Artificial diets used in laboratory rearing of the European grapevine moth, Lobesia botrana (Lepidoptera: Tortricidae).

Al-Attar, Jalal; Mansour, Mohammed

doi:10.48311/jcp.2020.1514

Artificial diets used in laboratory rearing of the European grapevine moth, Lobesia botrana (Lepidoptera: Tortricidae).

https://doi.org/10.48311/jcp.2020.1514

Volume 9, Issue 4
December 2020

Pages 733-740

Document Type : Original Research

Authors

J. Al-Attar

M. Mansour

Department of Agriculture, Syrian Atomic Energy Commission (SAEC), Damascus, Syrian Arab Republic.

Abstract

The larval nutrition of the grapevine moth, Lobesia botrana, is determinant for its fitness; the amount and quality of the food ingested by larvae strongly influence the insect growth and reproduction. Utilizing appropriate artificial diets is a critical step in establishing a laboratory rearing colony. Generally, two types of diets are used in grapevine moth lab rearing, diets that stay moist and soft (agar-based diets) and those that dry out and harden with time (non-agar-based diets). Agar-based diets are satisfactory for producing small quantities of insects in small food containers, but with large containers, difficulties may occur. The relatively high cost of agar is another reason that stimulated the search for less expensive binders. To the contrary, non-agar based diets are generally used when large numbers of insects are required and where cost becomes a critical factor. In addition, many general-purpose diets (with or without agar) are used for rearing this insect. The selection of a particular diet, however, is a personal decision that should be based on the quality of the produced insects and the diet suitability for the rearing purpose. This paper discusses the artificial diets used by researchers for Lobesia botrana laboratory rearing.

