# Fungal alkaloids mediate defense against bruchid beetles in field populations of an arborescent ipomoea

**Authors:** Alberto Prado, Susana Pineda-Solis, Roberto Garibay-Orijel, Donald Windsor, Jean-Luc Boevé

PMC · DOI: 10.1007/s10886-025-01578-2 · 2025-02-25

## TL;DR

This study shows that fungal alkaloids in an arborescent morning glory plant help protect its seeds from bruchid beetles in the wild.

## Contribution

The study identifies fungal endophytes and their alkaloids in Ipomoea murucoides and links them to bruchid beetle resistance in seeds.

## Key findings

- Seeds from trees with Ceramothyrium fungi had higher swainsonine and less bruchid damage.
- Five sesquiterpenes were detected in leaf trichomes of both fungal-colonized trees.
- Seed levels of tropine and tropinone did not differ between the two fungal symbionts.

## Abstract

Several Convolvulaceae species harbor heritable fungal endophytes from which alkaloids are translocated to reproductive tissues of the plant host. Evidence for the distribution and ecological role of these fungal alkaloids, however, is lacking or incomplete for many host species and growth forms. Here we report on the identity of the fungal endophytes and quantities of alkaloids present in the leaves and seeds of the arborescent morning glory, Ipomoea murucoides (Convolvulaceae). Young folded leaf samples taken from the wild, harbored mycelium of one of two fungal taxa wrapped around the leaves’ glandular trichomes. Most trees harbored the swainsonine producing Ceramothyrium (Chaetothyriales) fungi while a few trees were found to harbor a Truncatella (Xylariales) species, suggesting endophyte replacement. Seeds had higher concentrations of the indolizidine alkaloid swainsonine than leaves. Additionally, seeds from trees harboring Ceramothyrium fungi exhibited less bruchid damage and had higher concentrations of swainsonine than seeds from trees harboring Truncatella fungi. Five sesquiterpenes were detected in the leaf trichomes in both Ceramothyrium and Truncatella colonized trees. The seed content of the tropane alkaloids, tropine and tropinone, did not differ significantly among the two fungal symbionts. It is likely that the host allocates the defensive chemicals from leaves to seeds, protecting them from seed predators such as bruchid beetles. Overall, our field data show that Ipomoea species provides an interesting opportunity to study vertical and horizontal fungal symbiont transmissions.

The online version contains supplementary material available at 10.1007/s10886-025-01578-2.

## Linked entities

- **Chemicals:** swainsonine (PubChem CID 51683), sesquiterpenes (PubChem CID 139087999), tropine (PubChem CID 449293), tropinone (PubChem CID 446337)
- **Species:** Ipomoea murucoides (taxon 1393930), Ceramothyrium (taxon 66612), Truncatella (taxon 55735)

## Full-text entities

- **Chemicals:** swainsonine (MESH:D017026), sesquiterpenes (MESH:D012717), tropine (MESH:C005864), Ceramothyrium (-), tropinone (MESH:C016808), alkaloids (MESH:D000470), tropane alkaloids (MESH:D014326)
- **Species:** Ceramothyrium (genus) [taxon 66612], Sordariomycetes (class) [taxon 147550], Ipomoea murucoides (species) [taxon 1393930], Truncatella (genus) [taxon 152317]

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11850502/full.md

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Source: https://tomesphere.com/paper/PMC11850502