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South American Fruit Fly (suggested common name) Anastrepha fraterculus (Wiedemann) (Insecta: Diptera: Tephritidae)

Vanessa Simões Dias and Andrea Lucky

Introduction

Anastrepha fraterculus (Wiedemann) is an insect pest commonly referred to as the South American fruit fly, which occurs from the southern United States to Argentina (Figure 1). Recent research has revealed this species to be a complex of at least eight cryptic species (yet unnamed), currently described as morphotypes, rather than a single biological species (Hernández-Ortiz et al. 2004, 2012, 2015).

Figure 1. Anastrepha fraterculus (Wiedemann) female laying eggs in a peach.
Figure 1.  Anastrepha fraterculus (Wiedemann) female laying eggs in a peach.
Credit: Dori Nava, Embrapa Clima Temperado

Overall, the morphotypes in the complex are highly polyphagous with the potential to infest at least 110 host plants, including economically important fruit crops, such as guava, citrus, and apples (Zucchi 2016). However, depending on their distribution, each fly morphotype may have its own host range, which is still unknown. Uncertainties around the taxonomic status of the complex represent a huge challenge to plant protection authorities (Hendrichs et al. 2015). Because of the economic importance of this group of flies, it is crucial to know which species within the complex are indeed insect pests in order for plant protection authorities to establish quarantine barriers and prevent the introduction of pest species across countries and spread within each country.

Synonymy

The suspicion that Anastrepha fraterculus was a complex of multiple species was initially raised by Stone in 1942. Subsequently, the status of cryptic species within Anastrepha fraterculus was confirmed by multiple lines of evidences, such as isozymes (enzymes with different amino acid sequences that catalyze the same reactions), karyotypes, molecular cytogenetics, morphometry, chemical profiles, and behavioral studies (Morgante et al. 1980; Steck 1991; Selivon and Perondini 1998; Smith-Caldas et al. 2001; Hernández-Ortiz et al. 2004, 2012, 2015; Selivon et al. 2005; Canal et al. 2015; Vera et al. 2006; Cáceres et al. 2009; Rull et al. 2013; Devescovi et al. 2014; Vanicková et al. 2015; Dias et al. 2016). These cryptic species of the Anastrepha fraterculus complex are often called morphotypes, representing groups of similar organisms.

Currently, eight morphotypes are recognized in the Neotropics as part of the nominal species Anastrepha fraterculus: Andean, Brazilian-1, Brazilian-2, Brazilian-3, Ecuadorian, Mexican, Peruvian, and Venezuelan morphotypes (Hernández-Ortiz et al. 2004, 2012, 2015). Those eight morphotypes are related to three distinct and directly unrelated phenotypic lineages, Andean, Brazilian, and Meso-Caribbean, suggesting the non-monophyly of the Anastrepha fraterculus complex (Hernández-Ortiz et al. 2015). However, to date, all phenotypes from the Anastrepha fraterculus complex remain named Anastrepha fraterculus.

The following synonyms for Anastrepha fraterculus are listed by the Integrated Taxonomic Information System (ITIS 2017):

Dacus fraterculus (Wiedemann 1830) (original designation)

Tephritis mellea (Walker 1837)

Trypeta unicolor (Loew 1862)

Anthomyia frutalis (Weyenbergh 1874)

Anastrepha peruviana (Townsend 1913)

Anastrepha braziliensis (Greene 1934)

Anastrepha costarukmanii (Capoor 1954)

Anastrepha scholae (Capoor 1955)

Anastrepha pseudofraterculus (Capoor 1955)

Anastrepha lambayecae (Korytkowski & Ojeda 1968)

Distribution

Species of the Anastrepha fraterculus complex are native to and most common in South America (Argentina, Brazil, Colombia, Ecuador, Peru, Venezuela), but can also be found in Central America (Guatemala, Panama) and North America (Mexico and the United States).