Keywords

artificial diet

grapevine moth

insect rearing

Lobesia botrana

20.1001.1.22519041.2020.9.4.3.6

Awmack, C. S. and Leather, S. R. 2002. Host plant quality and fecundity in herbivorous insects. Annual Review of Entomology, 47(1): 817–844.
Bathon, H., Singh, P. and Clare G. K. 1991. Rearing methods, pp. In van der Geest, L.P.S. and Evenhuis, H. H. (Eds.) Tortricid pests: Their Biology, Natural Enemies and Control. Vol. 5 of World Crop Pests, Helle, W. (Ed.) Elsevier, Amsterdam, The Netherlands. pp.283-293.
BCFGA 1972. Growers must take over financing of sterilized codling moth problem. British Columbia Fruit Growers’ Association. British Columbia Orchardist, 12(6): 18–19.
Bloem, S., Bloem, K. A. and Fielding, L. S. 1997. Mass-rearing and storing codling moth larvae in diapause: a novel approach to increase production for sterile insect release. Journal of the Entomological Society of British Columbia, 94: 75–81.
Brinton, F. E., Proverbs, M. D. and Carty, B. E. 1969. Artificial diet for mass production of the codling moth, Carpocapsa pomonella (Lepidoptera: Olethreutidae). Canadian Entomologist, 101(6): 577–584.
Carpenter, J. E., Bloem, S. and Bloem, K.A. 2004. Progress on extraction of codling moth pupae from diet to facilitate handling, shipping and irradiation of insects, pp. 119-124. In: Working material. Improvement of codling moth SIT to facilitate expansion of field application. Second Research Coordination Meeting, 8–12 March 2004, Stellenbosch, South Africa. IAEA-314-D4-RC876. IAEA, Vienna, Austria.
Chambers, D. L. 1977. Quality control in mass rearing. Annual Review of Entomology. 22(1): 289–308.
Dyck, V. A. 2010. Rearing codling moth for the sterile insect technique. FAO Plant Production and Protection Paper (199).
Guennelon, G., Sender, C., d'Arcier, F. and Audemard, H. 1970. Mise au point d'un milieu artificial pour l'élevage au laboratoire des larves de l'Eudémis de la vigne, Lobesia botrana Den. Et Schiff. (Lepidoptera Tortricidae). Annales de Zoologie Ecologie Animale, 2(1): 51–77.
House, H. L. 1961. Insect nutrition. Annual Review of Entomology. 6(1): 13-26. Available online: http://www.ceris.purdue.edu/napis/pests/misc/fexotic.txt.
Howell, J. F. 1970. Rearing the codling moth on an artificial diet. Journal of Economic Entomology, 63(4): 1148–1150.
Howell, J. F. 1971. Problems involved in rearing the codling moth on diet in trays. Journal of economic entomology, 64(3): 631–636.
Ignoffo, C. M. 1963. A successful technique for mass-rearing cabbage loopers on a semi-synthetic diet. Annals of the Entomological Society of America, 56(2): 178–182.
Ifoulis, A. A. and Savopoulou-Soultani, M. 2004. Biological control of Lobesia botrana (Lepidoptera: Tortricidae) larvae by using different formulations of Bacillus thuringiensis in 11 vine cultivars under field conditions. Journal of Economic Entomology, 97(2): 340–343.
Ivaldi-sender, C. 1974. Techniques simples pour un elevage permanent de la tordeuse orientale, Grapholita molesta (Lepidoptera, Tortricidae) sur simlieu artificiel. Annales de zoologie: Ecologie animale, 6: 337–343.
Maher, N. 2002. Oviposition Site Selection by Lobesia botrana (Lepidoptera : Tortricidae): Influence of non-Volatile chemical cues from host plant fruit. PhD. Thesis No. 968. Univ. Victor Segalen Bordeaux 2, FR.
Maison, P. and Pargade, P. 1967. Le piégeage sexuel de l'Eudémis au service de l'avertissemet agricole. Phytoma, 19(190): 9.
Mansour, M. and Al-Attar, J. 2012. Effects of gamma irradiation on the grape vine moth, Lobesia botrana, eggs. Radiation Physics and Chemistry, 81(11): 1776 – 1780.
Mansour, M. and Al-Attar, J. 2014. Effects of gamma irradiation on the grape vine moth, Lobesia botrana, mature larvae. Radiation Physics and Chemistry, 97: 370–373.
Mohammad, F., Mansour, M. and Ghanem, I. 1997. An artificial diet with local ingredients for codling moth (Lepidoptera: Olethreutidae) mass rearing in Syria. SAEC Report No. 51. In Arabic.
Moreau, J., Benrey, B. and Thiery, D. 2006. Assessing larval food quality for phytophagous insects: are the facts as simple as they appear? Functional Ecology, 20(4): 592–600.
Moreau, J.P. 1965. Comportement des vers de la grappe vis-a-vis de divers cépages et essais d'alimentation artificielle. Revue de Zoologie Agricole et Appliquée, 64: 13–16.
Moschos, T. 2006. Yield loss quantification and economic injury level estimation for the carpophagous generations of the European grapevine moth Lobesia botrana Den. et Schiff.(Lepidoptera: Tortricidae). International Journal of Pest Management, 52(02): 141–147.
Roditakis, N. and Karandinos, M. 2001. Effect of photoperiod and temperature on pupal diapause induction of grape berry moth Lobesia botrana. Physiological Entomology, 26(4): 329-340.
Roehrich, R. 1967. Elevage des chenilles de l'Eudémis (Lobesia botrana Schiff.) sur des aliments naturels de remplacement. Revue de Zoologie Agricole et Appliquée, 66: 111–5.
Roehrich, R. and Boller, E. 1991. Tortricids in vineyards. In: Van der Gesst, L. P. S. and Evenhuis, H.H. (Eds). Tortricid Pests, their Biology Natural Enemies and Control. Elsevier Science Publishers, pp. 507–514.
Saour, G. 2014. Sterile insect technique and F1 sterility in the European grapevine moth, Lobesia botrana. Journal of insect science, 14(1): 8. Available online: http://www.insectscince.org/14.8
Savopoulou-Soultani, M., Stavridis, D. G.,Vassiliou, A., Stafilidis, J. and Iraklidis, I. 1994. Response of Lobesia botrana (Lepidoptera: Tortricidae) to levels of sugars and protein in artificial diets. Journal of Economic Entomology, 87(1): 84–90.
Savopoulou-Soultani, M. 1985. The influence of Botrytis cinerea on the biology of Lobesia botrana. Ph. D. dissertation, Aristotelian University of Thessaloniki.
Shahini, S., Kullaj, E., Çakalli, A., Cakalli, M., Lazarevska, S., Pfeiffer, D.G. and Gumeni, F. 2010. Population dynamics and biological control of European grapevine moth (Lobesia botrana: Lepidoptera: Tortricidae) in Albania using different strains of Bacillus thuringiensis. International Journal of Pest Management, 56(3): 281–286.
Singh, P. 1977. Artificial Diets for Insects, Mites, and Spiders. IFI/Plenum, New York, USA.
Singh, P. 1983. A general purpose laboratory diet mixture for rearing insects. International Journal of Tropical Insect Science, 4(4): 357–362.
Singh, P. 1984. Insect diets. Historical developments, recent advances, and future prospects, In King, E.G. and Leppla, N.C. (Eds.), Advances and Challenges in Insect Rearing. Agricultural Research Service, United States Department of Agriculture, New Orleans, LA, USA, pp. 32–44.
Steinitz, H., Sadeh, A., Kliot, A. and Harari, A. 2015. Effects of radiation on inherited sterility in the European grapevine moth (Lobesia botrana). Pest management science, 71(1): 24–31.
Thiéry, D. and Moreau, J. 2005. Relative performance of European grapevine moth (Lobesia botrana) on grapes and other hosts. Occologia, 143(4): 548-557.
Thiéry, D. 2008 Les lépidoptères, ravageurs avérés ou potentiels de la vigne en France. In: Kreiter, S. (Ed.) Ravageur de la vigne. Bordeaux, Féret publication, pp. 211–252.
Thiéry, D., Monceau, K. and Moreau, J. 2014. Larval intraspecific competition for food in the European grapevine moth Lobesia botrana. Bulletin of Entomological Research, 104(4): 517.Touzeau, J. and Vonderheyden, F. 1968. L'élevage semi-industriel des tordeuses de la grappe destinées au piégeage sexuel. Phytoma, 20: 25–30.
Tzanakakis, M. E., and Savopoulou, M. C. 1973. Artificial diets for larvae of Lobesia botrana (Lepidoptera: Tortricidae). Annals of the Entomological Society of America, 66(2): 470–471.
Vanderzant, E. S. 1969. Physical aspects of artificial diets. Entomologia Experimentalis et Applicata, 12(5): 642–650.
Varela, L. G., Smith, R. J., Cooper, M. L. and Hoenisch, R. W. 2010. European grapevine moth, Lobesia botrana. Napa valley vineyards. Practical Winery and Vineyard. March/April, pp. 1–5.
Wildbolz, T. and Mani, E. 1971. Current work on genetic control of Carpocapsa pomonella, In Proceedings, Panel: Application of Induced Sterility for Control of Lepidopterous Populations. Joint FAO/IAEA Division of Atomic Energy in Food and Agriculture, 1–5 June 1970, Vienna, Austria. STI/PUB/281. IAEA, Vienna, Austria. pp. 151–155.

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