# Mining the Hidden Pharmacopeia: Fungal Endophytes, Natural Products, and the Rise of AI-Driven Drug Discovery

**Authors:** Ruqaia Al Shami, Walaa K. Mousa

PMC · DOI: 10.3390/ijms27031365 · International Journal of Molecular Sciences · 2026-01-29

## TL;DR

This paper explores how AI is transforming the discovery of natural products from fungal endophytes into a predictive science for drug development.

## Contribution

It highlights the integration of AI with fungal endophyte natural products to enable systematic drug discovery and biomanufacturing.

## Key findings

- AI accelerates genome mining and metabolomic annotation of fungal endophytes.
- Generative AI models enable de novo design of bioactive natural product-inspired scaffolds.
- AI transforms natural product discovery into a hypothesis-driven, industrializable process.

## Abstract

Emerging from millions of years of evolutionary optimization, Natural products (NPs) remain unique, unparalleled sources of bioactive scaffolds. Unlike synthetic molecules engineered around single therapeutic targets, NPs often exhibit multi-target, system-level bioactivity, aligned with the principles of network pharmacology, which modulates pathways in a coordinated, non-disruptive manner. This approach reduces resistance, buffers compensatory feedback loops, and enhances therapeutic resilience. Fungal endophytes represent one of the most chemically diverse and biologically sophisticated NP reservoirs known, producing polyketides, alkaloids, terpenoids, and peptides with intricate three-dimensional architectures and emergent bioactivity patterns that remain exceptionally difficult to design de novo. Advances in artificial intelligence (AI), machine learning, deep learning, and multi-omics integration have redefined the discovery landscape, transforming previously intractable fungal metabolomes and cryptic biosynthetic gene clusters (BGCs) into tractable, predictable, and engineerable systems. AI accelerates genome mining, metabolomic annotation, BGC-metabolite linking, structure prediction, and activation of silent pathways. Generative AI and diffusion models now enable de novo design of NP-inspired scaffolds while preserving biosynthetic feasibility, opening new opportunities for direct evolution, pathway refactoring, and precision biomanufacturing. This review synthesizes the chemical and biosynthetic diversity of major NP classes from fungal endophytes and maps them onto the rapidly expanding ecosystem of AI-driven tools. We outline how AI transforms NP discovery from empirical screening into a predictive, hypothesis-driven discipline with direct industrial implications for drug discovery and synthetic biology. By coupling evolutionarily refined chemistry with modern computational intelligence, the field is poised for a new era in which natural-product leads are not only rediscovered but systematically expanded, engineered, and industrialized to address urgent biomedical and sustainability challenges.

## Full-text entities

- **Chemicals:** alkaloids (MESH:D000470), terpenoids (MESH:D013729), peptides (MESH:D010455), polyketides (MESH:D061065)

## Full text

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## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12897619/full.md

## References

227 references — full list in the complete paper: https://tomesphere.com/paper/PMC12897619/full.md

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Source: https://tomesphere.com/paper/PMC12897619