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Toxoptera citricidus

2006; Wiley; Volume: 36; Issue: 3 Linguagem: Catalão

10.1111/j.1365-2338.2006.01040.x

1365-2338

apterae are medium-sized aphids, mm long. They are shiny, very dark brown to black. They need to be examined microscopically to observe the very long, fine and erect hairs on the legs and body margins. Siphunculi are as for the alatae but relatively …,

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EPPO BulletinVolume 36, Issue 3 p. 451-456 Free Access Toxoptera citricidus First published: 15 December 2006 https://doi.org/10.1111/j.1365-2338.2006.01040.xCitations: 6 European and Mediterranean Plant Protection Organization Organisation Européenne et Méditerranéenne pour la Protection des Plantes AboutSectionsPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinkedInRedditWechat PM 7/75 (1) Specific scope This standard describes a diagnostic protocol for Toxoptera citricidus. Specific approval and amendment Approved in 2006-09. Introduction Toxoptera citricidus is a sap-sucking insect in the family Aphididae (aphids). The aphid feeds on Citrus species and occasionally on other Rutaceae. Non-rutaceous plants are not normally suitable hosts of T. citricidus, but may be colonized when young and tender citrus foliage is unavailable. T. citricidus can cause direct damage to citrus trees by attacking shoots, flower buds and sometimes young fruit but the major impact of T. citricidus is due to its transmission of Citrus tristeza closterovirus (CTV). Among aphid vectors of CTV, T. citricidus is the most efficient (high transmission efficiency, prolific reproduction, dispersal adequately timed with citrus flush cycles to maximize chances of acquiring and transmitting the virus). In particular, it can efficiently transmit the severe strains of CTV causing quick decline and death of citrus trees grafted on sour orange (Citrus aurantium). T. citricidus is also reported to transmit other diseases such as Citrus vein enation virus, stem-pitting virus, Eureka-seedling virus and bud union decline of citrus. It is also reported as able to transmit mosaic viruses of abaca, pea, yam and zucchini and chili veinal mottle virus (Potyvirus). This aphid occurs predominantly in humid tropical regions and is presumed to originate from South-east Asia but it has also spread to areas of Mediterranean climate. It is widespread in Africa south of the Sahara and also present in Morocco and Tunisia, Asia (from India to Japan), Australia, New Zealand, the Pacific Islands and subtropical and warm temperate areas of South America. It has spread to important citrus-growing areas in Central America, the Caribbean and southern USA. Recently, its presence has been detected in the EPPO region, in Portugal (Madeira in 1994 and mainland in 2004) and Spain (unpublished). Further information can be found in the EPPO datasheet on Toxoptera citricidus (EPPO/CABI, 1997) and the Crop Protection Compendium (CABI, 2005). Identity Name: Toxoptera citricidus (Kirkaldy) Synonyms: Toxoptera citicida (Kirkaldy) Aphis aeglis (Shinji) Aphis nigricans (van der Goot) Aphis tavaresi (del Guercio) Myzus citricidus (Kirkaldy) Paratoxoptera argentiniensis (Blanchard) Note: In the past many records of T. citricidus actually refer to T. aurantii (Boyer de Fonscolombe), the black citrus aphid, but only rarely does the reverse occur Taxonomic position: Insecta Hemiptera, Homoptera, Aphididae EPPO computer code: TOXOCI Phytosanitary categorization: EPPO A1 list: no. 45, EU Annex designation: II/A1. Detection An infestation of T. citricidus may be detected on citrus plants by the presence of distorted leaves and impaired shoot growth. On Citrus trees, even a few aphids on a young shoot will arrest blossom bud development and cause them to fall. Growth of shoots is greatly impaired and they become distorted; leaves become brittle, wrinkled and curl