Plant: Difference between revisions
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Later, a phylogeny based on genomes and transcriptomes from 1,153 plant species was proposed<ref name="1000plants">{{cite journal |last1=Leebens-Mack |first1=M. |last2=Barker |first2=M. |last3=Carpenter |first3=E. |last4=Deyholos |first4=M.K. |last5=Gitzendammer |first5=M.A. |last6=Graham |first6=S.W. |last7=Grosse |first7=I. |last8=Li |first8=Zheng |title=One thousand plant transcriptomes and the phylogenomics of green plants |journal=Nature |volume=574 |issue=7780 |year=2019 |pages=679–685 |doi=10.1038/s41586-019-1693-2 |pmid=31645766}}</ref>. The placing of algal groups is supported by phylogenies based on genomes from the Mesostigmatophyceae and Chlorokybophyceae that have since been sequenced<ref name="MvirideGenome1">{{cite journal |last1=Liang |first1=Zhe |display-authors=etal |title=Mesostigma viride Genome and Transcriptome Provide Insights into the Origin and Evolution of Streptophyta |journal=Advanced Science |volume=7 |issue=1 |year=2019 |pages=1901850 |doi=10.1002/advs.201901850}}</ref><ref name="Mv_and_Ca_Genomes">{{cite journal |last1=Wang |first1=Sibo |display-authors=etal |title=Genomes of early-diverging streptophyte algae shed light on plant terrestrialization |journal=Nature Plants |volume=6 |issue=2 |year=2020 |pages=95-106 |doi=10.1038/s41477-019-0560-3}}</ref>. The classification of Bryophyta is supported both by Puttick ''et al.'' 2018<ref name="Puttick2018">{{cite journal |last1=Puttick |first1=Mark |display-authors=etal |title=The Interrelationships of Land Plants and the Nature of the Ancestral Embryophyte |journal=Current Biology |volume=28 |issue=5 |year=2018 |pages=733-745 |doi=10.1016/j.cub.2018.01.063 |pmid=29456145}}</ref> and phylogenies involving the hornwort genomes that have also since been sequenced<ref name="HornwortGenome1">{{cite journal |last1=Zhang |first1=Jian |display-authors=etal |title=The hornwort genome and early land plant evolution |journal=Nature Plants |volume=6 |issue=2 |year=2020 |pages=107–118 |doi=10.1038/s41477-019-0588-4}}</ref><ref name="HornwortGenome2">{{cite journal |last1=Li |first1=Fay Wei |display-authors=etal |title=Anthoceros genomes illuminate the origin of land plants and the unique biology of hornworts |journal=Nature Plants |volume=6 |issue=3 |year=2020 |pages=259-272 |doi=10.1038/s41477-020-0618-2}}</ref>. |
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{{barlabel |size=1 |at=0.1 |label=[[Streptophyte algae grade]]|cladogram= |
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|1=[[Red_algae|Rhodophyta]] |
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|1=[[Glaucophyte|Glaucophyta]] |
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|1=[[Chlorophyta]] |
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|1=[[Prasinococcaceae|Prasinococcales]] |
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|1=[[Mesostigmatophyceae]]|bar1=black |
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|1=[[Chlorokybophyceae]]|bar1=black |
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|2=''[[Spirotaenia]]''|bar2=black |
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|1=[[Klebsormidiophyceae|Klebsormidiales]]|bar1=black |
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|1=''[[Chara_(alga)|Chara]]''|bar1=black |
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|1=[[Coleochaetophyceae|Coleochaetales]]|bar1=black |
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|1=[[Zygnematophyceae]]|bar1=black |
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|label1=[[Bryophyta|Bryophytes]] |
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|1=[[Hornwort|Hornworts]] |
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|1=[[Marchantiophyta|Liverworts]] |
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|2=[[Moss|Mosses]] |
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|1=[[Lycophyte|Lycophytes]] |
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|label2=[[Spermatophyte|Spermatophytes]] |
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=== Embryophytes === |
=== Embryophytes === |
Revision as of 16:10, 5 June 2020
Plants Temporal range:
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Scientific classification | |
Clade: | Diaphoretickes |
Clade: | CAM |
Clade: | Archaeplastida |
Kingdom: | Plantae sensu Copeland, 1956 |
Superdivisions | |
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Synonyms | |
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Plants are mainly multicellular, predominantly photosynthetic eukaryotes of the kingdom Plantae. Historically, plants were treated as one of two kingdoms including all living things that were not animals, and all algae and fungi were treated as plants. However, all current definitions of Plantae exclude the fungi and some algae, as well as the prokaryotes (the archaea and bacteria). By one definition, plants form the clade Viridiplantae (Latin name for "green plants"), a group that includes the flowering plants, conifers and other gymnosperms, ferns and their allies, hornworts, liverworts, mosses and the green algae, but excludes the red and brown algae.
Green plants obtain most of their energy from sunlight via photosynthesis by primary chloroplasts that are derived from endosymbiosis with cyanobacteria. Their chloroplasts contain chlorophylls a and b, which gives them their green color. Some plants are parasitic or mycotrophic and have lost the ability to produce normal amounts of chlorophyll or to photosynthesize. Plants are characterized by sexual reproduction and alternation of generations, although asexual reproduction is also common.
There are about 320,000 species of plants, of which the great majority, some 260–290 thousand, produce seeds.[5] Green plants provide a substantial proportion of the world's molecular oxygen,[6] and are the basis of most of Earth's ecosystems. Plants that produce grain, fruit and vegetables also form basic human foods and have been domesticated for millennia. Plants have many cultural and other uses, as ornaments, building materials, writing material and, in great variety, they have been the source of medicines and psychoactive drugs. The scientific study of plants is known as botany, a branch of biology.
Definition
All living things were traditionally placed into one of two groups, plants and animals. This classification may date from Aristotle (384 BC – 322 BC), who made the distinction between plants, which generally do not move, and animals, which often are mobile to catch their food. Much later, when Linnaeus (1707–1778) created the basis of the modern system of scientific classification, these two groups became the kingdoms Vegetabilia (later Metaphyta or Plantae) and Animalia (also called Metazoa). Since then, it has become clear that the plant kingdom as originally defined included several unrelated groups, and the fungi and several groups of algae were removed to new kingdoms. However, these organisms are still often considered plants, particularly in popular contexts.
The term "plant" generally implies the possession of the following traits: multicellularity, possession of cell walls containing cellulose, and the ability to carry out photosynthesis with primary chloroplasts.[7][8]
Current definitions of Plantae
When the name Plantae or plant is applied to a specific group of organisms or taxon, it usually refers to one of four concepts. From least to most inclusive, these four groupings are:
Name(s) | Scope | Description |
---|---|---|
Land plants, also known as Embryophyta | Plantae sensu strictissimo | Plants in the strictest sense include the liverworts, hornworts, mosses, and vascular plants, as well as fossil plants similar to these surviving groups (e.g., Metaphyta Whittaker, 1969,[9] Plantae Margulis, 1971[10]). |
Green plants, also known as Viridiplantae, Viridiphyta, Chlorobionta or Chloroplastida | Plantae sensu stricto | Plants in a strict sense include the green algae, and land plants that emerged within them, including stoneworts. The relationships between plant groups are still being worked out, and the names given to them vary considerably. The clade Viridiplantae encompasses a group of organisms that have cellulose in their cell walls, possess chlorophylls a and b and have plastids bound by only two membranes that are capable of photosynthesis and of storing starch. This clade is the main subject of this article (e.g., Plantae Copeland, 1956[11]). |
Archaeplastida, also known as Plastida or Primoplantae | Plantae sensu lato | Plants in a broad sense comprise the green plants listed above plus the red algae (Rhodophyta) and the glaucophyte algae (Glaucophyta) that store Floridean starch outside the plastids, in the cytoplasm. This clade includes all of the organisms that eons ago acquired their primary chloroplasts directly by engulfing cyanobacteria (e.g., Plantae Cavalier-Smith, 1981[12]). |
Old definitions of plant (obsolete) | Plantae sensu amplo | Plants in the widest sense refers to older, obsolete classifications that placed diverse algae, fungi or bacteria in Plantae (e.g., Plantae or Vegetabilia Linnaeus,[13] Plantae Haeckel 1866,[14] Metaphyta Haeckel, 1894,[15] Plantae Whittaker, 1969[9]). |
Another way of looking at the relationships between the different groups that have been called "plants" is through a cladogram, which shows their evolutionary relationships. These are not yet completely settled, but one accepted relationship between the three groups described above is shown below[clarification needed].[16][17][18][19][20][21][22] Those which have been called "plants" are in bold (some minor groups have been omitted).
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groups traditionally called green algae |
The way in which the groups of green algae are combined and named varies considerably between authors.
