MONOPHLEBIDAE Signoret

Watson, Gillian W., 2022, Towards identification of the scale insects (Hemiptera: Coccomorpha) of continental Africa: 2. Checklists and keys to six archaeococcoid families, Zootaxa 5105 (3), pp. 301-356 : 316-321

publication ID

https://doi.org/10.11646/zootaxa.5105.3.1

publication LSID

lsid:zoobank.org:pub:187B04D7-4C35-4E27-9B2D-A616BF59F380

DOI

https://doi.org/10.5281/zenodo.6343187

persistent identifier

https://treatment.plazi.org/id/03D687D0-FFA9-984E-19E8-C912FA2EE348

treatment provided by

Plazi (2022-03-06 20:17:37, last updated 2024-11-28 20:54:10)

scientific name

MONOPHLEBIDAE Signoret
status

 

Family MONOPHLEBIDAE Signoret

Common names: Giant scales or monophlebids.

Background: The family Monophlebidae used to be regarded as a subfamily of the Margarodidae (sensu lato) ( Morrison 1928). The splitting of Margarodidae sensu lato into 11 families by Hodgson and Foldi (2006), based on male morphology, resulted in the monophlebids becoming a separate family of 47 genera containing 265 described species. The family is morphologically very diverse, with four tribes recognized: Llaveiini (all New World genera), Drosichini , Iceryini and Monophlebini . Monophlebid females are large, but the cuticle is very delicate, making them very difficult to collect and slide-mount without damage. Live specimens should be killed and preserved in alcohol without any attempt to detach them from the plant material, to avoid tearing the cuticle and losing the mouthparts ( Sirisena et al. 2013).

Appearance in life: Found on plant stems, branches, or leaves, often on woody hosts. Body of adult female normally oval and relatively large, up to 10 mm long or more ( Aspidoproctus maximus can reach 35 mm long); usually with white / yellow / brown wax secretions, these often flocculent, but occasionally without visible wax covering the body; sometimes with waxy projections from the body margins. To protect the eggs, some species form a large, sculptured white ovisac beneath and behind the abdomen, or develop a hollow marsupium by indentation of the venter of the abdomen. Antennae and legs well developed and heavily sclerotized, dark brown; antennae each with 9‒11 segments; legs all similar in size ( Miller et al. (2014)).

Identification: The best specimens for identification are young adult females just after the final moult, before the body has become distended with developing eggs. It is sometimes possible to identify intermediate-stage females ( Morrison (1928) provided some keys). Slide-mounted adult female up to 10 mm long or more, usually broadly oval ( Figs 9 View FIGURE 9 and 10 View FIGURE 10 ). Limbs well developed, usually conspicuous and dark; antennae each with 7‒11 segments; legs large, all similar in size, each tarsus 1 segmented; claw digitules not reaching to tip of claw and usually not enlarged apically. Internal anal tube present, the inner end with a simple sclerotized ring with or without pores. Cicatrices present. Abdominal spiracles numbering 1‒8 pairs, usually relatively conspicuous; thoracic spiracles each without pores in atrium (but pores often present just outside spiracular opening) ( Miller et al. (2014)).

Economic importance: Heavy infestations of monophlebids extract large volumes of phloem sap, drying plant tissues and causing leaf drop and branch dieback. Fouling of plant surfaces with sugary honeydew waste and the resultant sooty mould growth makes the plants unsightly and blocks light and air from the leaves, reducing photosynthesis and plant vigour, productivity and the market value of produce ( Kondo & Watson 2022 in press). The honeydew often attracts attendant ants. In India and neighboring areas, Drosicha mangiferae Green and D. stebbingii (Stebbing) (tribe Drosichini ) are pests of mango ( Karar et al. 2008). Some Icerya species are widespread pests, and in some parts of the world predators and dipteran parasites have been introduced to control them, e.g., cottony cushion scale, Icerya purchasi Maskell , is parasitised by Cryptochaetum iceryi (Williston) ( Diptera : Cryptochaetidae ), and I. aegyptiaca is preyed on by Novius cardinalis (Mulsant) and N. pumila (Weise) ( Coleoptera : Coccinellidae ) ( Kondo & Watson 2022 in press).

