# Intraspecific Competition Promotes Oviposition During Host Egg Incubation in the Parasitic Fly Philornis downsi

**Authors:** Barbara Kofler, Denis Mosquera, George E. Heimpel, Heinz Richner, Sabine Tebbich

PMC · DOI: 10.1002/ece3.71892 · Ecology and Evolution · 2025-08-03

## TL;DR

A parasitic fly now lays eggs earlier due to competition, threatening Galapagos birds.

## Contribution

Intraspecific competition, influenced by host density and infestation patterns, drives oviposition during host egg incubation in Philornis downsi.

## Key findings

- Higher host density increases per-nestling infestation when infestation intensity is low.
- Under high infestation intensity, greater host density reduces per-nestling infestation and improves larval survival.
- Oviposition during host incubation is not observed in the fly's native range, suggesting behavioral divergence in Galapagos.

## Abstract

Avian biodiversity declines are increasingly linked to invasive parasites threatening local bird populations that lack evolved defenses. The level of virulence in these interactions, in turn, influences the parasites' own fitness and drives co‐evolutionary dynamics. Studying newly established host–parasite systems can shed light on adaptive processes and associated behavioral and ecological aspects. The invasive parasitic fly Philornis downsi, unintentionally introduced to the Galapagos Islands, severely threatens native bird species, including endemic Darwin's finches. Over the past decades, P. downsi infestation rates have increased, shortening nestling survival and limiting larval development. Furthermore, an earlier shift in oviposition timing has been documented, with female flies infesting incubated host nests, despite P. downsi having previously been classified as an obligate nestling parasite. In this study, we investigated the hypothesis that intraspecific competition, shaped by host density and parasite infestation patterns, drives oviposition during the incubation of bird eggs in P. downsi. Host density, interacting with mean infestation intensity of simultaneously active nests, positively influenced oviposition during host incubation, and long‐term data identified the proportion of infested nests (prevalence) as a key driver. When mean infestation intensity was low, higher host density increased per‐nestling infestation and reduced larval survival, suggesting clustered nests attract more flies. In contrast, under high mean infestation intensity, greater host density led to lower per‐nestling infestation and higher larval survival. Our findings suggest high fly competition drives the earlier shift in the parasite's life cycle, while associated trade‐offs or potential adaptive strategies may explain the observed decrease in per‐nestling infestation intensity. Moreover, oviposition during host incubation was not observed in mainland Ecuador, the native range of the ancestral P. downsi population. Despite higher Philornis species diversity, reduced competition in mainland Ecuador contrasts with high infestation rates in Galapagos, indicating rapid behavioral divergence due to increased competition in the latter location.

This study investigates the mechanisms driving an earlier shift in oviposition timing of Philornis downsi, an invasive parasitic fly threatening native Galapagos bird species, including endemic Darwin's finches. While P. downsi was historically classified as an obligate nestling parasite, recent observations in Galapagos have revealed that females now oviposit during host egg incubation. Our study identified intraspecific competition—shaped by host density and infestation patterns—as a key driver of oviposition during host incubation in P. downsi.

## Linked entities

- **Species:** Philornis downsi (taxon 450213)

## Full-text entities

- **Species:** Philornis downsi (avian vampire fly, species) [taxon 450213], Philornis (genus) [taxon 253427], Drosophila melanogaster (fruit fly, species) [taxon 7227]

## Full text

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## Figures

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## References

72 references — full list in the complete paper: https://tomesphere.com/paper/PMC12318613/full.md

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Source: https://tomesphere.com/paper/PMC12318613