Description

Eggs

In general, the Anastrepha fraterculus eggs are creamy white, elongate, averaging 1.35 mm to 1.42 mm, have a conspicuous micropyle (opening for sperm entry) as well as a short chorionic extension in the egg apex, and are bluntly rounded in the egg end (Figure 2) (Murillo and Jirón 1994; Selivon and Perondini 1998). Eggs from different morphotypes within the Anastrepha fraterculus complex may differ in length, position of the micropyle, structure of papilla, pattern of sculpturing of the chorion, size, and number of aeropyles (respiratory channels) (Selivon et al. 1997; Selivon and Perondini 1998). Females deposit eggs inside the fruit through sclerotized ovipositors. The eggs hatch into larvae within two days.

Figure 2. Egg morphology of Anastrepha fraterculus (Wiedemann), Brazilian-1, in comparison to other Anastrepha species.
Figure 2.  Egg morphology of Anastrepha fraterculus (Wiedemann), Brazilian-1, in comparison to other Anastrepha species.
Credit: Vanessa Dias, University of Florida

 

Larvae

In order for Anastrepha fraterculus larvae to reach maturity, they must molt three times. Usually, the first instar occurs from 1 to 3 days old, the second instar from 4 to 6 days old, and the third instar (Figure 3) from 7 to 12 days old (Nieuwenhove and Ovruski 2011). The average body length of the third instar ranges from 8.77 mm to 10.02 mm across morphotypes (Canal et al. 2015). Several larval traits can be used to identify the different morphotypes within the Anastrepha fraterculus complex, particularly mandible shape, as shown in Figure 4 (Canal et al. 2015).

Figure 3. Ventral (top) and lateral (bottom) views of the Anastrepha fraterculus (Wiedemann) (Brazilian-1) third instar larvae.
Figure 3.  Ventral (top) and lateral (bottom) views of the Anastrepha fraterculus (Wiedemann) (Brazilian-1) third instar larvae.
Credit: Vanessa Dias, University of Florida

 

Figure 4. (A) Mouth hook of third instar larva from lateral view. (B) Estimated morphological differences in the shape of mouth hook of five morphotypes of the Anastrepha fraterculus (Wiedemann) complex.
Figure 4.  (A) Mouth hook of third instar larva from lateral view. (B) Estimated morphological differences in the shape of mouth hook of five morphotypes of the Anastrepha fraterculus (Wiedemann) complex.
Credit: Canal et al. (2015), ZooKeys, open access under Creative Commons Attribution License (CC BY 4.0)

 

Pupae

The pupal stage is inert, but extremely important due to the intensive level of cellular differentiation. Pupae of the Anastrepha fraterculus complex are cylindrical and brownish, becoming darker when the insect is fully developed (Figure 5A), but still inside of the pupae as a pharate adult (Figure 5B). In nature, pupae can usually be found buried in the ground. Pupae hatch into adults within two to three weeks.

Figure 5. Anastrepha fraterculus (Wiedemann) pupae. (A) Pupae of different ages (note change in coloration as pupae age—older one on the left). (B) Puparium with a pharate adult (fully formed fly) inside.
Figure 5.  Anastrepha fraterculus (Wiedemann) pupae. (A) Pupae of different ages (note change in coloration as pupae age—older one on the left). (B) Puparium with a pharate adult (fully formed fly) inside.
Credit: Vanessa Dias, University of Florida

 

Adults

The adults in the Anastrepha fraterculus complex are colorful, usually yellowish brown, ranging from 12 to 14 mm. Although they are highly variable, aspects of wings, genitalia (particularly female genitalia), and thorax (mesonotum) constitute important characteristics to identify the species within the complex (Hernández-Ortiz et al. 2004, 2012, 2015) (Figure 6). According to Greene (1934), Anastrepha fraterculus adults can be distinguished from other species of the genus by the shape of the ovipositor (females) and wing pattern. There is no sexual dimorphism, except in the sexual characteristics and size (females are usually larger than males) (Figure 7). For instance, one of the characteristics exclusive to females is the ovipositor, which can measure 2 mm long.

