WING MORPHOLOGY AND DEVELOPMENT References from my library

A Web Page by Roy J. Beckemeyer

Last updated: 11 January 2006

1. Alexander, R.D., & W.L. Borwn, Jr., 1963, Mating behavior and the origin of insect wings, Occas. Pap. Mus. Zool. Univ. Mich., No. 628, pp. 1-19
2. Amoros, M., M. Corominas, P. Deak, & F. Serras, 2002, The ash2 gene is involved in Drosophila wing development, Int. J. Dev. Biol., 46:321-324
3. Arbesman, S., L. Enthoven, & A. Monteiro, 2003, Ancient Wings: animating the eovlution of butterfly wing patterns, Biosystems, 71:289-295
4. Arnold, J.W., 1963, A note on the pterostigma of insects, Canadian Entomologist, 95(1):13-16
5. Averof. M., & S. M. Cohen, Evolutionary origin of insect wings from ancestral gills, Nature, 385:627-630
6. Baonza, A., & A. Garcia-Bellido, 2000, Notch signalling directly controls cell proliferation in the Drosophila wing disc, PNAS, 97(6):2609-2614
7. Baonza, A., F. Roch, & Enrique Martin-Blanco, 2000, DER signalling restricts the boundaries of teh wing field during Drosophila evlopment, Proc. Nat. Acad. Sci., 97(13):7331-7335
8. Bechly, G., C. Brauckmann, W. Zessin, & E. Groening, 2001, New results concerning the morphology of the most ancient dragonflies (Insecta: Odonatoptera) from the Namurian of Hagen-Vorhalle (Germany), J. Zool. Syst. Evol. Research, 39:209-226
9. Beckemeyer, R.J., & G,.W. Byers, 2001, Forewing morphology of Dunbaria fasciipennis Tillyard (Palaeodictyoptera: Spillapteridae), with notes on a specimen from the University of Kansas Natural History Museum, J. Kansas Entomol. Soc., 74(4):221-230
10. Beltran, S., E. Blanco, F. Serras, B. Perez-Villamil, R. Guigo, S. Artavanis-Tsakonas, & M. Corominas, 2002, Transcriptional network controlled by the trithorax-group gene ash-2 in Drosophila melanogaster, PNAS, 100(6):3293-3298
11. Bethoux, O., A. Nel, & J. Lapeyrie, 2004, The extinct order Caloneurodea (Insecta: Pterygota: Panorthoptera): Wing venation, systematics and phylogenetic relationships, Annales Zoologici (Warszawa), 54(2):289-318
12. Biehs, B., M.A. Sturtevant, & E. Bier, 1998, Boundaries in the Drosophila wing imaginal disc organize vein-specific genetic programs, Development, 125:4245-4257
13. Blair, S.S., 1993, Mechanisms of compartment formation: Evidence that non-proliferating cells do not play a critical role in defining the D/V lineage restriction in the developing wing of Drosophila, Developement, 119:339-351
14. Bradley, J.C., 1939, Guide to the study of the evolution of the wings of insects, 2nd Edition, Daw, Illston and Company, Ithaca, NY69 pp/
15. Carle, F.L., 1982, The wing vein homologies and phylogeny of the Odonata: A continuing debate, Soc. Int. Odonat. Rapid Comm. No. 4, Utrecht, The Netherlands
16. Carroll, S.B., J.K. Grenier, & S.D. Weatherbee, 2001, From DNA to diversity: Molecular genetics and the evolution of animal design, Blackwell Science, Malden, MA
17. Casares, F., & R.S. Mann, 2000, A dual role for homothorax in inhibiting wing blade development and specifying proximal wing identities in Drosophila, Development, 127:1499-1508
18. Cifuentes, F. J., & A. Garcia-Bellido, 1997, Proximo-distal specification in the wing disc of Drosophila by the nubbin gene, Proc. Natl. Acad. Sci. USA, 94:11405-11410
19. Clark, H.W., 1940, The adult musculature of the anisopterous dragonfly thorax (Odonata, Anisoptera), J. Morphology, 67:523-565
20. Cohen, B., A.A. Simcox, & S.M. Cohen, 1993, Allocation of the thoracic imaginal primordia in the Drosophila embryo, Development, 117:597-608
21. Comstock, J.H., 1918, The wings of insects, The Comstock Publishing Company, Ithaca, NY
