# Applications and properties of computationally designed de novo proteins

**Authors:** Martin Pacesa

PMC · DOI: 10.1063/4.0000965 · 2025-10-27

## TL;DR

Scientists are using computational methods to design new proteins that can be used for research and medical purposes, with high success rates and no need for extensive testing.

## Contribution

The development of BindCraft, an automated pipeline for designing protein binders with high success rates and nanomolar affinity.

## Key findings

- BindCraft achieves 10-100% experimental success rates in designing protein binders.
- Designed binders effectively target cell-surface receptors, allergens, and CRISPR-Cas9.
- Applications include reducing allergen binding and redirecting AAV capsids for gene delivery.

## Abstract

Computational protein design is emerging as a powerful technique for creating novel protein tools with applications in structural biology, diagnostics, and therapeutics. Recent advances, particularly deep learning methods such as AlphaFold2, have significantly accelerated our ability to design stable, arbitrary protein folds with high experimental success rates. In this talk, we will explore the biophysical properties and potential applications of these de novo designed proteins, focusing specifically on addressing challenges associated with designing functional proteins that mediate precise biological interactions. To overcome these challenges, we developed BindCraft, an open-source, automated pipeline for de novo protein binder design. BindCraft achieves high experimental success rates (10-100%) and generates binders with nanomolar affinity without requiring extensive screening or experimental optimization—even for targets without previously characterized binding sites. We showcase this by designing binders against diverse targets, including cell-surface receptors, common allergens, and complex multi-domain nucleases such as CRISPR-Cas9. Additionally, we demonstrate practical applications by significantly reducing allergen binding in patient-derived samples and redirecting AAV capsids for targeted gene delivery. This work highlights how computationally designed proteins can serve as versatile tools in structural biology, opening new opportunities for investigating biological mechanisms and facilitating advanced structural studies.

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Source: https://tomesphere.com/paper/PMC12585433