Figure 6. Morphological characteristics used to identify individuals from the Anastrepha fraterculus (Wiedemann) complex. 1. Thorax. 2. Aculeus tip (part of the ovipositor). 3 and 4. Multiple measurements from the wings.
Figure 6.  Morphological characteristics used to identify individuals from the Anastrepha fraterculus (Wiedemann) complex. 1. Thorax. 2. Aculeus tip (part of the ovipositor). 3 and 4. Multiple measurements from the wings.
Credit: Hernández-Ortiz et al. (2015), ZooKeys, open access under Creative Commons Attribution License (CC BY 4.0)

 

Figure 7. Female (left) and male (right) of Anastrepha fraterculus (Wiedemann). Both specimens are from the Brazilian-1 morphotype.
Figure 7.  Female (left) and male (right) of Anastrepha fraterculus (Wiedemann). Both specimens are from the Brazilian-1 morphotype.
Credit: Vanessa Dias, University of Florida

Sexual behavior of these insects is complex, variable, and very interesting. Males from the Anastrepha fraterculus complex exhibit a lek mating system in which calling individuals get together on trees (usually under the leaves) to attract, court, and mate with receptive females (Morgante et al. 1983) (Figure 8).

Figure 8. Anastrepha fraterculus (Wiedemann) mating.
Figure 8.  Anastrepha fraterculus (Wiedemann) mating.
Credit: Vanessa Dias, University of Florida

Multiple signals, such as visual (symmetry of structures), acoustical (buzzing), and chemical (pheromones), are used by males to court females (Segura et al. 2007; Gomez-Cendra et al. 2011; Brizová et al. 2013; Dias et al. 2016) (Figure 9).

Figure 9. Male from the Anastrepha fraterculus (Wiedemann) complex releasing pheromone to attract females (see the abdomen tip of the male).
Figure 9.  Male from the Anastrepha fraterculus (Wiedemann) complex releasing pheromone to attract females (see the abdomen tip of the male).
Credit: Vanessa Dias, University of Florida

 

Hosts

The species within the Anastrepha fraterculus complex infest at least 110 host plants, including several families, such as Anacardiaceae, Annonaceae, Myrtaceae, and many others (Zucchi 2016):

Table 1. 

