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11 April 2019 Density and Egg Parasitism of Stink Bugs (Hemiptera: Pentatomidae) in Mimosa
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Stink bugs (Hemiptera: Pentatomidae) are primary pests in most fruit, vegetable, grain, and row crops worldwide. The polyphagous habits of these pest species compels them to forage within and between closely associated non-crop and crop habitats across farmscapes in response to changing food resources. The exotic mimosa tree, Albizia julibrissin Durazz (Fabaceae), commonly grows in thickets along roadsides and in woodlands adjacent to agricultural crops across the southeastern USA. Thus, the objective of this study was to determine if mimosa was a host plant of stink bugs in southwest Georgia. Chinavia hilaris (Say) (Hemiptera: Pentatomidae) fed and developed on mimosa during early Jul through mid-Aug. Nymphs and adults of C. hilaris fed more frequently on fruit than on leaves of mimosa. Other stink bugs viz., Euschistus servus (Say), E. tristigmus (Say), E. obscurus (Palisot), Nezara viridula (L.), Thyanta custator custator (F.), and Loxa flavicollis (Drury) (all Hemiptera: Pentatomidae), also were detected on mimosa, but only as adults feeding on fruit. Trissolcus edessae Fouts (Hymenoptera: Scelionidae) was the most prevalent parasitoid of C. hilaris eggs on mimosa, but Anastatus reduvii (Howard) (Hymenoptera: Eupelmidae) also emerged from eggs of this stink bug. Overall, 46.6% of the C. hilaris eggs found on mimosa were parasitized. In conclusion, C. hilaris is the primary stink bug species developing on mimosa in southwest Georgia, serving as a potential source of this stink bug into nearby crops.

Numerous stink bug species (Hemiptera: Pentatomidae), including Chinavia hilaris (Say), Euschistus servus (Say), E. tristigmus (Say), and Nezara viridula (L.), cause economic injury to many agronomic crops (McPherson & McPherson 2000). Stink bugs feed on developing cotton seeds and lint, which can cause shedding of young bolls, yellowing of lint, yield reduction, and transmission of the bacterial pathogen Pantoea agglomerans (Enterobactacteriaceae) that can damage seed and lint (Barbour et al. 1990; Medrano et al. 2009).

The plant-feeding habits of stink bug pests compels them to move within and between closely associated non-crop and crop habitats across farmscapes in response to changing food resources. Mimosa, Albizia julibrissin Durazz (Fabaceae), was introduced in the mid-1700s as an ornamental in the US. This exotic tree commonly grows in thickets along roadsides and in woodlands adjacent to agricultural crops across the southeastern USA. The fruit (i.e., pod) of this legume is 8 to 20 cm long and, in general, yields 5 to 16 seeds, each about 6 to 12 mm in length (Meyer 2010). Chinavia hilaris previously has been reported on mimosa in South Carolina, USA (Jones & Sullivan 1982). In southwest Georgia, the capture of C. hilaris adults and nymphs in stink bug pheromone-baited traps near mimosa in field borders adjacent to crops, and the spatial distribution of C. hilaris in these crops, indicated that this tree was a source of this stink bug dispersing into crops, primarily to cotton (Cottrell & Tillman 2015). This study was conducted to investigate the seasonal abundance and feeding habits of stink bug species in mimosa, and to provide estimates of parasitism of naturally occurring stink bug eggs on this tree.

