Syntrichia caninervis

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Steppe Screw Moss
Syntrichia caninervis 02.jpg
Syntrichia caninervis
Scientific classification OOjs UI icon edit-ltr.svg
Kingdom: Plantae
Division: Bryophyta
Class: Bryopsida
Subclass: Dicranidae
Order: Pottiales
Family: Pottiaceae
Genus: Syntrichia
Species:
S. caninervis
Binomial name
Syntrichia caninervis
(Mitt.) Broth.
Synonyms

Barbula bornmuelleri (Schiffn.) Paris
Barbula caninervis (Mitt.) A.Jaeger
Barbula desertorum (Broth.) Paris
Grimmia cucullata J.X.Luo - P.C.Wu
Syntrichia desertorum (Broth.) J.J.Amann.
Syntrichia pseudodesertorum (J.Froehl.) S.Agnew - Vondr.
Tortula bistratosa
Tortula bornmuelleri Schiffn.
Tortula caninervis subsp. caninervis
ortula caninervis (Mitt.) Broth.
Tortula desertorum Broth.
Tortula pseudodesertorum J.Froehl.
Turula saharae Trab.

Contents

Syntrichia caninervis, also known as steppe screw moss, is a desert moss species distributed throughout the world. As an extremophile, it is able to withstand desiccation under dry conditions with little access to water and is commonly found in hypolithic communities. It makes use of a novel adaptation to the desert environment to harvest and collect water sources such as dew, fog, snow, and rain, using tiny hairs instead of roots. In laboratory experiments, S. caninervis has shown the ability to survive in a simulated Martian environment.

Description

The plant was first described by English bryologist William Mitten (1819–1906) to the Linnean Society of London in May 1858, with a description published in their journal in February 1859. [1] It belongs to the Syntrichia genus [2] and the Pottiaceae family. [3] [4] It is commonly known as steppe screw moss. [5]

Distribution and habitat

S. caninervis has a widespread global distribution and is an extremophile [6] commonly found in extreme desert environments [7] and hypolithic communities [2] with the capacity to withstand desiccation under dry conditions. [8] It has been observed growing in China, Mongolia, Siberia, central and southwestern Asia, Europe, and North America. [9] In Tibet, Antarctica, and circumpolar regions, it is part of the biological soil crust, which is a resilient type of ground cover often found in arid lands. [10] In North America, the plant is found throughout the western and northwestern United States and in two western Canadian provinces. In the United States, it is found as far east as New Mexico, Colorado, Wyoming and Montana, all the way through Idaho, Utah, Arizona, and Nevada, and as far west as California, Oregon, and Washington. Two of the most common plant communities in the United States are found in the Mojave Desert and in the Columbia River drainage basin. In Canada, it is found in British Columbia and Alberta. [9]

Extremophile characteristics

Drought tolerance

S. caninervis is well-known for its ability to tolerate drought conditions, making it well-adapted to desert environments. Among these adaptions is its tiny hairs on the leaves that allow it to exploit multiple different sources of water, such as dew, fog, snow, and rain. [7] Another example is its ability to photosynthesize once remoistened after desiccation. [11]

Extreme temperature tolerance

Research has shown that S. caninervis can survive freezing temperatures as low as −196 °C (−320.8 °F) (in liquid nitrogen) for up to 30 days. It has also demonstrated the ability to withstand storage at −80 °C (−112 °F) for up to 5 years. In both cases, the moss was able to regenerate upon thawing, with dehydrated specimens showing faster recovery compared to hydrated ones. [10]

Radiation resistance

S. caninervis exhibits remarkable tolerance to gamma radiation. It can survive exposure to doses of up to 500 Gy, which is lethal to most plants and far exceeds the lethal dose for humans (around 50 Gy). Some studies have even suggested that exposure to 500 Gy of gamma radiation may promote the plant's growth. [10]

Simulated Martian conditions

In laboratory experiments, S. caninervis has demonstrated the ability to survive simulated Martian conditions. These conditions included an atmosphere composed of 95% CO₂, temperature fluctuations between −60 and 20 °C (−76 and 68 °F), high levels of UV radiation, and low atmospheric pressure. Dried moss plants achieved a 100% regeneration rate within 30 days after being subjected to these conditions for up to 7 days. [10]

Varieties

The Global Biodiversity Information Facility lists the following five varieties for Syntrichia caninervis: [12]

Related Research Articles

<span class="mw-page-title-main">Extremophile</span> Organisms capable of living in extreme environments

An extremophile is an organism that is able to live in extreme environments, i.e., environments with conditions approaching or stretching the limits of what known life can adapt to, such as extreme temperature, pressure, radiation, salinity, or pH level.

<span class="mw-page-title-main">Desiccation</span> State of extreme dryness or process of thorough drying

Desiccation is the state of extreme dryness, or the process of extreme drying. A desiccant is a hygroscopic substance that induces or sustains such a state in its local vicinity in a moderately sealed container. The word desiccation comes from Latin de- 'thoroughly', and siccare 'to dry'.