downwards. Branches may become deformed and leaves shrivelled. Attacked flowers fail to open or do so abortively since the ovaries are deformed. Caution should be shown however, as other aphid species, such as Brachycaudus helichrysi (Kaltenbach), the leaf-curling plum aphid, can also cause distorted leaves. Another sign of an aphid infestation is the presence of honeydew on which black, sooty moulds develop. Ants may also be present, collecting honeydew from the aphids. Aphids are most likely to be detected if the young growth is inspected. They can also be found by beating foliage over a white surface. Yellow traps (water or sticky) or suction traps can help to monitor populations of alatae, but are only an indication that aphids are present in the area and are not suitable for detecting outbreaks at an early stage. An infestation of T. citricidus may be indicated by the presence of medium-sized, shiny, very dark brown to black aphids. When they are disturbed they may make stridulatory movements with their hind legs, but they do not produce audible sounds, unlike T. aurantii, which produces a sound that can be heard up to 45 cm away. Also an indication of the presence of T. citricidus in the field, is that when the insect is squeezed onto a white surface, a red colour is obtained. Likewise specimens in alcohol colour the fluid deep red whereas specimens of other Toxoptera species do not. Nineteen species of aphids have been recorded from citrus (Blackman & Eastop, 2000). Some of these cause leaf distortion and like T. citricidus are coloured brown to black and mixed colonies of two or more species are common (Halbert & Brown, 1998). All identification must be confirmed by examination of slide mounted specimens in the laboratory. Specimens can be stored in 70–80% alcohol until prepared for slide mounting. Identification Some identification features can be seen using a × 20 hand lens or a dissecting microscope, however, for full identification a permanent slide mount (Appendix 1) should be made and retained for reference. The most comprehensive key to aphids found on citrus is Blackman & Eastop (2000) (Appendix 2). Identification of aphids is generally based on mature apterous and alate aphids, see Appendix 2 (Blackman & Eastop, 2000) and Appendix 3 (Martin, 1991), as not all larvae stages of immature aphids can be reliably identified. Identification of larvae First instar larvae of Toxoptera spp. can be identified using the key in Appendix 4 (Martin, 1991). If other instar immatures are present they can be reared to adults for identification. Identification of adults Species of the genus Toxoptera closely resemble those of the genus Aphis, but are easily distinguished from the latter by the presence of a stridulatory apparatus consisting of latero-ventral ridges on the abdomen and peg-like hairs on the hind tibiae, Web Fig. 1 (CSL) and Appendix 2, Web Fig. 2(q) (Blackman & Eastop, 2000). Identification of T. citricidus apterae T. citricidus apterae are medium-sized aphids, 1.5–2.8 mm long. They are shiny, very dark brown to black. They need to be examined microscopically to observe the very long, fine and erect hairs on the legs and body margins. Siphunculi are as for the alatae but relatively shorter. The cauda is thick and bluntly rounded at the apex. T. citricidus apterae can be identified using the keys for apterous citrus aphids (Blackman & Eastop, 2000) (Appendix 2), polyphagous tree-dwelling aphids (Blackman & Eastop, 1994), apterous and alate Toxoptera spp. (Eastop, 1966), apterous and alate Toxoptera spp. (Martin, 1991) (Appendix 3), apterous and alate aphids that are citrus pests in the United States of America (Stoetzel, 1994), apterous and alate citrus aphids (Tao & Tan, 1961). Identification of T. citricidus alatae T. citricidus alatae are medium-sized aphids, 1.5–2.8 mm long. They are shiny black and can be identified, using a pocket lens, by the wholly