Leymus arenarius

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Leymus arenarius
Leymus arenarius habitus.jpeg
Scientific classification OOjs UI icon edit-ltr.svg
Kingdom: Plantae
Clade: Tracheophytes
Clade: Angiosperms
Clade: Monocots
Clade: Commelinids
Order: Poales
Family: Poaceae
Subfamily: Pooideae
Genus: Leymus
Species:
L. arenarius
Binomial name
Leymus arenarius
(L.) Hochst.
Synonyms

Elymus arenariusL.

Leymus arenarius. 153 cm high. Strandrag (Leymus arenarius) -Ystad2020.jpg
Leymus arenarius. 153 cm high.

Leymus arenarius is a psammophilic (sand-loving) species of grass in the family Poaceae, native to the coasts of Atlantic and Northern Europe. Leymus arenarius is commonly known as sand ryegrass, [1] sea lyme grass, or simply lyme grass. [2]

Taxonomy

Leymus arenarius originated from the hybridization of L. racemosus and another unknown species in central Eurasia or from a polyploidization event. [3] DNA analysis shows that inland and coastal plants are statistically not different from each other. L. arenarius is a recent cultivar, and has had little time to accumulate genetic differences.[ clarification needed ]Leymus arenarius is much younger than its North American relative L. mollis , which has been around since the ice age. Icelandic L. arenarius is molecularly uniform. Polish L. arenarius is also reported to be molecularly uniform. [3]

Distribution

Leymus arenarius is native to the coasts of northern and western Europe. A closely related species Leymus mollis (previously Elymus arenarius ssp. mollis) is native to the northern coasts of North America.

Growth and development

Nitrogen

Leymus arenarius can grow exponentially in terms of height and root growth in the presence of nitrogen. Leymus arenarius is known to take up nitrogen into its root system. Raising nitrogen concentrations can aid in growth as over time plant mass above to surface will not change, but will accumulate in the root system. The roots themselves also retain nitrogen as they come in contact with it and in the surrounding un-vegetated areas. This assists in primary succession with surrounding flora and fauna, and a decrease in soil erosion. After volcanic events L. arenarius causes dunes and their soil depth to grow exponentially over time. [4] Nitrogen increases seed production, raising the yield of seeds as much as 70% in Icelandic L. arenarius. The seed density also increased with the addition of nitrogen, in comparison to phosphorus and potassium which only produce marginal increases for both seed yield and density. Leaf size and density are also influenced by nutrient additions. Removing nitrogen, phosphorus, or potassium resulted in a reduction of leaf mass up to 20%. Nitrogen usage is a cost-effective tool to use to increase abundance and effectiveness of L.arenarius. [5]

Fungi

Leymus arenarius benefits from the presence of arbuscular mycorrhizal fungi. The presence of the fungi increases the ability of L. arenarius to have an extensive root system and to bind soil particles. When adding fungi in its natural habitat, more seeds survived and grew than without the fungi present. [6]

Adaptability

Leymus arenarius can adapt easily to a highly salinized area. When comparing the salt tolerances of the Icelandic populations and the inland populations, the Icelandic populations expressed a higher salt tolerance than the inland populations. The trait for salt tolerance is heritable. The seeds of Icelandic populations germinated more in the presence of a high salt concentration than seeds of the inland population. In Finland the same salinity tolerance is also observed near roadsides where salt is distributed every season during snowfall. The pH near roadsides is closer to the pH present near saltwater beaches. [7]

Pathogene resistance

Leymus arenarius has a high immunity to pathogens. In total there are 160 transcripts for antimicrobial peptides present in seedlings. There are 30 transcripts encoding for unique antimicrobial peptides. These are not present in other plant species, and add to the immune system of the plant itself, making it immune to more pathogens than any of its relatives. [8]

Uses

In Europe, the plant's stems are used for roof thatching and can be woven into a coarse fabric. Seeds have provided food in the past. Beginning as early as the 18th century, the plant's extensive network of roots was used in stabilizing sands on northern coastal beaches. [9] In Iceland, the grass was harvested as a wild grain as early as the 12th century. [10]

Law

During the 17th century reign of William III, the Scottish Parliament passed a law protecting Leymus arenarius. Under the 18th century reign of George I, the British Parliament expanded the law to protect the plant on English coasts. This law went as far as declaring the cutting or possession of the grass to be a penal offense. [9]

Related Research Articles

<span class="mw-page-title-main">Mycorrhiza</span> Fungus-plant symbiotic association

A mycorrhiza is a symbiotic association between a fungus and a plant. The term mycorrhiza refers to the role of the fungus in the plant's rhizosphere, its root system. Mycorrhizae play important roles in plant nutrition, soil biology, and soil chemistry.

