Biology of Anthonomus testaceosquamosus Linell, 1897 (Coleoptera: Curculionidae)

Biology of Anthonomus testaceosquamosus Linell, 1897 (Coleoptera: Curculionidae): Comparison

Please note this is a comparison between Version 2 by Nora Tang and Version 1 by Alexandra M Revynthi.

Although native to northeastern Mexico and southern Texas, the hibiscus bud weevil (HBW), Anthonomus testaceosquamosus Linell 1897, was recently discovered infesting hibiscus in south Florida in 2017. During outbreak events, HBW feeding on hibiscus buds has been found to significantly affect the marketability of the crop. Therefore, it is vital that an integrated pest management (IPM) program be developed for this pest in order to mitigate the economic loss to the hibiscus industry of south Florida.

invasive pest
hibiscus bud weevil
artificial diet

1. Introduction

The hibiscus bud weevil (HBW) (Anthonomus testaceosquamosus, Coleoptera: Curculionidae) is a small (≈4 mm) insect that infests China rose hibiscus (Hibiscus rosa-sinensis L., Malvales: Malvaceae). It originates in northeastern Mexico and southern Texas ^[1] and has been associated with multiple hosts within the family Malvaceae [1,2]^[1][2]. Female weevils oviposit their eggs inside hibiscus flower buds, inserted close to the anthers. Upon emergence, larvae feed on pollen and remain in the flower bud until they reach adulthood ^[3]. In Texas, heavy infestations on different varieties of tropical hibiscus resulted in bud drop, thereby decreasing the marketability of the plants ^[3]. In May 2017, HBW was detected infesting hibiscus in south Florida for the first time ^[4]; by the spring shipping period of 2019, HBW outbreaks were already responsible for large economic losses to the state’s hibiscus industry.

The discovery of HBW in south Florida is of particular concern due to the importance of the hibiscus industry in the area. Florida is the number one hibiscus-producing state, of which most is grown in south Florida (including Miami-Dade County). Approximately 20% to 25% of plants sold from Miami-Dade County are hibiscus, and this ornamental is shipped throughout the North American continent. As of 2017, the market value of ornamental plants in the county was 697 million (farmgate price) ^[5]. Therefore, the Florida Department of Agriculture and Consumer Services, Division of Plant Industry (FDACS-DPI), is now regulating this pest to curtail its spread. Currently, if HBW is detected at a nursery, the grower must sign a compliance agreement requiring that all plants be weevil-free prior to shipping. Hibiscus growers have a narrow shipping window of 3 months in the spring of each year, from March through June. Any losses incurred during this critical period can be devastating to these growers, and to the Florida industry as a whole.

Despite frequent insecticide applications and the implementation of sanitation practices (i.e., collection and destruction of fallen buds), hibiscus growers remain unable to control HBW populations. Therefore, it is vital that an integrated pest management (IPM) program be developed for this pest to mitigate economic losses to the hibiscus industry of south Florida. However, a comprehensive understanding of a pest’s biology is critical for the development of such a program. Although close relatives of HBW such as the cotton boll weevil, A. grandis, and the pepper weevil, A. eugenii, have been studied extensively [6,7,8,9,10]^{[6][7][8][9][10]}, little information is available for the HBW aside from an initial FDACS-DPI Pest Alert ^[4] and a University of Florida Fact Sheet ^[11]. Consequently, we investigated important biological parameters regarding the HBW life cycle. Specifically, we assessed the effects of temperature and diet on HBW development and fecundity. Here, we present for the first time a comprehensive study on the biology of this pest under different feeding regimes and rearing temperatures.