Materials and Methods

This field study was conducted from 2013 through 2018. Over the 6-yr study, uncultivated mimosa trees in woodlands adjacent to commercial cotton fields were sampled for stink bugs at 4 sites: Grainbin (31.5656°N, 83.2979°W), Redbarn (31.5543°N, 83.3132°W), Palm (31.5369°N, 83.3321°W), and Starr (31.5719°N, 83.2969°W), in Irwin County, Georgia, USA. The number of sites and trees per site varied among yr because some of the trees were accidentally killed or hurt by growers, or did not produce fruit during a season due to drought conditions. Also, additional sites were included as mimosa trees were detected at other sites. With only 1 exception, mimosa trees were sampled weekly. In 2013, 4 trees were sampled for 5 wk at ‘Grainbin’ from 25 Jul to 22 Aug. In 2014, 3 trees were examined for 8 wk at ‘Grainbin’ from 10 Jul to 28 Aug. In 2015, 2 trees at ‘Starr’, 5 at ‘Grainbin’, and 7 at ‘Palm’ were sampled for 5 wk from 15 Jul to 12 Aug. In 2016, 9 trees at ‘Palm’ were sampled for 2 wk, on 28 Jul and 4 Aug. In 2017, 2 trees at ‘Starr’, 3 at ‘Grainbin’, 4 at ‘Redbarn’, and 5 at ‘Palm’ were examined for 7 wk on 29 Jun and from 20 Jul to 24 Aug. In 2018, 2 trees at ‘Starr’, 4 at ‘Redbarn’, and 6 at ‘Palm’ were sampled for 13 wk from 7 Jun to 30 Aug. For each mimosa sample, a whole plant, including foliage and fruiting structures, was examined for the presence of stink bugs. When necessary, a 1.5-m long cattle show stick with a small hook at the end was used to gently pull down a branch to look for insects. Species and developmental stages of stink bugs were recorded in the field using a HP iPAQ pocket personal computer (Hewlett-Packard Co., Palo Alto, California, USA). At the Grainbin site, feeding (i.e., proboscis inserted into the food source) by stink bug nymphs and adults was recorded by the plant part (i.e., leaf, stem, or fruit) each individual fed on for each tree for each sampling date in 2013 and 2014.

Naturally occurring stink bug egg masses detected in the field were brought into the laboratory and held in a walk-in environmental chamber (27 °C, 60% relative humidity, 14:10 h [L:D] photoperiod) for emergence of adult parasitoids. Trissolcus species (Hymenoptera: Scelionidae) were identified using a key to Nearctic species of Trissolcus (Talamas et al. 2015). Females of Anastatus (Hymenoptera: Eupelmidae) were identified using a key to North American species of this genus (Burks 1967). There is no key to Anastatus males. Anastatus reduvii (Howard) and A. mirabilis (Walsh & Riley) are the only 2 Eupelmidae parasitoids known to emerge from stink bug eggs in southwest Georgia, and only 1 species emerges from a single egg mass (Tillman 2016). Therefore, Anastatus males emerging with Anastatus females were assumed to be the same species. Predation of eggs was assessed as described in Tillman (2011). Voucher specimens of all insects were deposited in the USDA, ARS, Crop Protection & Management Research Laboratory in Tifton, Georgia.

All data were analyzed using SAS statistical software (SAS Institute 2010). Chi-square analyses were used to compare frequencies of parasitoid species parasitizing C. hilaris egg masses on mimosa, frequencies of plant parts fed on by nymphs of this stink bug, and frequencies on location of egg masses on mimosa (PROC FREQ). Seasonal means for the number of C. hilaris egg masses, nymphs, and adults per tree were calculated and graphed for 2013, 2014, 2015, 2017, and 2018 (PROC MEANS). Only data on stink bug species, and parasitism and predation of C. hilaris egg masses, are presented for the 2016 data set.


Over the 6 yr study, 7 plant-feeding stink bug species were detected on mimosa. Chinavia hilaris was the predominant stink bug species (63.5%) (c² = 1617.7; df = 5; P < 0.001) followed by N. viridula (12.9%), E. tristigmus (10.3%), E. servus (9.7%), Thyanta custator custator (F.) (3.0%), E. obscurus (Palisot) (0.4%), and Loxa flavicollis (Drury) (0.2%). Chinavia hilaris, E. servus, and E. tristigmus were consistently present on mimosa over each yr of the study. However, E. obscurus and T. c. custator were detected on mimosa only for 3 yr and N. viridula for only 2 yr. Two females of L. flavicollis were found on mimosa in 2018. Only C. hilaris developed from nymphs to adults on mimosa. For the remaining stink bug species, only adults were detected, generally feeding on fruit.