<span class="mw-page-title-main">Mangrove</span> Shrub growing in brackish water

A mangrove is a shrub or tree that grows mainly in coastal saline or brackish water. Mangroves grow in an equatorial climate, typically along coastlines and tidal rivers. They have special adaptations to take in extra oxygen and to remove salt, which allow them to tolerate conditions that would kill most plants. The term is also used for tropical coastal vegetation consisting of such species. Mangroves are taxonomically diverse, as a result of convergent evolution in several plant families. They occur worldwide in the tropics and subtropics and even some temperate coastal areas, mainly between latitudes 30° N and 30° S, with the greatest mangrove area within 5° of the equator. Mangrove plant families first appeared during the Late Cretaceous to Paleocene epochs, and became widely distributed in part due to the movement of tectonic plates. The oldest known fossils of mangrove palm date to 75 million years ago.

<span class="mw-page-title-main">Salt marsh</span> Coastal ecosystem between land and open saltwater that is regularly flooded

A salt marsh, saltmarsh or salting, also known as a coastal salt marsh or a tidal marsh, is a coastal ecosystem in the upper coastal intertidal zone between land and open saltwater or brackish water that is regularly flooded by the tides. It is dominated by dense stands of salt-tolerant plants such as herbs, grasses, or low shrubs. These plants are terrestrial in origin and are essential to the stability of the salt marsh in trapping and binding sediments. Salt marshes play a large role in the aquatic food web and the delivery of nutrients to coastal waters. They also support terrestrial animals and provide coastal protection.

<span class="mw-page-title-main">Pioneer species</span> First species to colonize or inhabit damaged ecosystems

Pioneer species are resilient species that are the first to colonize barren environments, or to repopulate disrupted biodiverse steady-state ecosystems as part of ecological succession. A number of kinds of events can create good conditions for pioneers, including disruption by natural disasters, such as wildfire, flood, mudslide, lava flow or a climate-related extinction event or by anthropogenic habitat destruction, such as through land clearance for agriculture or construction or industrial damage. Pioneer species play an important role in creating soil in primary succession, and stabilizing soil and nutrients in secondary succession.

<span class="mw-page-title-main">Endophyte</span> Endosymbiotic bacterium or fungus

An endophyte is an endosymbiont, often a bacterium or fungus, that lives within a plant for at least part of its life cycle without causing apparent disease. Endophytes are ubiquitous and have been found in all species of plants studied to date; however, most of the endophyte/plant relationships are not well understood. Some endophytes may enhance host growth and nutrient acquisition and improve the plant's ability to tolerate abiotic stresses, such as drought, and decrease biotic stresses by enhancing plant resistance to insects, pathogens and herbivores. Although endophytic bacteria and fungi are frequently studied, endophytic archaea are increasingly being considered for their role in plant growth promotion as part of the core microbiome of a plant.

<span class="mw-page-title-main">Arbuscular mycorrhiza</span> Symbiotic penetrative association between a fungus and the roots of a vascular plant

An arbuscular mycorrhiza (AM) is a type of mycorrhiza in which the symbiont fungus penetrates the cortical cells of the roots of a vascular plant forming arbuscules. Arbuscular mycorrhiza is a type of endomycorrhiza along with ericoid mycorrhiza and orchid mycorrhiza. They are characterized by the formation of unique tree-like structures, the arbuscules. In addition, globular storage structures called vesicles are often encountered.

<i>Festuca ovina</i> Species of flowering plant

Festuca ovina, sheep's fescue or sheep fescue, is a species of grass. It is sometimes confused with hard fescue.