black third antennal segment, succeeded by a pale fourth but identification must be confirmed by examining slide mounted specimens, Appendix 3 (Martin, 1991). The median vein of the forewings is normally forked twice. Siphunculi are about 1/6 body length and strongly sculptured, while the cauda is rather bulbously rounded at the apex. T. citricidus alatae can be identified using the keys apterous and alate Toxoptera spp. (Eastop, 1966), apterous and alate Toxoptera spp. (Martin, 1991) (Appendix 3), apterous and alate aphids that are citrus pests in the USA (Stoetzel, 1994), apterous and alate citrus aphids (Tao & Tan, 1961). Of the 19 aphid species reported to feed on citrus, 14 can be keyed out using the key of Blackman & Eastop (2000) (Appendix 2). Six of the 19 aphids are more likely to be confused with T. citricidus, namely Aphis craccivora, A. gossypii, A. neri, A. spiraecola, T. aurantii and T. odinae. All of these six can be keyed out using Blackman and Eastop's key (2000). There are three other described species of Toxoptera which can be compared with T. citricidus using the details given below and in Table 1. Table 1. Comparison with other Toxoptera species Character T. citricidus T. aurantii T. odinae Size of apterae and alatae 1.5–2.8 mm 1.1–2.0 mm 1.3–2.4 mm Colour – apterae shiny, very dark brown to black shiny, reddish–brown, brown–black to black grey–brown to reddish–brown Colour – immatures brown brownish brown Colour – alatae shiny black abdomen dark brown to black abdomen reddish–brown to dark brown abdomen Antennae – apterae not so conspicuously black–and–white banded black–and–white banded pale Antennae alatae segment III – black with a pale base segment IV – pale segment III and IV – white with a dark tip segment III and IV – pale Antennal setae – segment III longer than the basal diameter of the segment shorter than the basal diameter of the segment twice as long as the basal diameter of the segment Forewing – media normally twice branched normally once branched normally twice branched Forewing – pterostigma pale black pale Siphunculi black – longer than cauda black – longer than cauda dusky – 3/4 length of cauda Cauda black black black Caudal setae – apterae 25–54 9–20 15–18 Caudal setae – alatae 25–40 8–19 15–18 Stridulation no audible sound to the human ear an audible sound to human ears Not known Preserved specimens colour fluid deep red (also squashed aphids colour a white surface red) do not colour fluid or a white surface red do not colour fluid or a white surface red Host plants Rutaceae almost exclusively – only occasionally on members of other plant families 120 + species in more than 10 plant families including the Rutaceae 25 + species in more than 15 plant families including the Rutaceae, although not commonly on Citrus spp. Toxoptera aurantii (Boyer de Fonscolombe) is the most widespread and polyphagous of the other Toxoptera spp. and is therefore the one most commonly encountered that may be confused with T. citricidus. T. aurantii can be found in warm temperate, subtropical and tropical areas and under glass elsewhere. T. odinae (van der Goot) is polyphagous, occurring on various trees and shrubs in Asia, including South-east Asia, and is widespread in Africa south of the Sahara. T. victoriae was only described by Martin in 1991, from Zanthoxylum scandens in Hong Kong. It may occur on other Zanthoxylum spp. that are of tree habit. In the key, Appendix 2, it will key out to T. odinae but can be separated from the latter species by using the key in Appendix 3. Adults of T. victoriae (Martin) are shiny black and immatures are reddish-brown. Reference material The Natural History Museum, London holds reference specimens which have been identified by UK national specialists. No type material is held there. Reporting and documentation Guidance on reporting and documentation is given in EPPO Standard PM 7/77 (1) Documentation and