Abstract
AbstractSap-feeding hemipteran insects live in associations with diverse heritable endosymbiotic bacteria and fungi that provide essential nutrients deficient in their diets. These symbionts typically reside in bacteriomes, dedicated organs made up of specialized cells termed bacteriocytes. The bacteriome organization varies between insect clades that are ancestrally associated with different microbes. As these symbioses evolve and additional microorganisms complement or replace the ancient associates, the organization of the symbiont-containing tissue becomes even more variable.Planthoppers (Hemiptera: Fulgoromorpha) are ancestrally associated with bacterial symbiontsSulciaandVidania, but in many of the planthopper lineages, these symbionts are now accompanied or have been replaced by other heritable bacteria (e.g.,Sodalis, Arsenophonus, Purcelliella) or fungi. We know the identity of many of these microbes, but the symbiont distribution within the host tissues and the bacteriome organization have not been systematically studied using modern microscopy techniques.Here, we combine light, fluorescence, and transmission electron microscopy with phylogenomic data to compare symbiont tissue distributions and the bacteriome organization across planthoppers representing 15 families. We identify and describe seven primary types of symbiont localization and seven types of the organization of the bacteriome. We show thatSulciaandVidania, when present, occupy distinct bacteriomes distributed within the body cavity. The more recently acquired gammaproteobacterial and fungal symbionts generally occupy separate groups of cells organized into distinct bacteriomes or mycetomes, distinct from those withSulciaandVidania. They can also be localized in the cytoplasm of fat body cells. Alphaproteobacterial symbionts colonize a wider range of host body habitats:Asaia-like symbionts often colonize the host gut lumen, whereasWolbachiaandRickettsiaare usually scattered across tissues and cell types, including bacteriocytes containing other symbionts, bacteriome sheath, fat body cells, gut epithelium, as well as hemolymph. However, there are exceptions, including Gammaproteobacteria that share bacteriome withVidania, or Alphaproteobacteria that colonizeSulciacells.We discuss how planthopper symbiont localization correlates with their acquisition and replacement patterns and the symbionts’ likely functions. We also discuss the evolutionary consequences, constraints, and significance of these findings.
Publisher
Cold Spring Harbor Laboratory