Biology: Monophlebids occur on many host-plant species, mostly woody shrubs and trees. There are 1‒3 generations annually, depending on climatic conditions. Usually, the female has four developmental instars; there is no cyst stage. The male has five instars; unlike in most scale insect families, the male prepupa is quite mobile, with well-developed legs and antennae. In India, D. mangiferae has one generation per year. The eggs, laid in ovisacs in the soil or leaf litter around the host plant, diapause through the winter and hatch early in spring. The crawlers walk up the host plant to the leaves to feed and moult; the sexes are indistinguishable until the third instar. In the male, the prepupa has wing buds and wanders about before forming a waxy test, where it completes development. Adults appear in late spring and mate on the host plant before the females migrate down to the ground to produce ovisacs and eggs ( Karar et al. 2008). Icerya purchasi , which is present in Africa, has a similar life cycle but remains on the plant throughout; the adult “female” (which is a hermaphrodite that can self-fertilise) lays eggs into a fluted wax ovisac attached to both the body and the substrate. Males are rare; they mate with females, but it is not clear whether their sperm are used for reproduction. Inseminated eggs produce hermaphrodites and unfertilised eggs produce males ( Hughes-Schrader 1930, 1963; Normark 2003; Mongue et al. 2021).

Checklist and distributions of Monophlebidae in continental Africa (3 tribes, 13 genera, 71 species, based on García Morales et al. 2016; Gavrilov-Zimin & Stekolshikov 2018, and Watson et al. 2021).

Tribe Drosichini (1 genus, 1 species)

Afrodrosicha nimbae Vayssière : Guinea

Tribe Iceryini (5 genera, 29 species)

Crypticerya ” aegyptiensis Foldi: Egypt

Crypticerya ” marocensis Foldi: Morocco

Crypticerya ” thibaudi Foldi: Egypt

Crypticerya ” sp. (sensu Foldi 2010); undescribed, on Rosa ): Kenya

Gigantococcus alboluteus (Cockerell) : Nigeria

Gigantococcus bicolor (Newstead) : Ghana

Gigantococcus bimaculatus (De Lotto) : Kenya

Gigantococcus brachystegiae (Hall) : Zimbabwe

Gigantococcus cajani (Newstead) : Nigeria

Gigantococcus caudatus (Newstead) : Sierra Leone, Uganda

Gigantococcus euphorbiae (Brain) : Benin, Mozambique, South Africa, Zimbabwe

Gigantococcus ewarti (Newstead) : Nigeria

Gigantococcus gowdeyi (Newstead) : Ghana, Uganda

Gigantococcus longisetosus (Newstead) : Democratic Republic of the Congo, Kenya, Sierra Leone, Tanzania

Gigantococcus maximus (Newstead) : Democratic Republic of the Congo, Gabon, Ghana, Ivory Coast, Kenya, Nigeria, Uganda

Gigantococcus nigroareolatus (Newstead) ; Benin, Democratic Republic of the Congo, Ghana, Tanzania, Uganda

Gigantococcus pattersoni (Newstead) : Ghana, Kenya

Gigantococcus rodriguezi (Castel-Branco) : Mozambique

Gigantococcus schoutedeni (Vayssière) : Democratic Republic of the Congo, Kenya, Senegal

Gigantococcus splendidus (Lindinger) : Tanzania

Gigantococcus sulfureus (Linidinger) : Tanzania, Uganda

Gigantococcus theobromae (Newstead) : Nigeria

Gueriniella serratulae (Fabricius) : Algeria

Icerya aegyptiaca (Douglas) : Egypt, Kenya, Tanzania ( Zanzibar)

Icerya corticalis Vayssière : Democratic Republic of the Congo

Icerya natalensis (Douglas) : South Africa

Icerya purchasi Maskell : Algeria, Angola, Democratic Republic of the Congo, Egypt, Eritrea, Ethiopia, Kenya, Libya, Malawi, Morocco, Mozambique, Senegal, Somalia, South Africa, Sudan, Tanzania (including Zanzibar), Togo, Tunisia, Uganda, Zambia, Zimbabwe

Icerya seychellarum (Westwood) : Egypt, Ethiopia, Kenya, Malawi, South Africa, Uganda

Steatococcus ” hystrix Gavrilov-Zimin & Stekolshikov: Mali

Tribe Monophlebini (7 genera, 41 species)

Aspidoproctus armatus Newstead : Democratic Republic of the Congo, Mozambique, Tanzania, Zimbabwe

