Haustorium

In botany and mycology, a haustorium (plural haustoria) is a rootlike structure that grows into or around another structure to absorb water or nutrients. For example, in mistletoe or members of the broomrape family, the structure penetrates the host's tissue and draws nutrients from it. In mycology, it refers to the appendage or portion of a parasitic fungus (the hyphal tip), which performs a similar function. Microscopic haustoria penetrate the host plant's cell wall and siphon nutrients from the space between the cell wall and plasma membrane but do not penetrate the membrane itself.[1] Larger (usually botanical, not fungal) haustoria do this at the tissue level.

Hyaloperonospora parasitica: hyphae and haustoria
A coconut sprout, the edible haustorium of germinating coconut seeds

The etymology of the name corresponds to the Latin word haustor meaning the one who draws, drains or drinks,[2][3] and refers to the action performed by the outgrowth.

In fungi

Fungi in all major divisions form haustoria. Haustoria take several forms. Generally, on penetration, the fungus increases the surface area in contact with host plasma membrane releasing enzymes that break up the cell walls, enabling greater potential movement of organic carbon from host to fungus. Thus, an insect hosting a parasitic fungus such as Cordyceps may look as though it is being "eaten from the inside out" as the haustoria expand inside of it.

The simplest forms of haustoria are small spheres. The largest are complex formations adding significant mass to a cell, expanding between the cell wall and cell membrane. In the Chytridiomycota, the entire fungus may become enclosed in the cell, and it is arguable whether this should be considered analogous to a haustorium.

Haustoria arise from intercellular hyphae, appressoria, or external hyphae. The hypha narrows as it passes through the cell wall and then expands on invaginating the cell. A thickened, electron-dense collar of material is deposited around the hypha at the point of invagination. Further, the host cell wall becomes highly modified in the invaginated zone. Inclusions normally present in plasma membrane are absent, and the outer layer contains more polysaccharide. The wall of both partners is severely reduced.

Functional exchange takes place within the haustorial complex. The host supplies organic carbon to the fungus, and the metabolic activity within the complex is considerably greater than outside. Carbon from the host is absorbed by the fungus, and transported to the rest of the thallus. The host plant appears to be functioning according to signals from the fungus and the complex appears to be under the control of the invader.[4]

The haustorium may be mycelium or root-shaped.

In plants

Mistletoes (including Loranthaceae and Viscaceae) attach to their hosts via a haustorium. The haustoria attacks the host's xylem and/or phloem and attaches itself to the host.[5] This structure both anchors the mistletoe, and taps into the host plant. Mistletoes use passive mechanisms to draw water from their hosts. They keep their leaf stomata open night and day which sets up a moisture gradient between mistletoe and host.[6]

A second meaning of 'haustorium' in botany is to describe tissues in a developing plant embryo that transfer nutrients from the seed's endosperm to the embryo. These tissues are found widely in the seeds of flowering plants.[7]

References

  1. Szabo, Les (July 3, 2001). "Hidden robbers: The role of fungal haustoria in parasitism of plants". PNAS. 98 (14): 7654–7655. Bibcode:2001PNAS...98.7654S. doi:10.1073/pnas.151262398. PMC 35395. PMID 11438718.
  2. Gaffiot, Félix (1934). Dictionnaire illustré Latin-Français (in French). Paris: Librairie Hachette. p. 737. Retrieved 13 May 2020.
  3. haustor. Charlton T. Lewis and Charles Short. A Latin Dictionary on Perseus Project.
  4. "Mycology – Structure and Function – Haustoria". Archived from the original on 2011-02-21. Retrieved 2010-10-17.
  5. Press, Malcolm C.; Phoenix, Gareth K. (June 2005). "Impacts of parasitic plants on natural communities". New Phytologist. 166 (3): 737–751. doi:10.1111/j.1469-8137.2005.01358.x. ISSN 0028-646X. PMID 15869638.
  6. Watson, D. M. (2011) Mistletoes of Southern Australia, CSIRO Publishing, Collingwood, VIC
  7. Bhatnagar, S.P. and Veena Sawhney. (1981) "Endosperm—Its Morphology, infrastructure, and Histochemistry", International Review of Cytology

Bibliography

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