Difference between revisions of "Azolla"
in Lamarck et al., Encycl. 1: 343. 1783.
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|accepted_name=Azolla | |accepted_name=Azolla | ||
− | |accepted_authority=Lamarck | + | |accepted_authority=Lamarck |
|publications={{Treatment/Publication | |publications={{Treatment/Publication | ||
− | |title=in Lamarck et al.,Encycl. | + | |title=in Lamarck et al., Encycl. |
|place=1: 343. 1783 | |place=1: 343. 1783 | ||
|year=1783 | |year=1783 | ||
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|distribution=Tropical to temperate regions. | |distribution=Tropical to temperate regions. | ||
− | |discussion=<p>Azolla is divided into sect. Azolla and sect. Rhizosperma (Meyen) Mettenius, which are sometimes recognized as subgenera. New World species belong to sect. Azolla and differ from sect. Rhizosperma by having 3 floats per megasporocarp (fig. 25.1), subdichotomous branching, and straight barbs on microsporangial masses (rather than 9 floats per megasporocarp, pinnate branching, and needlelike hairs or hairs absent on microsporangial masses). The genus was more diverse in past geologic ages: 30 species are known from the Cretaceous (J. W. Hall 1974).</p><!-- | + | |discussion=<p><i>Azolla</i> is divided into sect. <i>Azolla</i> and sect. Rhizosperma (Meyen) Mettenius, which are sometimes recognized as subgenera. New World species belong to sect. <i>Azolla</i> and differ from sect. Rhizosperma by having 3 floats per megasporocarp (fig. 25.1), subdichotomous branching, and straight barbs on microsporangial masses (rather than 9 floats per megasporocarp, pinnate branching, and needlelike hairs or hairs absent on microsporangial masses). The genus was more diverse in past geologic ages: 30 species are known from the Cretaceous (J. W. Hall 1974).</p><!-- |
− | --><p>The species of Azolla are difficult taxonomically because (1) about 80% of the specimens lack sori, which are necessary for identification, and (2) the characteristics needed to identify the species are difficult to observe. A scanning electron microscope is needed to see sculpturing of the megaspores, and a light microscope is needed to see the number of cells per hair on the upper leaf lobe. (These hairs are best seen in profile on mature leaves; at least 40× magnification is needed.)</p><!-- | + | --><p>The species of <i>Azolla</i> are difficult taxonomically because (1) about 80% of the specimens lack sori, which are necessary for identification, and (2) the characteristics needed to identify the species are difficult to observe. A scanning electron microscope is needed to see sculpturing of the megaspores, and a light microscope is needed to see the number of cells per hair on the upper leaf lobe. (These hairs are best seen in profile on mature leaves; at least 40× magnification is needed.)</p><!-- |
− | --><p>Previous workers emphasized the number of septae (internal partitions) in the barbs on the microsporangial masses as a primary differentiating characteristic among species of Azolla (e.g., H. K. Svensen 1944). This character is not constant, however, either within a species or within an individual (R. K. Godfrey et al. 1961; L. V. Hill and B. Gopal 1967; K. Seto and T. Nasu 1975). Because nearly all floristic work in North America since the 1940s has been based on Svenson's synoptic treatment, the identity of most specimens is questionable, and therefore ranges are imprecisely known.</p><!-- | + | --><p>Previous workers emphasized the number of septae (internal partitions) in the barbs on the microsporangial masses as a primary differentiating characteristic among species of <i>Azolla</i> (e.g., H. K. Svensen 1944). This character is not constant, however, either within a species or within an individual (R. K. Godfrey et al. 1961; L. V. Hill and B. Gopal 1967; K. Seto and T. Nasu 1975). Because nearly all floristic work in North America since the 1940s has been based on Svenson's synoptic treatment, the identity of most specimens is questionable, and therefore ranges are imprecisely known.</p><!-- |