Algae
Algae comprise several different groups of organisms which produce food by photosynthesis and thus have traditionally been included in the plant kingdom. The seaweeds range from large multicellular algae to single-celled organisms and are classified into three groups, the green algae, red algae and brown algae. There is good evidence that the brown algae evolved independently from the others, from non-photosynthetic ancestors that formed endosymbiotic relationships with red algae rather than from cyanobacteria, and they are no longer classified as plants as defined here.[23][24]
The Viridiplantae, the green plants – green algae and land plants – form a clade, a group consisting of all the descendants of a common ancestor. With a few exceptions, the green plants have the following features in common; primary chloroplasts derived from cyanobacteria containing chlorophylls a and b, cell walls containing cellulose, and food stores in the form of starch contained within the plastids. They undergo closed mitosis without centrioles, and typically have mitochondria with flat cristae. The chloroplasts of green plants are surrounded by two membranes, suggesting they originated directly from endosymbiotic cyanobacteria.
Two additional groups, the Rhodophyta (red algae) and Glaucophyta (glaucophyte algae), also have primary chloroplasts that appear to be derived directly from endosymbiotic cyanobacteria, although they differ from Viridiplantae in the pigments which are used in photosynthesis and so are different in colour. These groups also differ from green plants in that the storage polysaccharide is floridean starch and is stored in the cytoplasm rather than in the plastids. They appear to have had a common origin with Viridiplantae and the three groups form the clade Archaeplastida, whose name implies that their chloroplasts were derived from a single ancient endosymbiotic event. This is the broadest modern definition of the term 'plant'.
In contrast, most other algae (e.g. brown algae/diatoms, haptophytes, dinoflagellates, and euglenids) not only have different pigments but also have chloroplasts with three or four surrounding membranes. They are not close relatives of the Archaeplastida, presumably having acquired chloroplasts separately from ingested or symbiotic green and red algae. They are thus not included in even the broadest modern definition of the plant kingdom, although they were in the past.
The green plants or Viridiplantae were traditionally divided into the green algae (including the stoneworts) and the land plants. However, it is now known that the land plants evolved from within a group of green algae, so that the green algae by themselves are a paraphyletic group, i.e. a group that excludes some of the descendants of a common ancestor. Paraphyletic groups are generally avoided in modern classifications, so that in recent treatments the Viridiplantae have been divided into two clades, the Chlorophyta and the Streptophyta (including the land plants and Charophyta).[25][26]
The Chlorophyta (a name that has also been used for all green algae) are the sister group to the Charophytes, from which the land plants evolved. There are about 4,300 species,[27] mainly unicellular or multicellular marine organisms such as the sea lettuce, Ulva.
The other group within the Viridiplantae are the mainly freshwater or terrestrial Streptophyta, which consists of the land plants together with the Charophyta, itself consisting of several groups of green algae such as the desmids and stoneworts. Streptophyte algae are either unicellular or form multicellular filaments, branched or unbranched.[26] The genus Spirogyra is a filamentous streptophyte alga familiar to many, as it is often used in teaching and is one of the organisms responsible for the algal "scum" on ponds. The freshwater stoneworts strongly resemble land plants and are believed to be their closest relatives.[citation needed] Growing immersed in fresh water, they consist of a central stalk with whorls of branchlets.
Fungi
Linnaeus' original classification placed the fungi within the Plantae, since they were unquestionably neither animals or minerals and these were the only other alternatives. With 19th century developments in microbiology, Ernst Haeckel introduced the new kingdom Protista in addition to Plantae and Animalia, but whether fungi were best placed in the Plantae or should be reclassified as protists remained controversial. In 1969, Robert Whittaker proposed the creation of the kingdom Fungi. Molecular evidence has since shown that the most recent common ancestor (concestor), of the Fungi was probably more similar to that of the Animalia than to that of Plantae or any other kingdom.[28]
Whittaker's original reclassification was based on the fundamental difference in nutrition between the Fungi and the Plantae. Unlike plants, which generally gain carbon through photosynthesis, and so are called autotrophs, fungi do not possess chloroplasts and generally obtain carbon by breaking down and absorbing surrounding materials, and so are called heterotrophic saprotrophs. In addition, the substructure of multicellular fungi is different from that of plants, taking the form of many chitinous microscopic strands called hyphae, which may be further subdivided into cells or may form a syncytium containing many eukaryotic nuclei. Fruiting bodies, of which mushrooms are the most familiar example, are the reproductive structures of fungi, and are unlike any structures produced by plants.[citation needed]
Diversity
The table below shows some species count estimates of different green plant (Viridiplantae) divisions. It suggests there are about 300,000 species of living Viridiplantae, of which 85–90% are flowering plants. (Note: as these are from different sources and different dates, they are not necessarily comparable, and like all species counts, are subject to a degree of uncertainty in some cases.)
Informal group | Division name | Common name | No. of living species | Approximate No. in informal group |
---|---|---|---|---|
Green algae | Chlorophyta | green algae (chlorophytes) | 3,800–4,300 [29][30] | 8,500
(6,600–10,300) |
Charophyta | green algae (e.g. desmids & stoneworts) | 2,800–6,000 [31][32] | ||
Bryophytes | Marchantiophyta | liverworts | 6,000–8,000 [33] | 19,000
(18,100–20,200) |
Anthocerotophyta | hornworts | 100–200 [34] | ||
Bryophyta | mosses | 12,000 [35] | ||
Pteridophytes | Lycopodiophyta | club mosses | 1,200 [24] | 12,000
(12,200) |
Pteridophyta | ferns, whisk ferns & horsetails | 11,000 [24] | ||
Seed plants | Cycadophyta | cycads | 160 [36] | 260,000
(259,511) |
Ginkgophyta | ginkgo | 1 [37] | ||
Pinophyta | conifers | 630 [24] | ||
Gnetophyta | gnetophytes | 70 [24] | ||
Magnoliophyta | flowering plants | 258,650 [38] |
The naming of plants is governed by the International Code of Nomenclature for algae, fungi, and plants and International Code of Nomenclature for Cultivated Plants (see cultivated plant taxonomy).
Evolution
The evolution of plants has resulted in increasing levels of complexity, from the earliest algal mats, through bryophytes, lycopods, ferns to the complex gymnosperms and angiosperms of today. Plants in all of these groups continue to thrive, especially in the environments in which they evolved.
An algal scum formed on the land 1,200 million years ago, but it was not until the Ordovician Period, around 450 million years ago, that land plants appeared.[39] However, new evidence from the study of carbon isotope ratios in Precambrian rocks has suggested that complex photosynthetic plants developed on the earth over 1000 m.y.a.[40] For more than a century it has been assumed that the ancestors of land plants evolved in aquatic environments and then adapted to a life on land, an idea usually credited to botanist Frederick Orpen Bower in his 1908 book The Origin of a Land Flora. A recent alternative view, supported by genetic evidence, is that they evolved from terrestrial single-celled algae,[41] and that even the common ancestor of red and green algae, and the unicellular freshwater algae glaucophytes, originated in a terrestrial environment in freshwater biofilms or microbial mats.[42] Primitive land plants began to diversify in the late Silurian Period, around 420 million years ago, and the results of their diversification are displayed in remarkable detail in an early Devonian fossil assemblage from the Rhynie chert. This chert preserved early plants in cellular detail, petrified in volcanic springs. By the middle of the Devonian Period most of the features recognised in plants today are present, including roots, leaves and secondary wood, and by late Devonian times seeds had evolved.[43] Late Devonian plants had thereby reached a degree of sophistication that allowed them to form forests of tall trees. Evolutionary innovation continued in the Carboniferous and later geological periods and is ongoing today. Most plant groups were relatively unscathed by the Permo-Triassic extinction event, although the structures of communities changed. This may have set the scene for the evolution of flowering plants in the Triassic (~200 million years ago), which exploded in the Cretaceous and Tertiary. The latest major group of plants to evolve were the grasses, which became important in the mid Tertiary, from around 40 million years ago. The grasses, as well as many other groups, evolved new mechanisms of metabolism to survive the low CO2 and warm, dry conditions of the tropics over the last 10 million years.
A 1997 proposed phylogenetic tree of Plantae, after Kenrick and Crane,[44] is as follows, with modification to the Pteridophyta from Smith et al.[45] The Prasinophyceae are a paraphyletic assemblage of early diverging green algal lineages, but are treated as a group outside the Chlorophyta:[46] later authors have not followed this suggestion.
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A newer proposed classification follows Leliaert et al. 2011[47] and modified with Silar 2016[20][21][48][49] for the green algae clades and Novíkov & Barabaš-Krasni 2015[50] for the land plants clade. Notice that the Prasinophyceae are here placed inside the Chlorophyta.
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Later, a phylogeny based on genomes and transcriptomes from 1,153 plant species was proposed[51]. The placing of algal groups is supported by phylogenies based on genomes from the Mesostigmatophyceae and Chlorokybophyceae that have since been sequenced[52][53]. The classification of Bryophyta is supported both by Puttick et al. 2018[54] and phylogenies involving the hornwort genomes that have also since been sequenced[55][56].
Embryophytes
The plants that are likely most familiar to us are the multicellular land plants, called embryophytes. Embryophytes include the vascular plants, such as ferns, conifers and flowering plants. They also include the bryophytes, of which mosses and liverworts are the most common.