reporting on a diagnosis. Further information Further information on this organism can be obtained from Roger Hammon, Pest and Disease Identification Team, Central Science Laboratory, Sand Hutton, York, YO41 1LZ, UK. Footnotes 1 The figures in this standard marked ‘Web Fig.’ are published on the EPPO Website http://www.eppo.org. Acknowledgements This protocol was prepared by Roger Hammon, Pest and Disease Identification Team, Central Science Laboratory, Sand Hutton, York, YO41 1LZ, UK on the basis of an original draft prepared by the Department of Diagnostics, Plant Protection Service, Wageningen, the Netherlands. Vic Eastop, Roger Blackman and Jon Martin (British Natural History Museum, London, UK) have provided the keys included in this protocol. References Blackman RL & Eastop VF (1994) Aphids on the World's Trees. An identification and information guide: i–viii, 1– 987, 16 plates. CAB International, Wallingford (GB)/ The Natural History Museum, London (GB). Blackman RL & Eastop VF (2000) Aphids on the World's Crops: an Identification and Information Guide, 2nd edn. i–x, 1– 466. Wiley, Chichester (GB). CABI (2005) CABI Crop Protection Compendium. CAB International, Wallingford (GB). EPPO/CABI (1997) Datasheets on Quarantine Pests: Toxoptera citricidus. In Quarantine Pests for Europe, edition 2nd edn, pp. 543– 546. CAB International, Wallingford, (GB). Eastop VF (1966) A taxonomic study of Australian Aphidoidea (Homoptera). Australian Journal of Zoology 14, 399– 592. Halbert SE & Brown LG (1998) Toxoptera citricida (Kirkaldy), Brown citrus aphid, Identification, Biology and Management Strategies. Entomology Circular no. 374. Division of Plant Industry. Florida Department of Agriciculture & Consumer Services (US). Martin JH (1991) A new Toxoptera species from Rutaceae in Hong Kong (Homoptera: Aphididae). Bulletin of Entomological Research 81, 277– 281. Mondal PK, Basu RS & Raychaudhuri DN (1976) Studies on the aphids from eastern India XXX. The genus Toxoptera. Oriental Insects 10, 533– 540. Nieto Nafría JM, Alonso-Zarazaga MA & Pérez Hidalgo N (2005) Toxoptera citricida or Toxoptera citricidus? The validity of a specific name (Hemiptera, Aphididae, Aphidini). Graellsia 61, 141– 142. Remaudiére G & Remaudiére M (1997) Catalogue of the World's Aphididae (Homoptera: Aphidoidea). Institut National de la Recherche Agronomique, Paris (FR). Stoetzel MB (1994) Aphids (Homoptera: Aphididae) of potential importance on Citrus in the United States with illustrated keys to species. Proceedings of the Entomological Society of Washington 96, 74– 90. Tao CC & Tan MF (1961) Identification, seasonal population and chemical control of citrus aphids. Journal of Agricultural Research, Taipei 10, 41– 53. Appendix 1 Permanent microscope-slide preparation of aphids 1 Heat specimens gently, at 70°C, in 70% ethanol for 5–10 min 2 Transfer to 10% KOH and heat until colour just begins to leach out of specimens. To aid maceration the body can be squeezed with fine spatulas and the contents can be gently worked to the rear of the body and squeezed out. If this proves difficult then an incision can be made in one side of the body and the contents squeezed out through this. Caution must be taken to avoid splitting the body 3 Transfer to cold 70% alcohol for at least 10 min 4 Transfer to cold glacial acetic acid for 5 min 5 Reset the heating block to 80°C and heat in chloral phenol until completely cleared 6 Rinse in glacial acetic acid 7 Transfer to fresh cold glacial acetic acid for 5 min 8 Leave in clove oil for at least 10 min 9 Mount aphids on a microscope slide, in Canada balsam, ventral side up with appendages spread. Appendix 2 Key to aphids recorded on Citrus spp. (Blackman & Eastop, 2000) Fourteen aphid species recorded from citrus are included in the key: • Aphis craccivora, A. gossypii, A. nerii, A. spiraecola • Aulacorthum magnoliae, A. solani • Brachycaudus helichrysi • Brachyunguis harmalae • Macrosiphum euphorbiae • Myzus persicae • Sinomegoura citricola • Toxoptera aurantii, T. citricidus, T. odinae. [Five other species have been recorded one or more times from citrus but are not keyed here: Aphis arbuti Ferrari 1872, A. fabae, Brachycaudus cardui, Pterochloroides persicae and Rhopalosiphum maidis]. 