Neuroptera Explained

The insect order Neuroptera, or net-winged insects, includes the lacewings, mantidflies, antlions, and their relatives. The order consists of some 6,000 species.[1] Neuroptera is grouped together with the Megaloptera (alderflies, fishflies, and dobsonflies) and Raphidioptera (snakeflies) in the unranked taxon Neuropterida (once known as Planipennia).

Adult neuropterans have four membranous wings, all about the same size, with many veins. They have chewing mouthparts, and undergo complete metamorphosis.

Neuropterans first appeared during the Permian period, and continued to diversify through the Mesozoic era.[2] During this time, several unusually large forms evolved, especially in the extinct family Kalligrammatidae, often called "the butterflies of the Jurassic" for their large, patterned wings.[3] Following the end of the

Anatomy and biology

Neuropterans are soft-bodied insects with relatively few specialized features. They have large lateral compound eyes, and may or may not also have ocelli. Their mouthparts have strong mandibles suitable for chewing, and lack the various adaptations found in most other holometabolan insect groups.

They have four wings, usually similar in size and shape, and a generalised pattern of veins.[4] Some neuropterans have specialised sense organs in their wings, or have bristles or other structures to link their wings together during flight.[5]

The larvae are specialised predators, with elongated mandibles adapted for piercing and sucking. The larval body form varies between different families, depending on the nature of their prey. In general, however, they have three pairs of thoracic legs, each ending in two claws. The abdomen often has adhesive discs on the last two segments.[5]

Life cycle and ecology

The larvae of most families are predators. Many chrysopids, hemerobiids and coniopterygids eat aphids and other pest insects, and some have been used for biological control (either from commercial distributors, but also abundant and widespread in nature).[6] [7]

Larvae in various families cover themselves in debris (including other insects, living and dead[8]) as camouflage, taken to an extreme in the ant lions, which bury themselves completely out of sight and ambush prey from "pits" in the soil. Larvae of some Ithonidae are root feeders, and larvae of Sisyridae are aquatic, and feed on freshwater sponges. A few mantispids are parasites of spider egg sacs.

As in other holometabolic orders, the pupal stage is enclosed in some form of cocoon composed of silk and soil or other debris. The pupa eventually cuts its way out of the cocoon with its mandibles, and may even move about for a short while before undergoing the moult to the adult form.[5]

Adults of many groups are also predatory, but some do not feed, or consume only nectar.

Beetles, wasps, and some lake flies parasitize neuropteran larvae.

Evolution

Neuropterans first appeared near the end of the Permian period, as shown by fossils of the Permithonidae from the Tunguska basin in Siberia and a similar fauna from Australia.[2]

The osmylids are of Jurassic or Early Cretaceous origin and may be the most ancient of the Neuropteran groups. The extinct osmylid Protosmylus is fossilized in middle Eocene Baltic amber.[9] The genus Burmaleon is described from two fossils of Cenomanian age Burmese amber, implying crown group radiation in the Early Cretaceous or earlier.[10] [11] The family Kalligrammatidae lived from the Jurassic to Aptian (Lower Cretaceous) periods.[12]

Ithonidae are from the Jurassic to Recent, and the extinct lineages of the family were widespread geographically.[13]

Following the end of the Cretaceous period, the diversity of neuropterans appears to have declined.[14]

Phylogeny

Molecular analysis in 2018 using mitochondrial rRNA and mitogenomic data places the Megaloptera as sister to Neuroptera, and Raphidioptera as sister to this combined lineage, though these results were considered tentative.[15] [16] The fossil record has contributed to the understanding of the group's phylogeny.[1] [17] [18] [19] Relationships within the Myrmeleontiformia are still in flux.[20]

A phylogenomic analysis published in 2023 confirmed the topology of the neuropterid orders and found the relationships between the families of Neuropterida as shown in the following phylogenetic tree.[21]

Taxonomy

Review of the Neropterid group orders by Engel, Winterton, and Breitkreuz (2018) included grouping of the Neuropteran families in a nested set of clades, an abandonment of the paraphyletic suborder "Hemerobiiformia" and redefinition of Myrmeleontiformia as a clade.[22]