All of these plants have eukaryotic cells with cell walls composed of cellulose, and most obtain their energy through photosynthesis, using light, water and carbon dioxide to synthesize food. About three hundred plant species do not photosynthesize but are parasites on other species of photosynthetic plants. Embryophytes are distinguished from green algae, which represent a mode of photosynthetic life similar to the kind modern plants are believed to have evolved from, by having specialized reproductive organs protected by non-reproductive tissues.
Bryophytes first appeared during the early Paleozoic. They mainly live in habitats where moisture is available for significant periods, although some species, such as Targionia, are desiccation-tolerant. Most species of bryophytes remain small throughout their life-cycle. This involves an alternation between two generations: a haploid stage, called the gametophyte, and a diploid stage, called the sporophyte. In bryophytes, the sporophyte is always unbranched and remains nutritionally dependent on its parent gametophyte. The embryophytes have the ability to secrete a cuticle on their outer surface, a waxy layer that confers resistant to desiccation. In the mosses and hornworts a cuticle is usually only produced on the sporophyte. Stomata are absent from liverworts, but occur on the sporangia of mosses and hornworts, allowing gas exchange.
Vascular plants first appeared during the Silurian period, and by the Devonian had diversified and spread into many different terrestrial environments. They developed a number of adaptations that allowed them to spread into increasingly more arid places, notably the vascular tissues xylem and phloem, that transport water and food throughout the organism. Root systems capable of obtaining soil water and nutrients also evolved during the Devonian. In modern vascular plants, the sporophyte is typically large, branched, nutritionally independent and long-lived, but there is increasing evidence that Paleozoic gametophytes were just as complex as the sporophytes. The gametophytes of all vascular plant groups evolved to become reduced in size and prominence in the life cycle.
In seed plants, the microgametophyte is reduced from a multicellular free-living organism to a few cells in a pollen grain and the miniaturised megagametophyte remains inside the megasporangium, attached to and dependent on the parent plant. A megasporangium enclosed in a protective layer called an integument is known as an ovule. After fertilisation by means of sperm produced by pollen grains, an embryo sporophyte develops inside the ovule. The integument becomes a seed coat, and the ovule develops into a seed. Seed plants can survive and reproduce in extremely arid conditions, because they are not dependent on free water for the movement of sperm, or the development of free living gametophytes.
The first seed plants, pteridosperms (seed ferns), now extinct, appeared in the Devonian and diversified through the Carboniferous. They were the ancestors of modern gymnosperms, of which four surviving groups are widespread today, particularly the conifers, which are dominant trees in several biomes. The name gymnosperm comes from the Greek composite word γυμνόσπερμος (γυμνός gymnos, "naked" and σπέρμα sperma, "seed"), as the ovules and subsequent seeds are not enclosed in a protective structure (carpels or fruit), but are borne naked, typically on cone scales.
Fossils
This section needs additional citations for verification. (November 2018) |
Plant fossils include roots, wood, leaves, seeds, fruit, pollen, spores, phytoliths, and amber (the fossilized resin produced by some plants). Fossil land plants are recorded in terrestrial, lacustrine, fluvial and nearshore marine sediments. Pollen, spores and algae (dinoflagellates and acritarchs) are used for dating sedimentary rock sequences. The remains of fossil plants are not as common as fossil animals, although plant fossils are locally abundant in many regions worldwide.
The earliest fossils clearly assignable to Kingdom Plantae are fossil green algae from the Cambrian. These fossils resemble calcified multicellular members of the Dasycladales. Earlier Precambrian fossils are known that resemble single-cell green algae, but definitive identity with that group of algae is uncertain.
The earliest fossils attributed to green algae date from the Precambrian (ca. 1200 mya).[57][58] The resistant outer walls of prasinophyte cysts (known as phycomata) are well preserved in fossil deposits of the Paleozoic (ca. 250–540 mya). A filamentous fossil (Proterocladus) from middle Neoproterozoic deposits (ca. 750 mya) has been attributed to the Cladophorales, while the oldest reliable records of the Bryopsidales, Dasycladales) and stoneworts are from the Paleozoic.[46][59]
The oldest known fossils of embryophytes date from the Ordovician, though such fossils are fragmentary. By the Silurian, fossils of whole plants are preserved, including the simple vascular plant Cooksonia in mid-Silurian and the much larger and more complex lycophyte Baragwanathia longifolia in late Silurian. From the early Devonian Rhynie chert, detailed fossils of lycophytes and rhyniophytes have been found that show details of the individual cells within the plant organs and the symbiotic association of these plants with fungi of the order Glomales. The Devonian period also saw the evolution of leaves and roots, and the first modern tree, Archaeopteris. This tree with fern-like foliage and a trunk with conifer-like wood was heterosporous producing spores of two different sizes, an early step in the evolution of seeds.[60]
The Coal measures are a major source of Paleozoic plant fossils, with many groups of plants in existence at this time. The spoil heaps of coal mines are the best places to collect; coal itself is the remains of fossilised plants, though structural detail of the plant fossils is rarely visible in coal. In the Fossil Grove at Victoria Park in Glasgow, Scotland, the stumps of Lepidodendron trees are found in their original growth positions.
The fossilized remains of conifer and angiosperm roots, stems and branches may be locally abundant in lake and inshore sedimentary rocks from the Mesozoic and Cenozoic eras. Sequoia and its allies, magnolia, oak, and palms are often found.
Petrified wood is common in some parts of the world, and is most frequently found in arid or desert areas where it is more readily exposed by erosion. Petrified wood is often heavily silicified (the organic material replaced by silicon dioxide), and the impregnated tissue is often preserved in fine detail. Such specimens may be cut and polished using lapidary equipment. Fossil forests of petrified wood have been found in all continents.
Fossils of seed ferns such as Glossopteris are widely distributed throughout several continents of the Southern Hemisphere, a fact that gave support to Alfred Wegener's early ideas regarding Continental drift theory.
Structure, growth and development
Most of the solid material in a plant is taken from the atmosphere. Through the process of photosynthesis, most plants use the energy in sunlight to convert carbon dioxide from the atmosphere, plus water, into simple sugars. These sugars are then used as building blocks and form the main structural component of the plant. Chlorophyll, a green-colored, magnesium-containing pigment is essential to this process; it is generally present in plant leaves, and often in other plant parts as well. Parasitic plants, on the other hand, use the resources of their host to provide the materials needed for metabolism and growth.
Plants usually rely on soil primarily for support and water (in quantitative terms), but they also obtain compounds of nitrogen, phosphorus, potassium, magnesium and other elemental nutrients from the soil. Epiphytic and lithophytic plants depend on air and nearby debris for nutrients, and carnivorous plants supplement their nutrient requirements, particularly for nitrogen and phosphorus, with insect prey that they capture. For the majority of plants to grow successfully they also require oxygen in the atmosphere and around their roots (soil gas) for respiration. Plants use oxygen and glucose (which may be produced from stored starch) to provide energy.[61] Some plants grow as submerged aquatics, using oxygen dissolved in the surrounding water, and a few specialized vascular plants, such as mangroves and reed (Phragmites australis),[62] can grow with their roots in anoxic conditions.
Factors affecting growth
The genome of a plant controls its growth. For example, selected varieties or genotypes of wheat grow rapidly, maturing within 110 days, whereas others, in the same environmental conditions, grow more slowly and mature within 155 days.[63]
Growth is also determined by environmental factors, such as temperature, available water, available light, carbon dioxide and available nutrients in the soil. Any change in the availability of these external conditions will be reflected in the plant's growth and the timing of its development.[citation needed]
Biotic factors also affect plant growth. Plants can be so crowded that no single individual produces normal growth, causing etiolation and chlorosis. Optimal plant growth can be hampered by grazing animals, suboptimal soil composition, lack of mycorrhizal fungi, and attacks by insects or plant diseases, including those caused by bacteria, fungi, viruses, and nematodes.[63]
Simple plants like algae may have short life spans as individuals, but their populations are commonly seasonal. Annual plants grow and reproduce within one growing season, biennial plants grow for two growing seasons and usually reproduce in second year, and perennial plants live for many growing seasons and once mature will often reproduce annually. These designations often depend on climate and other environmental factors. Plants that are annual in alpine or temperate regions can be biennial or perennial in warmer climates. Among the vascular plants, perennials include both evergreens that keep their leaves the entire year, and deciduous plants that lose their leaves for some part of it. In temperate and boreal climates, they generally lose their leaves during the winter; many tropical plants lose their leaves during the dry season.[citation needed]
The growth rate of plants is extremely variable. Some mosses grow less than 0.001 millimeters per hour (mm/h), while most trees grow 0.025-0.250 mm/h. Some climbing species, such as kudzu, which do not need to produce thick supportive tissue, may grow up to 12.5 mm/h.[citation needed]
Plants protect themselves from frost and dehydration stress with antifreeze proteins, heat-shock proteins and sugars (sucrose is common). LEA (Late Embryogenesis Abundant) protein expression is induced by stresses and protects other proteins from aggregation as a result of desiccation and freezing.[64]
Effects of freezing
When water freezes in plants, the consequences for the plant depend very much on whether the freezing occurs within cells (intracellularly) or outside cells in intercellular spaces.[65] Intracellular freezing, which usually kills the cell[66] regardless of the hardiness of the plant and its tissues, seldom occurs in nature because rates of cooling are rarely high enough to support it. Rates of cooling of several degrees Celsius per minute are typically needed to cause intracellular formation of ice.[67] At rates of cooling of a few degrees Celsius per hour, segregation of ice occurs in intercellular spaces.[68] This may or may not be lethal, depending on the hardiness of the tissue. At freezing temperatures, water in the intercellular spaces of plant tissue freezes first, though the water may remain unfrozen until temperatures drop below −7 °C (19 °F).[65] After the initial formation of intercellular ice, the cells shrink as water is lost to the segregated ice, and the cells undergo freeze-drying. This dehydration is now considered the fundamental cause of freezing injury.
