Malpighian tubule system

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The Malpighian tubule system is a type of excretory and osmoregulatory system found in some insects, myriapods, arachnids and tardigrades. It has also been described in some crustacean species,[1] and is likely the same organ as the posterior caeca which has been described in crustaceans.[2][3][4][5][6]

Stylised diagram of the last part of the insect's digestive tract showing malpighian tubule (orthopteran type)

The system consists of branching tubules extending from the alimentary canal that absorbs solutes, water, and wastes from the surrounding hemolymph. The wastes then are released from the organism in the form of solid nitrogenous compounds and calcium oxalate. The system is named after Marcello Malpighi, a seventeenth-century anatomist.

Structure

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Malpighian tubules of a dissected cockroach, indicated by yellow arrow. Scale bar, 2 mm.

Malpighian tubules are slender tubes normally found in the posterior regions of arthropod alimentary canals. Each tubule consists of a single layer of cells that is closed off at the distal end with the proximal end joining the alimentary canal at the junction between the midgut and hindgut. Most tubules are normally highly convoluted. The number of tubules varies between species although most occur in multiples of two. Tubules are usually bathed in hemolymph and are in proximity to fat body tissue. They contain actin for structural support and microvilli for propulsion of substances along the tubules. Malpighian tubules in most insects also contain accessory musculature associated with the tubules which may function to mix the contents of the tubules or expose the tubules to more hemolymph. The insect orders, Dermaptera and Thysanoptera do not possess these muscles and Collembola and Hemiptera:Aphididae completely lack a Malpighian tubule system.

General mode of action

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Pre-urine is formed in the tubules, when nitrogenous waste and electrolytes are transported through the tubule walls. Wastes such as urea and amino acids are thought to diffuse through the walls, while ions such as sodium and potassium are transported by active pump mechanisms. Water follows thereafter. The pre-urine, along with digested food, merge in the hindgut. At this time, uric acid precipitates out, and sodium and potassium ions are actively absorbed by the rectum, along with water via osmosis. Uric acid is left to mix with faeces, which are then excreted.

Alternative modes of action

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Complex cycling systems of Malpighian tubules have been described in other insect orders. Hemipteran insects use tubules that permit movement of solutes into the distal portion of the tubules while reabsorption of water and essential ions directly to the hemolymph occurs in the proximal portion and the rectum. Both Coleoptera and Lepidoptera use a cryptonephridial arrangement where the distal end of the tubules are embedded in fat tissue surrounding the rectum. Such an arrangement may serve to increase the efficiency of solute processing in the Malpighian tubules.

Other uses

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Arachnocampa luminosa larvae

Although primarily involved in excretion and osmoregulation, Malpighian tubules have been modified in some insects to serve accessory functions. Larvae of all species in genus Arachnocampa use modified and swollen Malpighian tubules to produce a blue-green light[7] attracting prey towards mucus-coated trap lines. In insects which feed on plant material containing noxious allelochemicals, Malpighian tubules also serve to rapidly excrete such compounds from the hemolymph.

See also

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References

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  1. ^ Henson, H. (1932). "The Development of the Alimentary Canal in Pieris Brassicae and the Endodermal origin of the Malpighian Tubules of Insects". Journal of Cell Science. s2-75 (298): 283–305. doi:10.1242/jcs.s2-75.298.283.
  2. ^ Castejón, Diego; Rotllant, Guiomar; Alba-Tercedor, Javier; Ribes, Enric; Durfort, Mercè; Guerao, Guillermo (4 February 2022). "Morphological and histological description of the midgut caeca in true crabs (Malacostraca: Decapoda: Brachyura): Origin, development and potential role". BMC Zoology. 7 (1): 9. doi:10.1186/s40850-022-00108-x. PMC 10127032. PMID 37170150.
  3. ^ "Comparative Anatomy of the Alimentary Canal of Hyperiid Amphipods". Journal of Crustacean Biology. 14 (2): 346–370. 1994. doi:10.1163/193724094X00335.
  4. ^ Graf, Francois; Meyran, Jean-Claude (1983). "Premolt calcium secretion in midgut posterior caeca of the crustacean Orchestia: Ultrastructure of the epithelium". Journal of Morphology. 177 (1): 1–23. doi:10.1002/jmor.1051770102. PMID 30064178. S2CID 51890859.
  5. ^ Günzl, Hans (1991). "The ultrastructure of the posterior gut and caecum inAlona affinis (Crustacea, Cladocera)" (PDF). Zoomorphology. 110 (3): 139–144. doi:10.1007/BF01632870.
  6. ^ Shyamsundari, K.; Rao, K. Hanumantha (1976). "Studies on the Alimentary Canal of Amphipods. Excretory Caeca". Crustaceana. 31 (2): 190–192. doi:10.1163/156854076X00224. JSTOR 20103092.
  7. ^ Green, L.B.S. (1979) The fine structure of the light organ of the New Zealand glow-worm Arachnocampa luminosa (Diptera: Mycetophilidae). Tissue and Cell 11: 457–465.
  • Gullan, P.J. and Cranston, P.S. (2000) The Insects: An Outline of Entomology. Blackwell Publishing UK ISBN 1-4051-1113-5
  • Romoser, W.S. and Stoffolano Jr., J.G. (1998) The Science of Entomology. McGraw-Hill Singapore ISBN 0-697-22848-7
  • Bradley, T.J. The excretory system: structure and physiology. In: Kerkut, G.A. and Gilbert, L.I. eds. Comprehensive insect physiology, biochemistry and pharmacology. Vol.4 Pergamon Press New York ISBN 0-08-030807-4 pp. 421–465