2.Biology of Anthonomus testaceosquamosus Linell

The HBW is a newly invasive pest in south Florida for which there is currently only one report that demonstrates its potential impact on the hibiscus industry ^[3]. Here we present the first comprehensive study on the biology of HBW reared at various temperatures and on various food sources, including its natural host (hibiscus buds), an artificial diet (pink bollworm diet), hibiscus pollen, and only water. Of the temperature regimes evaluated, 27 °C was the most favorable for weevil development. At this temperature, HBW successfully completed its life cycle within 15 days on its natural host (Table 21). These results are consistent with the high weevil populations observed in hibiscus nurseries between March and June. The abundance of flower buds in combination with favorable climatic conditions is conducive for weevil population growth during these months. Since hibiscus plants are shipped nationally and internationally from Miami-Dade County from March through June, the peak numbers of HBW during this critical period pose a serious threat to the Florida hibiscus industry. Growers must ensure that this regulated pest is absent from all hibiscus stock prior to shipment.

Table 1. Mean developmental time (days) ± SE of the hibiscus bud weevil (Anthonomus testaceosquamosus) under different temperatures and food sources at 60% RH and 12:12 h L:D. Within each column, different letters indicate significant differences (Tukey, p < 0.05).

Food Source	Temperature (°C)	Egg (n)	First Instar (n)	Second Instar (n)	Third Instar (n)	Pupa (n)	Egg to Adult (n)
Hibiscus buds	10	78.2 ± 0.55a (20)	-

21, Table 3 and Table 4), its population growth was significantly lower than on hibiscus buds (Table 4). In the congeneric A. grandis, the pink bollworm diet was found to be an excellent rearing medium as the wheat germ within the diet stimulated oviposition [22]^[13]; this effect was not observed with HBW. Our results are more similar to those reported by Toapanta et al. ^[10] and Toba et al. [23]^[14], whereby A. eugenii required more time to develop when reared on an artificial diet than when it was reared on its natural host. Seal and Martin [24]^[15] used the artificial cotton boll weevil diet to successfully rear A.eugenii. The cotton boll weevil diet and pink boll worm diet are very similar. The main difference is that the former contains cholesterol [22,24]^[13][15]. However, we do not know whether the lack of cholesterol is responsible for the low oviposition of the HBW. Future experiments should test the HBW ability to develop and reproduce on the cotton boll weevil diet. Given these results, we conclude that the artificial pink bollworm diet can serve as an alternative food source for laboratory rearing when hibiscus buds are not available, but hibiscus buds remain the most suitable food source for HBW reproduction.

Table 2. Mean head capsule widths (μm) of larvae of the hibiscus bud weevil (Anthonomus testaceosquamosus) at 27 ± 1 °C, 60% RH and 12:12 h (L:D) photoperiod. Within each column, different letters indicate significant differences (Tukey, p < 0.05).

Instar	n	Width ± SE	Range	Dyar’s Constant
First

) when it developed, fed, and reproduced solely on hibiscus buds, on the artificial boll worm diet, or when it developed on the diet and reproduced on hibiscus buds. Within each column different letters indicate significant differences (Tukey, p < 0.05).

Development, Feeding and Oviposition	n	Net Reproductive Rate (Ro) *	Intrinsic Rate of Increase (rm) **	Generation Time (T) ***	Doubling Time (Dt) ***	Finite Rate of Increase (λ) ***
-	-	-	29-
248.14 ± 8.57a	129–318.37	-
Hibiscus buds	20	136.73a 135.54–137.91	0.4547a 0.4522–0.4573	15	13 ± 1.33b (20)	4.9 ± 0.86a (10)	12.75 ± 2.46a (4)	87 ± 14.01a (3)	-	-
Second	26	383.31 ± 4.65b	318.38–461.38	1.48	27	3.35 ± 0.31d (20)	2.6 ± 0.24a (20)	3.73 ± 0.48a	20.85b 20.46–21.23 (19)	2.05 ± 0.19b (18)	4.1 ± 0.27 (18)	15.78 ± 0.83 (18)
Third	43	563.23 ± 5.07c	461.39–633	0.0841b1.48	0.0834–0.0847	36.09b 35.96–36.09	8.24b 8.18–8.30	1.0877b 1.0871–1.0885	34	5.5 ± 0.29c (20)	2.53 ± 0.29a (19)	8.92 ± 1.3b (13)	25.5 ± 8.86ac (6)	-	-
Artificial diet	27	2.22 ± 0.05e (129)	1.94 ± 0.05b (128)	3.9 ± 0.08a (128)	4.25 ± 0.23b (128)	4.21 ± 0.07 (128)	16.47 ± 0.3 (128)