− | --><p>The maps for this treatment are tentative. For the most part, I have noted occurrences only in those states or regions from which specimens have been identified using characteristics given in this key. Literature that attributes a particular species of Azolla to a particular state or province must be questioned because the specimens were presumably identified using the inconsistent glochidial characteristics given by H. K. Svenson (1944). More work is needed to determine the distribution of Azolla species in North America.</p><!-- | + | --><p>The maps for this treatment are tentative. For the most part, I have noted occurrences only in those states or regions from which specimens have been identified using characteristics given in this key. Literature that attributes a particular species of <i>Azolla</i> to a particular state or province must be questioned because the specimens were presumably identified using the inconsistent glochidial characteristics given by H. K. Svenson (1944). More work is needed to determine the distribution of <i>Azolla</i> species in North America.</p><!-- |
− | --><p>Agriculturally, Azolla is famous for its symbiosis with the nitrogen-fixing Anabaena azollae Strasburger, a cyanobacterium (blue-green alga) found at the stem apices, beneath indusia, and in cavities of the upper leaf lobes. Because the plants fix nitrogen, they are often used as a green fertilizer or mixed with livestock feed as a nutritional supplement. Azolla pinnata has been cultivated for many centuries in rice paddies of northern Vietnam and southeastern China, where it acts as a fertilizer after it decomposes.</p><!-- | + | --><p>Agriculturally, <i>Azolla</i> is famous for its symbiosis with the nitrogen-fixing Anabaena azollae Strasburger, a cyanobacterium (blue-green alga) found at the stem apices, beneath indusia, and in cavities of the upper leaf lobes. Because the plants fix nitrogen, they are often used as a green fertilizer or mixed with livestock feed as a nutritional supplement. <i>Azolla</i> pinnata has been cultivated for many centuries in rice paddies of northern Vietnam and southeastern China, where it acts as a fertilizer after it decomposes.</p><!-- |
− | --><p>Azolla is the most frequently studied genus of ferns in the world because of its economic importance. The three North American species are naturalized in Europe and South Africa, and they have been introduced into Hawaii for horticulture and into Asia for agriculture. All species have been studied for agricultural uses in rice-producing areas.</p><!-- | + | --><p><i>Azolla</i> is the most frequently studied genus of ferns in the world because of its economic importance. The three North American species are naturalized in Europe and South Africa, and they have been introduced into Hawaii for horticulture and into Asia for agriculture. All species have been studied for agricultural uses in rice-producing areas.</p><!-- |
− | --><p>Azolla is usually found in stagnant or slow-moving water of ponds, lakes, marshes, swamps, and streams. Plants turn reddish when under stress, such as from poor nutrition, salinity, or high temperatures. Sporulation needs further investigation.</p><!-- | + | --><p><i>Azolla</i> is usually found in stagnant or slow-moving water of ponds, lakes, marshes, swamps, and streams. Plants turn reddish when under stress, such as from poor nutrition, salinity, or high temperatures. Sporulation needs further investigation.</p><!-- |
--><p>Species ca. 7 (3 in the flora).</p> | --><p>Species ca. 7 (3 in the flora).</p> | ||
|tables= | |tables= | ||
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name=Azolla | name=Azolla | ||
|author=Thomas A. Lumpkin | |author=Thomas A. Lumpkin | ||
− | |authority=Lamarck | + | |authority=Lamarck |
|rank=genus | |rank=genus | ||
|parent rank=family | |parent rank=family | ||
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|distribution=Tropical to temperate regions. | |distribution=Tropical to temperate regions. | ||
|reference=baillonville1987a;hall1974a;lumpkin1982a;moore1969a;svenson1944a;zimmerman1989a | |reference=baillonville1987a;hall1974a;lumpkin1982a;moore1969a;svenson1944a;zimmerman1989a | ||
− | |publication title=in Lamarck et al.,Encycl. | + | |publication title=in Lamarck et al., Encycl. |
|publication year=1783 | |publication year=1783 | ||
|special status= | |special status= | ||
− | |source xml=https:// | + | |source xml=https://bitbucket.org/aafc-mbb/fna-data-curation/src/2e0870ddd59836b60bcf96646a41e87ea5a5943a/coarse_grained_fna_xml/V2/V2_390.xml |
|genus=Azolla | |genus=Azolla | ||
}}<!-- | }}<!-- | ||
-->[[Category:Treatment]][[Category:Azollaceae]] | -->[[Category:Treatment]][[Category:Azollaceae]] |
Latest revision as of 20:23, 5 November 2020
Roots 3–5 cm. Stems prostrate, 1–3 cm, or nearly erect, 3–5 cm, hairs absent. Leaves with 1(–2)-celled hairs on upper surface of upper lobe. Sporocarps in pairs. Megasporocarp megaspore with 3 floats. Microsporocarp masses entirely covered with arrowlike barbs. x = 22.