Populations of C. hilaris were present on mimosa in Jul and Aug (Fig. 1). Observations of feeding by C. hilaris on mimosa in 2013 and 2014 revealed that nymphs (second through fifth instars) fed more frequently on fruit (98.5%) than on leaves (1.5%) (c² = 121.1; df = 1; P < 0.001). Adults (n = 41) fed only on fruit, and females laid egg masses more often on fruit (77.4%) than on leaves (22.6%) (c² = 9.3; df =1; P < 0.002). No C. hilaris were observed feeding on stems of mimosa. On 29 Jun 2017, only small seeds were present in small pods, and no C. hilaris were detected on trees. In 2018, trees flowered from early to mid-Jun. Small seeds were present in small pods from mid- to late Jun. No C. hilaris were detected on mimosa trees until pods with medium-sized seeds were sampled on 5 Jul. Only early instars (i.e., first, second, and third instars) were present on mimosa on 10 Jul 2014, and 5 Jul and 12 Jul 2018. In addition, some egg masses were detected on mimosa on 15 Jul 2015 and 12 Jul 2018. Altogether, these results strongly indicate that C. hilaris occurred and developed on fruiting mimosa. In 2017 and 2018, adult numbers decreased as pods with large seeds began senescing (i.e., drying out and turning brown). Numbers of nymphs (principally fourth and fifth instars late season), though, increased around mid-Aug, decreasing when pods senesced. A similar pattern occurred for C. hilaris numbers in Aug 2014 and 2015. Numbers of C. hilaris nymphs were relatively low in Aug in 2013 compared to the other yr, perhaps due to the drought conditions.

Only 2 species of parasitoids parasitized naturally occurring egg masses of C. hilaris. Trissolcus edessae Fouts (Hymenoptera: Scelionidae) was the most prevalent parasitoid of C. hilaris eggs on mimosa (87.8%) (c² = 136.1; df = 1; P < 0.001). Anastatus reduvii (Howard) (Hymenoptera: Eupelmidae) also emerged from eggs (12.2%) of this stink bug. Overall, 46.6% of the eggs were parasitized and 10.5% were preyed upon.


Chinavia hilaris fed and successfully developed to adults on mimosa fruit (i.e., pods), confirming mimosa as a reproductive host plant for this stink bug. However, mimosa was not a reproductive host plant for the other stink bug species detected on this tree, and served solely as a source of food for adults. Similar to the results of the current study, populations of C. hilaris were present on mimosa from mid-Jul through Aug in South Carolina (Jones & Sullivan 1982). In the current study, adults of C. hilaris decreased in number on mimosa as nymphs began to peak early to mid-Aug, indicating that new adults developing from nymphs on the tree dispersed from this woodland food source to seek a new host plant. Timing of senescence of mimosa and likely dispersal of C. hilaris adults from this host plant coincides with the presence of fruit (i.e., bolls) on cotton, suggesting that mimosa could be a source of this stink bug in this crop. Indeed, the capture of C. hilaris adults and nymphs in pheromone-baited traps near mimosa, and subsequent presence of C. hilaris in crops near mimosa in an earlier study indicated that this tree was a source of this stink bug dispersing into cotton (Cottrell & Tillman 2015). Mark-recapture studies in the same woodland habitats of the current study demonstrated that elderberry (Sambucus nigra subsp. canadensis [L.] R. Bolli), a non-crop host plant of C. hilaris, was a source of this stink bug moving into cotton (Tillman & Cottrell 2016). Similarly, damage to apple by C. hilaris was greatest near woodlands (Mundinger & Chapman 1932), and infestations of this stink bug in soybean were consistently found on border rows next to woodlands (Miner 1966), suggesting that host plants in woodlands were sources of C. hilaris in apple and soybean.

Fig. 1.