22. Comstock, J.H., & J.G. Needham, 1898, The wings of insects.  Chapter 1. An introduction to the study of the homologies of the wing-veins, The American Naturalist, 32:43-48
23. Comstock, J.H., & J.G. Needham, 1898, The wings of insects.  Chapter 2. The venation of the typical insect wing, The American Naturalist, 32:81-89
24. Comstock, J.H., & J.G. Needham, 1898, The wings of insects.  Chapter 3. The specialization of wings by reduction, The American Naturalist, 32:231-257, 335-340, 413-424, 561-565
25. Comstock, J.H., & J.G. Needham, 1898-1899, The wings of insects.  Chapter 4. The specialization of wings by addition, The American Naturalist, 32:769-777, 903-911, 33:117-126, 573-582
26. Comstock, J.H., & J.G. Needham, 1899, The wings of insects.  Chapter 5. The development of wings, The American Naturalist, 33: 845-860
27. Conley, C.A., R. Silburn, M.A. Singer, A. Ralston, D. Rohwer-Nutter, D.J. Olson, W. Gelbart, & S.A. Blair, 2000, Crossveinless 2 contains cysteine-rich domains and is required for high levels of BMP-like activity during the formation of the cross veins in Drosophila, Development, 127:3947-3959
28. Crozatier, M., B. Glise, & A. Vincent, 2002, Connecting Hh, Dpp and EGF signalling in patterning of the Drosophila wing; the pivotal role of collier/knot in the AP organizer, Development, 129:4261-4269
29. D'Andrea, M., & S. Cafri, 1988, Spines on the wing veins in Odonata. I. Zygoptera, Odonatologica, 17:313-335
30. D'Andrea, M., & S. Cafri, 1989, Spines on the wing veins in Odonata. II. Anisozygoptera and Anisoptera, Odonatologica, 18:147-178
31. D'Andrea, M., & S. Cafri, 1993, Spines on the wing veins in Odonata. 3. The wing edge, Adv. Odonatol., 6:21-43
32. De Celis, J., 1997, Expression and function of decapentaplegic and thick veins during the differentiation of the veins in the Drosophila wing, Development, 124:1007-1018
33. De Celis, J., S. Bray, & A. Garcia-Bellido, 1997, Development, 124:1919-1928
34. De Celis, J., & F. J. Diaz-Benjumea, 2003, Developmental basis for vein pattern variations in insect wings, Int. J. Dev. Biol., 47:653-663
35. Comstock, J.H., 1918, The wings of insects, Comstock Publ. Co., Ithaca, NY
36. Deuve, T., 2001, Origin of the Hexapoda, Annales de la Societe Entomologique de France, 37(1-2):7-304
37. Diaz-Benjumea, F.J., & S. M. Cohen, 1995, Serrate signals through Notch to establish a Wingless-dependent organizer at the dorsl/ventral compartment boundary of the Drosophila wing, Development, 121:4215-4225
38. Emerald, B.S., & J. K Roy, 1997, Homeotic transformation in Drosophila, Science, 389:684
39. Fristrom, D., P. Gotwals, S. Eaton, T. B. Kornberg, M. Sturtevant, E. Bier, & J. W. Fristrom, 1994, blistered: a gene required for vein/intervein formation in wings of Drosophila, Development, 120:2661-2671
40. Fristrom, D., M. Wilcox, & J. Fristrom, 1993, The distribution of PS integrins, laminin A and F-actin during key stages in Drosophila wing development, Development, 117:509-523
41. Galant, R., & S. B. Carroll, 2002, Evolution of a transcriptional repression domain in an insect Hox protein, Nature, 415:910-913
42. Gompel, N. B. Prud'homme, P.J. Wittkopp, V.A. Kassner, & S.B. Carroll, 2005, Chance caught on the wing: cis-regulatory evolution and the origin of pigment patterns in Drosophila, Nature, 433:481-487
43. Gorb, S.N., A. Kesel, & J. Berger, 2000, Microsculpture of the wing surface in Odonata: evidence for cuticular wax covering, Arthropod Structure & Development, 29:129-135
44. Goto, S., & S. Hayashi, 1997, Specification of the embryonic limb primordium by graded activity of Decapentaplegic, Development, 124:125-132
