Decellebruchus atrolineatus

Taxonavigation

Ordo: Coleoptera
Familia: Bruchidae
Genus: Decellebruchus

Name

Decellebruchus atrolineatus (Pic, 1921) comb. n. – Wikispecies link – Pensoft Profile

• Bruchus atrolineatus Pic, 1921: 15, 1932^[1]: 36; Decelle 1951^[2]: 184, 1961^[3]: 8, 1975a: 21 (comb. n.).
• Bruchidius atrolineatus: Prevett 1961^[4]: 636, 1967^[5]: 5, 1971^[6]: 247; Booker 1967^[7]: 2; Luca 1968a^[8]: 188, 1968b^[9]: 589; Decelle 1975a^[10]: 15; Southgate 1978^[11]: 219; Biemont et al. 1982^[12]: 2610; Hamon et al. 1982^[13]: 327; Pfaffenberger 1985^[14]: 3; Germain et al. 1987^[15]: 157; Monge et al. 1988^[16]: 297, 1989^[17]: 95; Huignard et al. 1989^[18]: 197; Pouzat and Nammour 1989^[19]: 319; Udayagiri and Wadhi 1989^[20]: 119; Lenga et al. 1990^[21]: 79; Glitho and Huignard 1990^[22]: 195; Pfaffenberger and Monge 1991^[23]: 309; Pichard et al. 1991^[24]: 185; Shimada and Ishihara 1991^[25]: 289; Credland 1992^[26]: 1; Ishihara and Shimada 1995^[27]: 127; Ofuya and Credland 1996^[28]: 323; Kingsolver 1988^[29]; Sanon et al. 2005^[30]; Löbl and Smetana 2010^[31]: 341.
• Callosobruchus atrolineatus: Zacher 1952^[32]: 465; Shomar 1963^[33]: 178.
• Bruchus semiflabellatus Pic, 1931; Bondar 1936^[34]: 37 (syn.); Kingsolver and Silva 1991^[35]: 413 (syn.); Udayagiri and Wadhi 1989^[20]: 119.
• Acanthoscelides semiflabellatus: Blackwelder 1946^[36]: 761.
• Callosobruchus semiflabellatus: Zacher 1952^[32]: 465.
• Decellebruchus atrolineatus: Anton 1994^[37]: 100; Kergoat et al. 2005^[38]: 605 (without indicating clearly new combination).

Description

Male (Fig. 1a–b). Length (pronotum-elytra): 2.4–2.6 mm; width: 1.4–1.6 mm; maximum thoracic depth 1.5–1.7 mm. Color: Antennae with the first three segments yellowish, the rest dark or partially dark; head, prosternum, metasternum, base of meso-femur and meta-femora, and coxae dark; pronotum with two longitudinal dark bands, which may together form a dark spot; elyton variegate; pygidium with three pairs of dark spots, two apical, two median-lateral, and two basal; rest of body yellowish. Vestiture: Body with mixed yellowish and white pubescence; scutellum with whitish pubescence; fore coxa with a tuft of white setae; pygidium with yellowish and whitish pubescence forming a variegate pattern. Head: Short and broad, densely micropunctulate, frons with a strong median carina, distance between eyes 2.3.–3.3× as wide as eye width, eye cleft 0.60–0.71× its length by ocular sinus, posterior margin of eye protruding from adjacent surfaces, postocular lobe rounded and setose; distance from base of antennae to apex of labrum 0.39–0.55× as long as distance from upper limits of eyes to apex of labrum; antennomeres I–III filiform, IV subserrate, V–XI pectinate; antennomere II 2.8–3.8× as long as antennomere XI; antennomere VII 4.4–5.6× wider that long; antenna extending slightly beyond humerus. Prothorax: Subconical, without lateral carina; densely foveolate, disc convex, slightly gibbous before scutellum and with shallow median channel; prosternal process narrow, triangular, acute, half as long as procoxae. Meso- and metathorax: Scutellum square, bidentate apically; elytral striae regular, striae 4 and 5 abbreviated basally by tubercle, humeri raised. Legs: First protarsomere 2.0–3.0× as long as second, first mesotarsomere 1.8–2.3× as long as second, first metatarsomere 2.6–3.0× as long as second; metacoxa densely punctate; hind femur constricted basally and apically, expanded medially to about width of coxa; without external carina ventrally; internal ventral carina with small subapical acuminate spine about half as long as width of tibial base; hind tibia straight, enlarged, with only mesal and ventral carinae; tibial corona with 4 spinules, mucro 0.10–0.13× as long as first tarsomere; without sinus at base of spine; first hind tarsomere with ventrolateral glabrous longitudinal carina. Abdomen: Pygidium vertical (Fig. 2); last sternite emarginate. Genitalia: Median lobe moderately long, ventral valve triangular and deeply arcuate, internal sac with many small spines or needles, without large sclerites (Fig. 3a); lateral lobes elongate, expanded at apex, cleft about 0.53 their length; basal strut an obsolete perpendicular keel (Fig. 3b). Female (Fig. 4a–b). Length (pronotum-elytra) 2.4–2.8 mm, width: 1.5–1.7 mm, Maximum thoracic depth 1.6–1.8 mm. Similar to male except antennae serrate; distance between eyes 1.8.–2.0× as wide as eye width; pygidium subvertical; last sternite not emarginate.