Mean number of C. hilaris egg masses, nymphs, and adults on mimosa over time in 2013, 2014, 2015, 2017, and 2018, and percentage of senesced pods over time in mimosa in 2017 and 2018. G = green pod; S = senesced pod; s = small-sized seeds in pods; M = medium-sized seeds in pods; L = large seeds in pods.


Based on the results of the current study and previous studies, overall percent parasitism of C. hilaris eggs ranges from 16 to 49% on various host plants (Yeargan 1979; Orr et al. 1986; Jones et al. 1996; Koppel et al. 2009; Tillman & Cottrell 2016). In an earlier study, diversity of egg parasitoids emerging from C. hilaris was greater, and percent parasitism was higher in woodland habitats (41%) compared with those observed in crops (21%) (Tillman 2016). Four species of parasitoids, T. edessae, A. reduvii, A. mirabilis (Walsh & Riley), and Ooencyrtus sp. parasitized egg masses of C. hilaris in wooded areas, but only T. edessae parasitized eggs of this stink bug in crops. In the current study, both T. edessae and A. reduvii parasitized eggs of C. hilaris in mimosa. Trissolcus edessae was the principal parasitoid emerging from C. hilaris egg masses on Sesbania punicea (Cav.) Benth, another non-crop host plant of this stink bug in wetland habitats (Tillman 2015). In elderberry, these 2 parasitoid species, as well as A. mirabilis, parasitized C. hilaris in woodlands (Tillman & Cottrell 2016).

Conservation of T. edessae and A. reduvii in woodland habitats has the potential to enhance biological control of C. hilaris in agricultural ecosystems. The importance of nectar provision on parasitoid fitness has been demonstrated for various hymenopteran parasitoid species (Berndt & Wratten 2005; Araj et al. 2006). Incorporating buckwheat near soybean increased parasitism of E. servus egg masses by Telenomus podisi Ashmead in adjacent cotton (Tillman et al. 2015). Nectar provision along field edges could provide a food source to parasitoids in their woodland habitats and as they disperse from woodlands into crops. Anastatus species were the most prevalent parasitoids emerging from naturally occurring eggs of Halyomorpha halys (Stål) (Hemiptera: Pentatomidae) in ornamental nurseries in Maryland, USA (Jones et al. 2014). Trissolcus edessae and A. reduvii are 2 prevalent egg parasitoids of H. halys in the southeastern US (Tillman unpublished data). Providing nectar to T. edessae and Anastatus species near woodlands is one of many management strategies available for managing C. hilaris and, potentially, H. halys.


Thanks to Kristie Graham (USDA, ARS, Crop Protection & Management Research Laboratory, Tifton, Georgia) for her technical assistance in the field.

References Cited

  1. Araj SA, Wratten SD, Lister AJ, Buckley L. 2006. Floral nectar affects longevity of the aphid parasitoid Aphidius ervi and its hyperparasitoid Dendrocerus aphidum.New Zealand Plant Protection59: 178–183. Google Scholar

  2. Barbour KS, Bradley JrJR, Bachelor JS. 1990. Reduction in yield and quality of cotton damaged by green stink bug (Hemiptera: Pentatomidae).Journal of Economic Entomology83: 842–845. Google Scholar

  3. Berndt LA, Wratten SD. 2005. Effects of alyssum flowers on the longevity, fecundity, and sex ratio of the leafroller parasitoid Dolichogenidea tasmanica.Biological Control32: 65–69. Google Scholar

  4. Burks BD. 1967. The North American species of Anastatus Motschulsky (Hymenoptera, Eupelmidae).Transactions of the American Entomology Society93: 423–432. Google Scholar

  5. Cottrell TE, Tillman PG. 2015. Spatiotemporal distribution of Chinavia hilaris (Hemiptera: Pentatomidae) in corn farmscapes.Journal of Insect Science15: 28. Google Scholar

  6. Jones AL, Jennings DE, Hooks CRR, Shrewsbury PM. 2014. Sentinel eggs underestimate rates of parasitism of the exotic brown marmorated stink bug, Halyomorpha halys.Biological Control78: 61–66. Google Scholar

