Syntrichia latifolia

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Syntrichia latifolia
Syntrichia latifolia (a, 144721-481013) 4539.JPG
Scientific classification Red Pencil Icon.png
Kingdom: Plantae
Division: Bryophyta
Class: Bryopsida
Subclass: Dicranidae
Order: Pottiales
Family: Pottiaceae
Genus: Syntrichia
Species:
S. latifolia
Binomial name
Syntrichia latifolia
Hübener, 1833
Synonyms [1]
  • Barbula latifolia(Bruch ex Hartm.) Huebener
  • Tortula latifoliaBruch
  • Tortula latifoliaBruch ex Hartm.

Syntrichia latifolia (Bruch ex Hartm.) Huebener, formerly Tortula latifolia Bruch ex Hartm, and commonly known as Water Screw-moss, [2] is a species of moss belonging to the family Pottiaceae. [3] Syntrichia species differ from members of Tortula due to synapomorphic leaf qualities, such as different basal and distal cells, as well as different costal cross sections where Tortula has an abaxial epidermis and Syntrichia lacks one. [4]

Contents

A close up image of S. latifolia shows the varying leaf colour. Syntrichia latifolia (b, 144924-481046) 3213.JPG
A close up image of S. latifolia shows the varying leaf colour.


Distribution and Habitat

It is commonly found in Europe and the Pacific Northwest region of North America. [5] Syntrichia latifolia grows on trees, sidewalks, and concrete.

Gametophytic leaf of S. latifolia. Note the costa and rounded leaf tip. Syntrichia latifolia (a, 144721-481013) 4557.JPG
Gametophytic leaf of S. latifolia. Note the costa and rounded leaf tip.

Physiology

Gametophyte generation (haploid)

Syntrichia latifolia is a small moss. It is a yellowish-green colour, but can also be seen as dull green. The stems can occur as small to large tufts. Stems are found as simple or forked ranging from 1-2 cm but can sometimes be short as 4 mm long. Their epidermal cells are differentiated into 1-3 layers with a central strand present.

The leaves have a costa that is multistratose, while the lamina is unistratose. Syntrichia latifolia (b, 144924-481046) 3324.JPG
The leaves have a costa that is multistratose, while the lamina is unistratose.

Leaves of Syntrichia latifolia are roughly 1.5cm wide and 3cm long. [6] Young leaves are yellowish-green, and tend to become orange or brown with age. When the leaves are wet, they tend to crowd together and twist, and when they are wet they tend to spread out. The leaves are not fragile. The leaves are obvate to spatulate, with broad obtuse and rounded apices. The leaves are identifiable by their costa, which ends a few cells before the tip of the leaf. The costa is multistratose (multiple layers of cells), while the lamina is unistratose (single layer of cells). The costa is generally strong, and ends just below the apex as a hyaline or coloured awn or sometimes excurrent as a short mucro. There is one median layer of large guide cells, one to three layers of smaller adaxial cells, an abaxial stereid band, and sometimes hydroids, but no abaxial epidermis.


Sporophyte generation (diploid)

The sporophytes of S. latifolia are relatively infrequent. When they are present, the seta, sporangium capsule, and operculum are red. [7] Consistent with other members of the Bryopsida class, there are arthrodontous (joint-toothed) peristome teeth found at the tip of the sporangium. The spores of Syntrichia latifolia are papillose. The outer layer of peristome teeth are hygroscopic, and when moist, they close over the tip of the sporangium to keep the spores inside. Spores are dispersed when the outer layer of peristome teeth are dry, to increase chances of successful dispersal through wind.

Reproduction

Gemmae produced on the leaf surface of S. latifolia. Syntrichia latifolia (a, 144721-481013) 4571.JPG
Gemmae produced on the leaf surface of S. latifolia.

Asexual

This plant engages in asexual reproduction through the use of haploid gemmae. The gemmae are produced on the dorsal leaf surface, though sometimes found on the ventral surface as well. [8]

Sexual

Sexual reproduction in this moss occurs through the use of haploid spores. The spores are produced inside the sporangium, and when mature, they are released into the wind.

Life Cycle

Stages of growth of a sporophyte from fertilization in an archegonium. Bryophyta 1.png
Stages of growth of a sporophyte from fertilization in an archegonium.

When a haploid spore or gemmae lands on suitable surface, it will germinate into a haploid gametophytic generation. First it will grow into a protonematal stage, where rhizoids and protonematal filaments develop and anchor to the substratum. Then, leafy gametophytic shoots develop. When the gametophyte is mature, it will either produce antheridia or archegonia, as it is dioicous and thus only produces either female or male structures on one plant. [9]

When a haploid sperm cell produced in an antheridia swims down the neck canal of the archegonia, it will fertilize the haploid egg inside, producing a diploid zygote. The sporophyte generation grows from the diploid zygote. The diploid seta elongates and the diploid sporangium matures at the tip. Inside the sporangium, spores undergo meiosis to become haploid before reaching maturity. When they are ready to be released and the outer peristome teeth are dry, they are dispersed into the wind.


Related Research Articles

Gametophyte 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.