Aspidoproctus bifurcatus Thorpe : Tanzania, Zimbabwe

Aspidoproctus bouvieri Vayssière : Gabon

Aspidoproctus carinatus (Lindinger) : Tanzania

Aspidoproctus congolensis Vayssière : Democratic Republic of the Congo

Aspidoproctus ellenbergeri Vayssière : Zambia

Aspidoproctus ghesquierei Vayssière : Democratic Republic of the Congo

Aspidoproctus giganteus Newstead : Nigeria

Aspidoproctus glaber (Lindinger) ; Malawi, Zimbabwe

Aspidoproctus magnicornis Thorpe : Uganda

Aspidoproctus maximus (Lounsbury) : Tanzania, Zimbabwe

Aspidoproctus mimeuri Vayssière : Senegal

Aspidoproctus mirabilis (Cockerell) : South Africa, Tanzania

Aspidoproctus neavei Newstead : Malawi

Aspidoproctus pallidus (Newstead) : Tanzania

Aspidoproctus parvus (Lindinger) : Tanzania

Aspidoproctus pertinax (Newstead) : Malawi, Zimbabwe

Aspidoproctus tricornis (Newstead) : Kenya, Malawi, South Africa, Zimbabwe

Aspidoproctus verrucosus Newstead ; Uganda

Aspidoproctus vuileti (Vayssière) : Niger

Aspidoproctus zimmermanni (Newstead) , comb. n. (see below): Tanzania

Monophleboides africanus (Newstead) : Namibia

Monophleboides arachidis Vayssière : Democratic Republic of the Congo

Monophleboides gymnocarpi (Hall) : Egypt

Monophleboides hirtus (Brain) : Malawi, South Africa

Monophleboides sjostedti (Newstead) : Tanzania

Monophleboides suaedae halocnemae (Vayssière) : Tunisia

Monophleboides suaedae suaedae (Vayssière) : Tunisia

Monophlebus dumonti Vayssière : Tunisia

Monophlebus hoggarensis Vayssière ; Algeria

Monophlebus raddoni Westwood : Ghana, Uganda

Palaeococcus fuscipennis (Burmeister) : Algeria

Pseudaspidoproctus acaciae (Joubert) : South Africa

Pseudaspidoproctus africanus (Newstead) : Tanzania

Pseudaspidoproctus fortis (Cockerell) : South Africa

Pseudaspidoproctus fulleri (Cockerell) : Kenya, South Africa

Pseudaspidoproctus hyphaeniacus (Hall) : Egypt, Libya

Pseudaspidoproctus vayssieriellus Ghesquière : Democratic Republic of the Congo, Nigeria

Vrydagha lepesmei Vayssière ; Democratic Republic of the Congo

Walkeriana andreae Green : Democratic Republic of the Congo

Walkeriana digitifrons Newstead : Uganda

Key to most of the known genera of Monophlebidae in continental Africa

1(0) Abdominal spiracles numbering 2‒4 pairs (on posterior abdominal segments). Cicatrices numbering 1‒13. Body covered with hairs and flagellate setae................................................................. tribe Iceryini ... 2

- Abdominal spiracles usually difficult to see, numbering 5‒7 pairs. Cicatrices numbering 1 or 3 or very numerous. Body covered with spines and/or hairs................................................................................ 6

2(1) Abdominal spiracles numbering 4 pairs. Labium long, with 3 segments, the basal segment very narrow. Anal tube inner ring with 2 rows of pores.................................................................. Gueriniella View in CoL ( Fig. 11 View FIGURE 11 )

- Abdominal spiracles numbering 2 or 3 pairs. Labium short and conical, with 2 indistinct segments, the basal segment wide. Anal tube inner ring without pores....................................................................... 3

3(2) Ventral cicatrices numbering 6‒23 posterior to vulva, grouped in a circular area on midline........ “ Crypticerya View in CoL ” ( Fig. 12 View FIGURE 12 )

- Ventral cicatrices numbering 1 or 3 posterior to vulva in a single row across midline................................ 4

4(3) Compound multilocular pores absent. Open-centre pores present or absent........................... Icerya View in CoL ( Fig. 10 View FIGURE 10 )

- Compound multilocular pores present. Open-centre pores absent............................................... 5

5(4) Dorsal setae robust, spiniform and slightly lanceolate, quite crowded; most setae in marginal areas robust, some up to 5x as long as a dorsal seta, crowded. Marsupium present. With 3 cicatrices....................... “ Steatococcus View in CoL ” hystrix ( Fig. 13 View FIGURE 13 )

- Dorsal setae fine and hair-like, not crowded; setae in marginal areas hairlike, sometimes robust and very long but not crowded. Marsupium present or absent. With 1 or 3 cicatrices...................................... Gigantococcus View in CoL ( Fig. 14 View FIGURE 14 )

6(1) Body very densely covered with hairs, all same type, finely pointed. Antenna usually with 8 or 9 segments.................................................................................. tribe Drosichini ... Afrodrosicha View in CoL ( Fig. 15 View FIGURE 15 )