In controlled laboratory tests, HBW was not able to complete its life cycle at low (10, 15 °C) or high temperatures (34 °C), suggesting that these environmental conditions are unfavorable for HBW population growth in the field. During the winter months in south Florida, temperatures average 15 °C, but during occasional cold fronts and frost events, temperatures can drop below 0 °C. In this period, hibiscus plants are small, in their vegetative growth stage, and lacking flower buds. During the summer months, however, afternoon temperatures can exceed 34 °C in July and August. During this time, hibiscus cuttings are kept in greenhouses prior to planting. Therefore, environmental conditions in combination with food availability may account for the fluctuations in weevil populations observed in nurseries. It remains unknown whether the HBW has an overwintering form and if yes, which form this is. Our measurements of HBW head capsule width and length indicated the presence of three larval instars (Table 12), which agrees with other Anthonomus species such as A. grandis [7,9]^[7][9] and A. eugenii [10,21]^[10][12]. Due to the various challenges and the labor required to maintain a laboratory colony with hibiscus buds, we also evaluated an alternative, artificial diet for rearing HBW. We found that although HBW can develop and reproduce on the pink bollworm artificial diet (Table

Table 3. Reproductive parameters for the hibiscus bud weevil (Anthonomus testaceosquamosus) when it developed, fed, and reproduced solely on hibiscus buds, on the artificial boll worm diet, or when it developed on the diet and reproduced on hibiscus buds. Within each column, different letters indicate significant differences (Tukey, p < 0.05).

Development, Feeding and Oviposition	Fecundity * (n)	Fertility ** (n)	Pre-Oviposition Period *** (n)	Oviposition Period *** (n)	Post-Oviposition Period *** (n)
10.82a
	10.76–10.88	1.52a		1.51–1.53	1.5758a 1.5717–1.5798
Artificial diet	21	7.65c 7.48–7.83	0.0578c 0.0572–0.0584	35.2c 35.03–35.3	11.99c 11.86–12.13	1.0599c 1.0588–1.0601
Artificial diet and Hibiscus buds	20
Hibiscus buds	5.85 ± 0.48a (20)	55.2 ± 2.32 (10)	4.05 ± 0.4c (20)	40.35 ± 3.53 (20)	4.45 ± 1b (20)
Artificial diet	0.2 ± 0.04b (21)	NA	6.33 ± 0.3b (21)	32.29 ± 3.48 (21)	19.85 ± 3.94a (21)
Artificial diet + Hibiscus buds	0.73 ± 0.57b (20)	62 ± 0.03 (25)	11.35 ± 1.21a (20)	38.45 ± 3.15 (20)	19.85 ± 3.2a (20)

Values are mean ± SE. * (eggs/Female/Day). ** (% hatch). *** Days.

Table 4. Life table parameters and 95% confidence intervals for the hibiscus bud weevil (Anthonomus testaceosquamosus

* Female/female. ** Female/Female/Day. *** Day.