Sporangium Enclosure in which spores are formed

A sporangium is an enclosure in which spores are formed. It can be composed of a single cell or can be multicellular. Virtually all plants, fungi, and many other lineages form sporangia at some point in their life cycle. Sporangia can produce spores by mitosis, but in nearly all land plants and many fungi, sporangia are the site of meiosis and produce genetically distinct haploid spores.

Alternation of generations Reproductive cycle of plants and algae

Alternation of generations is the predominant type of life cycle in plants and algae. It consists of a multicellular haploid sexual phase, the gametophyte, which has a single set of chromosomes alternating with a multicellular diploid asexual phase, the sporophyte which has two sets of chromosomes.

Moss 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.

Bryophyte Terrestrial plants that lack vascular tissue

Bryophytes are a proposed taxonomic division containing three groups of non-vascular land plants (embryophytes): the liverworts, hornworts and mosses. They are characteristically limited in size and prefer moist habitats although they 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'.

Sporophyte Diploid multicellular stage in the life cycle of a plant or alga

A sporophyte is the diploid multicellular stage in the life cycle of a plant or alga. It develops from the zygote produced when a haploid egg cell is fertilized by a haploid sperm and each sporophyte cell therefore has a double set of chromosomes, one set from each parent. All land plants, and most multicellular algae, have life cycles in which a multicellular diploid sporophyte phase alternates with a multicellular haploid gametophyte phase. In the seed plants, the largest groups of which are the gymnosperms and flowering plants (angiosperms), the sporophyte phase is more prominent than the gametophyte, and is the familiar green plant with its roots, stem, leaves and cones or flowers. In flowering plants the gametophytes are very reduced in size, and are represented by the germinated pollen and the embryo sac.

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

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

Lunularia

Lunularia cruciata, the crescent-cup liverwort, is a liverwort of the order Marchantiales, and the only species in the genus Lunularia and family Lunulariaceae. The name, from Latin luna, moon, refers to the moon-shaped gemma cups.

Monoicy is a sexual system in haploid plants where both sperm and eggs are produced on the same gametophyte, in contrast with dioicy, where each gametophyte produces only sperm or eggs but never both. Both monoicous and dioicous gametophytes produce gametes in gametangia by mitosis rather than meiosis, so that sperm and eggs are genetically identical with their parent gametophyte.

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. The resulting clonal plants are genetically identical to the parent plant and each other, unless mutations occur.

<i>Marchantia polymorpha</i> Species of liverwort in the family Marchantiaceae

Marchantia polymorpha is a species of large thalloid liverwort in the class Marchantiopsida. M. polymorpha is highly variable in appearance and contains several subspecies. This species is dioicous, having separate male and female plants. M. polymorpha has a wide distribution and is found worldwide. Common names include common liverwort or umbrella liverwort.

<i>Dawsonia superba</i> Species of moss

Dawsonia superba is a moss in the class Polytrichaceae that is found in Australia, New Guinea, Malaysia and New Zealand. D. superba is the tallest self-supporting moss in the world, reaching heights of 60 cm. It has analogous structures to those in vascular plants that support large size, including hydroid and leptoid cells to conduct water and photosynthate, and lamellae that provide gas chambers for more efficient photosynthesis. D. superba is a member of the class Polytrichopsida, although it has a sporophyte that is unique from other hair-cap mosses.

<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.

Splachnaceae 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>Polyphlebium venosum</i> Species of fern

Polyphlebium venosum, the veined bristle-fern or bristle filmy fern, is a fern in the family Hymenophyllaceae. It is only found in wet forests, mainly growing as an epiphyte on the shady side of the soft tree fern, Dicksonia antartica. It also grows on logs, trunks of trees and rarely on trunks of Cyathea species or on wet rock-faces. It is found in the wetter parts of Eastern Australia and New Zealand. P. venosum has poor long-distance dispersal compared to other ferns due to its short lived spore. Notable features of Polyphlebium venosum include it being one cell layer thick, 5–15 cm in length, having many branching veins and a trumpet shaped indusium.

<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>Ulota</i> Genus of mosses

Ulota is a genus of mosses comprising 69 species with a worldwide distribution, though most species are found in the southern hemisphere.

<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.

References

  1. "Syntrichia latifolia". Global Biodiversity Information Facility . Retrieved 16 August 2021.
  2. "Syntrichia latifolia". British Bryological Society. Retrieved 2022-03-05.
  3. "Syntrichia latifolia Hübener, 1833". www.gbif.org. Retrieved 2022-03-05.
  4. "Syntrichia in Flora of North America @ efloras.org". www.efloras.org. Retrieved 2022-03-05.
  5. "Syntrichia latifolia Hübener, 1833". www.gbif.org. Retrieved 17 February 2021.
  6. "Syntrichia latifolia". British Bryological Society. Retrieved 2022-03-05.
  7. "Tortula latifolia in Global Plants on JSTOR". plants.jstor.org. Retrieved 2022-04-05.
  8. "Tortula latifolia in Global Plants on JSTOR". plants.jstor.org. Retrieved 2022-04-05.
  9. "Tortula latifolia in Global Plants on JSTOR". plants.jstor.org. Retrieved 2022-04-05.