<i>Fusarium culmorum</i> Fungal disease, head blight of wheat

Fusarium culmorum is a fungal plant pathogen and the causal agent of seedling blight, foot rot, ear blight, stalk rot, common root rot and other diseases of cereals, grasses, and a wide variety of monocots and dicots. In coastal dunegrass, F. culmorum is a nonpathogenic symbiont conferring both salt and drought tolerance to the plant.

Microbial inoculants, also known as soil inoculants or bioinoculants, are agricultural amendments that use beneficial rhizosphericic or endophytic microbes to promote plant health. Many of the microbes involved form symbiotic relationships with the target crops where both parties benefit (mutualism). While microbial inoculants are applied to improve plant nutrition, they can also be used to promote plant growth by stimulating plant hormone production. Although bacterial and fungal inoculants are common, inoculation with archaea to promote plant growth is being increasingly studied.

<i>Leymus racemosus</i> Species of grass

Leymus racemosus is a species of perennial wild rye known by the common name mammoth wild rye. It is native to southeastern and eastern Europe, Middle Asia, Caucasus, Siberia, China, Mongolia, New Zealand, and parts of North America. Culms are 50–100 cm long, and 10–12 mm in diameter.

<span class="mw-page-title-main">Plant use of endophytic fungi in defense</span>

Plant use of endophytic fungi in defense occurs when endophytic fungi, which live symbiotically with the majority of plants by entering their cells, are utilized as an indirect defense against herbivores. In exchange for carbohydrate energy resources, the fungus provides benefits to the plant which can include increased water or nutrient uptake and protection from phytophagous insects, birds or mammals. Once associated, the fungi alter nutrient content of the plant and enhance or begin production of secondary metabolites. The change in chemical composition acts to deter herbivory by insects, grazing by ungulates and/or oviposition by adult insects. Endophyte-mediated defense can also be effective against pathogens and non-herbivory damage.

<i>Juncus roemerianus</i> Species of flowering plant

Juncus roemerianus is a species of flowering plant in the rush family known by the common names black rush, needlerush, and black needlerush. It is native to North America, where its main distribution lies along the coastline of the southeastern United States, including the Gulf Coast. It occurs from New Jersey to Texas, with outlying populations in Connecticut, New York, Mexico, and certain Caribbean islands.

<i>Leymus multicaulis</i> Species of grass

Leymus multicaulis, also known as manystem wild rye or manystem lyme grass, is a species of the genus Leymus. The species name of manystem wild rye, multicaulis, suggests the “many stems” of the species. Leymus multicaulis is considered a type of grass. Manystem wild rye has only one cotyledon in each of its seeds. The xylem and phloem within the roots are arranged in a ring pattern. The vascular bundles are scattered throughout the stem. These traits make Leymus multicaulis a monocot. Leymus multicaulis is a flowering plant, or angiosperm.

<span class="mw-page-title-main">Mycorrhizal network</span> Underground fungal networks that connect individual plants together

A mycorrhizal network is an underground network found in forests and other plant communities, created by the hyphae of mycorrhizal fungi joining with plant roots. This network connects individual plants together. Mycorrhizal relationships are most commonly mutualistic, with both partners benefiting, but can be commensal or parasitic, and a single partnership may change between any of the three types of symbiosis at different times.

<i>Leymus mollis</i> Species of grass

Leymus mollis is a species of grass known by the common names American dune grass, American dune wild-rye, sea lyme-grass, strand-wheat, and strand grass. Its Japanese name is hamaninniku. It is native to Asia, where it occurs in Japan, China, Korea, and Russia, and northern parts of North America, where it occurs across Canada and the northern United States, as well as Greenland. It can also be found in Iceland.

<span class="mw-page-title-main">Ectomycorrhiza</span> Non-penetrative symbiotic association between a fungus and the roots of a vascular plant

An ectomycorrhiza is a form of symbiotic relationship that occurs between a fungal symbiont, or mycobiont, and the roots of various plant species. The mycobiont is often from the phyla Basidiomycota and Ascomycota, and more rarely from the Zygomycota. Ectomycorrhizas form on the roots of around 2% of plant species, usually woody plants, including species from the birch, dipterocarp, myrtle, beech, willow, pine and rose families. Research on ectomycorrhizas is increasingly important in areas such as ecosystem management and restoration, forestry and agriculture.