Anacardium occidentale, cashew

Mangifera indica, mango

Andira humilis

Manilkara zapota, sapodilla

Annona crassiflora, araticum do cerrado

Marlierea edulis

Annona rugulosa, custard apple

Mouriri acutiflora

Averrhoa carambola, starfruit

Mouriri glazioviana

Butia eriospatha, wooly jelly palm

Myrceugenia euosma

Byrsonima, serrettes

Myrcia aff. clausseniana

Campomanesia spp., guavira, white guabiroba

Myrciaria cauliflora, Brazilian grapetree

Carica papaya, papaya

Myrciaria jaboticaba, Brazilian grapetree

Celtis iguanaea, Iguana hackberry

Passiflora edulis, passion fruit

Chrysophyllum gonocarpum, white star apple

Picramnia sp., bitterbush

Cydonia oblonga, common quince

Plinia glomerata, yellow jaboticaba

Citrus aurantifolia, key lime

Plinia strigipes

Citrus aurantium, bitter orange

Pouteria caimito, abiu

Citrus limon, lemon

Pouteria gardneriana, abuai

Citrus maxima, pomelo, jabong

Pouteria ramiflora

Citrus reticulata, tangerine

Prunus avium, wild cherry, sweet cherry, gean

Citrus sinensis, orange or sweet orange

Prunus domestica, plum

Coffea arabica, common coffee

Prunus mume, Chinese plum, Japanese apricot

Coffea canephora, robusta coffee

Prunus persica, peach

Cryptocarya aschersoniana

Prunus sellowii, wild Brazilian peach

Diatenopteryx sorbifolia

Prunus sp., peach

Diospyros kaki, Japanese persimmon, kaki

Psidium araca, wild guava, Brazilian guava

Eriobotrya japonica, loquat

Psidium cattleyanum, strawberry guava

Eugenia brasiliensis, Brazil cherry

Psidium guajava, guava

Eugenia dodoneifolia

Psidium guineense, Brazilian guava, Castilian guava, sour guava, Guinea guava

Eugenia gemminiflora

Psidium kennedyanum

Eugenia involucrata, cherry of the Rio Grande

Psidium myrtoides, araçá-una

Eugenia leitonii, araçá piranga

Psidium sellowiana

Eugenia platyphylla

Punica granatum, pomegranate

Eugenia platysema

Pyrus communis, European pear

Eugenia pyriformis, uvaia

Rollinia aff. sericea

Eugenia schomburgkii

Rollinia emarginata

Eugenia stipitata, araçá, araçá-boi

Rollinia laurifolia

Eugenia uniflora, Surinam cherry

Rollinia sericea, araticum-alvadio

Ficus carica, fig

Rubus sp., raspberries, blackberries, dewberries

Fortunella japonica, round kumquat

Rubus ulmifolius, Elmleaf blackberry

Fragaria ananassa, strawberry

Salacia campestris

Fragaria vesca, strawberry

Simaba guianensis

Garcinia brasiliensis, bakupari

Solanum sp.

Helicostylis sp.

Spondias dulcis, ambarella, jew plum

Inga edulis, ice cream bean, monkey tail

Spondias purpurea, jocote

Inga sellowiana, ingá mirim, ingá da serra

Spondias sp., hog plums, Spanish plums

Jacaratia heptaphylla

Stenocalyx dysentericus, cagaita, cagaiteira

Jambosia sp., rose apple

Syzygium aqueum, watery rose apple

Malpighia emarginata, Barbados cherry

Syzygium jambos, rose apple

Malpighia glabra, Barbados cherry

Syzygium malaccense, Malay rose apple

Malpighia sp., cherries

Terminalia catappa, Indian almond

Malus domestica, apple

Vitis vinifera, grapes

 

Ximenia americana, tallow-wood

 

Economic Importance

Anastrepha fraterculus is an important pest in South America. For instance, attack by females from the Brazilian-1 morphotype to apple orchards in southern Brazil can result in economic losses estimated at US $110 million (about 5% of the production or approximately 60,000 tons). In the same region, it is estimated that the losses in peaches can reach around 40% of the total production. Grapes can also be attacked, but the larvae cannot complete their development in grapes (Figure 10).

Figure 10. Damage to grapes caused by females of Anastrepha fraterculus (Wiedemann) complex.
Figure 10.  Damage to grapes caused by females of Anastrepha fraterculus (Wiedemann) complex.
Credit: Vanessa Dias, University of Florida

 

Management

Besides pesticides and toxic baits, more environmental friendly techniques can be applied to reduce the population of insects from the Anastrepha fraterculus complex. One of those approaches is the Sterile Insect Technique (SIT), a method of control based on the reduction of fertility in a target population through the mating of sterile males (released from the laboratory) and fertile females (wild females from the target pest population) (Lance and McInnis 2005).

The successful implementation of SIT programs depends on correctly understanding species boundaries within the Anastrepha fraterculus complex because sexual compatibility is a requirement for the success of the technique (Hendrichs et al. 2015). In addition, biological control and mating disruption are other promising strategies that can be used in integrated pest management programs to control Anastrepha fraterculus populations.

Acknowledgements

The authors would like to thank Vicente Hernández-Ortiz, Instituto de Ecología AC—Mexico, Nelson Canal,Universidad del Tolima—Colombia, and Silvana Caravantes, International Atomic Energy Agency, for reviewing this article and contributing with helpful suggestions.

