Buxbaumia viridis

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Buxbaumia viridis
Buxbaumia viridis 220313.JPG
Scientific classification OOjs UI icon edit-ltr.svg
Kingdom: Plantae
Division: Bryophyta
Class: Bryopsida
Order: Buxbaumiales
Family: Buxbaumiaceae
Genus: Buxbaumia
Species:
B. viridis
Binomial name
Buxbaumia viridis
(Moug. ex Lam. et DC.) Brid. ex Moug. et Nestl

Buxbaumia viridis, also known as the green shield-moss, is a rare bryophyte found sporadically throughout the northern hemisphere. [1] [2] The gametophyte of this moss is not macroscopically visible; the large, distinct sporophyte of B. viridis is the only identifying structure of this moss. [3] This moss can be found singularly or in small groups on decaying wood, mostly in humid, sub-alpine to alpine Picea abies , Abies alba , or mixed tree forests. [1] This moss is rare and conservation efforts are being made in most countries B. viridis is found in.

Contents

Characteristics

Gametophyte

The gametophyte of Buxbaumia viridis is microscopic, existing mostly as non-competitive, slow-growing protonema. [4] It is not desiccation-tolerant. B. viridis is dioicus, with its antheridia and archegonia forming on small, singular leaves borne on the ends of the protonema. [5] The leaves that contain the archegonia are not present long as they quickly develop into sporophytes. [3] Fertilization usually happens mid-spring to early summer. [6]

Sporophyte

Cuticle of B. viridis peeling back from sporophyte. Buxbaumia viridis 300613.JPG
Cuticle of B. viridis peeling back from sporophyte.

The sporophyte of Buxbaumia viridis is characteristic of the moss and is usually the only way to identify its presence in an area. The seta is straight and measures 5-10mm. [7] [8] The capsule is asymmetrical. The immature capsule is green, shiny, and may have an opalescent sheen due to the waxy cuticle covering it. [8] The cuticle is a made of wax and contains way granules and crystals; this type of cuticle is associated with a few other mosses and liverworts such as in the Polytrichopsida and Marchantiaceae, as well as tracheophytes. [3] After the capsule matures in late summer to early fall, it develops its asymmetric shape and turns brown. The cuticle also begins to peel back, taking part of the epidermis with it. [3] [6] This gives the capsule a stringy appearance as the cuticle curls and frays. The sporophyte has an operculum, and this falls off to disperse spores. [4] Spore count can rage from 1.4 to 9.0 million, which is a much higher number compared to other mosses. [5] Sporophytes mature over the winter, and sporophytes can be found any time of year. [5] [6]

Habitat

Buxbaumia viridis is an epixylic species, meaning it lives on wood surfaces. [7] It favors heavily decayed wood, usually to the point where the decayed wood is deformed (30–60 years old depending on species and size). [5] It does not grow exclusively to one tree species, but it is found more often on conifer species such as Picea abies and Abies alba; it can also be found on other conifers and deciduous trees such as Fagus sylvatica . [6] Rarely it can be found on mineral soil or humus. [2]

B. viridis also requires constant humidity and shady or sheltered areas to survive. [1] Dry conditions can lead to protonema death, a reduction in spore count, and decreased germination. [5]

B. viridis exists in sub-alpine to alpine forests with extensive decaying wood. [1] [8]

Distribution

Buxbaumia viridis is widely distributed across the northern hemisphere, although populations are scattered and individual plants are scarce. [1] B. viridis is found in most of Europe, southwestern Asia, and Western North America. [1]

Ecology

Buxbaumia viridis is a poor competitor, likely because it exists mostly as protonema. [7] It is known to co-occur with some other species of mosses and liverworts such as Herzogiella seligeri , Rhizomnium punctatum, Dicranum scoparium, Tetraphis pellucida , and Chiloscyphus profundus . [4] Due to the moss being dioicous, having low fertilization rates, and not being desiccation tolerant, this leads to low establishment rates. [5] Fertilization of the archegonia happens mid spring to early summer, and maturation and spore dispersal of the sporophytes happens late spring to early summer. [6]

B. viridis is not a long-lived species due to the nature of its preferred substrate. [5] The advanced stage of decay of the substrate means it is vulnerable to significant change, and this means B. viridis may not be present at the same site from one year to the next. [5] B. viridis requires large amount of decayed wood for growth and future establishment; the mass of strongly decayed wood in an area is a good predictor of the presence of B. viridis. [7]

Although a generally unrecorded behavior on mosses, herbivory on B. viridis sporophytes has been observed. [6] Cut setas have been observed with an unknown perpetrator. [6] Small slugs from the Arion genus have also been observed scraping the outer part of the capsule to eat the spores inside. [6] It is unlikely that slug herbivory has any benefit to B. viridis, and accounts for 30% of sporophyte loss. [6]

It is likely that the actual number of individual B.viridis plants are higher than the recorded number because it can exist as protonema without producing a sporophyte, thus going undetected. [2]

Conservation

Status

Buxbaumia viridis is at risk of extinction; it is classified as vulnerable in Europe by the European Committee for the Conservation of Bryophytes and it is on the European Red-List for bryophytes. [1] [9] It is protected by law in Europe and most European countries are required to monitor it.

