Timothy D. Paine

A new Huanglongbing Species, "Candidatus Liberibacter psyllaurous," found to infect tomato and potato, is vectored by the psyllid Bactericera cockerelli (Sulc).

ABSTRACT A new huanglongbing (HLB) “Candidatus Liberibacter” species is genetically characterized, and the bacterium is designated “Candidatus Liberibacter psyllaurous.” This bacterium infects the psyllid Bactericera cockerelli and its solanaceous host plants potato and tomato, potentially resulting in “psyllid yellowing.” Host plant-dependent HLB transmission and variation in psyllid infection frequencies are found.

Mechanisms and deployment of resistance in trees to insects.

Preface. Acknowledgement. 1. Resistance in trees to insects - An overview of mechanisms and interactions S. Larson. 2. Mechanisms of resistance in conifers and bark beetle attack strategies F. Lieutier. 3. Mechanisms of resistance in trees to defoliators K. Clancy. 4. Mechanisms of Resistance in Conifers against shoot infesting insects. The case of the white pine weevil Pissodes strobi (Peck): (Coleoptera: Curculionidae) R.I. Alfaro, et al. 5. Host tree resistance to wood-boring insects T.D. Paine. 6. Plant resistance against gall-forming insects: the role of hypersensititiy T.G. Cornelissen, et al. 7. The resistance of hybrid willows to specialist and generalist herbivores and pathogens: the potential role of secondary chemistry and parent host plant status J. Hjalten, P. Hallgren. 8. Deploying pest resistance in genetically-limited forest plantations: developing ecologically-based strategies for managing risk D.J. Robinson. 9. Deployment of tree resistance to insects in short-rotation Populus D.R. Coyle, et al. 10. Strategies for Deployment of Insect Resistant Ornamental Plants D.A. Herms. 11. Possibilities to utilize tree resistance to insects in forest pest management in central and western Europe C.H. Heidger, F. Lieutier. 12. Deployment of tree resistance to pests in Asia N. Kamata. 13. Using Resistance in Tropical Forest Plantations J.D. Nichols, et al. Index.

Frequency of secondary symbiont infection in an invasive psyllid relates to parasitism pressure on a geographic scale in California.

ABSTRACT Two endosymbionts, an obligate primary symbiont and a facultative secondary symbiont, are harbored within the invasive red gum (eucalyptus) lerp psyllid, Glycaspis brimblecombei, in California. An extensive survey of diversity and frequency of G. brimblecombeis secondary symbiont in multiple populations throughout the state of California was conducted using PCR detection, restriction enzymes, cloning, and sequencing. A total of 380 G. brimblecombei individuals in 19 populations were screened for secondary symbionts. Based on molecular screening results, only one type of secondary symbiont was present in G. brimblecombei populations in California. Overall, 40% of the 380 psyllids screened were infected with the secondary symbiont. Interestingly, secondary symbiont infection frequencies in G. brimblecombei populations varied dramatically from 0 to 75% and were significantly related to parasitism pressure by Psyllaphaegus bliteus, a solitary endoparasitoid of the psyllid.

Native and Exotic Pests of Eucalyptus: A Worldwide Perspective

Eucalyptus species, native to Australia, Indonesia, the Philippines, and New Guinea, are the most widely planted hardwood timber species in the world. The trees, moved around the globe as seeds, escaped the diverse community of herbivores found in their native range. However, a number of herbivore species from the native range of eucalypts have invaded many Eucalyptus-growing regions in North America, Europe, Africa, Asia, and South America in the last 30 years. In addition, there have been shifts of native species, particularly in Africa, Asia, and South America, onto Eucalyptus. There are risks that these species as well as generalist herbivores from other parts of the world will invade Australia and threaten the trees in their native range. The risk to Eucalyptus plantations in Australia is further compounded by planting commercially important species outside their endemic range and shifting of local herbivore populations onto new host trees. Understanding the mechanisms underlying host specificity of Australian insects can provide insight into patterns of host range expansion of both native and exotic insects.

Behavior and biology of the tomato psyllid, Bactericerca cockerelli, in response to the Mi-1.2 gene

The Mi‐1.2 gene, identified from wild varieties of tomato, Solanum peruvianum (Mill) (Solanaceae), has been incorporated into near‐isogenic commercial varieties of tomato and has been shown to confer resistance to three different species of phloem feeders: aphids, whiteflies, and nematodes. The results presented here show that plants bearing Mi‐1.2 were also resistant to the tomato psyllid, Bactericerca [Paratrioza] cockerelli (Sulc) (Homoptera: Psyllidae), a serious pest of tomato, Solanum lycopersicon (Mill), in the western half of North America. In choice studies, tomato psyllids preferred to settle on plants that did not contain the gene [Moneymaker (mi‐1.2)] compared to near‐isogenic plants with the gene [Motelle (Mi‐1.2)]. As a result, total oviposition was higher on the susceptible variety, although no‐choice studies indicated that there were no differences in numbers of eggs laid by individual females on either variety. Survival from egg to adult was higher on plants lacking the gene compared to plants containing the gene. However, there were no differences in total development time of individuals reared from either variety. The results suggest that mechanisms of resistance to the tomato psyllid observed in plants bearing the Mi‐1.2 gene are distinct from the mechanisms of resistance to the three phloem feeders examined in other studies.