DNA damage and repair
Plants are continuously exposed to a range of biotic and abiotic stresses. These stresses often cause DNA damage directly, or indirectly via the generation of reactive oxygen species.[69] Plants are capable of a DNA damage response that is a critical mechanism for maintaining genome stability.[70] The DNA damage response is particularly important during seed germination, since seed quality tends to deteriorate with age in association with DNA damage accumulation.[71] During germination repair processes are activated to deal with this accumulated DNA damage.[72] In particular, single- and double-strand breaks in DNA can be repaired.[73] The DNA checkpoint kinase ATM has a key role in integrating progression through germination with repair responses to the DNA damages accumulated by the aged seed.[74]
Plant cells
Plant cells are typically distinguished by their large water-filled central vacuole, chloroplasts, and rigid cell walls that are made up of cellulose, hemicellulose, and pectin. Cell division is also characterized by the development of a phragmoplast for the construction of a cell plate in the late stages of cytokinesis. Just as in animals, plant cells differentiate and develop into multiple cell types. Totipotent meristematic cells can differentiate into vascular, storage, protective (e.g. epidermal layer), or reproductive tissues, with more primitive plants lacking some tissue types.[75]
Physiology
Photosynthesis
Plants are photosynthetic, which means that they manufacture their own food molecules using energy obtained from light. The primary mechanism plants have for capturing light energy is the pigment chlorophyll. All green plants contain two forms of chlorophyll, chlorophyll a and chlorophyll b. The latter of these pigments is not found in red or brown algae. The simple equation of photosynthesis is as follows:
Immune system
By means of cells that behave like nerves, plants receive and distribute within their systems information about incident light intensity and quality. Incident light that stimulates a chemical reaction in one leaf, will cause a chain reaction of signals to the entire plant via a type of cell termed a bundle sheath cell. Researchers, from the Warsaw University of Life Sciences in Poland, found that plants have a specific memory for varying light conditions, which prepares their immune systems against seasonal pathogens.[76] Plants use pattern-recognition receptors to recognize conserved microbial signatures. This recognition triggers an immune response. The first plant receptors of conserved microbial signatures were identified in rice (XA21, 1995)[77] and in Arabidopsis thaliana (FLS2, 2000).[78] Plants also carry immune receptors that recognize highly variable pathogen effectors. These include the NBS-LRR class of proteins.
Internal distribution
Vascular plants differ from other plants in that nutrients are transported between their different parts through specialized structures, called xylem and phloem. They also have roots for taking up water and minerals. The xylem moves water and minerals from the root to the rest of the plant, and the phloem provides the roots with sugars and other nutrient produced by the leaves.[75]
Genomics
Plants have some of the largest genomes among all organisms.[79] The largest plant genome (in terms of gene number) is that of wheat (Triticum asestivum), predicted to encode ≈94,000 genes[80] and thus almost 5 times as many as the human genome. The first plant genome sequenced was that of Arabidopsis thaliana which encodes about 25,500 genes.[81] In terms of sheer DNA sequence, the smallest published genome is that of the carnivorous bladderwort (Utricularia gibba) at 82 Mb (although it still encodes 28,500 genes)[82] while the largest, from the Norway Spruce (Picea abies), extends over 19,600 Mb (encoding about 28,300 genes).[83]
Ecology
The photosynthesis conducted by land plants and algae is the ultimate source of energy and organic material in nearly all ecosystems. Photosynthesis, at first by cyanobacteria and later by photosynthetic eukaryotes, radically changed the composition of the early Earth's anoxic atmosphere, which as a result is now 21% oxygen. Animals and most other organisms are aerobic, relying on oxygen; those that do not are confined to relatively rare anaerobic environments. Plants are the primary producers in most terrestrial ecosystems and form the basis of the food web in those ecosystems. Many animals rely on plants for shelter as well as oxygen and food.[citation needed]
Land plants are key components of the water cycle and several other biogeochemical cycles. Some plants have coevolved with nitrogen fixing bacteria, making plants an important part of the nitrogen cycle. Plant roots play an essential role in soil development and the prevention of soil erosion.[citation needed]
Distribution
Plants are distributed almost worldwide. While they inhabit a multitude of biomes and ecoregions, few can be found beyond the tundras at the northernmost regions of continental shelves. At the southern extremes, plants of the Antarctic flora have adapted tenaciously to the prevailing conditions.[citation needed]
Plants are often the dominant physical and structural component of habitats where they occur. Many of the Earth's biomes are named for the type of vegetation because plants are the dominant organisms in those biomes, such as grasslands, taiga and tropical rainforest.[citation needed]
Ecological relationships
This section needs additional citations for verification. (November 2018) |
Numerous animals have coevolved with plants. Many animals pollinate flowers in exchange for food in the form of pollen or nectar. Many animals disperse seeds, often by eating fruit and passing the seeds in their feces. Myrmecophytes are plants that have coevolved with ants. The plant provides a home, and sometimes food, for the ants. In exchange, the ants defend the plant from herbivores and sometimes competing plants. Ant wastes provide organic fertilizer.
The majority of plant species have various kinds of fungi associated with their root systems in a kind of mutualistic symbiosis known as mycorrhiza. The fungi help the plants gain water and mineral nutrients from the soil, while the plant gives the fungi carbohydrates manufactured in photosynthesis. Some plants serve as homes for endophytic fungi that protect the plant from herbivores by producing toxins. The fungal endophyte, Neotyphodium coenophialum, in tall fescue (Festuca arundinacea) does tremendous economic damage to the cattle industry in the U.S.
Various forms of parasitism are also fairly common among plants, from the semi-parasitic mistletoe that merely takes some nutrients from its host, but still has photosynthetic leaves, to the fully parasitic broomrape and toothwort that acquire all their nutrients through connections to the roots of other plants, and so have no chlorophyll. Some plants, known as myco-heterotrophs, parasitize mycorrhizal fungi, and hence act as epiparasites on other plants.