Threats

Its poor establishment rates, poor competitive ability, scattered populations, and its sensitivity to environmental changes put Buxbaumia viridis at risk of extinction. [5] Anthropogenic activities also threaten this moss; forest management practices often reduce the amount of decaying material present in a forest, and this affects the ability of B.viridis to establish new populations. [6] Forestry practice such as clearcutting is one of the largest threats to this moss as it reduces new potential areas for establishment and removes cover. [1]

Some forest management practices can be helpful; breaking up substrate reduces the competition B. viridis experiences from other bryophytes. [2]

Related Research Articles

<span class="mw-page-title-main">Gametophyte</span> Haploid stage in the life cycle of plants and algae

A gametophyte is one of the two alternating multicellular phases in the life cycles of plants and algae. It is a haploid multicellular organism that develops from a haploid spore that has one set of chromosomes. The gametophyte is the sexual phase in the life cycle of plants and algae. It develops sex organs that produce gametes, haploid sex cells that participate in fertilization to form a diploid zygote which has a double set of chromosomes. Cell division of the zygote results in a new diploid multicellular organism, the second stage in the life cycle known as the sporophyte. The sporophyte can produce haploid spores by meiosis that on germination produce a new generation of gametophytes.

<span class="mw-page-title-main">Moss</span> Division of non-vascular land plants

Mosses are small, non-vascular flowerless plants in the taxonomic division Bryophytasensu stricto. Bryophyta may also refer to the parent group bryophytes, which comprise liverworts, mosses, and hornworts. Mosses typically form dense green clumps or mats, often in damp or shady locations. The individual plants are usually composed of simple leaves that are generally only one cell thick, attached to a stem that may be branched or unbranched and has only a limited role in conducting water and nutrients. Although some species have conducting tissues, these are generally poorly developed and structurally different from similar tissue found in vascular plants. Mosses do not have seeds and after fertilisation develop sporophytes with unbranched stalks topped with single capsules containing spores. They are typically 0.2–10 cm (0.1–3.9 in) tall, though some species are much larger. Dawsonia, the tallest moss in the world, can grow to 50 cm (20 in) in height. There are approximately 12,000 species.

<span class="mw-page-title-main">Bryophyte</span> Terrestrial plants that lack vascular tissue

Bryophytes are a group of land plants, sometimes treated as a taxonomic division, that contains three groups of non-vascular land plants (embryophytes): the liverworts, hornworts, and mosses. In the strict sense, the division Bryophyta consists of the mosses only. Bryophytes are characteristically limited in size and prefer moist habitats although some species can survive in drier environments. The bryophytes consist of about 20,000 plant species. Bryophytes produce enclosed reproductive structures, but they do not produce flowers or seeds. They reproduce sexually by spores and asexually by fragmentation or the production of gemmae. Though bryophytes were considered a paraphyletic group in recent years, almost all of the most recent phylogenetic evidence supports the monophyly of this group, as originally classified by Wilhelm Schimper in 1879. The term bryophyte comes from Ancient Greek βρύον (brúon) 'tree moss, liverwort' and φυτόν (phutón) 'plant'.

<span class="mw-page-title-main">Hornwort</span> Division of non-vascular land plants with horn-shaped sporophytes

Hornworts are a group of non-vascular Embryophytes constituting the division Anthocerotophyta. The common name refers to the elongated horn-like structure, which is the sporophyte. As in mosses and liverworts, hornworts have a gametophyte-dominant life cycle, in which cells of the plant carry only a single set of genetic information; the flattened, green plant body of a hornwort is the gametophyte stage of the plant.

<i>Fissidens adianthoides</i> Species of moss

Fissidens adianthoides, the maidenhair pocketmoss, is a moss in the family Fissidentaceae. It was first collected by Hedwig in 1801.

<i>Buxbaumia</i> Genus of mosses

Buxbaumia is a genus of twelve species of moss (Bryophyta). It was first named in 1742 by Albrecht von Haller and later brought into modern botanical nomenclature in 1801 by Johann Hedwig to commemorate Johann Christian Buxbaum, a German physician and botanist who discovered the moss in 1712 at the mouth of the Volga River. The moss is microscopic for most of its existence, and plants are noticeable only after they begin to produce their reproductive structures. The asymmetrical spore capsule has a distinctive shape and structure, some features of which appear to be transitional from those in primitive mosses to most modern mosses.

