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American palm cixiid Haplaxius crudus Van Duzee (Insecta: Hemiptera: Cixiidae)

Brian W. Bahder

Introduction

The American palm cixiid, Haplaxius crudus, is a common insect species that belongs to the order Hemiptera, family Cixiidae. It is widespread and abundant in the state of Florida, but also occurs as far north as South Carolina and as far west as Texas. Furthermore, it is common throughout the Caribbean basin. This insect feeds on a wide variety of palm species as adults while the immature stages feed on a diversity of grass species (over 40). This species is of high economic concern due to its ability to transmit the lethal yellowing (LY) phytoplasma (Howard and Thomas 1980) and is also the putative vector of lethal bronzing (LB) phytoplasma, both of which are fatal diseases of palms.

Description

Adults

Adults of Haplaxius crudus (Figure 1) are the most commonly encountered life stage and are approximately 2.5 to 3 mm long. Females are slightly longer and more robust than males with a sword-like ovipositor. Both males and females are a light yellow color, however females in general are darker in color with the abdomen having an olive/brownish hue. Males are a much brighter yellow over the entire body with parts of the abdomen either being orange or green. However, color is inconclusive for species determination and confirmation can only be attained by observing features present in the male genitalia (Figure 2) using a microscope. There are five nymphal instars (life stage between each time the insect sheds its exoskeleton) that are generally white in color with grey hue to the head and thorax and covered in many wax-producing pits (Figure 3). First instar: First instar nymphs are approximately 0.5 mm long, second instars: approximately 1 mm long, third instars: approximately 1.5 mm, fourth instars: approximately 2 mm, and fifth instar nymphs: approximately 2.5 mm long.

Adult Haplaxius crudus: A) dorsal view of female, B) lateral view of female, C) dorsal view of male, and D) lateral view of male; scale bar = 1mm .
Figure 1. Adult Haplaxius crudus: A) dorsal view of female, B) lateral view of female, C) dorsal view of male, and D) lateral view of male; scale bar = 1mm .
Credit: Brian Bahder

 

Genitalia of male Haplaxius crudus used for species confirmation: A) left lateral view of aedeagus, B) right lateral view of aedeagus, C) ventral view of terminalia, and D) lateral view of terminalia; illustrations from Kramer 1979.
Figure 2. Genitalia of male Haplaxius crudus used for species confirmation: A) left lateral view of aedeagus, B) right lateral view of aedeagus, C) ventral view of terminalia, and D) lateral view of terminalia; illustrations from Kramer 1979.
Credit: Brian Bahder

Life Cycle

The immature lifestages of Haplaxius crudus are small and rather cryptic due to their preferred habitat (thatch layer of grasses). Eggs are laid at the base of grasses, often in the thatch layer of common turfgrass species. It takes anywhere from 10 to 20 days for the eggs to hatch. The duration of each instar is approximately one week under warm conditions, going from egg to adult in 1.5 months (at 30°C) (Tsai and Kirsch 1978). All nymphal instars are strict grass feeders. After adults emerge, they migrate into palm canopies where they feed exclusively on palm foliage for the duration of their adult life. When mating occurs, it is initiated in the palm canopy where males and females find each other using vibrational signals on the leaf surface. Mating pairs can easily be found on palm foliage during the correct time of year (usually spring, however mating can occur year-round in the southern half of the state). After copulation, females migrate into appropriate grass hosts to lay eggs (an average of 13, but ranging from 5 to 31).

Immature life stages of Haplaxius crudus: A) dorsal view of female 1st instar, B) dorsal view of 2nd instar, C) dorsal view of 3rd instar, D) dorsal view of 4th instar, and E) dorsal view of 5th instar; scale bar = 0.5 mm
Figure 3. Immature life stages of Haplaxius crudus: A) dorsal view of female 1st instar, B) dorsal view of 2nd instar, C) dorsal view of 3rd instar, D) dorsal view of 4th instar, and E) dorsal view of 5th instar; scale bar = 0.5 mm
Credit: Brian Bahder

Host Range

As adults, H. crudus only feeds on palm (Arecaceae) foliage (Figure 4). Within the Arecaceae, it has a wide host range, having been collected on more than 30 species of palms. While it does seem to be more readily collected on coconut palm (Cocos nucifera), this could be due to surrounding grassy habitat generally associated with coconut plantations rather than true host preference. Nymphs have been documented from over 40 different species of grasses and sedges throughout the Neotropics. However, in Florida the preferred host in the urban landscape is St. Augustinegrass (Reinert 1980).