At 27 °C, population growth and net reproductive rate of HBW (Table 4) were higher than that of A. grandis [6,7,9]^[6][7][9] and A. eugenii ^[10] reared at a similar temperature and photoperiod. Moreover, HBW generation time and doubling time were much shorter in comparison to these other two important agricultural pests [7,10]^[7][10]. These results suggest that if left unmanaged, HBW has the potential to cause significant economic damage to the hibiscus industry. The HBW is widespread in Miami-Dade County in south Florida and has been shown to cause significant injury to hibiscus. The main management practice is chemical control using contact and systemic insecticides. However, whenever feasible, sanitation practices are also being implemented. Collection and destruction of dropped, infested buds have been proven to contribute to the management of weevil populations in nurseries ^[3]. HBW oviposition did not differ between flower buds and artificial diet and was similar to values reported for A. grandis [6,7]^[6][7] and A. eugenii [10,24,25]^[10][15][16]. However, unlike these two and other congeneric weevil species [26^[17][18],27], HBW oviposits multiple eggs per flower bud. Under laboratory conditions, HBW females were found to oviposit up to 12 eggs per bud, while the maximum number of eggs that has been found per bud in the field is four. Variability in HBW oviposition has also been reported as a function of hibiscus bud size, as Bográn et al. ^[3] found that buds measuring 0.5–1.5 cm in length were more frequently infested than smaller or larger buds. Although HBW oviposits multiple eggs per bud, only a couple of adults will emerge from each bud. This result may be explained by larval cannibalism. Cannibalism is a common phenomenon across the animal kingdom [28^[19][20],29], and is well-documented in insects [30]^[21] and in the family Curculionidae [31,32]^[22][23]. It can serve as a ‘life boat’ survival mechanism when food is scarce [33]^[24], which may be a common occurrence inside small hibiscus buds where the amount of pollen is limited and larvae cannot disperse in search of more pollen. In our experiments, it was not possible to observe larval cannibalism because to score daily oviposition we had to destroy the bud and remove all the eggs. Moreover, in weevil development experiments we only inserted one egg per bud or cell.

3. Conclusions

HBW can successfully complete its life cycle within 2 weeks on H. rosa-sinensis at an optimal temperature of 27 °C. Hibiscus buds are a more efficient food source for weevil reproduction than the artificial pink bollworm diet. When buds are not available, weevils are capable of survival on hibiscus pollen and water, but oviposition is sacrificed. The current study generates useful information regarding the biology of a destructive pest of hibiscus, an economically important ornamental cultivated in south Florida. Given that a comprehensive understanding of the biology of a pest is critical for development of an effective IPM program, our results provide a knowledge base for improving management strategies for HBW in Florida nurseries.