1. Antennal tubercles weakly developed (Web Fig. 1a–c) 2 Antennal tubercles well-developed (Web Fig. 1d–f) 10 2. Terminal process a little shorter than base of last antennal segment (Web Fig. 2a). Siphunculi (Web Fig. 2b) much shorter than cauda (Web Fig. 2f) Brachyunguis harmalae Terminal process much longer than base of last antennal segment. Siphunculi shorter or longer than cauda (e.g. Web Fig. 2c–e, i–o, t–w) 3 3. Cauda helmet-shaped in dorsal view, not longer than its width at base (Web Fig. 2g) Brachycaudus helichrysi Cauda tongue-shaped or triangular in dorsal view, longer than its basal width (Web Fig. 2f, h) 4 4. Dorsal abdomen with an extensive black patch (Web Fig. 2i) Aphis craccivora Dorsal abdomen without an extensive black patch 5 5. Siphunculi much shorter than cauda (Web Fig. 2j) Toxoptera odinae Siphunculi longer than, or at least as long as, cauda (Web Fig. 2k–o) 6 6. Terminal process of antenna more than 3.5 times longer than base of last segment. Cauda with at least 10 hairs 7 Terminal process of antenna less than 3.5 times longer than base of last segment. Cauda usually with less than 10 hairs 9 7. Cauda with usually more than 20 hairs (Web Fig. 21). Hairs on antennal segment III longer than diameter of this segment at its base (Web Fig. 2p). Thoracic segments often partly sclerotized Toxoptera citricidus Cauda with usually less than 20 hairs. Hairs on antennal segment III often shorter than diameter of this segment at its base. Thoracic tergites usually unsclerotized 8 8. Siphunculi less than 1.5 times longer than cauda (Web Fig. 2k). Stridulatory apparatus present (Web Fig. 2q) Toxoptera aurantii Siphunculi more than 1.5 times longer than cauda (Web Fig. 2m). Stridulatury apparatus absent Aphis nerii 9. Cauda paler than siphunculi, with 4–7 hairs (Web Fig. 2o). Femoral hairs all rather short, less than width of femur at base (Web Fig. 2r) Aphis gossypii Cauda as dark as siphunculi, with 6–12 hairs (Web Fig. 2n). Some femoral hairs long and fine, exceeding width of femur at its base (Web Fig. 2) Aphis spiraecola 10. Inner faces of antennal tubercles convergent in dorsal view (Web Fig. 1f) Myzus persicae Inner faces of antennal tubercles parallel or divergent (Web Fig. 1d, e) 11 11. Siphunculi a little shorter than the dark cauda (Web Fig. 2d, t) Sinomegoura citricola Siphunculi much longer than cauda (Web Fig. 2u−w) 12 12. Head, legs and antennae mainly dark. Femora basally pale but with distal 0.5–0.75 black. Siphunculi slightly swollen over distal 0.7 of length (Web Fig. 2e, u). Cauda with a constriction Aulacorthum magnoliae Head, legs and antennae mainly pale. Siphunculi tapering or parallel over most of length (Web Fig. 2v, w). Cauda without any constriction 13 13. Inner faces of antennal tubercles parallel (Web Fig. 1e). Siphunculi without any polygonal reticulation (Web Fig. 2v). Cauda only 0.1–0.125 of body length Aulacorthum solani Inner faces of antennal tubercles divergent (Web Fig. 1d). Siphunculi with a subapical zone of polygonal reticulation (Web Fig. 2w). Cauda longer, 0.14–0.2 of body length Macrosiphum euphorbiae © The Natural History Museum, London Appendix 3 Key to Toxoptera species, adult apterae and alatae (Martin, 1991) This key is designed for both apterae and alatae. Although adult alatae of T. victoriae (Martin) sp. n. have not been seen, the presence of the key characters in the fourth instar alatoid nymphs indicates that alatae will be readily recognisable from characters also present in apterae. With the variability of many ratios (e.g. siphunculus length: cauda length) such measurements are used as secondary recognition characters in this key, and are simplified for ease of use. Mondal et al. (1976) can be consulted for details of measurements of the three major Toxoptera species, based upon Indian material. 