- Body with hairs and/or spines, often of more than 1 type, not crowded over entire surface. Antenna with 8‒11 segments..................................................................................... tribe Monophlebin ... 7

7(6) Claw with 3 denticles. Multilocular pores of 2 types, some with large loculi, some with small loculi. Palaeococcus View in CoL ( Fig. 16 View FIGURE 16 )

- Claw without denticles. Multilocular pores of 1 or more types ................................................. 8

8(7) Ventral cicatrices very numerous on head, thorax and abdomen, forming irregular rows that form a broad submarginal band on each side. Ventral marsupial opening relatively small and subcircular, bordered by a dense band of disc pores. In life, marsupial opening normally covered by a white layer of felted wax................................... Aspidoproctus View in CoL ( Fig. 17 View FIGURE 17 )

- Ventral cicatrices numbering 1 or 3, situated posterior to vulva in a row across midline. Marsupial opening, if present, often U- or V-shaped and bordered by relatively few pores; not covered with felted wax in life............................ 9

9(8) Body margin with about 12 segmental tubercles on each side of thorax and abdomen, each bearing single or small groups of tubular bilocular pores. Body with numerous, conspicuous quadrilocular pores. Dorsum with patches of densely crowded spines.............................................................................. Walkeriana View in CoL ( Fig. 18 View FIGURE 18 )

- Body margin without tubular bilocular pores or segmental tubercles. Quadrilocular pores, if present, small and inconspicuous. Dorsum without patches of crowded spines............................................................... 10

10(9) Body with at least a few cylindrical spines. Marsupium present. Ventral cicatrices numbering 3 Pseudaspidoproctus View in CoL ( Fig. 19 View FIGURE 19 )

- Body without cylindrical spines. Marsupium absent. Ventral cicatrices numbering 1 or 3........................... 11

11(10) Antenna with 10 segments. Ventral cicatrices numbering 3. Anal tube with internal ring bearing pores.... Vrydagha View in CoL ( Fig. 20 View FIGURE 20 )

- Antenna with 11 segments. With 1 or 3 ventral cicatrices. Anal tube without internal ring of pores.................... 11

12(11) Body margin with large tubular bilocular pores......................................... Monophleboides View in CoL ( Fig. 21 View FIGURE 21 )

- Body margin without large tubular bilocular pores................................................. Monophlebus View in CoL

Foldi, I. (2010) Trois especes nouvelles du genre Crypticerya Cockerell de la region mediterraneenne (Hemiptera, Coccoidea, Monophlebidae). Bulletin de la Societe entomologique de France, 115 (3), 289 - 304. https: // doi. org / 10.3406 / bsef. 2010.2686

Garcia Morales, M., Denno, B. D., Miller, D. R., Miller, G. L., Ben-Dov, Y. & Hardy, N. B. (2016) ScaleNet: a literature-based model of scale insect biology and systematics. Database. Available from: http: // scalenet. info (accessed 12 January 2022) https: // doi. org / 10.1093 / database / bav 118.

Gavrilov-Zimin, I. A. & Stekolshikov, A. V. (2018) A new species of the genus Steatococcus Ferris, 1921 (Homoptera, Coccinea: Margarodidae) with some additions to the fauna of the Republic of Mali. Entomological Review, 98 (7), 365 - 367. https: // doi. org / 10.1134 / S 0013873818070060

Gullan, P. J. & Cook, L. G. (2007) Phylogeny and higher classification of the scale insects (Hemiptera: Sternorrhyncha: Coccoidea). Zootaxa, 1668 (1), 413 - 425. https: // doi. org / 10.11646 / zootaxa. 1668.1.22

Hodgson, C. J. & Foldi, I. (2006) A review of the Margarodidae sensu Morrison (Hemiptera: Coccoidea) and some related taxa based on the morphology of adult males. Zootaxa, 1263 (1), 1 - 250. https: // doi. org / 10.11646 / zootaxa. 1263.1.1

Hughes-Schrader, S. (1930) Contributions to the life history of the iceryine coccids, with special reference to parthenogenesis and hermaphroditism. Annals of the Entomological Society of America, 23, 359 - 380. https: // doi. org / 10.1093 / aesa / 23.2.359

Hughes-Schrader, S. (1963) Hermaphroditism in an African coccid, with notes on other Margarodids (Coccoidea-Homoptera). Journal of Morphology, 113, 173 - 184. https: // doi. org / 10.1002 / jmor. 1051130205

Karar, H., Arif, M. J., Sayyed, H. A., Saeed, S., Abbas, G. & Gogi, M. D. (2008) Integrated pest management of mango mealybug (Drosicha mangiferae) in mango orchards. International Journal of Agriculture & Biology, 11, 81 - 84.