45. Grenier, J. K., & S. B. Carroll, 2000, Functional evolution of the Ultrbithorax protein, PNAS, 97(2):704-709
46. Haas, F., & J. Kukalova-Peck, 2001, Dermaptera hindwing structure and folding: New evidence for familial, ordinal and superordinal relationships within Neoptera (Insecta), Eur. J. Entomol., 98:445-509
47. Hamilton, K.G.A., 1971, The insect wing, Part I. Origin and development of wings from notal lobes, J. Kansas Ent. Soc., 44(4):421-433
48. Hamilton, K.G.A., 1972, The insect wing, Part II.Vein homology and the archetypal insect wing, J. Kansas Ent. Soc., 45(1):54-58
49. Hamilton, K.G.A., 1972, The insect wing, Part III.Venation of the orders, J. Kansas Ent. Soc., 45(2):145-162
50. Hamilton, K.G.A., 1972, The insect wing, Part IV.Venational trends and the phylogeny of the winged orders, J. Kansas Ent. Soc., 45(3):295-308
51. Hatch, G., 1966, Structure and mechanics of the dragonfly thorax, Ann. Ent. Soc. Am., 59(4):702-714
52. Heming, B.S., 2003, Insect development and evolution, Comstock Publishing Associates, a Div. of Cornell University Press, Ithaca, NY, xv + 444 pp.
53. Huppert, S.S., T.L. Jacobsen, & M.A.T. Muskavitch, 1997, Feedback regulation is central to Delta-Notch signalling required for Drosophila wing vein morphogenesis, Development, 124:3283-3291
54. Kukalova-Peck, J., 1974, Wing-folding in the Paleozoic insect order Diaphanopterodea (Paleoptera), with a description of new representatives of the family Elmoidae, Psyche, 81(2):315-333
55. Kukalova-Peck, J., 1974, Pteralia of the Paleozoic insect orders Palaeodictyoptera, Megasecoptera, and Diaphonopterodea (Paleoptera), Psyche, 81:416-430
56. Kukalova-Peck, J., 1982, Origin of the insect wing and wing articulation from the arthropodan leg, Can. J. Zool., 61:1618-1669
57. Kukalova-Peck, J., 1978, Origin and evolution of insect wings and their relation to metamorphosis, as documented by the fossil record, J. Morph., 156:53-126
58. Kukalova-Peck, J., 1984, Ephemeroid wing venation based upon new gigantic Carboniferous mayflies and basic morphology, phylogeny, and metamorphosis of pterygote insects (Insecta: Ephemerida), Can. J. Zool., 63:933-955
59. Kukalova-Peck, J., 1986, New Carboniferous Diplura, Monura, and Thysanura, the hexapod ground plan, and the role of thoracic side lobes in the origin of wings (Insecta), Can. J. Zool., 65:2327-2345
60. Kukalova-Peck, J., 1992, The "Uniramia" do not exist: The ground plan of the Pterygota as revealed by Permian Diaphanopterodea from Russia (Insecta: Palaeodictyopteroidea), Can. J. Zool., 70:236-255
61. Kukalova-Peck, J., & C. Brauckmann, 1990, Wing folding in pterygote insects, and the oldest Diaphanopterodea from the early Late Carboniferous of West Germany, Can. J. Zool., 68:1104-1111
62. Kukalova-Peck, J., & E.S. Richardson, Jr., 1983, New Homoiopteridae (Insecta: Paleodictyoptera) with wing articulation from Upper Carboniferous strata of Mazon Creek, Illinois, Can. J. Zool., 61: 1670-1687
63. Kukalova-Peck, J., & N.D. Sinichenkova, 1992, The wing venation and systematics of Lower Permian Diaphanopterodea from the Ural Mountains, Russia (Insecta: Palaeoptera), Can. J. Zool., 70:229-235
64. Kurata, S., M.J. Go, S. A. Tsakonas, & W. J. Gehring, 2000, Notch signalling and the determination of appendage identity, PNAS, 97(5):2117-2122
65. Kiger, J. A., Jr., J. E. Natzle, & M. M. Green, 2001, Hemocytes are essential for wing maturation in Drosophila melanogaster, PNAS, 98(18):10190-10195
66. Lameere, A., 1922, Sur la nervation alaire des insectes, Bull. de la Classe de sciences, Bruxelles, Plais des Academies, 8:138-149
67. Levine, M., 2002, How insects lose their limbs, Nature, 415:848-849
