- Author: Mark Hoddle
Avocado leaves infested with trioza was intercepted in March at the San Diego/Mexico border. Avocado leavers are used to wrap tamales. Trioza infested leaves make a tastier tamale.
Introduction
 Figure 1. Adult Trioza on a Hass avocado leaf. |
Four species of Trioza are currently known to attack avocado foliage and nymphal feeding causes some form of leaf deformation. Trioza anceps Tuthill is associated with avocados throughout Mexico and Central America. Trioza perseae Tuthill has been described from avocados growing in Peru, and Trioza aguacatae Hollis and Martin and Trioza godoyae Hollis and Martin are known from avocados in Michoacan Mexico, and San Jose Costa Rica, respectively (Hollis and Martin 1997).
All four Trioza spp. appear to have an extremely restricted host range and have only been recorded from leaves of avocados (Persea americana). Further, under some circumstances certain Trioza species (e.g., T. perseae) may even be restricted to particular races of P. americana, which is suggestive of extreme monophagy and host specialization (Hollis and Martin, 1997).
Trioza species have been found on smuggled avocado plants intercepted in San Antonio and Brownsville in Texas, and San Diego in California (Texas and California are states in the USA) (Hollis and Martin 1997). Currently, none of the four Trioza species known to attack avocado leaves are present in the major avocado growing states of the USA (i.e., California, Florida, Texas, and Hawaii). However, given the relatively close proximity of Mexico to California , the high daily volume of tourism, traffic (road, rail, sea, and air), and trade across the California-Mexico border, and the potential for illegal movement of plant material through these identifiable conduits, Trioza anceps and T. aguacatae have high invasion and establishment potential should they be illegally moved on avocado plants that are introduced into California. Consequently, Trioza species represent a serious biosecurity risk for California (the largest avocado producing region in the USA at ~65,000 acres), and other minor avocado producing areas in the USA (especially Texas and Florida).
Around 58 species of psyllids (~2% of described species) are associated with host plants in the Lauraceae, the plant family to which avocados belong. The majority of these psyllid species, ~72% of them, belong to the family Triozidae which contains the genus Trioza, of which ~64% cause some type of leaf deformation to their lauraceous hosts (Hollis and Martin 1997).
| Pest Identification and Biology |
 Figure 2. The characteristic feeding position adopted by adults. |
 Figure 3. Adult Trioza sp. from Guatemala on avocado leaves |
 Figure 4. Trioza nymph inside an opened gall removed from a Hass avocado leaf in Guatemala. |
 Figure 5. A Trioza nymph on exuviae on Hass avocado leaves.< |
Adult Trioza. Trioza species adults are small (~3mm in length), winged, and depending on the species, coloration is either pale green or brown with ochraceous markings. Forewings are hyaline with pronounced veination that may be useful for species identifications. Adults have been observed feeding on avocado leaves, presumably imbibing phloem. Female Trioza species probably oviposit eggs into young avocado leaves by partially inserting them into leaf tissue with the ovipositor. Virtually nothing is known about the basic developmental and reproductive biology and ecology of Trioza species associated with avocados and these are important areas of research in need of attention.
Trioza nymphs. Nymphs are the life stage responsible for causing characteristic deformaties to avocado leaves. Trioza species normally have five nymphal instars before molting to the adult stage. Female T. anceps, T. aguacatae, and T. godoyae apparently lay eggs on the underside of young tender avocado leaves. Nymphs of T. anceps and T. aguacatae upon emerging from eggs create a "pit" within which they commence feeding. As nymphs mature, they induce the formation of protective galls within which they feed. Galls are typically conical vertical growths of leaf material that form on the leaf surface opposite to which the feeding pit is initiated. Typically this is the upper leaf surface for T. anceps and T. aguacatae. T. perseae nymphs apparently feed in pits on the upper leaf surface which then causes gall formation on the lower surface of the leaf (Hollis and Martin 1997). T. godoyae nymphs do not form projecting galls, instead nymphs of this species cause the edges of leaves to roll and feeding occurs within these protective structures (Hollis and Martin 1997).
