microvillus, any of numerous microscopic bristlelike protrusions that occur on the surface of a wide variety ofcell types, includingintestinalepithelial cells,neurons,photoreceptors (light-sensitive cells), and certain cells of theimmune system, such as dendritic cells andlymphocytes. Structurally, microvilli are supported by filaments of aprotein known asactin; these filaments are arranged into bundles. Thepolymerization of actin filaments potentially drives the protrusion of microvilli from the cell surface and contributes to the unique highly curved form of themembranes on which microvilli occur.

The curvature of microvilli protrusions and their enrichment with a variety of proteins andlipids influence and contribute to thediverse functions of microvilli. On the surface of epithelial cells, such as in the lining of thesmall intestine, for example, microvilli feature prominently in specialized plasma membranes known asbrush borders, where they increase cell surface area and thereby facilitate the absorption of ingested food and water molecules. Other types of microvilli are involved in the detection ofsound in the ear, where their movement, caused by sound waves, sends an electrical signal to thebrain. In the immune system, microvilli are thought to serve a role in the transmission of signals involved in the activation of immune responses.

Microvilli in brush borders are perhaps the bestcharacterized in terms of structure and function. Brush borders are found on simple cuboidal and simple columnar epithelial cells that line the inner surface of the small intestine and the proximal tubule of thekidney. In the human small intestine, the brush border consists of individual microvilli approximately 0.1 μm in diameter and 1 μm in height; each epithelial cell may have as many as 1,000 microvilli. The microvilli play an important role in the digestion and absorption of intestinal contents by enlarging the absorbing surface approximately 25 times. They also secrete theenzymes disaccharidase and peptidase that hydrolyzedisaccharides and polypeptides tomonosaccharides and dipeptides toamino acids, respectively. Molecular receptors for specific substances are found on the microvilli surfaces at different levels in the small intestine, and there are transport proteins in the microvillusmembrane associated with the passage ofsodium ions,d-glucose, and amino acids. Owing to the presence of actin in the core of the microvillus and myosin in the brush border, microvilli further have motor activity that presumably initiates the stirring and mixing actions within the lumen of the small intestine.

Microvilli also serve unique functions in other organisms. Inarthropods, for example, most apposition eyes (a type ofcompound eye that is characteristic of diurnalinsects) contain a receptive structure known as the rhabdom, which is rodlike and consists of interdigitating microvilli contributed by a small number ofphotoreceptor cells. The number of microvilli varies, with eight being the typical number found in insects.

Inbees, the organization of the photopigment molecules on the microvilli in the rhabdoms makes navigation bypolarization patterns possible. Aphoton is detected only when the light-sensitivedouble bond of the photopigment molecule lies in the plane of polarization of the photon. The rhabdoms in the dorsal regions of bee eyes have their photopigment molecules aligned with the axes of the microvilli, which lie parallel to one another in the photoreceptor. As a result, each photoreceptor is able to act as a detector for a particular plane of polarization. The wholearray of detectors in the bee’s eyes is arranged in a way that matches the polarization pattern in the sky, thus enabling the bee to easily detect the symmetry plane of the pattern, which is the plane containing theSun.

Many insects use a similar mechanism to find water when flying between pools. In this case, there are pairs of photoreceptors with opposing microvillar orientations in the downward-pointing region of the eye, and, when the photoreceptors are differentially stimulated by polarized light from a reflecting surface, the insect makes a dive. The reason that humans cannot detect polarized light is that the photopigment molecules can take up all possible orientations within the disks of the rods and cones; this differs from the microvilli of arthropods, in which the molecules are constrained to lie parallel to the microvillaraxis.

In cephalopods, photoreceptors are made from arrays of microvilli, which depolarize (become less negative) in response to light. The reflecting eyes of Pectenscallops have tworetinas, one made up of a layer of conventional microvillus receptors close to the mirror and out of focus and the second made up of a layer with ciliary receptors in the plane of the image.

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