68. Marcus, J.M., 2001, The development and evolution of crossveins in insect wings, J. Anat. 2001:211-216
69. Martin-Blanco, E., F. Roch, E. Noll, A. Baonza, J.B. Duffy, & N. Perrimon, 1999, A temporal switch in DER signalling controls the specification and differentiation of veins and interveins in the Drosophila wing, Development, 126:5739-5747
70. Martynov, A.B., 1924, Sur l'interpretation de la nervuration et de la tracheation des ailes des Odonates et des Agnathes, Revue Russe d' entomologie, 18:145-174
71. Martynov, A.B., 1930, The interpretation of the wing venation and tracheation of the Odonata and Agnatha, Psyche, 245-280
72. Milan, M., S. Campuzano, & A. Garcia-Bellido, 1997, Developmental parameters of cell death in the wing disc of Drosophila, Proc. Natl. Acad. Sci. USA, 94:5691-5696
73. Milan, M., U. Weihe, S. Tiong, W. Bender, & S. M. Cohen, 2001, msh specifies dorsal cell fate in the Drosophila wing, Development, 128:3263-3268
74. Minelli, A., 2003, The origin and evolution of appendages, Int. J. Dev. Biol., 47:573-581
75. Mohler, J., M. Seecoomar, S. Agarwal, E. Bier, & J. Hsai, 2000, Development, 127:55-63
76. Montagne, J., J. Groppe, K. Guillemin, M.A. Krasnow, W.J. Gehring, & M. Affolter, 1996, The Drosophila Serum Response Factor gene is required for the formation of intervein tissue of the wing and is allelic to blistered, Development, 122:2589-2597
77. Needham, J.G., 1903, A geneologic study of dragonfly wing venation, Proc. U.S.N.M., 26:703-764
78. Needham, J.G., 1917, Notes on some recent studies of dragonfly wing tracheation (Odon.), Entomological News, 28:169-173
79. Needham, J.G., 1951, Prodrome for a Manual of the dragonflies of North America, with extended comments on wing venation systems, Trans. Am. Entomol. Soc., 78:21-62
80. Nijhout, H. F., & D. J. Emlen, 1998, COmpetition among body parts in the development and evolution of insect morphology, Proc. Natl. Acad. Sci. USA, 95:3685-3689
81. Nijhout, H. F., & L. W. Grunert, 2002, Bombyxin is a growth factor for wing imaginal disks in Lepidoptera, PNAS, 99(24):15446-15450
82. O'Grady, P.M., & R. DeSalle, 2000, Insect Evolution: How the fruit fly changed (some of) its spots, Current Biology Dispatch, R75-R77
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84. Pfau, H.K., 1991, Contributions of functional morphology to the phylogenetic systematics of Odonata, Adv. Odonatol., 5:109-141
85. Ponomarenko, A.G., 1972, The nomenclature of wing venation in beetles (Coleoptera), Entomological Review, 51(4):454-458
86. Resino, J., P. Salama-Cohen, & A. Garcia-Bellido, 2002, Determining the role of patterned cell proliferation in the shape and size of the Drosophila wing, PNAS, 99(11):7502-7507
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90. Ronshaugen, M., N. McGinnis, & W. McGinnis, 2002, Hox protein mutation and macroevolution of the insect body plan, Nature, 415:914-917
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93. Schmeider, R.G., 1922, The tracheation of the wings of early larval instars of Odonata Anisoptera, with special reference to the development of the radius, Entomological News, 33:257-262 + plates X,XI, 299-303
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103. Sturtevant, M.A., & E. Bier, 1995, Analysis of the genetic hierarchy guiding wing vein development in Drosophila, Development, 121:785-801
104. Sturtevant, M.A., B. Biehs, E. Marin, & E. Bier, 1997, The spalt gene links the A/P compartment boundary to a linear adult structure in the Drosophila wing, Development, 124:21-32
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