Very little, if anything, is known about the physiology of gall induction by Trioza species associated with avocados, how nutrition is acquired from within galls, factors influencing development (e.g., temperature, avocado race, leaf age, exposure of leaves to sun and shade, and densities of nymphs and galls per leaf).
| Feeding Damage |
Nymphal Trioza spp. induce galls that either develop on the upper or lower leaf surface, or they cause leaf margins to roll. The type of leaf damage observed on avocados is dependent on the species of Trioza infesting the plant. Trioza anceps and T. aguacate cause galls to develop on the upper leaf surface, T. perseae induces gall formation on the lower leaf surface, while T. godoyae infestations result in leaf margins curling.
Attacks by Trioza magnoliae on redbay (Persea borbonia) appear to more intense when plants are shaded, and galled leaves tend to be smaller, senesce more rapidly, and shoots with galled leaves grow less in comparison to shoots lacking galled leaves (Leege 2006). These field observations of T. magnoliae on P. borbonia suggest that gall induction negatively affects plant growth and reproduction (Leege 2006). Consequently, it is possible that Trioza species attacking avocados have similar negative impacts on this host plant. Therefore, it is not surprising that reports from Mexico indicate that heavy Trioza sp. infestations can cause premature leaf defoliation which reduces avocado fruit production (Ebeling 1950, Hernandez et al., 2000).
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| Natural Enemies as Biological Control |
There are no readily available published records on the natural enemy fauna associated with Trioza species that induce galls in avocados. It is likely that there are specialist hymenopterous parasitoids attacking Trioza nymphs within galls that await discovery in countries with endemic Trioza species. Discovery, identification, and study of these parasitoids, should they exist, could be very important for developing IPM programs in areas with naturally-occurring Trioza species. Knowledge of these natural enemies could be invaluable for future biological control programs against invasive Trioza species in countries with avocado industries that currently lack this pest. Adult Trioza are probably opportunistically preyed upon by generalist natural enemies (e.g., lace wing larvae, spiders, and coccinellids) on avocados.
Many species of psyllids are known to have parasitoids (e.g., Hymenoptera: Eulophidae) that attack nymphs. Some species of invasive psyllid attacking agriculturally important crops has been subjected to classical biological control (e.g., Asian citrus psyllid, Diaphorina citri in Florida with Tamarixia radiata (Waterston) [Hymenoptera: Eulophidae]). Invasive pest psyllids attacking landscape ornamentals have been controlled with specialist natural enemies also (e.g., Eugnenia psyllid, Trioza eugeniae, has been suppressed in parts of California with Tamarixia sp.).
- Author: Ben Faber
Along the coast, it is very common to see windbreaks protecting the citrus and avocado groves. Invariably the first two rows next to the eucalyptus trees are shorter and less thrifty than the citrus further away from the windbreak. This is due to competition primarily for water, but somewhat due to light, as well. Often by putting emitters on the windbreak, the completion stops. Growers will also root prune between the windbreak and the first row of citrus. Those roots inevitably grow back and pruning must be done again. This also occurs in areas where there are oak trees or other natives that are planted in or around the orchard. Growers will frequently plant right up to the canopy or even under the canopy of the native tree(s), with a similar result seen with windbreaks.
It is important to remember the architecture of roots. Not all trees are exactly alike, but a general rule of thumb is that the active roots go out one and half times the height of the tree. So a 40 foot tree will have competitive roots out 60 feet away from the trunk. That’s why it is best to keep a distance away from a competing tree, because avocados and citrus are just not as competitive as an oak or eucalyptus.
In low rainfall years, this competition is even more intense. Significant defoliation of the crop plant can be seen. The grower then thinks that it is some disease and ponders what to spray, when they should actually be spraying more water.