Many plants are epiphytes, meaning they grow on other plants, usually trees, without parasitizing them. Epiphytes may indirectly harm their host plant by intercepting mineral nutrients and light that the host would otherwise receive. The weight of large numbers of epiphytes may break tree limbs. Hemiepiphytes like the strangler fig begin as epiphytes but eventually set their own roots and overpower and kill their host. Many orchids, bromeliads, ferns and mosses often grow as epiphytes. Bromeliad epiphytes accumulate water in leaf axils to form phytotelmata that may contain complex aquatic food webs.[84]
Approximately 630 plants are carnivorous, such as the Venus Flytrap (Dionaea muscipula) and sundew (Drosera species). They trap small animals and digest them to obtain mineral nutrients, especially nitrogen and phosphorus.[85]
Importance
The study of plant uses by people is called economic botany or ethnobotany.[86] Human cultivation of plants is part of agriculture, which is the basis of human civilization.[87] Plant agriculture is subdivided into agronomy, horticulture and forestry.[88]
Food
Humans depend on plants for food, either directly or as feed for domestic animals. Agriculture deals with the production of food crops, and has played a key role in the history of world civilizations. Agriculture includes agronomy for arable crops, horticulture for vegetables and fruit, and forestry for timber.[89] About 7,000 species of plant have been used for food, though most of today's food is derived from only 30 species. The major staples include cereals such as rice and wheat, starchy roots and tubers such as cassava and potato, and legumes such as peas and beans. Vegetable oils such as olive oil provide lipids, while fruit and vegetables contribute vitamins and minerals to the diet.[90]
Medicines
Medicinal plants are a primary source of organic compounds, both for their medicinal and physiological effects, and for the industrial synthesis of a vast array of organic chemicals.[91] Many hundreds of medicines are derived from plants, both traditional medicines used in herbalism[92][93] and chemical substances purified from plants or first identified in them, sometimes by ethnobotanical search, and then synthesised for use in modern medicine. Modern medicines derived from plants include aspirin, taxol, morphine, quinine, reserpine, colchicine, digitalis and vincristine. Plants used in herbalism include ginkgo, echinacea, feverfew, and Saint John's wort. The pharmacopoeia of Dioscorides, De Materia Medica, describing some 600 medicinal plants, was written between 50 and 70 AD and remained in use in Europe and the Middle East until around 1600 AD; it was the precursor of all modern pharmacopoeias.[94][95][96]
Nonfood products
Plants grown as industrial crops are the source of a wide range of products used in manufacturing, sometimes so intensively as to risk harm to the environment.[97] Nonfood products include essential oils, natural dyes, pigments, waxes, resins, tannins, alkaloids, amber and cork. Products derived from plants include soaps, shampoos, perfumes, cosmetics, paint, varnish, turpentine, rubber, latex, lubricants, linoleum, plastics, inks, and gums. Renewable fuels from plants include firewood, peat and other biofuels.[98][99] The fossil fuels coal, petroleum and natural gas are derived from the remains of aquatic organisms including phytoplankton in geological time.[100]
Structural resources and fibres from plants are used to construct dwellings and to manufacture clothing. Wood is used not only for buildings, boats, and furniture, but also for smaller items such as musical instruments and sports equipment. Wood is pulped to make paper and cardboard.[101] Cloth is often made from cotton, flax, ramie or synthetic fibres such as rayon and acetate derived from plant cellulose. Thread used to sew cloth likewise comes in large part from cotton.[102]
Aesthetic uses
Thousands of plant species are cultivated for aesthetic purposes as well as to provide shade, modify temperatures, reduce wind, abate noise, provide privacy, and prevent soil erosion. Plants are the basis of a multibillion-dollar per year tourism industry, which includes travel to historic gardens, national parks, rainforests, forests with colorful autumn leaves, and festivals such as Japan's[103] and America's cherry blossom festivals.[104]
While some gardens are planted with food crops, many are planted for aesthetic, ornamental, or conservation purposes. Arboretums and botanical gardens are public collections of living plants. In private outdoor gardens, lawn grasses, shade trees, ornamental trees, shrubs, vines, herbaceous perennials and bedding plants are used. Gardens may cultivate the plants in a naturalistic state, or may sculpture their growth, as with topiary or espalier. Gardening is the most popular leisure activity in the U.S., and working with plants or horticulture therapy is beneficial for rehabilitating people with disabilities.[citation needed]
Plants may also be grown or kept indoors as houseplants, or in specialized buildings such as greenhouses that are designed for the care and cultivation of living plants. Venus Flytrap, sensitive plant and resurrection plant are examples of plants sold as novelties. There are also art forms specializing in the arrangement of cut or living plant, such as bonsai, ikebana, and the arrangement of cut or dried flowers. Ornamental plants have sometimes changed the course of history, as in tulipomania.[105]
Architectural designs resembling plants appear in the capitals of Ancient Egyptian columns, which were carved to resemble either the Egyptian white lotus or the papyrus.[106] Images of plants are often used in painting and photography, as well as on textiles, money, stamps, flags and coats of arms.[citation needed]
Scientific and cultural uses
Basic biological research has often been done with plants. In genetics, the breeding of pea plants allowed Gregor Mendel to derive the basic laws governing inheritance,[107] and examination of chromosomes in maize allowed Barbara McClintock to demonstrate their connection to inherited traits.[108] The plant Arabidopsis thaliana is used in laboratories as a model organism to understand how genes control the growth and development of plant structures.[109] NASA predicts that space stations or space colonies will one day rely on plants for life support.[110]
Ancient trees are revered and many are famous. Tree rings themselves are an important method of dating in archeology, and serve as a record of past climates.[citation needed]
Plants figure prominently in mythology, religion and literature. They are used as national and state emblems, including state trees and state flowers. Plants are often used as memorials, gifts and to mark special occasions such as births, deaths, weddings and holidays. The arrangement of flowers may be used to send hidden messages.[citation needed]
Negative effects
Weeds are unwanted plants growing in managed environments such as farms, urban areas, gardens, lawns, and parks. People have spread plants beyond their native ranges and some of these introduced plants become invasive, damaging existing ecosystems by displacing native species, and sometimes becoming serious weeds of cultivation.[citation needed]
Plants may cause harm to animals, including people. Plants that produce windblown pollen invoke allergic reactions in people who suffer from hay fever. A wide variety of plants are poisonous. Toxalbumins are plant poisons fatal to most mammals and act as a serious deterrent to consumption. Several plants cause skin irritations when touched, such as poison ivy. Certain plants contain psychotropic chemicals, which are extracted and ingested or smoked, including nicotine from tobacco, cannabinoids from Cannabis sativa, cocaine from Erythroxylon coca and opium from opium poppy. Smoking causes damage to health or even death, while some drugs may also be harmful or fatal to people.[111][112] Both illegal and legal drugs derived from plants may have negative effects on the economy, affecting worker productivity and law enforcement costs.[113][114]
See also
References
- ^ Cavalier-Smith, T. (1981). "Eukaryote kingdoms: Seven or nine?". BioSystems. 14 (3–4): 461–481. doi:10.1016/0303-2647(81)90050-2. PMID 7337818.
- ^ Lewis, L.A.; McCourt, R.M. (2004). "Green algae and the origin of land plants". American Journal of Botany. 91 (10): 1535–1556. doi:10.3732/ajb.91.10.1535. PMID 21652308.
- ^ Kenrick, Paul; Crane, Peter R. (1997). The origin and early diversification of land plants: A cladistic study. Washington, D.C.: Smithsonian Institution Press. ISBN 978-1-56098-730-7.
- ^ "The new higher level classification of eukaryotes with emphasis on the taxonomy of protists". Journal of Eukaryote Microbiology. 52 (5): 399–451. 2005. doi:10.1111/j.1550-7408.2005.00053.x. PMID 16248873.
{{cite journal}}
: Unknown parameter|authors=
ignored (help) - ^ "Numbers of threatened species by major groups of organisms (1996–2010)" (PDF). International Union for Conservation of Nature. 11 March 2010. Archived (PDF) from the original on 21 July 2011. Retrieved 27 April 2011.
- ^ Field, C.B.; Behrenfeld, M.J.; Randerson, J.T.; Falkowski, P. (1998). "Primary production of the biosphere: Integrating terrestrial and oceanic components". Science. 281 (5374): 237–240. Bibcode:1998Sci...281..237F. doi:10.1126/science.281.5374.237. PMID 9657713. Archived from the original on 25 September 2018. Retrieved 10 September 2018.
- ^ "plant[2] – Definition from the Merriam-Webster Online Dictionary". Archived from the original on 19 September 2011. Retrieved 25 March 2009.
- ^ "plant (life form) -- Britannica Online Encyclopedia". Archived from the original on 13 March 2009. Retrieved 25 March 2009.
- ^ a b Whittaker, R.H. (1969). "New concepts of kingdoms or organisms" (PDF). Science. 163 (3863): 150–160. Bibcode:1969Sci...163..150W. CiteSeerX 10.1.1.403.5430. doi:10.1126/science.163.3863.150. PMID 5762760. Archived from the original (PDF) on 17 November 2017. Retrieved 4 November 2014.
- ^ Margulis, L (1971). "Whittaker's five kingdoms of organisms: minor revisions suggested by considerations of the origin of mitosis". Evolution. 25 (1): 242–245. doi:10.2307/2406516. JSTOR 2406516. PMID 28562945.
- ^ Copeland, H.F. (1956). The Classification of Lower Organisms. Palo Alto: Pacific Books, p. 6, [1] Archived 14 October 2014 at the Wayback Machine.
- ^ Cavalier-Smith, T. (1981). "Eukaryote Kingdoms: Seven or Nine?". BioSystems. 14 (3–4): 461–481. doi:10.1016/0303-2647(81)90050-2. PMID 7337818.
- ^ Linnaeus, C. (1751). Philosophia botanica Archived 23 June 2016 at the Wayback Machine, 1st ed., p. 37.
- ^ Haeckel, E. (1866). Generale Morphologie der Organismen. Berlin: Verlag von Georg Reimer. pp. vol. 1: i–xxxii, 1–574, pls I–II, vol. 2: i–clx, 1–462, pls I–VIII.
- ^ Haeckel, E. (1894). Die systematische Phylogenie Archived 27 April 2016 at the Wayback Machine.
- ^ Based on Rogozin, I.B.; Basu, M.K.; Csürös, M.; Koonin, E.V. (2009), "Analysis of Rare Genomic Changes Does Not Support the Unikont–Bikont Phylogeny and Suggests Cyanobacterial Symbiosis as the Point of Primary Radiation of Eukaryotes", Genome Biology and Evolution, 1: 99–113, doi:10.1093/gbe/evp011, PMC 2817406, PMID 20333181
{{citation}}
: Unknown parameter|lastauthoramp=
ignored (|name-list-style=
suggested) (help) and Becker, B.; Marin, B. (2009), "Streptophyte algae and the origin of embryophytes", Annals of Botany, 103 (7): 999–1004, doi:10.1093/aob/mcp044, PMC 2707909, PMID 19273476{{citation}}
: Unknown parameter|lastauthoramp=
ignored (|name-list-style=
suggested) (help); see also the slightly different cladogram in Lewis, Louise A.; McCourt, R.M. (2004), "Green algae and the origin of land plants", Am. J. Bot., 91 (10): 1535–1556, doi:10.3732/ajb.91.10.1535, PMID 21652308{{citation}}
: Unknown parameter|lastauthoramp=
ignored (|name-list-style=
suggested) (help) - ^ Parfrey, Laura Wegener; Lahr, Daniel J.G.; Knoll, Andrew H.; Katz, Laura A. (16 August 2011). "Estimating the timing of early eukaryotic diversification with multigene molecular clocks". Proceedings of the National Academy of Sciences. 108 (33): 13624–13629. Bibcode:2011PNAS..10813624P. doi:10.1073/pnas.1110633108. PMC 3158185. PMID 21810989.