<span class="mw-page-title-main">Cryptobiosis</span> Metabolic state of life

Cryptobiosis or anabiosis is a metabolic state in extremophilic organisms in response to adverse environmental conditions such as desiccation, freezing, and oxygen deficiency. In the cryptobiotic state, all measurable metabolic processes stop, preventing reproduction, development, and repair. When environmental conditions return to being hospitable, the organism will return to its metabolic state of life as it was prior to cryptobiosis.

<span class="mw-page-title-main">Biological soil crust</span> Communities of living organisms on the soil surface in arid and semi-arid ecosystems

Biological soil crusts are communities of living organisms on the soil surface in arid and semi-arid ecosystems. They are found throughout the world with varying species composition and cover depending on topography, soil characteristics, climate, plant community, microhabitats, and disturbance regimes. Biological soil crusts perform important ecological roles including carbon fixation, nitrogen fixation and soil stabilization; they alter soil albedo and water relations and affect germination and nutrient levels in vascular plants. They can be damaged by fire, recreational activity, grazing and other disturbances and can require long time periods to recover composition and function. Biological soil crusts are also known as biocrusts or as cryptogamic, microbiotic, microphytic, or cryptobiotic soils.

<i>Selaginella lepidophylla</i> Species of spore-bearing plant

Selaginella lepidophylla, also known as a resurrection plant, is a species of desert plant in the spikemoss family (Selaginellaceae). It is native to the Chihuahuan Desert of the United States and Mexico. S. lepidophylla is renowned for its ability to survive almost complete desiccation. Resurrection plants are vascular rooted plants capable of surviving extreme desiccation, then resuming normal metabolic activity upon rehydration. The plant's hydro-responsive movements are governed by stem moisture content, tissue properties and a graded distribution of lignified cells affecting concentric stem stiffness and spiraling. During dry weather in its native habitat, its stems curl into a tight ball, uncurling only when exposed to moisture.

Poikilohydry is the lack of ability to maintain and/or regulate water content to achieve homeostasis of cells and tissue connected with quick equilibration of cell/tissue water content to that of the environment. The term is derived from Ancient Greek ποικίλος.

<span class="mw-page-title-main">EXPOSE</span> External facility on the ISS dedicated to astrobiology experiments

EXPOSE is a multi-user facility mounted outside the International Space Station (ISS) dedicated to astrobiology. EXPOSE was developed by the European Space Agency (ESA) for long-term spaceflights and was designed to allow exposure of chemical and biological samples to outer space while recording data during exposure.

A xerophyte is a species of plant that has adaptations to survive in an environment with little liquid water. Examples of xerophytes include cacti, pineapple and some gymnosperm plants. The morphology and physiology of xerophytes are adapted to conserve water during dry periods. Some species called resurrection plants can survive long periods of extreme dryness or desiccation of their tissues, during which their metabolic activity may effectively shut down. Plants with such morphological and physiological adaptations are said to be xeromorphic. Xerophytes such as cacti are capable of withstanding extended periods of dry conditions as they have deep-spreading roots and capacity to store water. Their waxy, thorny leaves prevent loss of moisture.

<span class="mw-page-title-main">Tardigrade</span> Phylum of microscopic animals, also known as water bears

Tardigrades, known colloquially as water bears or moss piglets, are a phylum of eight-legged segmented micro-animals. They were first described by the German zoologist Johann August Ephraim Goeze in 1773, who called them Kleiner Wasserbär. In 1777, the Italian biologist Lazzaro Spallanzani named them Tardigrada, which means "slow steppers".

Desiccation tolerance refers to the ability of an organism to withstand or endure extreme dryness, or drought-like conditions. Plants and animals living in arid or periodically arid environments such as temporary streams or ponds may face the challenge of desiccation, therefore physiological or behavioral adaptations to withstand these periods are necessary to ensure survival. In particular, insects occupy a wide range of ecologically diverse niches and, so, exhibit a variety of strategies to avoid desiccation.

<i>Deinococcus radiodurans</i> Radioresistant extremophile species of bacterium

Deinococcus radiodurans is a bacterium, an extremophile and one of the most radiation-resistant organisms known. It can survive cold, dehydration, vacuum, and acid, and therefore is known as a polyextremophile. The Guinness Book Of World Records listed it in January 1998 as the world's most radiation-resistant bacterium or lifeform.

<i>Acutuncus</i> Genus of tardigrades

Acutuncus is a genus of tardigrades containing a single species, Acutuncus antarcticus. Tardigrades, which are eight-legged micro-animals, are commonly referred to as water bears or moss piglets and are found all over the world in varying extreme habitats. First discovered in 1904 and originally named Hypsibius antarcticus, Acutuncus antarcticus is the most abundant tardigrade species in Antarctica.

<i>Chroococcidiopsis</i> Genus of bacteria

Chroococcidiopsis is a photosynthetic, coccoidal bacterium, and the only genus in the order Chroococcidiopsidales and in the family Chroococcidiopsidaceae. A diversity of species and cultures exist within the genus, with a diversity of phenotypes. Some extremophile members of Chroococcidiopsis are known for their ability to survive harsh environmental conditions, including both high and low temperatures, ionizing radiation, and high salinity.