- Author: Ben Faber
A microirrigaiton workshop on use and maintainence of systems in Spanish is being held on three successive dates in San Luis Obispo, Ventura and Fallbrook. These are the same workshop held on July 23, 24 and 25 in the respective areas. The workshops are intended for Spanish speaking workers who maintain and use microirrigation systems. The classes are free and no registration is required. These and future workshops are funded by USDA. For more information contact Lesa Scarborough at:
administration@californiaavocadosociety.org
951-225-9102 Office
951-225-9198 FAX
Click on the flyer below for more details
Irrigation flyer
- Author: Akif Eskalen and Virginia McDonald
Branch and trunk canker on avocado was formerly attributed to Dothiorella gregaria, hence the name Dothiorella canker. So far Botryopshaeria dothidea (anamorph: Fusicoccum aesculi) is the only known species causing Dothiorella canker on avocado in California. Symptoms observed on avocado with Dothiorella canker include shoot blight and dieback, leaf scorch, fruit rot, and cankers on branches and bark.
However, recent studies based on DNA analyses suggest greater species diversity of this pathogen group than based on morphological characteristics alone. Thus far, multiple species of Botryosphaeriaceae have been found to cause the typical Dothiorella canker (Fig3.) and stem-end rot (Fig 5) on avocado in California. Percent recovery of Botryosphaeria spp. based on morphological characters ranged from 40-100% in Riverside county, 42-53% in Ventura county, 33% in Santa Barbara county, 60% in San Diego county and 32-60% in San Luis Obispo county.
According to preliminary results from a continuing survey throughout avocado growing areas of California, multiple species of Botryosphaeria (Neofusicoccum australe, B. dothidea, N. luteum, and N. parvum) were found.
Pycnidia (overwintering structure) of Botryosphaeriaceae species were also observed on old diseased avocado tree branches. Sequenced rDNA fragments (ITS1, 5.8S rDNA, ITS2, amplified with ITS4 and ITS5 primers) were compared with sequences deposited in GenBank.
Pathogenicity tests were conducted in the greenhouse on 1-year-old avocado seedlings, Hass cv., with one randomly chosen isolate from each of the Botryosphaeriaceae species noted above. Four replicate seedlings were stem-wound inoculated with a mycelial plug and covered with Parafilm. Sterile PDA plugs were applied to four seedlings as a control. Over a period of 6 months, seedlings were assessed for disease symptoms that included browning of leaf edges and shoot dieback. Mean vascular lesion lengths on stems were 64, 66, 64, and 18 mm for B. dothidea, N. parvum, N. luteum, and N. australe, respectively. Each fungal isolate was consistently reisolated from inoculated seedlings, thus completing the pathogenicity test. To our knowledge, this is the first report of N. australe, N. luteum, and N. parvum recovered from branch cankers on avocado in California.
These results are significant because Botryosphaeriaceae canker pathogens are known to enter the host plant through fresh wounds (pruning, frost, and mechanical). With high-density planting becoming more common, which requires intensive pruning, the transmission rate of these pathogens could increase in California avocado groves. The Eskalen laboratory is currently investigating control measures for dothiorella canker and stem-end rot pathogens.
Branch dieback and trunk canker caused by the fungus
- Author: Akif Eskalen, Richard Stouthamer, S.C. Lynch, M. Twizeyimana, A. Gonzalez and T. Thibault
The polyphagus shot hole borer (PSHB) is an invasive beerle that forms a symbiosis with a new, as-yet-undescribed Fusarium sp., together causing Fusarium dieback on avocado and hother host plants in California and Israel. In California, PSHB was frist reported on black locust in 2003, but there were no reords of fungal damage until 2012, when Fusarium was recovered from the tissues of several bakyard avocado trees infested with PSHB in Los Angeles County. A study was conducted recently to determine the plant host range of the beerle-fungus complex in two heavily infested botanical gardens in Los Angeles County. Of the 335 tree species observed, 207 representing 58 plant families, showed signs and symptoms consisten with attack by PSHB. The fungs was revcovered from 54% of the plant species attacked by PSHB, indcated by the presence of the fungus at the site of the enty hole. Trees attacked by PSHB included 11 species of California natives, 13 agriculturally important species and many common street trees. Survey results also revealed 19 tree species that function as reproductive hosts for PSHB. Additionally, approximately a quarter of all tree indiviuals planted along the streets of southern California belong to a species classified as a reproductive host. The results suggest that the pest-disease compex could establish in a variety of plant communities locally and worldwide.