Material examined

NAMIBIA: Rundu, 28/V/2015, T. Chauke, 17°55’S 19°46’E, reared seed Glycine max (L.), intercepted at Pretoria SAAFQIS Plant Quarantine Station, South Africa, Sample Pta. 2811 (1 ex SANC). Caprivi region, 2002, intercepted at Pretoria SAAFQIS Plant Quarantine Station, South Africa (70 ex SANC). AFRICA: Intercepted at USA, 36/XII/2003, reared seed Phaseolus sp. (3 ex, FSCA); Intercepted at Atlanta, USA, 10/IX/2006, reared seed Phaseolus vulgaris L. (1 ex., FSCA). DEMOCRATIC REPUBLIC OF THE CONGO: N of Shaba Province, 28/III/1980, Whitecomb W.H., in cowpeas (1 ex., FSCA). NIGERIA: Intercepted at USA, 2/II/2004, Phaseolus sp. (7 ex., FSCA); Intercepted at USA, 3/II/2004, reared seed Phaseolus sp. (2 ex., CEAM). MEXICO: Ocolome, El Fuerte, Sinaloa, 21/I/2013, Lugo G.G.A., reared seed Vigna unguiculata (L.) WALP. (190 ex., CEAM).

Host plants

Dolichos lablab L., Glycine max (L.), Phaseolus vulgaris L. Vigna unguiculata (L.) Walp., Vigna unguiculata subsp. stenophylla (Harv.) Maréchal & Al., Vigna unguiculata subsp. unguiculata (L.)Walp. (Fabaceae). Zacher (1952)^[32] stated that Lablab niger Medik. and Medicago sativa L. are plant hosts of Decellebruchus atrolineatus, however this information must be corroborated.

Distribution

Algeria, Angola, Brazil, Burkina Faso, Cameroon, Central African Republic, Democratic Republic of the Congo, Egypt, Ethiopia, Gambia, Ghana, Jamaica, Kenya, Liberia, Mali, Mexico, Mozambique, Namibia, Niger, Nigeria, South Africa, Saudi Arabia, Senegal, Sudan, Tanzania, Uganda, United Kingdom, Yemen, Zanzibar.

Discussion

Decellebruchus atrolineatus has high economic importance, because it is a pest mainly in species in the genus Vigna. It is frequently found together with Callosobruchus maculatus (F.). Large losses due to this insect are reported frequently in some countries of Africa, where those bruchids are endemic (Booker 1967^[7], Germain et al. 1987^[15], Ofuya and Credland 1996^[28], Sanon et al. 2005^[30]).

Taxon Treatment

• Nápoles, J; 2016: Systematics of the seed beetle genus Decellebruchus Borowiec, 1987 (Coleoptera, Bruchidae) ZooKeys, (579): 59-81. doi

Images

Figure 1. Male habitus of Decellebruchus atrolineatus; a dorsal view b lateral view.  Figure 2. Male pygidium of Decellebruchus atrolineatus.  Figure 3. Male genitalia of Decellebruchus atrolineatus; a median lobe b lateral lobes.  Figure 4. Female habitus of Decellebruchus atrolineatus; a dorsal view b lateral view.