Water relations of host trees and resistance to the phloem-boring beetle Phoracantha semipunctata F. (Coleoptera: Cerambycidae).

Abstract Environmental stresses, particularly water deficit, predispose eucalypt trees to attack by the eucalyptus longhorned borer, Phoracantha semipunctata F. (Coleoptera: Cerambycidae). Our experiments with potted eucalypts revealed that reduced tree water potential was associated with lower resistance to colonization by neonate P. semipunctata, but the linear relationship between water potential and colonization success was reversed at higher larval densities. There was no indication that the bark exudate “kino” served to defend trees from borer attack. Larvae were not able to colonize the cambium of eucalypt logs with high bark moisture, and survival was low under high moisture conditions in artificial hosts composed of pure cellulose. In trees and cut logs with moist bark, larvae failed to reach the cambium, feeding instead in poorer-quality tissues just beneath the bark surface. Our findings suggest that variation in resistance of eucalypts to attack by the borer is associated with moisture content of the bark.

Host species preference and larval performance in the wood-boring beetle Phoracantha semipunctata F.

Adults of the wood-boring beetlePhoracantha semipunctata F. showed variability in their attractiveness to five varieties ofEucalyptus when presented with an array of logs in a natural setting. Logs of two host varieties (E. camaldulensis Dehnhardt and the hybridE. trabutii) attracted two to three times more adult beetles than did logs of other host species (E. cladocalyx F.,E. grandis Hill ex Maiden andE. tereticornis Small). In the field, high oviposition rates byP. semipunctata adults resulted in severe competition among larvae. Larval survivorship was low in field logs ofE. trabutii and high inE. cladocalyx logs, although these hosts were the most and least attractive to the adult beetles, respectively. However, when logs were hand infested at low larval densities, survivorship ofP. semipunctata larvae was highest in logs of bothE. camaldulensis andE. trabutii. These findings suggest that adult beetles in the field were most attracted to those logs ofEucalyptus species that represented the highest quality hosts for their progeny under conditions of reduced larval competition.

Mating behavior of the eucalyptus longhorned borer (Coleoptera: Cerambycidae) and the adaptive significance of long “horns”

Sexual dimorphism in insect antennal structure is often attributed to differences between the sexes in sensitivity to pheromones, the antennae of one sex being more elaborately structured (for example, plumose). Males of the family Cerambycidae (order Coleoptera) often have longer antennae than females, but of a similar general structure, suggesting that selective factors other than sensitivity to pheromones are at work. Both sexes of the eucalyptus longhorned borer, a cerambycid, were attracted to eucalyptus logs that were larval hosts. There, males located females by antennal contact, and male mating success therefore depended on the walking rate and width of the antennal spread. Elongate antennae may benefit males by increasing antennal spread width, but have no such advantage for females, suggesting an evolutionary explanation for sexual dimorphism.

Body size influences mating success of the Eucalyptus longhorned borer (Coleoptera: Cerambycidae).

Both sexes of adultPhoracantha semipunctata F. (Coleoptera: Cerambycidae) congregate on stressedEucalyptus that are the larval hosts. In a field study, 721 adultP. semipunctata captured on host trees varied considerably in body size with the largest individuals being about twice the length of the smallest. Females that were paired with a mate were similar in size to solitary females, suggesting that the probability of a female being mated was not affected by her size. However, large males had greater success than smaller males in obtaining mates. MaleP. semipunctata rely on antennal contact to locate and identify females on the larval host. Therefore, the rate at which males search for mates is a function of the area swept by their antennae per unit time. Because of their greater antennal spread, large males were able to search for females at double the rate of the smallest males. Large males also dominated in aggressive contests for females. The superior abilities of large maleP. semipunctata in both locating and defending mates account for the influence of body size on mating success.

Manipulation of plant defense responses by the tomato psyllid (Bactericerca cockerelli) and its associated endosymbiont Candidatus Liberibacter psyllaurous.

Some plant pathogens form obligate relationships with their insect vector and are vertically transmitted via eggs analogous to insect endosymbionts. Whether insect endosymbionts manipulate plant defenses to benefit their insect host remains unclear. The tomato psyllid, Bactericerca cockerelli (Sulc), vectors the endosymbiont “Candidatus Liberibacter psyllaurous” (Lps) during feeding on tomato (Solanum lycopersicum L.). Lps titer in psyllids varied relative to the psyllid developmental stage with younger psyllids harboring smaller Lps populations compared to older psyllids. In the present study, feeding by different life stages of B. cockerelli infected with Lps, resulted in distinct tomato transcript profiles. Feeding by young psyllid nymphs, with lower Lps levels, induced tomato genes regulated by jasmonic acid (JA) and salicylic acid (SA) (Allene oxide synthase, Proteinase inhibitor 2, Phenylalanine ammonia-lyase 5, Pathogenesis-related protein 1) compared to feeding by older nymphs and adults, where higher Lps titers were found. In addition, inoculation of Lps without insect hosts suppressed accumulation of these defense transcripts. Collectively, these data suggest that the endosymbiont-like pathogen Lps manipulates plant signaling and defensive responses to benefit themselves and the success of their obligate insect vector on their host plant.