Selected References

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Cáceres C, Segura DF, Vera MT, Wornoayporn V, Cladera JL, Teal P, Sapountzis P, Bourtzis K, Zacharopoulou A, Robinson AS. 2009. Incipient speciation revealed in Anastrepha fraterculus (Diptera: Tephritidae) by studies on mating compatibility, sex pheromones, hybridization, and cytology. Biological Journal of the Linnean Society 97: 152–165.

Canal NA, Hernández-Ortiz V, Tigrero SJO, Selivon D. 2015. Morphometric study of third-instar larvae from five morphotypes of the Anastrepha fraterculus cryptic species complex (Diptera, Tephritidae). In De Meyer M, Clarke AR, Vera MT, Hendrichs J (Eds) Resolution of Cryptic Species Complexes of Tephritid Pests to Enhance SIT Application and Facilitate International Trade. ZooKeys 540: 41–59.

Devescovi F, Abraham S, Roriz AKP, Nolazco N, Castaneda R, Tadeo E, Cáceres C, Segura DF, Teresa Vera M, Joachim-Bravo IS, Canal N, Rull J. 2014. Ongoing speciation within the Anastrepha fraterculus cryptic species complex: The case of the Andean morphotype. Entomologia Experimentalis Et Applicata 152: 238–247.

Dias VS, Silva JG, Lima KM, Petitinga CSCD, Hernández-Ortiz V, Laumann RA, Paranhos BJ, Uramoto K, Zucchi RA, Joaquim-Bravo IS. 2016. An integrative multidisciplinary approach to understanding cryptic divergence in Brazilian species of the Anastrepha fraterculus complex (Diptera: Tephritidae). Biological Journal of the Linnean Society 117: 725–746.

Greene CT. 1934. A revision of the genus Anastrepha based on a study of the wings and on the length of the ovipositor sheath (Diptera: Trypetidae). Proceedings of the Entomological Society of Washington 36: 127–179.

Hendrichs J, Vera MT, De Meyer M, Clarke AR. 2015. Resolving cryptic species complexes of major tephritid pests. In De Meyer M, Clarke AR, Vera MT, Hendrichs J (Eds) Resolution of Cryptic Species Complexes of Tephritid Pests to Enhance SIT Application and Facilitate International Trade. ZooKeys 540: 5–39.

Hernández-Ortiz V, Bartolucci AF, Morales-Valles P, Frias D, Selivon D. 2012. Cryptic species of the Anastrepha fraterculus Complex (Diptera: Tephritidae): A multivariate approach for the recognition of South American morphotypes. Annals of the Entomological Society of America 105: 305–318.

Hernández-Ortiz V, Canal NA, Tigrero Salas JO, Ruíz-Hurtado FM, Dzul-Cauich JF. 2015. Taxonomy and phenotypic relationships of the Anastrepha fraterculus complex in the Mesoamerican and Pacific Neotropical dominions (Diptera, Tephritidae). De Meyer M, Clarke AR, Vera MT, Hendrichs J (Eds) Resolution of Cryptic Species Complexes of Tephritid Pests to Enhance SIT Application and Facilitate International Trade. ZooKeys 540: 95–124.

Hernández-Ortiz V, Gomez-Anaya JA, Sanchez A, McPheron BA, Aluja M. 2004. Morphometric analysis of Mexican and South American populations of the Anastrepha fraterculus complex (Diptera: Tephritidae) and recognition of a distinct Mexican morphotype. Bulletin of Entomological Research 94: 487–499.

Lance D, McInnis D. 2005. Biological basis of the sterile insect technique. In Dyck VA, Hendrichs J, Robinson A. (eds) Sterile Insect Technique: principles and practice in area-wide integrated pest management. Springer, Dordrecht, pp 69–94.