Other References

1. ↑ Pic M (1932) Nouveautes diverses. Melanges Exotico-Entomologiques 59: 10–36.
2. ↑ Decelle J (1951) Contribution a l”etude des Bruchidae du Congo belge (Coleoptera: Phytophaga). Revue de zoologie et de botanique africaines 45: 172–192.
3. ↑ Decelle J (1961) Bruchidae (Coleoptera, Phytophagoidea). Parc National Albert- Mission G. F. Witte (1933–1935) 97(2): 5–10.
4. ↑ Prevett P (1961) Field infestation of cowpea (Vigna unguiculata) pods by beetles of the families Bruchidae and Curculionidae in northern Nigeria. Bulletin of Entomological Research 52(4): 635–645. doi: 10.1017/S0007485300055668
5. ↑ Prevett P (1967) Notes on the biology, food plants & distribution of Nigerian Bruchidae (Coleoptera), with particular reference to the northern region. Bulletin of the Entomological Society of Nigeria 1: 3–6.
6. ↑ Prevett P (1971) The larva of some Nigerian Bruchidae (Coleoptera). Transactions of the Royal Entomological Society of London 123(3): 247–312. doi: 10.1111/j.1365-2311.1971.tb00845.x
7. ↑ ^{7.0 7.1} Booker R (1967) Observations on three bruchids associated with cowpea in northern Nigeria. Journal of Stored Products Research 3: 1–15. doi: 10.1016/0022-474X(67)90082-3
8. ↑ Luca Y (1968a) A propos de Bruchidius atrolineatus (Pic) (Coleoptera: Bruchidae). Nouvelle description et remarques. Bulletin de l’I.F.A.N. T. XXX, sér. A, 1: 188–199.
9. ↑ Luca Y (1968b) La larve neonate de Bruchidius atrolineatus (Pic) (Coleoptera: Bruchidae). Bulletin de l’I.F.A.N. T. XXX, sér. A, 2: 589–592.
10. ↑ Decelle J (1975a) Les Coleopteres Bruchides d’Angola. Publicacoes culturais da Companhia de Diamantes de Angola 98: 13–32.
11. ↑ Southgate B (1978) The importance of the Bruchidae as pests of grain legumes, their distribution and control. In: Singh S van Emden H Ajibola T (Eds) Pests of Grain Legumes: Ecology and Control. Academy Press, London, 219–229.
12. ↑ Biemont J, Chauvin G, Germain J (1982) L’oeuf de Bruchidius atrolineatus (Pic) et son systeme de fixation. Canadian Journal of Zoology 60: 2610–2615. doi: 10.1139/z82-335
13. ↑ Hamon C, Biemont J, Chauvin G (1982) Ultrastructure et fonction secretrice des cellules de la paroi oviductes lateraux chez Acanthoscelides obtectus Say (Coleoptera: Bruchidae). International Journal of Insect Morphology and Embryology 11: 327–339. doi: 10.1016/0020-7322(82)90021-6
14. ↑ Pfaffenberger G (1985) Checklist of selected world species of described first and/or final larval instars. Coleopterists Bulletin 39(1): 1–6.
15. ↑ ^{15.0 15.1} Germain J, Monge J, Huignard J (1987) Development of two bruchid populations (Bruchidius atrolineatus (Pic) and Callososbruchus maculatus) (Fab.)) infesting stored cowpea (Vigna unguiculata Walp) pods in Niger. Journal of Stored Products Research 23(3): 157–162. doi: 10.1016/0022-474X(87)90045-2
16. ↑ Monge J, Germain J, Huignard J (1988) Importance des variations thermiques sur l’induction de la diapause reproductrice chez Bruchidius atrolineatus Pic (Coleoptere Bruchidae). Acta Oecologica 9(3): 297–307.
17. ↑ Monge J, Lenga A, Huignard J (1989) Induction of reproductive diapause in Bruchidius atrolineatus during the dry season in a Sahelian zone. Entomologia Experimentalis et Applicata 53: 95–104. do: 10.1111/j.1570-7458.1989.tb01292.x
18. ↑ Huignard J, Monge J, Germain J (1989) Influence of thermoperiodic variations on the induction of the reproductive diapause of Bruchidius atrolineatus (Pic) (Coleoptera: Bruchidae). In: Tonner M Soldan T Bennetova B (Eds) Regulation of Insect Reproductionj. IV Academia Praha, Praha, 197–207.
19. ↑ Pouzat J, Nammour D (1989) Electrophysiological investigations of sex pheromone reception and release in Bruchidius atrolineatus. Physiological Entomology 14: 319–324.