Plant reproduction is the production of new offspring in plants, which can be accomplished by sexual or asexual reproduction. Sexual reproduction produces offspring by the fusion of gametes, resulting in offspring genetically different from either parent. Asexual reproduction produces new individuals without the fusion of gametes, resulting in clonal plants that are genetically identical to the parent plant and each other, unless mutations occur.

<i>Takakia ceratophylla</i> Species of moss

Takakia ceratophylla is one of the two species of toothless mosses in the genus Takakia, under the Takakiaceae family. This species was first described by William Mitten in 1861. Takakia ceratophylla is vulnerable and threatened by habitat loss due to human activities.

<i>Aulacomnium palustre</i> Species of moss

Aulacomnium palustre, the bog groove-moss or ribbed bog moss, is a moss that is nearly cosmopolitan in distribution. It occurs in North America, Hispaniola, Venezuela, Eurasia, and New Zealand. In North America, it occurs across southern arctic, subboreal, and boreal regions from Alaska and British Columbia to Greenland and Quebec. Documentation of ribbed bog moss's distribution in the contiguous United States is probably incomplete. It is reported sporadically south to Washington, Wyoming, Georgia, and Virginia.

<i>Tetraphis pellucida</i> Species of moss

Tetraphis pellucida, the pellucid four-tooth moss, is one of two species of moss in the acrocarpous genus Tetraphis. Its name refers to its four large peristome teeth found on the sporophyte capsule.

<i>Hypnodendron comosum</i> Species of moss

Hypnodendron comosum, commonly known as palm moss or palm tree moss, is a ground moss which can be divided into two varieties: Hypnodendron comosum var. comosum and Hypnodendron comosum var. sieberi. Both Hypnodendron varieties most commonly grow in damp locations in the temperate and tropical rainforests of New South Wales, Victoria, and Tasmania in southern Australia and in New Zealand.

<span class="mw-page-title-main">Splachnaceae</span> Family of mosses

Splachnaceae is a family of mosses, containing around 70 species in 6 genera. Around half of those species are entomophilous, using insects to disperse their spores, a characteristic found in no other seedless land plants.

<i>Pogonatum urnigerum</i> Species of moss

Pogonatum urnigerum is a species of moss in the family Polytrichaceae, commonly called urn haircap. The name comes from "urna" meaning "urn" and "gerere" meaning "to bear" which is believed to be a reference made towards the plant's wide-mouthed capsule. It can be found on gravelly banks or similar habitats and can be identified by the blue tinge to the overall green colour. The stem of this moss is wine red and it has rhizoids that keep the moss anchored to substrates. It is an acrocarpous moss that grows vertically with an archegonium borne at the top of each fertilized female gametophyte shoot which develops an erect sporophyte.

<i>Climacium dendroides</i> Species of moss

Climacium dendroides, also known as tree climacium moss, belongs in the order Hypnales and family Climaciaceae, in class Bryopsida and subclass Bryidae. It is identified as a "tree moss" due to its distinctive morphological features, and has four species identified across the Northern Hemisphere. The species name "dendroides" describes the tree-like morphology of the plant, and its genus name came from the structure of the perforations of peristome teeth. This plant was identified by Weber and Mohr in 1804. They often have stems that are around 2-10 cm tall and growing in the form of patches, looking like small palm-trees. They have yellow-green branches at the tip of stems. The leaves are around 2.5-3 mm long, with rounder stem leaves and pointier branch leaves. Their sporophytes are only abundant in late winter and early spring, and appears as a red-brown shoot with long stalk and cylindrical capsules.

<i>Polytrichum strictum</i> Species of moss

Polytrichum strictum, commonly known as bog haircap moss or strict haircap, is an evergreen and perennial species of moss native to Sphagnum bogs and other moist habitats in temperate climates. It has a circumboreal distribution, and is also found in South America and Antarctica.

<i>Andreaea rupestris</i> Species of moss

Andreaea rupestris is a species of moss in the class Andreaeopsida, are commonly referred to as the "lantern mosses" due to the appearance of their dehisced sporangia. It is typically found on smooth, acidic, exposed rock in the Northern hemisphere. It exhibits the common features of the genus Andreaea such as being acrocarpous, having dark pigmentation, lacking a seta, and bearing 4 lines of dehiscence in its mature sporangia, but can be further identified upon careful examination of its gametophytic leaves which have an ovate base to a more blunt apex compared to other similar species.