Kondo, T. & Watson, G. W. (Eds.) (2022 in press) 3.7 Monophlebidae. In: Kondo, T. & Watson, G. W. (Eds.), Encyclopedia of Scale Insect Pests. CAB International, Wallingford, pp. 86 - 108.

Miller, D., Rung, A., Parikh, G., Venable, G., Redford, A. J., Evans, G. A. & Gill, R. J. (2014) Scale Insects, Edition 2. USDA APHIS Identification Technology Program (ITP), Fort Collins, Colorado. Available from: http: // idtools. org / id / scales / factsheet. php? name = 6726 (accessed 15 February 2022)

Mongue, A. J., Michaelides, S., Coombe, O., Tena, A., Kim, D-S., Normark, B. B., Hardner, A., Hoddle, M. S. & Ross, L. (2021) Sex, males, and hermaphrodites in the scale insect Icerya purchasi. Evolution. [published online] https: // doi. org / 10.1101 / 2020.09.04.281618

Morrison, H. (1928) A classification of the higher groups and genera of the coccid family Margarodidae. United States Department of Agriculture Technical Bulletin, 52, 1 - 239.

Normark, B. B. (2003) The evolution of alternative genetic systems in insects. Annual Review of Entomology, 48, 397 - 423. https: // doi. org / 10.1146 / annurev. ento. 48.091801.112703

Sirisena, U. G. A. I., Watson, G. W., Hemachandra, K. S. & Wijayagunasekara, H. N. P. (2013) A modified technique for the preparation of specimens of Sternorrhyncha for taxonomic studies. Tropical Agricultural Research Journal, 24 (2), 139 - 149.

Williams, D. J. & Watson, G. W. (1990) The Scale Insects of the Tropical South Pacific Region. Pt. 3. The Soft Scales (Coccidae) and Other Families. CAB International, Wallingford, 267 pp.

Gallery Image

FIGURE 9. Monophlebidae: Iceryini, adult female anatomy, from Unruh & Gullan (2007: 14, Fig. 1), © Magnolia Press, www. mapress.com/j/zt, reproduced with the copyright holder’s permission.

Gallery Image

FIGURE 10. Icerya seychellarum Westwood, adult female, from Williams & Watson (1990: 24, Fig. 5), reproduced with permission of the authors and CABI.

Gallery Image

FIGURE 11. Gueriniella serratulae (Fabricius), adult female, developed from Morrison (1928: 198, Fig. 105).

Gallery Image

FIGURE 12. “Crypticerya” aegyptiensis Foldi, adult female, from Foldi (2010: 292, Fig. 1). C: cicatrices. Reproduced with permission from Annales de la Société entomologique de France.

Gallery Image

FIGURE 13. “Steatococcus” hystrix Gavrilov-Zimin & Stekolshikov, adult female, from Gavrilov-Zimin & Stekolshikov (2018: 866), reproduced with permission from Pleiades Publishing, Ltd.

Gallery Image

FIGURE 14. Gigantococcus bimaculatus De Lotto, adult female, from De Lotto (1959: 386, Fig.1), reproduced with permission of the Entomological Society of Southern Africa.

Gallery Image

FIGURE 15. Afrodrosicha nimbae Vayssière, adult female, from Vayssière (1968: 1494-1495, Figs 1 and 2).

Gallery Image

FIGURE 16. Palaeococcus fuscipennis (Burmeister) ex Gavrilov-Zimin (2018: 172, Fig. 9.4.15.), reproduced with the author’s permission.

Gallery Image

FIGURE 17. Aspidoproctus maximus (Lounsbury), adult female, developed from Morrison (1928: 152, Fig. 75 and 153, Fig. 76).

Gallery Image

FIGURE 18. Walkeriana floriger (Walker), adult female, developed from Morrison (1928: 142, Fig. 68). Note that this illustration shows the genotype, a species that does not occur in Africa.

Gallery Image

FIGURE 19. Pseudaspidoproctus hyphaeniacus (Hall), adult female, developed from Morrison (1928: 139, Fig. 66). C: cicatrices; M: marsupium opening.

Gallery Image

FIGURE 20. Vrydagha lepesmei Vayssière), adult female, developed from Vayssière (1957: 2, Figs 1 and 3).

Gallery Image

FIGURE 21. Monophleboides gymnocarpi (Hall), adult female, developed from Morrison (1928: 126, Fig. 57).

Kingdom

Animalia

Phylum

Arthropoda

Class

Insecta

Order

Hemiptera

Family

Monophlebidae