Morgante JS, Malavasi A, Bush GL. 1980. Biochemical systematics and evolutionary relationships of Neotropical Anastrepha. Annals of the Entomological Society of America 73: 622–630.

Murillo T, Jiron LF. 1994. Egg morphology of Anastrepha obliqua and some comparative aspects with eggs of Anastrepha fraterculus (Diptera, Tephritidae). Florida Entomologist 77: 342–348.

Nieuwenhove GAV, Ovruski SM. 2011. Influence of Anastrepha fraterculus (Diptera: Tephritidae) larval instars on the production of (Hymenoptera: Braconidae) progeny and their sex ratio. Florida Entomologist 94: 863–868.

Rull J, Abraham S, Kovaleski A, Segura DF, Mendoza M, Clara Liendo M, Teresa Vera M. 2013. Evolution of pre-zygotic and post-zygotic barriers to gene flow among three cryptic species within the Anastrepha fraterculus complex. Entomologia Experimentalis Et Applicata 148: 213–222.

Selivon D, Morgante JS, Perondini ALP. 1997. Egg size, yolk mass extrusion and hatching behavior in two cryptic species of Anastrepha fraterculus (Wiedemann) (Diptera, Tephritidae). Brazilian Journal of Genetics 20: 587–594.

Selivon D, Perondini ALP, Morgante JS. 2005. A genetic-morphological characterization of two cryptic species of the Anastrepha fraterculus complex (Diptera: Tephritidae). Annals of the Entomological Society of America 98: 367–381.

Selivon D, Perondini ALP. 1998. Eggshell morphology in two cryptic species of the Anastrepha fraterculus complex (Diptera: Tephritidae). Annals of the Entomological Society of America 91: 473–478.

Smith-Caldas MRB, McPheron BA, Silva JG, Zucchi RA. 2001. Phylogenetic relationships among species of the fraterculus group (Anastrepha: Diptera: Tephritidae) inferred from DNA sequences of mitochondrial cytochrome oxidase I. Neotropical Entomology 30: 565–573.

Steck GJ. 1991. Biochemical systematics and population genetic-structure of Anastrepha fraterculus and related species (Diptera: Tephritidae). Annals of the Entomological Society of America 84: 10–28.

Stone A. 1942. The fruit flies of the genus Anastrepha. U.S. Department of Agriculture Miscellaneous Publication 439: 1–112. Washington, D.C.

Vanícková L, Brízová R, Pompeiano A, Ferreira LL, de Aquino NC, Tavares RF, Rodriguez LD, Mendonça AL, Canal NA, do Nascimento RR. 2015. Characterisation of the chemical profiles of Brazilian and Andean morphotypes belonging to the Anastrepha fraterculus complex (Diptera, Tephritidae). De Meyer M, Clarke AR, Vera MT, Hendrichs J (Eds) Resolution of Cryptic Species Complexes of Tephritid Pests to Enhance SIT Application and Facilitate International Trade. ZooKeys 540: 193–209.

Vera MT, Cáceres C, Wornoayporn V, Islam A, Robinson AS, De La Vega MH, Hendrichs J, Cayol JP. 2006. Mating incompatibility among populations of the South American fruit fly Anastrepha fraterculus (Diptera: Tephritidae). Annals of the Entomological Society of America 99: 387–397.

Zucchi RA (2016) Fruit flies in Brazil – Anastrepha species their host plants and parasitoids. http://www.lea.esalq.usp.br/anastrepha (30 November 2017)

Footnotes

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Publication #EENY-696

Release Date:February 6, 2018

Reviewed At:September 8, 2021

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About this Publication

This document is EENY-696, one of a series of the Entomology and Nematology Department, UF/IFAS Extension. Original publication date December 2017. 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 http://entomology.ifas.ufl.edu/creatures.

About the Authors

Vanessa Simões Dias; and Andrea Lucky; Entomology and Nematology Department; UF/IFAS Extension, Gainesville, FL 32611.

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