23.6:
Osmoregulation in Insects
Insects inhabit every continent on Earth and are found in virtually every habitat, even in the cold of Antarctica. Among the many adaptations necessary to survive in such diverse habitats, insects must often be resilient to dehydration. Osmoregulation is one of many adaptations that enable tolerance to dry environments.
It allows insects to retain enough water to stay hydrated, and like birds, excrete pasty or solid waste. The digestive tracts of most insects include malpighian tubules that extend from the intestine into the hemolymph, the insect equivalent of blood. Waste products, like uric acid, pass from the hemolymph into the malpighian tubules.
The tubules are lined with cells that contain molecular exchange pumps, which take in ions, such as sodium and potassium, that are transported into the tubules. The increased ion concentration causes water to passively follow ions into the tubules via osmosis. From the inner cavity of the tubule, or lumen, the waste, water, and ions travel to the rectum.
Here, most of the ions are transported back into the hemolymph. Due to osmosis, water again passively follows the ions back into the hemolymph, where it can be accessed in times of drought. The uric acid and other waste are then excreted from the body as a powder or waste. The osmoregulation of insects, therefore, allows them to safely excrete waste while conserving as much water as possible.
23.6:
Osmoregulation in Insects
Malpighian tubules are specialized structures found in the digestive systems of many arthropods, including most insects, that handle excretion and osmoregulation. The tubules are typically arranged in pairs and have a convoluted structure that increases their surface area.
Malpighian tubules extend from the digestive tract, typically the area between the midgut and hindgut, into the hemolymph—a mixture of blood and interstitial fluid found in insects and other arthropods, as well as most mollusks.
Unlike other excretory systems, the excretory processes of Malpighian tubules lack a filtration step. Metabolic wastes, like uric acid, diffuse into the tubules from the hemolymph.
The tubules are lined with a layer of transport epithelia. These specialized epithelial cells contain pumps that actively transport ions, like sodium (Na+) and potassium (K+), from the hemolymph into the interior of the tubule, called the lumen. Osmosis allows water to follow ions into the tubules passively.
From the tubule lumen, water, ions, and waste travel from the intestine to the rectum. Tiny, protruding microvilli lining the inside of the tubules help maximize solute-water coupling and the propulsion of uric acid crystals through the tubules.
In the rectum, specialized glands pump many of the ions back into the hemolymph. Osmosis again allows water to follow ions back into the hemolymph passively. The remaining nitrogenous waste, consisting mainly of concentrated uric acid, can then be excreted from the rectum as a paste or powder, along with feces. This system of recycling water and ions effectively allows the animal to conserve water in dehydrating environments such as deserts.
The number of Malpighian tubules varies across species, developmental stages, and even individuals. For example, worker ants of the Crematogaster lineolata and Myrmicina americana species have about 5 Malpighian tubules, while desert locusts (Schistocerca gregaria) have about 250!
Suggested Reading
Igarashi, Peter. 2005. “Overview: Nonmammalian Organisms for Studies of Kidney Development and Disease.” Journal of the American Society of Nephrology 16 (2): 296–98. [Source]
Odonnell, M. J. 2009. “Too Much of a Good Thing: How Insects Cope with Excess Ions or Toxins in the Diet.” Journal of Experimental Biology 212 (3): 363–72. [Source]
Piermarini, Peter, Carlos Esquivel, and Jerod Denton. 2017. “Malpighian Tubules as Novel Targets for Mosquito Control.” International Journal of Environmental Research and Public Health 14 (2): 111. [Source]