- ^ Derelle, Romain; Torruella, Guifré; Klimeš, Vladimír; Brinkmann, Henner; Kim, Eunsoo; Vlček, Čestmír; Lang, B. Franz; Eliáš, Marek (17 February 2015). "Bacterial proteins pinpoint a single eukaryotic root". Proceedings of the National Academy of Sciences. 112 (7): E693–E699. Bibcode:2015PNAS..112E.693D. doi:10.1073/pnas.1420657112. PMC 4343179. PMID 25646484.
- ^ Jackson, Christopher; Clayden, Susan; Reyes-Prieto, Adrian (1 January 2015). "The Glaucophyta: the blue-green plants in a nutshell". Acta Societatis Botanicorum Poloniae. 84 (2): 149–165. doi:10.5586/asbp.2015.020.
- ^ a b Sánchez-Baracaldo, Patricia; Raven, John A.; Pisani, Davide; Knoll, Andrew H. (12 September 2017). "Early photosynthetic eukaryotes inhabited low-salinity habitats". Proceedings of the National Academy of Sciences. 114 (37): E7737–E7745. doi:10.1073/pnas.1620089114. PMC 5603991. PMID 28808007.
- ^ a b Gitzendanner, Matthew A.; Soltis, Pamela S.; Wong, Gane K.-S.; Ruhfel, Brad R.; Soltis, Douglas E. (2018). "Plastid phylogenomic analysis of green plants: A billion years of evolutionary history". American Journal of Botany. 105 (3): 291–301. doi:10.1002/ajb2.1048. PMID 29603143.
- ^ Gawryluk, Ryan M. R.; Tikhonenkov, Denis V.; Hehenberger, Elisabeth; Husnik, Filip; Mylnikov, Alexander P.; Keeling, Patrick J. (8 August 2019). "Non-photosynthetic predators are sister to red algae". Nature. 572 (7768): 240–243. doi:10.1038/s41586-019-1398-6. ISSN 1476-4687. PMID 31316212.
- ^ Margulis, L. (1974). Five-kingdom classification and the origin and evolution of cells. Vol. 7. pp. 45–78. doi:10.1007/978-1-4615-6944-2_2. ISBN 978-1-4615-6946-6.
{{cite book}}
:|journal=
ignored (help) - ^ a b c d e Raven, Peter H.; Evert, Ray F.; Eichhorn, Susan E. (2005). Biology of Plants (7th ed.). New York: W.H. Freeman and Company. ISBN 978-0-7167-1007-3.
- ^ Lewis, Louise A.; McCourt, R.M. (2004), "Green algae and the origin of land plants", Am. J. Bot., 91 (10): 1535–1556, doi:10.3732/ajb.91.10.1535, PMID 21652308
{{citation}}
: Unknown parameter|lastauthoramp=
ignored (|name-list-style=
suggested) (help) - ^ a b Becker, B.; Marin, B. (2009), "Streptophyte algae and the origin of embryophytes", Annals of Botany, 103 (7): 999–1004, doi:10.1093/aob/mcp044, PMC 2707909, PMID 19273476
{{citation}}
: Unknown parameter|lastauthoramp=
ignored (|name-list-style=
suggested) (help) - ^ Guiry, M.D.; Guiry, G.M. (2007). "Phylum: Chlorophyta taxonomy browser". AlgaeBase version 4.2 World-wide electronic publication, National University of Ireland, Galway. Archived from the original on 18 June 2009. Retrieved 23 September 2007.
- ^ Deacon, J.W. (2005). Fungal Biology. Wiley. ISBN 978-1-4051-3066-0. Archived from the original on 3 June 2016. Retrieved 8 January 2016.
- ^ Van den Hoek, C.; Mann, D.G.; & Jahns, H.M. 1995. Algae: An Introduction to Phycology. pp. 343, 350, 392, 413, 425, 439, & 448 (Cambridge: Cambridge University Press). ISBN 0-521-30419-9
- ^ Guiry, M.D.; Guiry, G.M. (2011), AlgaeBase : Chlorophyta, World-wide electronic publication, National University of Ireland, Galway, archived from the original on 13 September 2019, retrieved 26 July 2011
{{citation}}
: Unknown parameter|lastauthoramp=
ignored (|name-list-style=
suggested) (help) - ^ Guiry, M.D.; Guiry, G.M. (2011), AlgaeBase : Charophyta, World-wide electronic publication, National University of Ireland, Galway, archived from the original on 13 September 2019, retrieved 26 July 2011
{{citation}}
: Unknown parameter|lastauthoramp=
ignored (|name-list-style=
suggested) (help) - ^ Van den Hoek, C.; Mann, D.G.; & Jahns, H.M. 1995. Algae: An Introduction to Phycology. pp. 457, 463, & 476. (Cambridge: Cambridge University Press). ISBN 0-521-30419-9
- ^ Crandall-Stotler, Barbara & Stotler, Raymond E., 2000. "Morphology and classification of the Marchantiophyta". p. 21 in A. Jonathan Shaw & Bernard Goffinet (Eds.), Bryophyte Biology. (Cambridge: Cambridge University Press). ISBN 0-521-66097-1
- ^ Schuster, Rudolf M., The Hepaticae and Anthocerotae of North America, volume VI, pp. 712–713. (Chicago: Field Museum of Natural History, 1992). ISBN 0-914868-21-7.
- ^ Goffinet, Bernard; William R. Buck (2004). "Systematics of the Bryophyta (Mosses): From molecules to a revised classification". Monographs in Systematic Botany. 98: 205–239.
- ^ Gifford, Ernest M.; Foster, Adriance S. (1988). Morphology and Evolution of Vascular Plants (3rd ed.). New York: W.H. Freeman and Company. p. 358. ISBN 978-0-7167-1946-5.
- ^ Taylor, Thomas N.; Taylor, Edith L. (1993). The Biology and Evolution of Fossil Plants. New Jersey: Prentice-Hall. p. 636. ISBN 978-0-13-651589-0.
- ^ International Union for Conservation of Nature and Natural Resources, 2006. IUCN Red List of Threatened Species:Summary Statistics Archived 27 June 2014 at the Wayback Machine
- ^ "The oldest fossils reveal evolution of non-vascular plants by the middle to late Ordovician Period (≈450–440 m.y.a.) on the basis of fossil spores" Transition of plants to land Archived 2 March 2008 at the Wayback Machine
- ^ Strother, Paul K.; Battison, Leila; Brasier, Martin D.; Wellman, Charles H. (26 May 2011). "Earth's earliest non-marine eukaryotes". Nature. 473 (7348): 505–509. Bibcode:2011Natur.473..505S. doi:10.1038/nature09943. PMID 21490597.
- ^ Harholt, Jesper; Moestrup, Øjvind; Ulvskov, Peter (1 February 2016). "Why Plants Were Terrestrial from the Beginning". Trends in Plant Science. 21 (2): 96–101. doi:10.1016/j.tplants.2015.11.010. PMID 26706443.
- ^ Ponce-Toledo, R. I.; Deschamps, P.; López-García, P.; Zivanovic, Y.; Benzerara, K.; Moreira, D. (2017). "An early-branching freshwater cyanobacterium at the origin of plastids". Current Biology. 27 (3): 386–391. doi:10.1016/j.cub.2016.11.056. PMC 5650054. PMID 28132810.
- ^ Rothwell, G.W.; Scheckler, S.E.; Gillespie, W.H. (1989). "Elkinsia gen. nov., a Late Devonian gymnosperm with cupulate ovules". Botanical Gazette. 150 (2): 170–189. doi:10.1086/337763. JSTOR 2995234.
- ^ Kenrick, Paul & Peter R. Crane. 1997. The Origin and Early Diversification of Land Plants: A Cladistic Study. (Washington, D.C., Smithsonian Institution Press.) ISBN 1-56098-730-8.
- ^ Smith Alan R.; Pryer, Kathleen M.; Schuettpelz, E.; Korall, P.; Schneider, H.; Wolf, Paul G. (2006). "A classification for extant ferns" (PDF). Taxon. 55 (3): 705–731. doi:10.2307/25065646. JSTOR 25065646. Archived from the original (PDF) on 26 February 2008.
