Insect Science

AbstractThe black curry leaf psyllid, Diaphorina communis, is a host of the citrus pathogen, ‘Candidatus Liberibacter asiaticus’ (‘CLas’). However, there is a paucity of information on its biology; hence, this study was conducted to evaluate survival and development on citrus, in this instance mandarin (Citrus reticulata) and curry leaf (Bergera koenigii), and transmission of ‘CLas’. Given its similarity with the Asian citrus psyllid (Diaphorina citri), sequences of the COI and 16S genes were examined to see if they could distinguish molecularly between nymphs of these two species. Field and laboratory experiments showed that D. communis nymphs transferred to mandarin branches failed to survive. Adults could survive on flush growth of ‘CLas’‐infected mandarin trees; however, little oviposition took place, and the single resulting nymph did not survive to the second instar. These observations suggest that D. communis does not develop, or rarely develops on mandarin and possibly other Citrus spp. Curry leaf appears to be its preferred host, and complete development can take place, possibly exclusively, on this species. Studies on acquisition of ‘CLas’ by D. communis and possible transmission assessed in 2014 and 2015 using greenhouse‐grown curry leaf and mandarin seedlings with naturally infected mandarin stumps as a source of ‘CLas’ indicated a low acquisition rate of ‘CLas’. In addition, although D. communis can acquire ‘CLas’, it either cannot transmit it or transmission is limited, and the pathogen may not multiply within the insect. Phylogenetic analyses indicate that differences in COI and 16S regions may prove useful for differentiating between early instar D. communis and D. citri nymphs when fifth instar nymphs and adults are not present on host plants.

Beetles are hosts to a remarkable diversity of bacterial symbionts. In this article, we review the role of these partnerships in promoting beetle fitness following a surge of recent studies characterizing symbiont localization and function across the Coleoptera. Symbiont contributions range from the supplementation of essential nutrients and digestive or detoxifying enzymes to the production of bioactive compounds providing defense against natural enemies. Insights on this functional diversity highlight how symbiosis can expand the host's ecological niche, but also constrain its evolutionary potential by promoting specialization. As bacterial localization can differ within and between beetle clades, we discuss how it corresponds to the microbe's beneficial role and outline the molecular and behavioral mechanisms underlying symbiont translocation and transmission by its holometabolous host. In reviewing this literature, we emphasize how the study of symbiosis can inform our understanding of the phenotypic innovations behind the evolutionary success of beetles.

Autophagy, also known as type II programmed cell death, is a cellular mechanism of “self-eating”. Autophagy plays an important role against pathogen infection in numerous organisms. Recently, it has been demonstrated that autophagy can be activated and even manipulated by plant viruses to facilitate their transmission within insect vectors. However, little is known about the role of autophagy in the interactions of insect vectors with plant bacterial pathogens. ‘Candidatus Liberibacter solanacearum’ (Lso) is a phloem-limited Gram-negative bacterium that infects crops worldwide. Two Lso haplotypes, LsoA and LsoB, are transmitted by the potato psyllid, Bactericera cockerelli and cause damaging diseases in solanaceous plants (e.g., zebra chip in potatoes). Both LsoA and LsoB are transmitted by the potato psyllid in a persistent circulative manner: they colonize and replicate within psyllid tissues. Following acquisition, the gut is the first organ Lso encounters and could be a barrier for transmission. In this study, we annotated autophagy-related genes (ATGs) from the potato psyllid transcriptome and evaluated their expression in response to Lso infection at the gut interface. In total, 19 ATGs belonging to 17 different families were identified. The comprehensive expression profile analysis revealed that the majority of the ATGs were regulated in the psyllid gut following the exposure or infection to each Lso haplotype, LsoA and LsoB, suggesting a potential role of autophagy in response to Lso at the psyllid gut interface.