Adults of Haplaxius crudus feeding on palm foliage, white arrow on left indicates feeding adult, with close up on right.
Figure 4. Adults of Haplaxius crudus feeding on palm foliage, white arrow on left indicates feeding adult, with close up on right.
Credit: De-fen Mou

Economic Importance

Haplaxius crudus is considered to be of major economic importance. In the 1970s and 1980s, H. crudus was confirmed as the vector of lethal yellowing (LY) (Figure 5), a disease caused by the 16SrIV-A phytoplasma that is lethal to a wide variety of economically important palm species in Florida. Throughout the Caribbean basin, LY has resulted in the death of millions of coconut palms, thus causing severe economic losses to both ornamental and agricultural sectors of many Caribbean nations. Haplaxius crudus is also the putative vector of lethal bronzing (LB) in Florida (Figure 5). It is important to note that in the absence of phytoplasma diseases, H. crudus causes no damage to palms that it feeds on. Due to the biology of the phytoplasmas, only a small proportion (less than 1%) of H. crudus are carrying the phytoplasma in the wild but due to the widespread distribution and abundance of H. crudus, this is enough to cause persistent disease pressure in the urban landscape and in nurseries.

Palms infected with palm lethal decline phytoplasmas; A) coconut palm infected with lethal yellowing (LY) in Jamaica and B) cabbage palm infected with lethal bronzing (LB) in Florida.
Figure 5. Palms infected with palm lethal decline phytoplasmas; A) coconut palm infected with lethal yellowing (LY) in Jamaica and B) cabbage palm infected with lethal bronzing (LB) in Florida.
Credit: Brian Bahder

 

Sampling and Management

Currently, the most time and cost effective method to sample for adults of H. crudus is by placing yellow sticky traps in the canopy of palms that are accessible from the ground (Figure 6). During peak adult activity, this method can capture over 300 individuals after about two weeks’ time. Adults can also be readily collected by sweep-netting palm canopies if living insects are needed. Finally, adults readily come to lights at night, so light-trapping with a mercury vapor lamp is also a useful collection method. Nymphs are far more difficult to reliably sample due to grasses covering a much large ground area than palms. Because of their cryptic habitat, yellow sticky traps, sweep netting and light trapping are not effective for sampling. Currently, the optimal strategy for collecting nymphs is by use of a Berlese funnel where clumps of grass and a thin layer of dirt/roots are dug up (Figure 6) and placed upside down inside the funnel and a light is turned on to heat the samples. As the grass dries, nymphs try to escape the light/heat and move downward, falling into a container with 95% ethanol. This method is labor intensive and not cost effective and is only recommended for specific research needs, however may be needed by nurseries in the future to supplement management programs.

As part of the palm phytoplasma diagnostic clinic at FLREC, processing of yellow sticky traps to determine presence/absence of H. crudus and if the local population carries the phytoplasma is now offered as an available service to all interested stakeholders. Sample submission forms and instructions can be found at www.bahderlab.com under the “Services” tab.

Current recommendations for management primarily involve weed/grass management in nurseries, systemic treatments of palms with dimethoate, and contact treatments against nymphs using diazinon (Howard and McCoy 1980). Both dimethoate and diazinon are commericially available. For grass management in nurseries, the current recommendation is to remove any and all grasses and replace with none monocot cover-crop. Research is ongoing to determine what chemical compounds and forumlations can be used effectively in grasses in nurseries to control populations of H. crudus.

Example of sampling protocol for collecting Haplaxius crudus; A) yellow sticky traps in palm canopies for adults, indicated by white arrow and B) grass/soil samples for nymphs in Berlese funnel.
Figure 6. Example of sampling protocol for collecting Haplaxius crudus; A) yellow sticky traps in palm canopies for adults, indicated by white arrow and B) grass/soil samples for nymphs in Berlese funnel.
Credit: Brian Bahder

Selected References

Howard, F.W. and McCoy, R.E., 1980. Reduction in spread of mycoplasma-like organism-associated lethal decline of the palm, Veitchia merrilli, by use of insecticides. Journal of Economic Entomology73(2), pp.268-270.

Howard, F.W. and Thomas, D.L., 1980. Transmission of palm lethal decline to Veitchia merrillii by a planthopper Myndus crudus. Journal of Economic Entomology73(5), pp.715-717.

Reinert, J.A., 1980. Phenology and density of Haplaxius crudus (Homoptera: Cixiidae) on three southern turfgrasses. Environmental Entomology9(1), pp. 13-15.

Tsai, J.H. and Kirsch, O.H., 1978. Bionomics of Haplaxius crudus (Homoptera: Cixiidae). Environmental Entomology7(2), pp. 305-308.

Publication #EENY-389

Release Date:August 5th, 2021

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About this Publication

This document is EENY-389, one of a series of the Department of Entomology and Nematology, UF/IFAS Extension. Original publication date September 2006. Revised November 2015. Reviewed July 2021. Visit the EDIS website at https://edis.ifas.ufl.edu for the currently supported version of this publication. This document is also available on the Featured Creatures website at https://entnemdept.ufl.edu/creatures/.

About the Authors

Brian W. Bahder, assistant professor, UF/IFAS Fort Lauderdale Reseach and Education Center, Davie, FL 33314.

Contacts

  • Brian Bahder
  • Elena Rhodes