1. Abdominal segment VIII bearing only 2, occasionally 3, dorsal hairs. Siphunculi almost always longer than cauda. Hairs on antennal segment III short, usually less than twice basal articular diameter of segment (Web Figs 4.11, 4.14) 2 Abdominal segment VIII bearing 4–12 dorsal hairs (Web Figs 4.2 and 4.10). Siphunculi either subequal to or less than three-quarters of length to cauda. Hairs on antennal segment III long and fine, over twice basal articular diameter of segment (Web Figs 4.8 and 4.9) 3 2. Apterae with antennal segments III and IV completely pale (Web Fig. 4.14). Alatae with antennal segment III brown to black (Web Fig. 4.13), and with median veins of forewings normally twice-branched. Siphunculi of both apterae and alatae covered by dense, coarse, imbrications. Cauda usually with more than 25 hairs. Hairs on antennal segment III longer than basal articular diameter of segment citricidus (Kirkaldy) Apterae with antennal segments III and IV each with a distinct brown apex (Web Fig. 4.12). Alatae with antennal segment III pale but with a distinct brown apex as in apterae (Web Fig. 4.11), and with median veins of forewings normally only once-branched. Siphunculi less coarsely imbricate. Cauda only rarely with more than 20 hairs, frequently with many less. Hairs on antennal segment III rarely longer than basal articular diameter of segment aurantii (Boyer de Fonscolombe) 3. Siphunculi short and conical, less than three-quarters length of cauda (Web Fig. 4.10). Base of last antennal segment usually with 2 hairs (often additionally with a short spine). Normal tibial hairs of all legs appearing similar, long and fine. Pale cuticle of antennal segments III–V similar in shade to other pale parts of body odinae (van der Goot) Siphunculi longer and basally broader, length subequal to cauda (Web Fig. 4.2). Base of last antennal segment with 5–7 hairs (Web Fig. 4.1). Tibial hairs of fore and middle pairs of legs noticeably shorter and more spine-like than the fine hairs of hind legs. Pale cuticle of antennal segments III–V markedly paler than any cuticle elsewhere on body victoriae (Martin) © Crown Copyright, 1991 Appendix 4 Key to Toxoptera species, first instar larvae (Martin, 1991) All larval stages of Toxoptera spp. are immediately distinguished from those of other genera by the presence of hind tibial pegs. First instar larvae are recognised by the presence of 4-segmented antennae. 1. Hairs on apical part of antennal segment III shorter than maximum diameter of segment. Siphunculi as long as, or longer than, maximum width 2 Hairs on apical part of antennal segment III twice maximum diameter of segment, or longer. Siphunculi normally shorter than maximum width 3 2. Siphunculi noticeably widest at base, about as long as maximum width distinct spinules scattered over surface. Body larger, 0.65–0.80 mm in length citricidus (Kirkaldy) Siphunculi almost parallel-sided, often rather longer than maximum width surface spinules may be present, but less distinct. Body smaller, 0.45–0.65 mm in length aurantii (Boyer de Fonscolombe) 3. Base at last (fourth) antennal segment with only 2 hairs. Abdominal segment VIII normally with only 2 dorsal hairs. Sides of siphunculi pigmented but mostly smooth. At least some hairs on fore and middle tibiae longer than median diameter of segment odinae (van der Goot) Base of last antennal segment with up to 5 hairs. Abdominal segment VIII with 4 dorsal hairs. Sides of siphunculi pigmented and roughened. Length of hairs on fore and middle tibiae maximally up to median diameter of segment victoriae Martin © Crown Copyright, 1991 Citing Literature Volume36, Issue3December 2006Pages 451-456 ReferencesRelatedInformation