Neuroptera

The fossil genus †Mesohemerobius from the Late Jurassic-Early Cretaceous of China has been treated as incertae sedis within Neuroptera, while the fossil families †Permoberothidae and †Permithonidae are treated as a sister group to clade Eidoneuroptera formed by Neuroptera + Megaloptera.[22]

In human culture

The use of Neuroptera in biological control of insect pests has been investigated, showing that it is difficult to establish and maintain populations in fields of crops.[24]

Five species of Neuroptera are among 1681 insect species eaten by humans worldwide.[25]

The New Guinea Highland people claim to be able to maintain a muscular build and great stamina despite their low protein intake as a result of eating insects including Neuroptera.[26]

External links

Notes and References

  1. Book: . 2005 . Evolution of the Insects . . 0-521-82149-5.
  2. A. G. Ponomarenko . D. E. Shcherbakov . amp . 2004 . New lacewings (Neuroptera) from the terminal Permian and basal Triassic of Siberia . . 38 . S2 . S197–S203 .
  3. Michael S. Engel . 2005 . A remarkable kalligrammatid lacewing from the Upper Jurassic of Kazakhstan (Neuroptera: Kalligrammatidae) . . 108 . 1 . 59–62 . 10.1660/0022-8443(2005)108[0059:ARKLFT]2.0.CO;2. 86240200 .
  4. Breitkreuz . L. C. V. . Winterton . S. L. . Engel . M. S. . 2017 . Wing tracheation in Chrysopidae and other Neuropterida (Insecta): a resolution of the confusion about vein fusion . American Museum Novitates . 3890. 1–44 . 10.1206/3890.1. 55878344.
  5. Book: Hoell, H. V., Doyen, J. T. & Purcell, A. H. . 1998 . Introduction to Insect Biology and Diversity, 2nd ed. . Oxford University Press . 447–450 . 0-19-510033-6.
  6. Book: Senior . L. J. . The use of lacewings in biological control . June 2001 . Lacewings in the Crop Environment . 296–302 . Cambridge University Press . 10.1017/cbo9780511666117.014 . 978-0511666117 . McEwen . P. K..
  7. Monserrat . Víctor J. . 2015-12-30 . Los hemeróbidos de la Península Ibérica y Baleares (Insecta, Neuropterida, Neuroptera: Hemerobiidae) . Graellsia . es . 71 . 2 . 026 . 10.3989/graellsia.2015.v71.129 . 1989-953X. free.
  8. Powell, Erin. (2023). Defensive behaviors of the mealybug Nipaecoccus nipae (Maskell, 1893) (Hemiptera: Pseudococcidae) and the green lacewing Ceraeochrysa claveri (Navás, 1911) (Neuroptera: Chrysopidae), with videos of dorsal packet loading and mealybug ostiole function. Insecta Mundi. 1–11.
  9. Engel, Michael S. . Grimaldi, David A. . 2007 . The neuropterid fauna of Dominican and Mexican amber (Neuropterida, Megaloptera, Neuroptera) . American Museum Novitates . 3587 . 1–58 .
  10. Myskowiak . J. . Huang . D. . Azar . D. . Cai . C. . Garrouste . R. . Nel . A. . 2016 . New lacewings (Insecta, Neuroptera, Osmylidae, Nymphidae) from the Lower Cretaceous Burmese amber and Crato Formation in Brazil . Cretaceous Research . 59 . 214–227 . 10.1016/j.cretres.2015.10.029.
  11. Yang . Q. . Wang . Y. . Labandeira . C.C. . Shih . C. . Ren . D. . 2014 . Mesozoic lacewings from China provide phylogenetic insight into evolution of the Kalligrammatidae (Neuroptera) . BMC Evolutionary Biology . 14 . 126 . 10.1186/1471-2148-14-126 . 24912379 . 4113026 . free .
