Predators and parasitoids of the harlequin ladybird, Harmonia axyridis, in its native range and invaded areas

2018

Piotr Ceryngier, Oldřich Nedveěd, Audrey A. Grez, Eric W. Riddick, Helen E. Roy, Gilles San Martin, Tove Steenberg, Petr Veselý, Tania Zaviezo, Álvaro Zúniga-Reinoso, Danny Haelewaters

DOI: 10.1007/s10530-017-1608-9


Abstract:

The harlequin ladybird Harmonia axyridis (Coleoptera: Coccinellidae) has rapidly spread in several continents over the past 30 years and is considered an invasive alien species. The success of H. axyridis as an invader is often attributed to weak control by natural enemies. In this paper, we provide an overview of current knowledge on predators and parasitoids of H. axyridis. The common feature of predators and parasitoids is that they directly kill exploited organisms. Currently available data show
that H. axyridis, displaying a variety of chemical, mechanical, and microbiological anti-predator defenses, is usually avoided by predators. However, some birds and invertebrates can eat this ladybird without harmful consequences. The primary defenses of H. axyridis against parasitoids include immune response and physiological and nutritional unsuitability for parasitoid development. These defenses are probably relatively efficient against most ladybird parasitoids, but not against flies of the genus Phalacrotophora. The latter are idiobiont parasitoids and hence can evade the host’s immune response. Indeed, rates of parasitism of H. axyridis by Phalacrotophora
in the Palaearctic region (both in the native range in Asia and in Europe) are relatively high. While strong evidence for enemy release on the invasive populations of H. axyridis is lacking, several cases of parasitoid acquisition have been recorded in
Europe, North America, and South America. We conclude that enemy release cannot be excluded as a possible mechanism contributing to the spread and increase of H. axyridis in the early stages of invasion, but adaptation of parasitoids may lead to novel
associations which might offset previous effects of enemy release. However, further work is required to elucidate the population-level effects of such interactions.


Back to scientific papers.