<span class="mw-page-title-main">Root microbiome</span> Microbe community of plant roots

The root microbiome is the dynamic community of microorganisms associated with plant roots. Because they are rich in a variety of carbon compounds, plant roots provide unique environments for a diverse assemblage of soil microorganisms, including bacteria, fungi, and archaea. The microbial communities inside the root and in the rhizosphere are distinct from each other, and from the microbial communities of bulk soil, although there is some overlap in species composition.

Leymus chinensis, commonly known as false wheatgrass or Chinese rye grass, is a species of wild rye native to China, Korea, Mongolia and Russia.

Orchid mycorrhizae are endomycorrhizal fungi which develop symbiotic relationships with the roots and seeds of plants of the family Orchidaceae. Nearly all orchids are myco-heterotrophic at some point in their life cycle. Orchid mycorrhizae are critically important during orchid germination, as an orchid seed has virtually no energy reserve and obtains its carbon from the fungal symbiont.

Tripartite symbiosis is a type of symbiosis involving three species. This can include any combination of plants, animals, fungi, bacteria, or archaea, often in interkingdom symbiosis.

References

  1. USDA, NRCS (n.d.). "Leymus arenarius". The PLANTS Database (plants.usda.gov). Greensboro, North Carolina: National Plant Data Team. Retrieved 2 June 2015.
  2. Sankiliuaq. Archived 2011-07-14 at the Wayback Machine Canada's Arctic: Nunavut. (retrieved 16 March 2009)
  3. 1 2 Mizianty, M; Frey, L; Bieniek, W; Boron, P; Szklarczyk, M (2007-10-18). "Variability and structure of natural populations of Hordelymus europaeus (L.) Jess. ex Harz and Leymus arenarius (L.) Hochst. as revealed by morphology and DNA markers". Plant Systematics and Evolution. 269 (1–2): 15–28. Bibcode:2007PSyEv.269...15M. doi:10.1007/s00606-007-0586-2. S2CID   7547705.
  4. Stefansdottir, G.; Aradottir, A. L.; Sigurdsson, B. D. (2014). "Accumulation of nitrogen and organic matter during primary succession of Leymus arenarius dunes on the volcanic island Surtsey, Iceland". Biogeosciences. 11 (20): 5763–5771. Bibcode:2014BGeo...11.5763S. doi: 10.5194/bg-11-5763-2014 .
  5. Greipsson, S.; Davy, A. J. (1997-10-01). "Responses of Leymus arenarius to Nutrients: Improvement of Seed Production and Seedling Establishment for Land Reclamation". Journal of Applied Ecology. 34 (5): 1165–1176. Bibcode:1997JApEc..34.1165G. doi:10.2307/2405229. JSTOR   2405229.
  6. Enkhtuya, Batkhuugyin; Óskarsson, Úlfur; Dodd, John C.; Vosátka, Miroslav (2003-06-01). "Inoculation of Grass and Tree Seedlings Used for Reclaiming Eroded Areas in Iceland with Mycorrhizal Fungi". Folia Geobotanica. 38 (2): 209–222. Bibcode:2003FolGe..38..209E. doi:10.1007/bf02803153. JSTOR   25133983. S2CID   25512316.
  7. Greipsson, S.; Ahokas, H.; Vähämiko, S. (1997-01-01). "A Rapid Adaptation to Low Salinity of Inland-Colonizing Populations of the Littoral Grass Leymus arenarius". International Journal of Plant Sciences. 158 (1): 73–78. doi:10.1086/297415. JSTOR   2475131. S2CID   84956155.
  8. Slavokhotova, Anna A.; Shelenkov, Andrey A.; Odintsova, Tatyana I. (2015-09-14). "Prediction of Leymus arenarius (L.) antimicrobial peptides based on de novo transcriptome assembly". Plant Molecular Biology. 89 (3): 203–214. doi:10.1007/s11103-015-0346-6. ISSN   0167-4412. PMID   26369913. S2CID   8623809.
  9. 1 2 Sea Lyme Grass. Plant Guide. (retrieved 11 April 2009)
  10. Nesbitt, Mark (2005). Prance, Ghillean; Nesbitt, Mark (eds.). The Cultural History of Plants. Routledge. p. 47. ISBN   0415927463.
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