# A 3D Fusarium keratitis model reveals isolate-specific adhesion and invasion properties in the Fusarium solani species complex

**Authors:** Anna Zimmermann, Johanna Theuersbacher, Hong Han, Léonie Herzog, Benedikt Schrenker, Christian Lotz, Christian Stigloher, Jost Hillenkamp, Kerstin Hünniger-Ast, Grit Walther, Daniel Kampik, Oliver Kurzai, Ronny Martin

PMC · DOI: 10.1128/msphere.00328-25 · 2025-11-04

## TL;DR

A new 3D model of eye infection shows that different Fusarium species cause varying levels of damage, with F. keratoplasticum being the most harmful.

## Contribution

A newly established 3D human cornea model reveals isolate-specific adhesion and invasion properties of Fusarium species.

## Key findings

- F. keratoplasticum showed the highest virulence with extensive invasion and host cell damage.
- F. falciforme adhered strongly but had limited invasion and damage.
- The 3D model showed deeper corneal penetration by Fusarium species compared to C. albicans.

## Abstract

Members of the Fusarium solani species complex (FSSC) are major causes of keratitis in humans. The underlying mechanisms leading to this disease are not well understood, partially due to the absence of more complex in vitro infection models. Here, we compared the pathogenicity of keratitis-causing FSSC members F. falciforme, F. keratoplasticum, and F. petroliphilum in a 2D monolayer infection model using a human corneal epithelial cell line and a newly established 3D human cornea infection model which comprises the multilayer epithelium and the stroma. In both models, F. keratoplasticum emerged as the most virulent species, showing extensive invasion and host cell damage and, in rare cases, even inducing the formation of transcellular tunnels. While F. falciforme exhibited strong adhesion to corneal epithelial cells, its capacity for invasion and damage was limited. F. petroliphilum was the least virulent among the FSSC species with low adhesion and invasion. The use of the 3D model allowed the investigation of fungal infection in a more physiologically relevant context and revealed that all three FSSC species disseminated deeper into the cornea than C. albicans under identical conditions. This may partly explain the unfavorable clinical outcome of Fusarium keratitis in patients, as the deep penetration of Fusarium hyphae complicates the accessibility of antifungal drugs to the pathogen. Our data indicate species-specific infection routes which might avoid recognition by the host cell defense system and could contribute to the overall high virulence of the species.

Fusarium keratitis is a rare fungal infection of the human eye. The outcome for affected patients is often poor, with loss of eyesight or even the entire eye being common. Investigation of this disease is challenging due to the absence of established in vitro complex infection models that go beyond a simple 2D monolayer of a single cell type. Here, we performed a comparative analysis of three Fusarium species in a classic 2D infection model and a newly established 3D human cornea model which comprised the epithelium and the stroma. Our experiments revealed that F. keratoplasticum shows a higher potential for invasion and host cell damage when compared to related species. The 3D human cornea model could be a helpful tool for future investigations of fungal pathogenicity and antifungal drug susceptibility during cornea infections.

## Linked entities

- **Diseases:** keratitis (MONDO:0003085)
- **Species:** Fusarium falciforme (taxon 195108), Fusarium keratoplasticum (taxon 1328300), Fusarium petroliphilum (taxon 203961), Fusarium solani (taxon 169388)

## Full-text entities

- **Diseases:** fungal (MESH:D009181), cornea (MESH:D065306), cornea infections (MESH:D007239), keratitis (MESH:D007634), Fusarium keratitis (MESH:D060585)
- **Species:** Fusarium keratoplasticum (species) [taxon 1328300], Candida albicans (species) [taxon 5476], Homo sapiens (human, species) [taxon 9606], Fusarium solani species complex (species group) [taxon 232080]

## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12646002/full.md

---
Source: https://tomesphere.com/paper/PMC12646002