Hiding in plain sight: a widespread native perennial harbors diverse haplotypes of 'Candidatus Liberibacter solanacearum' and its potato psyllid vector.

The unculturable bacterium 'Candidatus Liberibacter solanacearum' (CLso) is responsible for a growing number of emerging crop diseases. However, we know little about the diversity and ecology of CLso and its psyllid vectors outside of agricultural systems, which limits our ability to manage crop disease and understand the impacts this pathogen may have on wild plants in natural ecosystems. In North America, CLso is transmitted to crops by the native potato psyllid (Bactericera cockerelli). But the geographic and host plant range of the potato psyllid and CLso beyond the borders of agriculture are not well understood. A recent study of historic herbarium specimens revealed that a unique haplotype of CLso was present infecting populations of the native perennial Solanum umbelliferum in California decades before CLso was first detected in crops. We hypothesized that this haplotype, and other potentially novel CLso variants, are still present in S. umbelliferum populations. To test this, we surveyed populations of S. umbelliferum in Southern California for CLso and potato psyllid vectors. We found multiple haplotypes of CLso and the potato psyllid associated with these populations, with none of these genetic variants having been previously reported in California crops. These results suggest that CLso and its psyllid vectors are much more widespread and diverse in North American natural plant communities than suggested by data collected solely from crops and weeds in agricultural fields. Further characterization of these apparently asymptomatic haplotypes will facilitate comparison with disease-causing variants and provide insights into the continued emergence and spread of CLso.

The aphid Myzus persicae (Hemiptera: Aphididae) acquires chloroplast DNA during feeding on host plants.

Aphids (Hemiptera: Aphididae) extract nutrients from host plant phloem via stylets that facilitate salivation and sap uptake. When navigating to the phloem, aphids periodically puncture nonvascular cells and sample cell contents, but rarely cause significant cell damage. As a result, aphids are considered "stealthy" feeders. In contrast, insects that do cause damage, such as chewing herbivores, will take up host cell contents-including DNA-into their guts. Researchers can use molecular barcoding methods to identify recent host use patterns of chewing herbivores. This information is valuable for both pest management and basic ecological studies. Because of their stealthy feeding style, it was assumed that host plant DNA could not be recovered from aphids and other Sternorrhyncha. However, several recent studies document host plant DNA uptake by psyllids, which feed in a similar manner to aphids. Therefore, we hypothesized that aphids may also acquire DNA from host plants. Since aphids puncture and sample cytosol contents from cells, we predicted that aphids would be most likely to acquire DNA from chloroplasts. To test this, we performed host feeding and host transfer experiments with Myzus persicae (Sulzer), then used PCR to recover and sequence a region between the trnT and trnF genes from acquired chloroplast DNA. We found that M. persicae readily acquires chloroplast DNA, even prior to phloem contact, and that fragment sizes sufficient for host plant identification can be recovered. Our work suggests that molecular gut content analysis is a viable tool for studying aphid-host interactions.

Priming Melon Defenses with Acibenzolar-S-methyl Attenuates Infections by Phylogenetically Distinct Viruses and Diminishes Vector Preferences for Infected Hosts.

Plant virus management is mostly achieved through control of insect vectors using insecticides. However, insecticides are only marginally effective for preventing virus transmission. Furthermore, it is well established that symptoms of virus infections often encourage vector visitation to infected hosts, which exacerbates secondary spread. Plant defense elicitors, phytohormone analogs that prime the plant immune system against attack, may be a viable approach for virus control that complements insecticide use by disrupting pathologies that attract vectors. To explore this, we tested the effect of a commercial plant elicitor, acibenzolar-S-methyl (ASM), on infection rates, virus titers, and symptom development in melon plants inoculated with one of two virus species, Cucumber mosaic virus (CMV) and Cucurbit yellow stunting disorder virus (CYSDV). We also conducted behavioral assays to assess the effect of ASM treatment and virus inoculation on vector behavior. For both pathogens, ASM treatment reduced symptom severity and delayed disease progression. For CYSDV, this resulted in the attenuation of symptoms that encourage vector visitation and virion uptake. We did observe slight trade-offs in growth vs. defense following ASM treatment, but these effects did not translate into reduced yields or plant performance in the field. Our results suggest that immunity priming may be a valuable tool for improving management of insect-transmitted plant viruses.