Amblyseius herbicolus (Chant)
publication ID |
https://doi.org/ 10.24349/acarologia/20204376 |
DOI |
https://doi.org/10.5281/zenodo.4537616 |
persistent identifier |
https://treatment.plazi.org/id/767187FE-FFB3-FF9A-FE4C-9B57FDDE4CFA |
treatment provided by |
Felipe |
scientific name |
Amblyseius herbicolus (Chant) |
status |
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Amblyseius herbicolus (Chant) View in CoL
Typhlodromus (Amblyseius) herbicolus Chant 1959: 84 .
Amblyseius (Amblyseius) herbicolus, Muma 1961: 287 View in CoL .
Typhlodromus herbicolus, Hirschmann 1962: 23 .
Amblyseius herbicolus Moraes et al. 1986: 14, 1989a: 79 View in CoL , 2004: 27; Chant & McMurtry 2004: 208, 2007: 78.
Amblyseius impactus Chaudhri 1968: 553 View in CoL (synonymy according to Daneshvar & Denmark 1982; Denmark & Muma 1989).
Typhlodromus (Amblyseius) amitae Bhattacharyya 1968: 677 (synonymy according to Denmark & Muma 1989).
Amblyseius deleoni Muma & Denmark 1970: 68 View in CoL (synonymy according to Daneshvar & Denmark 1982; Denmark & Muma 1989).
Amblyseius giganticus Gupta 1981: 33 View in CoL (synonymy according to Gupta 1986).
Amblyseius (Amblyseialus) thermophilus Karg 1991: 12 View in CoL (synonymy according to El-Banhawy & Knapp 2011; Demite et al. 2020).
This species belongs to the largoensis species group as setae J2 and Z1 are present, setae s4 are minute and the ventrianal shield of the female is vase-shaped. It belongs to the largoensis species subgroup as setae Z4 are long, spermatheca has the calyx elongate and the female ventrianal shield is entire ( Chant and McMurtry 2004).
It is widespread in all tropical and subtropical regions of the world. It is the second most abundant phytoseiid mite on Coffea arabica L. in Brazil, associated with Brevipalpus phoenicis (Geijskes) , vector of the coffee ring spot virus and it was found to be an efficient predator ( Reis et al. 2007). Amblyseius herbicolus is also found associated with the broad mite, P. latus in crops such as chili pepper ( Capsicum annuum L.) in Brazil and has also a good potential for controlling the pest. Rodriguez-Cruz et al. (2013) had studied biological, reproductive and life table parameters of A. herbicolus on three different diets: broad mites, castor bean pollen ( Ricinus communis L.) and sun hemp pollen ( Crotalaria juncea L.). The predator was able to develop and reproduce on all these three diets. However, its intrinsic growth rate was higher on broad mites and castor bean pollen. Feeding on alternative food such as pollen can facilitate the predator’s mass rearing and maintain its population on crops when prey is absent or scarce. Many polyphagous generalist phytoseiid mites are important natural enemies because they can feed on plant provided pollen and various prey species, and thus persist in crops even in the absence of target pests ( McMurtry et al. 2013). Hence, populations of these predators can be established in a crop by providing alternative food, thus increasing biological control. Alternative food affects P. latus control on chilli pepper plants by predatory mites ( Duarte et al. 2015). Amblyseius herbicolus had high oviposition and population growth rates when fed with cattail pollen ( Typha latifolia L.), chilli pepper pollen and bee-collected pollen, and a low rate on the alternative prey T. urticae . Supplementing pepper plants with pollen resulted in better control of broad mite populations ( Duarte et al. 2015). Release of A. herbicolus on young plants with weekly addition of honeybee pollen or cattail pollen until plants produce flowers seems a viable strategy to sustain populations of this predator ( Duarte et al. 2015). Amblyseius herbicolus was recorded recently in Comoros archipelago ( Kreiter et al. 2018b) and in La Réunion ( Quilici et al. 1997, 2000; Kreiter et al. 2020c).
World distribution: Argentina, Australia, Azores, Benin, Brazil, Burundi, Canary Islands, China, Colombia, Comore Island, Costa Rica, Dominican Republic, Dr Congo, El Salvador, Ghana, Guadeloupe Island, Guatemala, Hawaii, Honduras, India, Iran, Kenya, Les Saintes Island, La Réunion Island, Madagascar Island, Malawi, Malaysia, Martinique Island, New Caledonia Island, Papua New Guinea, Peru, Philippines, Portugal, Puerto Rico, Rwanda, Senegal, Singapore, South Africa, Spain, Taiwan, Thailand, Turkey, USA, Venezuela, West Indies.
Specimens examined: a single ♀ during this study. Mont Lubin (346 m aasl, lat. 19°42 ′ 21 ″ S, long. 63°26 ′ 40 ″ E), 1 ♀ on Passiflora edulis Sims (Passifloraceae) , 15/XI/2018.
Remarks: morphological and morphometric characters and all measurements fit well with measurement values given by Kreiter et al. (2018b, 2020c) for specimens from Grande Comore in Comoros and from La Réunion and by Ferragut and Baumann (2019) for specimens from Mauritius.
No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.
Kingdom |
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Order |
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Family |
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SubFamily |
Amblyseiinae |
Tribe |
Amblyseiini |
SubTribe |
Amblyseiina |
Genus |
Amblyseius herbicolus (Chant)
Kreiter, Serge & Abo-Shnaf, Reham I. A. 2020 |
Amblyseius (Amblyseialus) thermophilus
Karg W. 1991: 12 |
Amblyseius herbicolus
Moraes G. J. de & McMurtry J. A. & Denmark H. A. & Campos C. B. 2004: 27 |
Moraes G. J. de & McMurtry J. A. & van den Berg H. & Yaninek J. S. 1989: 79 |
Moraes G. J. de & McMurtry J. A. & Denmark H. A. 1986: 14 |
Amblyseius giganticus
Gupta S. K. 1981: 33 |
Amblyseius deleoni
Muma M. H. & Denmark H. A. 1970: 68 |
Amblyseius impactus
Chaudhri W. M. 1968: 553 |
Typhlodromus (Amblyseius) amitae
Bhattacharyya S. K. 1968: 677 |
Typhlodromus herbicolus
Hirschmann W. 1962: 23 |
Amblyseius (Amblyseius) herbicolus
Muma M. H. 1961: 287 |
Typhlodromus (Amblyseius) herbicolus
Chant D. A. 1959: 84 |