  7. Jones WA, Sullivan MJ. 1982. Role of host plants in population dynamics of stink bug pests of soybean in South Carolina.Environmental Entomology11: 867–875. Google Scholar

  8. Jones WA, Shepard BM, Sullivan MJ. 1996. Incidence of parasitism of pentatomid (Heteroptera) pests of soybean in South Carolina with the review of studies in other states.Journal of Agricultural Entomology13: 243–263. Google Scholar

  9. Koppel AL, Herbert Jr DA, Kuhar TP, Kamminga K. 2009. Survey of stink bug (Hemiptera: Pentatomidae) egg parasitoids in wheat, soybean, and vegetable crops in southeast Virginia.Environmental Entomology38: 375–379. Google Scholar

  10. McPherson JE, McPherson RM. 2000. Stink Bugs of Economic Importance in America North of Mexico.CRC Press LLC, Boca Raton, Florida, USA. Google Scholar

  11. Medrano EG, Esquivel JF, Nichols RL, Bell AA. 2009. Temporal analysis of cotton boll symptoms resulting from southern green stink bug feeding and transmission of a bacterial pathogen.Journal of Economic Entomology102: 36–42. Google Scholar

  12. Meyer R. 2010. Albizia julibrissin. In Fire Effects Information System.US Department of Agriculture, Forest Service. (last accessed 26 Sep 2018). Google Scholar

  13. Miner FD. 1966. Biology and control of stink bugs on soybean.Arkansas Agricultural Experiment Station Bulletin708: 1–40. Google Scholar

  14. Mundinger FG, Chapman PJ. 1932. Plant bugs as pests of pear and other fruits in the Hudson Valley.Journal of Economic Entomology25: 655–658. Google Scholar

  15. Orr DB, Russin JS, Boethel DJ, Jones WA. 1986. Stink bug (Hemiptera: Pentatomidae) egg parasitism in Louisiana soybeans.Environmental Entomology15: 1250–1254. Google Scholar

  16. SAS Institute.2010. SAS 9.3 for windows.SAS Institute, Cary, North Carolina, USA. Google Scholar

  17. Talamas EJ, Johnson NF, Buffington M. 2015. Key to Nearctic species of Trissolcus Ashmead (Hymenoptera, Scelionidae), natural enemies of native and invasive stink bugs (Hemiptera, Pentatomidae).Journal of Hymenoptera Research43: 45–110. Google Scholar

  18. Tillman PG. 2011. Natural biological control of stink bug (Heteroptera: Pentatomidae) eggs in corn, peanut, and cotton farmscapes in Georgia.Environmental Entomology40: 303–314. Google Scholar

  19. Tillman PG. 2015. First record of Sesbania punicae (Fabales: Fabaceae) as a host plant for Chinavia hilaris (Hemiptera: Pentatomidae).Florida Entomologist98: 989–990. Google Scholar

  20. Tillman PG. 2016. Diversity of stink bug (Hemiptera: Pentatomidae) egg parasitoids in woodland and crop habitats in southwest Georgia.Florida Entomologist99: 286–291. Google Scholar

  21. Tillman PG, Khrimian A, Cottrell TE, Luo X, Mizell RFIII , Johnson J. 2015. Trap cropping systems and a physical barrier for suppression of stink bug (Hemiptera: Pentatomidae) in cotton.Journal of Economic Entomology108: 1–11. Google Scholar

  22. Tillman PG, Cottrell TE. 2016. Density and egg parasitism of stink bugs (Hemiptera: Pentatomidae) in elderberry and dispersal into crops.Journal of Insect Science16: 106. Google Scholar

  23. Yeargan KV. 1979. Parasitism and predation of stink bug eggs in soybean and alfalfa fields.Environmental Entomology8: 715–719. Google Scholar

P. Glynn Tillman "Density and Egg Parasitism of Stink Bugs (Hemiptera: Pentatomidae) in Mimosa," Florida Entomologist 102(1), 227-230, (11 April 2019).
Published: 11 April 2019

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