Distribution
Tropical to temperate regions.
Discussion
Azolla is divided into sect. Azolla and sect. Rhizosperma (Meyen) Mettenius, which are sometimes recognized as subgenera. New World species belong to sect. Azolla and differ from sect. Rhizosperma by having 3 floats per megasporocarp (fig. 25.1), subdichotomous branching, and straight barbs on microsporangial masses (rather than 9 floats per megasporocarp, pinnate branching, and needlelike hairs or hairs absent on microsporangial masses). The genus was more diverse in past geologic ages: 30 species are known from the Cretaceous (J. W. Hall 1974).
The species of Azolla are difficult taxonomically because (1) about 80% of the specimens lack sori, which are necessary for identification, and (2) the characteristics needed to identify the species are difficult to observe. A scanning electron microscope is needed to see sculpturing of the megaspores, and a light microscope is needed to see the number of cells per hair on the upper leaf lobe. (These hairs are best seen in profile on mature leaves; at least 40× magnification is needed.)
Previous workers emphasized the number of septae (internal partitions) in the barbs on the microsporangial masses as a primary differentiating characteristic among species of Azolla (e.g., H. K. Svensen 1944). This character is not constant, however, either within a species or within an individual (R. K. Godfrey et al. 1961; L. V. Hill and B. Gopal 1967; K. Seto and T. Nasu 1975). Because nearly all floristic work in North America since the 1940s has been based on Svenson's synoptic treatment, the identity of most specimens is questionable, and therefore ranges are imprecisely known.
The maps for this treatment are tentative. For the most part, I have noted occurrences only in those states or regions from which specimens have been identified using characteristics given in this key. Literature that attributes a particular species of Azolla to a particular state or province must be questioned because the specimens were presumably identified using the inconsistent glochidial characteristics given by H. K. Svenson (1944). More work is needed to determine the distribution of Azolla species in North America.
Agriculturally, Azolla is famous for its symbiosis with the nitrogen-fixing Anabaena azollae Strasburger, a cyanobacterium (blue-green alga) found at the stem apices, beneath indusia, and in cavities of the upper leaf lobes. Because the plants fix nitrogen, they are often used as a green fertilizer or mixed with livestock feed as a nutritional supplement. Azolla pinnata has been cultivated for many centuries in rice paddies of northern Vietnam and southeastern China, where it acts as a fertilizer after it decomposes.
Azolla is the most frequently studied genus of ferns in the world because of its economic importance. The three North American species are naturalized in Europe and South Africa, and they have been introduced into Hawaii for horticulture and into Asia for agriculture. All species have been studied for agricultural uses in rice-producing areas.
Azolla is usually found in stagnant or slow-moving water of ponds, lakes, marshes, swamps, and streams. Plants turn reddish when under stress, such as from poor nutrition, salinity, or high temperatures. Sporulation needs further investigation.
Species ca. 7 (3 in the flora).
Selected References
Lower Taxa
Key
1 | Largest hairs on upper leaf lobe unicellular; megaspores warty with raised angular bumps. | Azolla filiculoides |
1 | Largest hairs on upper leaf lobe with 2 or more cells; megaspores not covered with raised angular bumps. | > 2 |
2 | Megaspores not pitted, densely covered with tangled filaments (filosum). | Azolla caroliniana |
2 | Megaspores pitted, sparsely covered with a few long filaments (filosum). | Azolla mexicana |