- ^ a b Leliaert, F.; Smith, D.R.; Moreau, H.; Herron, M.D.; Verbruggen, H.; Delwiche, C.F.; De Clerck, O. (2012). "Phylogeny and molecular evolution of the green algae" (PDF). Critical Reviews in Plant Sciences. 31: 1–46. doi:10.1080/07352689.2011.615705. Archived from the original (PDF) on 26 June 2015.
- ^ Leliaert, Frederik; Verbruggen, Heroen; Zechman, Frederick W. (2011). "Into the deep: New discoveries at the base of the green plant phylogeny". BioEssays. 33 (9): 683–692. doi:10.1002/bies.201100035. PMID 21744372.
- ^ Silar, Philippe (2016), "Protistes Eucaryotes: Origine, Evolution et Biologie des Microbes Eucaryotes", HAL Archives-ouvertes: 1–462, archived from the original on 13 May 2016, retrieved 21 July 2016
- ^ Mikhailyuk, Tatiana; Lukešová, Alena; Glaser, Karin; Holzinger, Andreas; Obwegeser, Sabrina; Nyporko, Svetlana; Friedl, Thomas; Karsten, Ulf (2018). "New Taxa of Streptophyte Algae (Streptophyta) from Terrestrial Habitats Revealed Using an Integrative Approach". Protist. 169 (3): 406–431. doi:10.1016/j.protis.2018.03.002. ISSN 1434-4610. PMC 6071840. PMID 29860113.
- ^ Novíkov & Barabaš-Krasni (2015). Modern plant systematics. Liga-Pres. p. 685. doi:10.13140/RG.2.1.4745.6164. ISBN 978-966-397-276-3.
- ^ Leebens-Mack, M.; Barker, M.; Carpenter, E.; Deyholos, M.K.; Gitzendammer, M.A.; Graham, S.W.; Grosse, I.; Li, Zheng (2019). "One thousand plant transcriptomes and the phylogenomics of green plants". Nature. 574 (7780): 679–685. doi:10.1038/s41586-019-1693-2. PMID 31645766.
- ^ Liang, Zhe; et al. (2019). "Mesostigma viride Genome and Transcriptome Provide Insights into the Origin and Evolution of Streptophyta". Advanced Science. 7 (1): 1901850. doi:10.1002/advs.201901850.
- ^ Wang, Sibo; et al. (2020). "Genomes of early-diverging streptophyte algae shed light on plant terrestrialization". Nature Plants. 6 (2): 95–106. doi:10.1038/s41477-019-0560-3.
- ^ Puttick, Mark; et al. (2018). "The Interrelationships of Land Plants and the Nature of the Ancestral Embryophyte". Current Biology. 28 (5): 733–745. doi:10.1016/j.cub.2018.01.063. PMID 29456145.
- ^ Zhang, Jian; et al. (2020). "The hornwort genome and early land plant evolution". Nature Plants. 6 (2): 107–118. doi:10.1038/s41477-019-0588-4.
- ^ Li, Fay Wei; et al. (2020). "Anthoceros genomes illuminate the origin of land plants and the unique biology of hornworts". Nature Plants. 6 (3): 259–272. doi:10.1038/s41477-020-0618-2.
- ^ Knoll, Andrew H (2003). Life on a Young Planet: The First Three Billion Years of Evolution on Earth. Princeton University Press.
- ^ Tappan, H (1980). Palaeobiology of Plant Protists. Freeman, San Francisco.
- ^ Butterfield, Nicholas J.; Knoll, Andrew H.; Swett, Keene (1994). "Paleobiology of the Neoproterozoic Svanbergfjellet Formation, Spitsbergen". Lethaia. 27 (1): 76. doi:10.1111/j.1502-3931.1994.tb01558.x.
- ^ Stewart, Wilson A.; Rothwell, Gar W. (1993). Paleobotany and the evolution of plants (2 ed.). Cambridge University Press. ISBN 978-0521382946.
- ^ Wilson, Edward O.; et al. (1973). Life on Earth (First ed.). Stamford, Conn., Sinauer Associates. p. 145. ISBN 978-0-87893-934-3.
- ^ R.M.M., Crawford (1982). "Physiological responses in flooding". Encyclopedia of Plant Physiology. 12B: 453–477.
- ^ a b Robbins, W.W.; Weier, T.E.; et al., Botany: Plant Science, 3rd edition, Wiley International, New York, 1965.
- ^ Goyal, K.; Walton, L.J.; Tunnacliffe, A. (2005). "LEA proteins prevent protein aggregation due to water stress". Biochemical Journal. 388 (Part 1): 151–157. doi:10.1042/BJ20041931. PMC 1186703. PMID 15631617.
- ^ a b Glerum, C. 1985. Frost hardiness of coniferous seedlings: principles and applications. pp. 107–123 in Duryea, M.L. (Ed.). Proceedings: Evaluating seedling quality: principles, procedures, and predictive abilities of major tests. Workshop, October 1984, Oregon State Univ., For. Res. Lab., Corvallis OR.
- ^ Lyons, J.M.; Raison, J.K.; Steponkus, P.L. 1979. The plant membrane in response to low temperature: an overview. pp. 1–24 in Lyons, J.M.; Graham, D.; Raison, J.K. (Eds.). Low Temperature Stress in Crop Plants. Academic Press, New York NY.
- ^ Mazur, P. 1977. The role of intracellular freezing in the death of cells cooled at supraoptimal rates. Cryobiology 14:251–272.
- ^ Sakai, A.; Larcher, W. (Eds.) 1987. Frost Survival of Plants. Springer-Verlag, New York. 321 p.
- ^ Roldán-Arjona, T.; Ariza, R.R. (2009). "Repair and tolerance of oxidative DNA damage in plants". Mutation Research. 681 (2–3): 169–179. doi:10.1016/j.mrrev.2008.07.003. PMID 18707020.
- ^ Yoshiyama, K.O. (2016). "SOG1: a master regulator of the DNA damage response in plants". Genes and Genetic Systems. 90 (4): 209–216. doi:10.1266/ggs.15-00011. PMID 26617076.
- ^ Waterworth, W.M.; Bray, C.M.; West, C.E. (2015). "The importance of safeguarding genome integrity in germination and seed longevity". Journal of Experimental Botany. 66 (12): 3549–3558. doi:10.1093/jxb/erv080. PMID 25750428.
- ^ Koppen, G.; Verschaeve, L. (2001). "The alkaline single-cell gel electrophoresis/comet assay: a way to study DNA repair in radicle cells of germinating Vicia faba". Folia Biologica (Prague). 47 (2): 50–54. PMID 11321247.
- ^ Waterworth, W.M.; Masnavi, G.; Bhardwaj, R.M.; Jiang, Q.; Bray, C.M.; West, C.E. (2010). "A plant DNA ligase is an important determinant of seed longevity". Plant Journal. 63 (5): 848–860. doi:10.1111/j.1365-313X.2010.04285.x. PMID 20584150.
- ^ Waterworth, W.M.; Footitt, S.; Bray, C.M.; Finch-Savage, W.E.; West, C.E. (2016). "DNA damage checkpoint kinase ATM regulates germination and maintains genome stability in seeds". PNAS. 113 (34): 9647–9652. doi:10.1073/pnas.1608829113. PMC 5003248. PMID 27503884.
- ^ a b Campbell, Reece, Biology, 7th edition, Pearson/Benjamin Cummings, 2005.
- ^ Gill, Victoria (14 July 2010). "Plants 'can think and remember'". BBC News. Archived from the original on 5 June 2018. Retrieved 20 June 2018 – via www.bbc.co.uk.
- ^ Song, W.Y.; et al. (1995). "A receptor kinase-like protein encoded by the rice disease resistance gene, XA21". Science. 270 (5243): 1804–1806. Bibcode:1995Sci...270.1804S. doi:10.1126/science.270.5243.1804. PMID 8525370. Archived from the original on 7 November 2018. Retrieved 10 September 2018.
- ^ Gomez-Gomez, L.; et al. (2000). "FLS2: an LRR receptor-like kinase involved in the perception of the bacterial elicitor flagellin in Arabidopsis". Molecular Cell. 5 (6): 1003–1011. doi:10.1016/S1097-2765(00)80265-8. PMID 10911994.
- ^ Michael, Todd P.; Jackson, Scott (1 July 2013). "The First 50 Plant Genomes". The Plant Genome. 6 (2): 0. doi:10.3835/plantgenome2013.03.0001in.
- ^ Brenchley, Rachel; Spannagl, Manuel; Pfeifer, Matthias; Barker, Gary L.A.; D'Amore, Rosalinda; Allen, Alexandra M.; McKenzie, Neil; Krame r, Melissa; Kerhornou, Arnau (29 November 2012). "Analysis of the bread wheat genome using whole-genome shotgun sequencing". Nature. 491 (7426): 705–710. Bibcode:2012Natur.491..705B. doi:10.1038/nature11650. PMC 3510651. PMID 23192148.
