases:** ischemic stroke (MONDO:1060198), pulmonary embolism (MONDO:0005279), myocardial infarction (MONDO:0005068)

## Full-text entities

- **Genes:** FGB (fibrinogen beta chain) [NCBI Gene 2244] {aka HEL-S-78p}
- **Diseases:** Cardiovascular diseases (MESH:D002318), bleeding (MESH:D006470), thrombotic (MESH:D013927), ischemic stroke (MESH:D002544), pulmonary embolism (MESH:D011655), myocardial infarction (MESH:D009203)

## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12871562/full.md

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Source: https://tomesphere.com/paper/PMC12871562