Stolon

In biology, stolons (from Latin stolō, genitive stolōnis – "branch"), also known as runners, are horizontal connections between parts of an organism. They may be part of the organism, or of its skeleton. Typically, animal stolons are exoskeletons (external skeletons).

In botany

In

Stolons may have long or short

Stolons arise from the base of the plant.[4] In strawberries the base is above the soil surface; in many bulb-forming species and plants with rhizomes, the stolons remain underground and form shoots that rise to the surface at the ends or from the nodes. The nodes of the stolons produce roots, often all around the node and hormones produced by the roots cause the stolon to initiate shoots with normal leaves.^[5] Typically after the formation of the new plant the stolon dies away^[6] in a year or two, while rhizomes persist normally for many years or for the life of the plant, adding more length each year to the ends with active growth. The horizontal growth of stolons results from the interplay of different hormones produced at the growing point and hormones from the main plant, with some studies showing that stolon and rhizome growth are affected by the amount of shady light the plant receives with increased production and branching from plants exposed to mixed shade and sun, while plants in all day sun or all shade produce fewer stolons.^[7]

A number of plants have soil-level or above-ground rhizomes, including Iris species and many orchid species.

T. Holm (1929) restricted the term rhizome to a horizontal, usually subterranean, stem that produces roots from its lower surface and green leaves from its apex, developed directly from the plumule of the embryo. He recognized stolons as axillary, subterranean branches that do not bear green leaves but only membranaceous, scale-like ones.^[8]

A stolon of grasses is defined as a horizontal stem above or on the soil surface that often roots at the internodes.^[9]

Plants with stolons

In some Cyperus species the stolons end with the growth of tubers; the tubers are swollen stolons that form new plants.^[10]

Some species of crawling plants can also sprout adventitious roots, but are not considered stoloniferous: a stolon is sprouted from an existing stem and can produce a full individual. Examples of plants that extend through stolons include some species from the genera Riccia, Argentina (silverweed), Cynodon, Fragaria, and Pilosella (Hawkweeds), Zoysia japonica, Ranunculus repens. Plants with long, slender stolons are referred to as sarmentose plants.^[11]

Other plants with stolons below the soil surface include many grasses, Ajuga, Mentha,^[12] and Stachys. Several species of Irises have stolons attached to their rhizomes,^[13] including Iris stolonifera.

Hydrilla use stolons that produce tubers to spread themselves and to survive dry periods in aquatic habitats.^[18]

Convolvulus arvensis is a weed species in agriculture that spreads by under ground stolons that produce rhizomes.^[20]

In studies on grass species, with plants that produce stolons or rhizomes and plants that produce both stolons and rhizomes, morphological and physiological differences were noticed. Stolons have longer internodes and function as means of seeking out light and are used for propagation of the plant, while rhizomes are used as storage organs for carbohydrates and the maintenance of meristem tissue to keep the parent plant alive from one year to the next.^[21]

In mycology

In

bread molds

, and are seen as horizontally expanding across the mold.

In zoology

Some bryozoans form colonies through connection of individual units by stolons. Other colonies include sheets and erect colonies.^[22]

Some colonial Cnidaria develop as stolons with interconnected medusoid structures that later separate.^{[citation needed]}

Some worm-like animals, such as certain Polychaeta in the genus Myrianida, form stolons containing eggs or sperm which trail behind the main body before detaching to mate with other stolons.^[23]

The worm Megasyllis nipponica takes this to an extreme, developing stolons with their own eyes, antennae and brain which detach and mate with an opposite-sex stolon to produce fertilized eggs.^[24]

In palaeontology

Stolon-based reproduction is thought to have been used by

Rangeomorphs in the Ediacaran age.^[25][26]

See also

Wikimedia Commons has media related to Plant stolons.

• Offshoot (plant) – Lateral growth branching from plant stem
• Root – Basal organ of a vascular plant
• Sprigging – Method for plant propagation
• Vegetative reproduction – Asexual method of reproduction in plants

References

1. ^ ^{a b} Hickey, M.; King, C. (2001). The Cambridge Illustrated Glossary of Botanical Terms. Cambridge University Press.
2. ^ "Stolon". Dictionary.com. Retrieved 2007-05-07.
3. ^ Goebel, K. E. R. (1969) [1905]. Organography of plants, especially of the Archegoniatae and Spermaphyta. New York: Hofner publishing company.
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8. ^ Henderson, Norton C. "Iris". Flora of North America. eFloras.org. Retrieved 2005-05-10.
9. ISBN 978-0-643-09960-9
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10. ^ Tucker, Gordon C.; Marcks, Brian G.; Carter, J. R. "Cyperus serotinus". Flora of North America. eFloras.org. Retrieved 2005-05-10.
11. ^ Chisholm, Hugh, ed. (1911). "Sarmentose" . Encyclopædia Britannica. Vol. 24 (11th ed.). Cambridge University Press. p. 220.
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13. ^ "Home". Alpine Garden Society. Retrieved 8 November 2020.
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16. ^ Monaco Educational Service. "Introduction to stems". Botany. Archived from the original on 2005-04-13. Retrieved 2005-05-10.
17. ISBN 0-13-681007-1
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18. ^ "Hydrilla in the Catawba River Basin" (PDF). NCSU Aquatic Weed Management Program. Retrieved 2005-05-10.
19. ^ weakley, Alan S. "Flora of the Carolinas, Virginia, and Georgia, and Surrounding Areas, Part 6" (PDF). p. 808. Archived from the original (PDF) on 2006-03-04. Retrieved 2005-05-10.
20. ^ Harris, Peter. "Field and Hedge bindweeds Convolvulus arvensis L. and Calystegia sepium (L.) R. Br". Classical Biological Control of Weeds. Agriculture and Agri-Food Canada, Lethbridge Research Centre. Archived from the original on 2007-09-26. Retrieved 2005-05-10.
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22. ^ Levinton, Jeffrey S. "Marine Biology." 3rd Edition. Oxford Press. 2008.
23. ^ Pleijel, Fredrik (16 September 2016). "Runner up: Evolutionary Biology. "Polychaetous worm with engine and wagons"". Royal Society Photo Contest Winners Capture Breathtaking Details of our Rapidly Changing World. Retrieved 2023-12-08. This trainworm (Myrianida pinnigera), which is 35 mm from head to tail, lives on the sea floor. Its front end, the trainworm's engine, is followed by a row of carriages called 'stolons' that increase in size towards the worm's tail end. The carriages are the worm's swimming sexual organs. When the trainworm is mature, the last carriage in the train lets go and detaches. It swims up the water column to reproduce. The carriages, unlike the engine, all lack a gut and are full of either sperm or eggs. In the water column the well-developed sensory organs seek out another stolon to mate with. After mating the male stolons die. The females survive a short time to shelter the embryos, which are carried in their bellies. Meanwhile, the trainworm on the sea floor continues to produce stolon carriages.
24. ^ Rayne, Elizabeth (8 December 2023). "Worm's rear end develops its own head, wanders off to mate". Ars Technica. Retrieved 2023-12-08. This appendage will detach from the main body and swim away, carrying gonads that will merge with those from other disembodied rear ends and give rise to a new generation. Wait, what in the science fiction B-movie alien star system is this thing?
25. ^ Mitchell et al. (2015), doi:10.1038/nature14646
26. ^ Peterson et al. (2003), Integr Comp Biol, 43:127-36