20. ↑ ^{20.0 20.1} Udayagiri S, Wadhi S (1989) Catalog of Bruchidae. Memoirs of the American Entomological Institute 45: 1–301.
21. ↑ Lenga A, Monge J, Huignard J (1990) Role des facteurs thermiques dans l’induction de la diapause reproductrice chez Bruchidius atrolineatus Pic (Col: Bruchidae). Regulation des cycles saisonniers chez les Invertebres. Dourdan (France). Ed. INRA, 79–83.
22. ↑ Glitho I, Huignard J (1990) A histological and ultrastructural comparison of the male accessory reproductive glands of diapausing and non-diapausing adults in Bruchidius atrolineatus (Pic) (Coleoptera: Bruchidae). International Journal of Insect Morphology and Embryology 19: 195–209. doi: 10.1016/0020-7322(90)90005-A
23. ↑ Pfaffenberger G, Monge J (1991) Redescription of the larvae of Bruchidius atrolineatus (Pic) (Coleoptera: Bruchidae: Bruchinae). Coleopterists Bulletin 45(4): 309–316.
24. ↑ Pichard B, Leroi B, Bonet A (1991) Comparaison des cycles d’Acanthoscelides obtectus et d’A. obvelatus (Coleopteres: Bruchidae) a Tepoztlan (Mexique). Acta Oecologica 12(2): 185–201.
25. ↑ Shimada M, Ishihara M (1991) Two types of overwintering larvae in a wild multivoltine bruchid, Kytorhinus sharpianus Bridwell (Coleoptera: Bruchidae). Applied Entomology and Zoology 26(3): 289–297.
26. ↑ Credland P (1992) The structure of bruchid eggs may explain the ovicidal effect of oils. Journal of Stored Products Research 28(1): 1–9. doi: 10.1016/0022-474X(92)90025-L
27. ↑ Ishihara M, Shimada M (1995) Photoperiodic induction of larval diapause and temperature-dependent termination in a wild multivoltine bruchid, Kytorhinus sharpianus. Entomologia Experimentalis et Applicata 75: 127–134. doi: 10.1111/j.1570-7458.1995.tb01918.x
28. ↑ ^{28.0 28.1} Ofuya T, Credland P (1996) The Ability of Bruchidius atrolineatus (Pic) (Coleoptera: Bruchidae) to infest and damage seeds of different tropical legumes. Journal of Stored Products Research 32(4): 323–328. doi: 10.1016/S0022-474X(97)87176-7
29. ↑ Kingsolver J (1988) Pests not known to occur in the United States, or of limited distribution, no. 95: African Cowpea Bruchid with a key to Bruchidae of sored pulses. APHIS-PPQ 81–53, U.S. Department of Agriculture, 1–10.
30. ↑ ^{30.0 30.1} Sanon A, Dabiré C, Ouedraogo A, Huignard J (2005) Field occurrence of bruchid pésts of cowpea and associated parasitoids in a sub humid zone of Burkina Faso: Importance on the infestatioon of two cowpea varieties at harvest. Plant Phatology Journal 4(1): 14–20. doi: 10.3923/ppj.2005.14.20
31. ↑ Lobl I, Smetana A (2010) Catalogue of Paleartic Coleoptera. Vol. 6. Chrysomeloidea. Apollo Books, 339–353.
32. ↑ ^{32.0 32.1 32.2} Zacher F (1952) Die Nährpflanzen der Samenkäfer. Zeitschrift für angewandte Entomologie 33: 460–480.
33. ↑ Shomar N (1963) A monographic revision of the Bruchidae of Egypt (U.A.R.) (Coleoptera). Bulletin of the Entomological Society of Egypt 47: 141–196.
34. ↑ Bondar G (1936) Notas biologicas sobre Bruchideos observados no Brazil. Rio de Janeiro Instituto de Biologia Vegetal. Arquivos 3(1): 7–44.
35. ↑ Kingsolver J, Silva P (1991) Update of scientific names of Bruchidae (Coleoptera) listed by Bondar in “Notas Biologicas” (1931 and 1936). Anais da Sociedade Entomologica do Brasil 20(2): 411–415.
36. ↑ Blackwelder R (1946) Checklist of the coleopterous insects of Mexico, Central America, the West Indies, and South America. Bulletin of The United States National Museum 185(4): 551–763. doi: 10.5479/si.03629236.185.4
37. ↑ Anton K (1994) The Bruchidae (Coleoptera) of Saudi Arabia, with descriptions of two new species. Fauna of Saudi Arabia 14: 97–104.
38. ↑ Kergoat G, Delobel A, Fédière G, Le Rü B, Silvain J (2005) Both host-plant phylogeny and chemistry have shaped the African seed-beetle radiation. Molecular Phylogenetics and Evolution 35: 602–611. doi: 10.1016/j.ympev.2004.12.024