<i>Tortula muralis</i> Species of moss

Tortula muralis, commonly known as wall-screw moss, is a species of moss in the family Pottiaceae. T. muralis is found throughout the world.

<i>Polytrichastrum formosum</i> Species of moss

Polytrichastrum formosum, commonly known as the bank haircap moss, is a species of moss belonging to the family Polytrichaceae.

<i>Andreaea blyttii</i> Species of moss

Andreaea blyttii, also commonly known as Blytt's rock moss, is a moss belonging to the family Andreaeaceae, commonly known as rock moss, granite moss, or lantern moss because of this family's unique sporangium. It is part of the genus Andreaea which is known for forming dark brownish or reddish-black carpets in high elevations. This species was first described by Schimper in 1855.

<i>Dicranoloma billardierei</i> Non-vascular plant

Dicranoloma billardierei is a species of bryophyte in the genus Dicranoloma. This moss is extremely common in wet rainforest habitats. In the field, Dicranoloma billardierei, is often confused with Dicranoloma robustum and Dicranoloma fasciatum. However, the short and obtuse nature of the leaves make this moss normally very distinctive.

References

  1. 1 2 3 4 5 6 7 8 Dragićević, Snežana; Papp, Beáta; Erzberger, Peter (2012-10-01). "Distribution of Buxbaumia viridis (Moug. ex Lam. et DC.) Brid. ex Moug. et Nestl. (Bryophyta) in Montenegro". Acta Botanica Croatica. 71 (2): 365–370. doi: 10.2478/v10184-011-0066-1 . ISSN   0365-0588. S2CID   86528524.
  2. 1 2 3 4 Gawryś, Radosław; Szulc, Adam (2017-09-01). "New location of the moss Buxbaumia viridis in the Białowieża Forest". Forest Research Papers. 78 (3): 248–250. doi: 10.1515/frp-2017-0027 (inactive 2024-09-18). ISSN   2082-8926. S2CID   90291185.{{cite journal}}: CS1 maint: DOI inactive as of September 2024 (link)
  3. 1 2 3 4 Koch, Kerstin; Frahm, Jan-Peter; Pollawatn, Rossarin (2009). "The cuticle of the Buxbaumia viridis sporophyte". Flora - Morphology, Distribution, Functional Ecology of Plants. 204 (1): 34–39. Bibcode:2009FMDFE.204...34K. doi:10.1016/j.flora.2007.11.007. ISSN   0367-2530.
  4. 1 2 3 Holá, Eva; Vrba, Jan; Linhartová, Renata; Novozámská, Eva; Zmrhalová, Magda; Plášek, Vítězslav; Kučera, Jan (2014). "Thirteen years on the hunt for Buxbaumia viridis in the Czech Republic: still on the tip of the iceberg?". Acta Societatis Botanicorum Poloniae. 83 (2): 137–145. doi: 10.5586/asbp.2014.015 . ISSN   2083-9480.
  5. 1 2 3 4 5 6 7 8 9 Wiklund, Karin (2002). "Substratum preference, spore output and temporal variation in sporophyte production of the epixylic mossBuxbaumia viridis". Journal of Bryology. 24 (3): 187–195. Bibcode:2002JBryo..24..187W. doi:10.1179/037366802125001358. ISSN   0373-6687. S2CID   84590916.
  6. 1 2 3 4 5 6 7 8 9 10 Infante, Marta; Heras, Patxi (2018). "Notes on the Herbivory on Buxbaumia viridis Sporophytes in the Pyrenees". Cryptogamie, Bryologie. 39 (2): 185–194. doi:10.7872/cryb/v39.iss2.2018.185. ISSN   1290-0796. S2CID   90391092.
  7. 1 2 3 4 Spitale, D.; Mair, P. (2015-09-02). "Predicting the distribution of a rare species of moss: The case ofBuxbaumia viridis(Bryopsida, Buxbaumiaceae)". Plant Biosystems: 1–11. doi:10.1080/11263504.2015.1056858. ISSN   1126-3504. S2CID   87922984.
  8. 1 2 3 "Buxbaumia viridis in Flora of North America @ efloras.org". www.efloras.org. Retrieved 2020-04-09.
  9. Paciorek, Tomasz (2012). "New locality of moss Buxbaumia viridis (Moug. ex Lam. & DC.) Brid. 'ex' Moug. & Nestl. in relation to its distribution in the Beskid Sądecki range (Western Carpathians, Poland)". Acta Musei Silesiae, Scientiae Naturales. 61 (3): 285–288. doi:10.2478/v10210-012-0030-2 (inactive 2024-09-18).{{cite journal}}: CS1 maint: DOI inactive as of September 2024 (link)