A New Galling Insect Model Enhances Photosynthetic Activity in an Obligate Holoparasitic Plant

Overview

Journal Sci Rep

Specialty Science

Date 2021 Jun 22

PMID 34155293

Citations 7

Authors

Ryo Murakami

Ryo Ushima

Ryoma Sugimoto

Daisuke Tamaoki

Ichirou Karahara

Yuko Hanba

Tatsuya Wakasugi

Tsutomu Tsuchida

Affiliations

Soon will be listed here.

Abstract

Insect-induced galls are microhabitats distinct from the outer environment that support inhabitants by providing improved nutrients, defence against enemies, and other unique features. It is intriguing as to how insects reprogram and modify plant morphogenesis. Because most of the gall systems are formed on trees, it is difficult to maintain them in laboratories and to comprehend the mechanisms operative in them through experimental manipulations. Herein, we propose a new model insect, Smicronyx madaranus, for studying the mechanisms of gall formation. This weevil forms spherical galls on the shoots of Cuscuta campestris, an obligate parasitic plant. We established a stable system for breeding and maintaining this ecologically intriguing insect in the laboratory, and succeeded in detailed analyses of the gall-forming behaviour, gall formation process, and histochemical and physiological features. Parasitic C. campestris depends on host plants for its nutrients, and usually shows low chlorophyll content and photosynthetic activity. We demonstrate that S. madaranus-induced galls have significantly increased CO absorbance. Moreover, chloroplasts and starch accumulated in gall tissues at locations inhabited by the weevil larvae. These results suggest that the gall-inducing weevils enhance the photosynthetic activity in C. campestris, and modify the plant tissue to a nutrient-rich shelter for them.

Citing Articles

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