References

Burke, H.R.; Gates, D.B. Bionomics of Several North American Species of Anthonomus (Coleoptera: Curculionidae). Southwest. Nat. 1974, 19, 313.
Clark, W.E.; Burke, H.R.; Jones, R.W.; Anderson, R.S. The North American Species of the Anthonomus squamosus Species-Group (Coleoptera: Curculionidae: Curculioninae: Anthonomini). Coleopt. Bull. 2019, 73, 773.
Bográn, C.E.; Helnz, K.M.; Ludwlg, S. The Bud Weevil Anthonomus testaceosquamosus, a Pest of Tropical Hibiscus. In Proceedings of the SNA Research Conference Entomology, Atlanta, GA, USA, December 2003; Volume 48, pp. 147–149.
Skelley, P.E.; Osborne, L.S. Pest Alert Anthonomus testaceosquamosus Linell, the Hibiscus Bud Weevil, New in Florida; Florida Department of Agriculture and Consumer Services: Gainesville, FL, USA, 2018.
United States Department of Agriculture. Market Value of Agricultural Products Sold Including Food Marketing Practices and Value-Added Products: 2017 and 2012 Census of Agriculture 2017; United States Department of Agriculture: Washington, DC, USA, 2017; pp. 275–302.
Greenberg, S.M.; Sappington, T.W.; Spurgeon, D.W.; Sétamou, M. Boll Weevil (Coleoptera: Curculionidae) Feeding and Reproduction as Functions of Cotton Square Availability. Environ. Entomol. 2003, 32, 698–704.
Greenberg, S.M.; Sappington, T.W.; Adamczyk, J.J.; Liu, T.-X.; Setamou, M. Effects of Photoperiod on Boll Weevil (Coleoptera: Curculionidae) Development, Survival, and Reproduction. Environ. Entomol. 2008, 37, 1396–1402.
Greenberg, S.M.; Jones, G.D.; Adamczyk, J.J., Jr.; Eischen, F.; Armstrong, J.S.; Coleman, R.J.; Sétamou, M.; Liu, T.-X. Reproductive potential of field-collected overwintering boll weevils (Coleoptera: Curculionidae) fed on pollen in the laboratory. Insect Sci. 2009, 16, 321–327.
Greenberg, S.M.; Setamou, M.; Sappington, T.W.; Liu, T.-X.; Coleman, R.J.; Armstrong, J.S. Temperature-dependent development and reproduction of the boll weevil (Coleoptera: Curculionidae). Insect Sci. 2005, 12, 449–459.
Toapanta, M.A.; Schuster, D.J.; Stansly, P.A. Development and Life History of Anthonomus eugenii (Coleoptera: Curculionidae) at Constant Temperatures. Environ. Entomol. 2005, 34, 999–1008.
Revynthi, A.M.; Hernandez, Y.V.; Rodriguez, J.; Kendra, P.E.; Carrillo, D.; Mannion, C.M. The Hibiscus Bud Weevil (Anthonomus testaceosquamosus Linell, Coleoptera: Curculionidae); EDIS 2021, 9/2021; Funiversity of Florida: Gainesville, FL, USA, 2021; pp. 1–7.
Elmore, J.; Davis, A.; Campbell, R. The Pepper Weevil. U.S. Dep. Agric. Tech. Bull. 1934, 447, 25.
Cohen, A.C. Ecology of Insect Rearing Systems: A Mini-Review of Insect Rearing Papers from 1906–2017. Adv. Entomol. 2018, 6, 86–115.
Toba, H.H.; Kishaba, A.N.; Pangaldan, R.; Riggs, S. Laboratory rearing of pepper weevils on artificial diets. J. Econ. Entomol. 1969, 62, 257–258.
Seal, D.R.; Martin, C.G. Laboratory Rearing of Pepper Weevils (Coleoptera: Curculionidae) Using Artificial Leaf Balls and a Boll Weevil Diet. J. Entomol. Sci. 2017, 52, 395–410.
Fernández, D.C.; VanLaerhoven, S.L.; McCreary, C.; Labbé, R.M. An overview of the pepper weevil (Coleoptera: Curculionidae) as a pest of greenhouse peppers. J. Integr. Pest Manag. 2020, 11, 26.
Tonina, L.; Zanettin, G.; Miorelli, P.; Puppato, S.; Cuthbertson, A.G.S.; Grassi, A. Anthonomus rubi on strawberry fruit: Its biology, ecology, damage, and control from an ipm perspective. Insects 2021, 12, 701.
Easterbrook, M.A.; Fitzgerald, J.D.; Pinch, C.; Tooley, J.; Xu, X.M. Development times and fecundity of three important arthropod pests of strawberry in the United Kingdom. Ann. Appl. Biol. 2003, 143, 325–331.
Polis, G.A. The Evolution and Dynamics of Intraspecific Predation. Ann. Rev. Eeal Syst 1981, 12, 225–251.
Fox, L.R. Cannibalism in Natural Populations. Annu. Rev. Ecol. Syst. 1975, 6, 87–106.
Richardson, M.L.; Mitchell, R.F.; Reagel, P.F.; Hanks, L.M. Causes and consequences of cannibalism in non carnivorous insects. Annu. Rev. Entomol. 2010, 55, 39–53.
Bolívar-Silva, D.A.; Guedes, N.M.P.; Guedes, R.N.C. Larval cannibalism and fitness in the stored grain weevils Sitophilus granarius and Sitophilus zeamais. J. Pest Sci. 2018, 91, 707–716.
de Medeiros, B.A.S.; de Cássia Bená, D.; Vanin, S.A. Curculio Curculis lupus: Biology, behavior and morphology of immatures of the cannibal weevil Anchylorhynchus eriospathae G. G. Bondar, 1943. Peer J. 2014, 2014, e502.
van den Bosch, F.; de Roos, A.M.; Gabriel, W. Cannibalism as a life boat mechanism. J. Math. Biol. 1988, 26, 619–633.