  12. Bechly . G. . Makarkin . V. N. . 2016 . A new gigantic lacewing species (Insecta: Neuroptera) from the Lower Cretaceous of Brazil confirms the occurrence of Kalligrammatidae in the Americas . Cretaceous Research . 58 . 135–140. 10.1016/j.cretres.2015.10.014.
  13. Archibald . S.B. . Makarkin V.N. . Tertiary giant lacewings (Neuroptera: Polystechotidae): Revision and description of new taxa from Western North America and Denmark . . 4 . 2 . 119–155 . 2006 . January 27, 2010 . 10.1017/S1477201906001817. 55970660.
  14. Luo . Cihang . Liu . Hua . Jarzembowski . Edmund A. . June 2022 . High morphological disparity of neuropteran larvae during the Cretaceous revealed by a new large species . Geological Magazine . en . 159 . 6 . 954–962 . 10.1017/S0016756822000176 . 0016-7568.
  15. Yue . Bi-Song . Song . Nan . Lin . Aili . Zhao . Xincheng . Insight into higher-level phylogeny of Neuropterida: Evidence from secondary structures of mitochondrial rRNA genes and mitogenomic data . PLOS ONE . 13 . 1 . 2018 . e0191826 . 1932-6203 . 10.1371/journal.pone.0191826. 29381758 . 5790268 . 2018PLoSO..1391826S. free .
  16. Yan, Y. . Wang Y, Liu, X. . Winterton, S. L. . Yang, D. . The First Mitochondrial Genomes of Antlion (Neuroptera: Myrmeleontidae) and Split-footed Lacewing (Neuroptera: Nymphidae), with Phylogenetic Implications of Myrmeleontiformia . Int J Biol Sci . 2014 . 10 . 8 . 895–908 . 10.7150/ijbs.9454 . 25170303 . 4147223.
  17. Grimaldi, D. A. & Engel, M. S., 2005: Evolution of the Insects. Cambridge University Press, 2005, pages xv-755
  18. Engel, M. S. & Grimaldi, D. A., 2007: The neuropterid fauna of Dominican and Mexican amber (Neuropterida: Megaloptera, Neuroptera). American Museum Novitates: #3587, pages 1-58
  19. Parker, S. P. (ed.), 1982: Synopsis and classification of living organisms. Vols. 1 & 2. McGrew-Hill Book Company
  20. Jones, J.R. (2019) Total‐evidence phylogeny of the owlflies (Neuroptera, Ascalaphidae) supports a new higher‐level classification. Zoologica Scripta: 06 October 2019 https://doi.org/10.1111/zsc.12382
  21. Cai . Chen-Yang . Tihelka . Erik . Liu . Xing-YUE . Engel . Michael S. . Improved modelling of compositional heterogeneity reconciles phylogenomic conflicts among lacewings . 2023 . Palaeoentomology . 6 . 257245897 . 10.11646/palaeoentomology.6.1.8 . free .
  22. Engel . M. S. . Winterton . S. L. . Breitkreuz . L. C. . 2018 . Phylogeny and evolution of Neuropterida: where have wings of lace taken us? . Annual Review of Entomology . 63 . 531–551 . 10.1146/annurev-ento-020117-043127. 29324039 .
  23. Engel, M. S. . Grimaldi, D. A. . 2008 . Diverse Neuropterida in Cretaceous amber, with particular reference to the paleofauna of Myanmar (Insecta) . Nova Supplementa Entomologica . 20 . 1–86.
  24. Xu . X. X. . Electrophysiological and Behavior Responses of Chrysopa phyllochroma (Neuroptera Chrysopidae) to Plant Volatiles . Environmental Entomology . 2014 . 44 . 5 . 1425–1433 . 10.1093/ee/nvv106 . 26314008 . 46558266 . 0046-225X.
  25. Book: Ramos-Elorduy, J. . 2005 . Insects: a hopeful resource . Maurizio G. Paoletti . Ecological Implications of Minilivestock . 263–291 . Enfield, New Hampshire . Science Publishers . 978-1578083398.
  26. Book: MacClancy, Jeremy . Consuming the Inedible: Neglected Dimensions of Food Choice . Berghahn . 2007 .