<i>Nostoc commune</i> Species of bacterium

Nostoc commune is a species of cyanobacterium in the family Nostocaceae. Common names include star jelly, witch's butter, mare's eggs. It is the type species of the genus Nostoc and is cosmopolitan in distribution.

Daniela Billi is an Italian astrobiologist working at the University of Rome Tor Vergata. She is known for her work on desert cyanobacteria of the genus Chroococcidiopsis.

<i>Tortula</i> Genus of mosses in the family Pottiaceae

Tortula is a genus of mosses in the family Pottiaceae.

<i>Bryum argenteum</i> Species of moss

Bryum argenteum, the silvergreen bryum moss or silvery thread moss, is a species of moss in the family Bryaceae. It is one of the most common mosses of urban areas and can be easily recognized without a microscope.

<i>Ptychomnion aciculare</i> Species of moss

Ptychominon aciculare is a species of moss found predominantly in Australia, New Zealand, New Caledonia, Samoa, Juan Fernandez Islands and Chile. It is easily recognised given its similarity, especially when partially dried, to a pipe-cleaner. This name is commonly accepted across Australia and New Zealand. It has been observed growing from between sea level to sub-alpine altitudes (1200m).

<i>Syntrichia</i> Genus of mosses

Syntrichia is a large, cosmopolitan genus of mosses in the family Pottiaceae. The genus name is of Greek origin for "with" and "hair", referring to the "twisted peristome united by a basal membrane".

References

  1. Mitten, William (February 21, 1859) [https://www.biodiversitylibrary.org/page/167668 "Musci Indiae Orientalis, an enumeration of the mosses of the East Indies". Journal of the Proceedings of the Linnean Society, Bot., Suppl. 1: 39. Retrieved July 7, 2024.
  2. 1 2 Dabravolski, S.A; Isayenkov, S.V. (2022). "Metabolites Facilitating Adaptation of Desert Cyanobacteria to Extremely Arid Environments". Plants. 11 (23): 3225. doi: 10.3390/plants11233225 . PMC   9736550 . PMID   36501264.
  3. Canadian Journal of Botany: Journal Canadien de Botanique. National Research Council of Canada. 2002.
  4. Ochyra, Ryszard; Bednarek-Ochyra, Halina; Smith, Ronald Ian Lewis (2008-11-13). Illustrated Moss Flora of Antarctica. Cambridge University Press. ISBN   978-0-521-81402-7.
  5. Gurera, Dev; Bhushan, Bharat (2020-03-20). "Passive water harvesting by desert plants and animals: lessons from nature". Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences. 378 (2167): 20190444. Bibcode:2020RSPTA.37890444G. doi:10.1098/rsta.2019.0444. ISSN   1364-503X. PMID   32008451. Archived from the original on 2023-01-31. Retrieved 2024-07-02.
  6. Silva, A.T.; Gao, B.; Fisher, K.M.; et al. (March 2021). "To dry perchance to live: Insights from the genome of the desiccation-tolerant biocrust moss Syntrichia caninervis". The Plant Journal. 105 (5): 1339–1356. doi:10.1111/tpj.15116. PMID   33277766. Archived from the original on 2024-01-14. Retrieved 2024-07-07.
  7. 1 2 Pan, Zhao; Pitt, William G.; Zhang, Yuanming; Wu, Nan; Tao, Ye; Truscott, Tadd T. (2016-06-06). "The upside-down water collection system of Syntrichia caninervis". Nature Plants. 2 (7): 16076. doi:10.1038/nplants.2016.76. ISSN   2055-0278. PMID   27302768. Archived from the original on 2024-06-04. Retrieved 2024-07-07.
  8. Pan, Zhao; Pitt, William G.; Zhang, Yuanming; Wu, Nan; Tao, Ye; Truscott, Tadd T. (2016-06-06). "The upside-down water collection system of Syntrichia caninervis". Nature Plants. 2 (7): 16076. doi:10.1038/nplants.2016.76. ISSN   2055-0278. PMID   27302768.
  9. 1 2 "Syntrichia caninervis". Flora of North America . 2007. pp. 619, 625, 626. Archived from the original on 2024-04-19. Retrieved 2024-07-08. See distribution map Archived 2024-04-19 at the Wayback Machine .
  10. 1 2 3 4 Li, X.; Bai, W.; Yang, Q.; et al. (2024). "The extremotolerant desert moss Syntrichia caninervis is a promising pioneer plant for colonizing extraterrestrial environments". The Innovation. 5 (4): 1–9. doi:10.1016/j.xinn.2024.100657. Archived from the original on 2024-07-08. Retrieved 2024-07-07.
  11. Zhang, J.; Zhang, Y. M.; Downing, A.; Wu, N.; Zhang, B. C. (2011-03-01). "Photosynthetic and cytological recovery on remoistening Syntrichia caninervis Mitt., a desiccation-tolerant moss from Northwestern China". Photosynthetica. 49 (1): 13–20. doi:10.1007/s11099-011-0002-6.
  12. "Syntrichia caninervis Mitt." Archived 2024-04-19 at the Wayback Machine . Global Biodiversity Information Facility. Retrieved July 7, 2024.
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