- ^ Arabidopsis Genome Initiative (14 December 2000). "Analysis of the genome sequence of the flowering plant Arabidopsis thaliana". Nature. 408 (6814): 796–815. Bibcode:2000Natur.408..796T. doi:10.1038/35048692. PMID 11130711.
- ^ Ibarra-Laclette, Enrique; Lyons, Eric; Hernández-Guzmán, Gustavo; Pérez-Torres, Claudia Anahí; Carretero-Paulet, Lorenzo; Chang, Tien-Hao; Lan, Tianying; Welch, Andreanna J.; Juárez, María Jazmín Abraham (6 June 2013). "Architecture and evolution of a minute plant genome". Nature. 498 (7452): 94–98. Bibcode:2013Natur.498...94I. doi:10.1038/nature12132. PMC 4972453. PMID 23665961.
- ^ Nystedt, Björn; Street, Nathaniel R.; Wetterbom, Anna; Zuccolo, Andrea; Lin, Yao-Cheng; Scofield, Douglas G.; Vezzi, Francesco; Delhomme, Nicolas; Giacomello, Stefania (30 May 2013). "The Norway spruce genome sequence and conifer genome evolution". Nature. 497 (7451): 579–584. Bibcode:2013Natur.497..579N. doi:10.1038/nature12211. PMID 23698360.
- ^ Frank, Howard, Bromeliad Phytotelmata Archived 20 August 2009 at the Wayback Machine, October 2000
- ^ Barthlott, W.; Porembski, S.; Seine, R.; Theisen, I. 2007. The Curious World of Carnivorous Plants: A Comprehensive Guide to Their Biology and Cultivation. Timber Press: Portland, Oregon.
- ^ Kochhar, S.L. (31 May 2016). Economic Botany: A Comprehensive Study. Cambridge University Press. ISBN 9781316675397.
- ^ Wrench, Jason S. (9 January 2013). Workplace Communication for the 21st Century: Tools and Strategies that Impact the Bottom Line [2 volumes]: Tools and Strategies That Impact the Bottom Line. ABC-CLIO. ISBN 9780313396328.
- ^ United States Agricultural Research Service (1903). Report on the Agricultural Experiment Stations. U.S. Government Printing Office.
- ^ "The Development of Agriculture". National Geographic. 2016. Archived from the original on 14 April 2016. Retrieved 1 October 2017.
- ^ "Food and drink". Kew Gardens. Archived from the original on 28 March 2014. Retrieved 1 October 2017.
- ^ "Chemicals from Plants". Cambridge University Botanic Garden. Archived from the original on 9 December 2017. Retrieved 9 December 2017. Note that the details of each plant and the chemicals it yields are described in the linked subpages.
- ^ Tapsell, L.C.; Hemphill, I.; Cobiac, L. (August 2006). "Health benefits of herbs and spices: the past, the present, the future". Med. J. Aust. 185 (4 Suppl): S4–24. doi:10.5694/j.1326-5377.2006.tb00548.x. PMID 17022438.
- ^ Lai, P.K.; Roy, J.; Roy (June 2004). "Antimicrobial and chemopreventive properties of herbs and spices". Curr. Med. Chem. 11 (11): 1451–1460. doi:10.2174/0929867043365107. PMID 15180577.
{{cite journal}}
: CS1 maint: multiple names: authors list (link) - ^ "Greek Medicine". National Institutes of Health, USA. 16 September 2002. Archived from the original on 9 November 2013. Retrieved 22 May 2014.
- ^ Hefferon, Kathleen (2012). Let Thy Food Be Thy Medicine. Oxford University Press. p. 46. ISBN 978-0199873982.
- ^ Rooney, Anne (2009). The Story of Medicine. Arcturus Publishing. p. 143. ISBN 978-1848580398.
- ^ "Industrial Crop Production". Grace Communications Foundation. 2016. Archived from the original on 10 June 2016. Retrieved 20 June 2016.
- ^ "Industrial Crops and Products An International Journal". Elsevier. Archived from the original on 2 October 2017. Retrieved 20 June 2016.
- ^ Cruz, Von Mark V.; Dierig, David A. (2014). Industrial Crops: Breeding for BioEnergy and Bioproducts. Springer. pp. 9 and passim. ISBN 978-1-4939-1447-0. Archived from the original on 22 April 2017. Retrieved 1 October 2017.
- ^ Sato, Motoaki (1990). Thermochemistry of the formation of fossil fuels (PDF). The Geochemical Society. Archived (PDF) from the original on 20 September 2015. Retrieved 1 October 2017.
{{cite book}}
:|work=
ignored (help) - ^ Sixta, Herbert, ed. (2006). Handbook of pulp. Vol. 1. Winheim, Germany: Wiley-VCH. p. 9. ISBN 978-3-527-30997-9.
- ^ "Natural fibres". Discover Natural Fibres. Archived from the original on 20 July 2016. Retrieved 20 June 2016.
- ^ Sosnoski, Daniel (1996). Introduction to Japanese culture. Tuttle. p. 12. ISBN 978-0-8048-2056-1. Retrieved 13 December 2017.
- ^ "History of the Cherry Blossom Trees and Festival". National Cherry Blossom Festival: About. National Cherry Blossom Festival. Archived from the original on 14 March 2016. Retrieved 22 March 2016.
- ^ Lambert, Tim (2014). "A Brief History of Gardening". British Broadcasting Corporation. Archived from the original on 9 June 2016. Retrieved 21 June 2016.
- ^ Wilkinson, Richard H. (2000). The Complete Temples of Ancient Egypt. Thames and Hudson. pp. 65–66. ISBN 978-0-500-05100-9.
- ^ Blumberg, Roger B. "Mendel's Paper in English". Archived from the original on 13 January 2016. Retrieved 9 December 2017.
- ^ "Barbara McClintock: A Brief Biographical Sketch". WebCite. Archived from the original on 21 August 2011. Retrieved 21 June 2016.
- ^ "About Arabidopsis". TAIR. Archived from the original on 22 October 2016. Retrieved 21 June 2016.
- ^ "Engineering Life". NASA. Archived from the original on 8 June 2016. Retrieved 21 June 2016.
- ^ "cocaine/crack". Archived from the original on 20 May 2007. Retrieved 25 May 2007.
- ^ "Deaths related to cocaine". Archived from the original on 17 July 2006. Retrieved 25 May 2007.
- ^ "Illegal drugs drain $160 billion a year from American economy". Archived from the original on 15 February 2008.
- ^ "The social cost of illegal drug consumption in Spain". September 2002. Archived from the original on 2 October 2007. Retrieved 25 May 2007.
Further reading
- General
- Evans, L.T. (1998). Feeding the Ten Billion – Plants and Population Growth. Cambridge University Press. Paperback, 247 pages. ISBN 0-521-64685-5.
- Kenrick, Paul & Crane, Peter R. (1997). The Origin and Early Diversification of Land Plants: A Cladistic Study. Washington, D.C.: Smithsonian Institution Press. ISBN 1-56098-730-8.
- Raven, Peter H.; Evert, Ray F.; & Eichhorn, Susan E. (2005). Biology of Plants (7th ed.). New York: W.H. Freeman and Company. ISBN 0-7167-1007-2.
- Taylor, Thomas N. & Taylor, Edith L. (1993). The Biology and Evolution of Fossil Plants. Englewood Cliffs, NJ: Prentice Hall. ISBN 0-13-651589-4.
- Trewavas A (2003). "Aspects of Plant Intelligence". Annals of Botany. 92 (1): 1–20. doi:10.1093/aob/mcg101. PMC 4243628. PMID 12740212.
- Species estimates and counts
- International Union for Conservation of Nature and Natural Resources (IUCN) Species Survival Commission (2004). IUCN Red List [2].
- Prance G.T. (2001). "Discovering the Plant World". Taxon. 50 (2, Golden Jubilee Part 4): 345–359. doi:10.2307/1223885. JSTOR 1223885.
External links
- Jones, T.M.; Reid, C.S.; Urbatsch, L.E. "Visual study of divisional Plantae".
{{cite journal}}
: Cite journal requires|journal=
(help) (requires Microsoft Silverlight) - Chaw, S.-M.; et al. (1997). "Molecular Phylogeny of Extant Gymnosperms and Seed Plant Evolution: Analysis of Nuclear 18s rRNA Sequences" (PDF). Mol. Biol. Evol. 14 (1): 56–68. doi:10.1093/oxfordjournals.molbev.a025702. PMID 9000754. Archived from the original (PDF) on 24 January 2005.
- Index Nominum Algarum
- Interactive Cronquist classification
- Plant Resources of Tropical Africa
- Tree of Life
- Botanical and vegetation databases
- African Plants Initiative database
- Australia
- Chilean plants at Chilebosque
- e-Floras (Flora of China, Flora of North America and others)
- Flora Europaea
- Flora of Central Europe (in German)
- Flora of North America
- List of Japanese Wild Plants Online
- Meet the Plants-National Tropical Botanical Garden
- Lady Bird Johnson Wildflower Center – Native Plant Information Network at University of Texas, Austin
- The Plant List
- United States Department of Agriculture not limited to continental US species