Dryopteridaceae
Ecotype
Seed Dispersal
Spores
Plastids
Effect of storage method on spore viability in five globally threatened fern species. (1/13)
Spore germination of five globally threatened fern species [Culcita macrocarpa C. Presl, Dryopteris aemula (Aiton) O. Kuntze, D. corleyi Fraser-Jenkins, D. guanchica Gibby and Jermy and Woodwardia radicans (L.) Sm.] was determined after 1, 6 or 12 months of storage in glass vials (dry storage) or on agar (wet storage) at -20, 5 or 20 degrees C. In all species, storage technique, storage temperature and the technique-temperature interaction all had a significant effect on germination percentage. In most cases, the germination percentage was best maintained by wet storage at 5 or 20 degrees C. In the case of the hygrophilous species C. macrocarpa and W. radicans, 6 or 12 months' dry storage killed most spores. Only Woodwardia radicans germinated in the dark during wet storage at 20 degrees C. Wet storage at 5 degrees C prevented dark germination, and reduced bacterial and fungal contamination. Wet storage at -20 degrees C killed all or most spores in all species. In the three Dryopteris species, the differences among the storage conditions tested were smaller than in C. macrocarpa and W. radicans, and the decline in spore viability during storage was less marked, with high germination percentages being observed after 12 months of dry storage at all three temperatures. Dry storage, which has lower preparation time and space requirements than wet storage, was generally more effective at the lower temperatures (-20 or 5 degrees C). (+info)Antioxidant activity of two phloroglucinol derivatives from Dryopteris crassirhizoma. (2/13)
The rhizome of Dryopteris crassirhizoma NAKAI exhibited significant antioxidant activity, as assessed by the 1,1-diphenyl-2-picrylhydrazyl (DPPH) radical scavenging activity in vitro. Two phloroglucinol derivatives, flavaspidic acids PB (1) and AB (2), were isolated from the rhizome of D. crassirhizoma by a bioassay-guided fractionation. 1H-, 13C-NMR, and UV analysis were used to determine the structures. Furthermore, the two compounds were tested for their antioxidant activities, such as their DPPH radical scavenging, superoxide radical scavenging, and lipid peroxidation (LPO) inhibitory activities. Compounds 1 and 2 exhibited potent antioxidant activity against the LPO inhibitory test with IC(50) values of 12.9 and 13.1 microM, respectively, compared with alpha-tocopherol (IC(50); 15.6 microM) and butylated hydroxy anisole (BHA, IC(50); 10.8 microM), while the two compounds had a moderated effect on the DPPH radical scavenging activity (IC(50); 71.7, 76.3 microM) as well as superoxide radical scavenging activity (IC(50); 58.6, 64.4 microM). The potent activity of the flavaspidic acids (1, 2) on inhibiting LPO might be due to possible stabilization as a result of chelating with iron. (+info)Overwintering leaves of a forest-floor fern, Dryopteris crassirhizoma (Dryopteridaceae): a small contribution to the resource storage and photosynthetic carbon gain. (3/13)
BACKGROUND AND AIMS: Dryopteris crassirhizoma is a semi-evergreen fern growing on the floor of deciduous forests. The present study aimed to clarify the photosynthetic and storage functions of overwintering leaves in this species. METHODS: A 2-year experiment with defoliation and shading of overwintering leaves was conducted. Photosynthetic light response was measured in early spring (for overwintering leaves) and summer (for current-year leaves). KEY RESULTS: No nitrogen limitation of growth was detected in plants subjected to defoliation. The number of leaves, their size, reproductive activity (production of sori) and total leaf mass were not affected by the treatment. The defoliation of overwintering leaves significantly reduced the bulk density of rhizomes and the root weight. The carbohydrates consumed by the rhizomes were assumed to be translocated for leaf production. Photosynthetic products of overwintering leaves were estimated to be small. CONCLUSION: Overwintering leaves served very little as nutrient-storage and photosynthetic organs. They partly functioned as a carbon-storage organ but by contrast to previous studies, their physiological contribution to growth was found to be modest, probably because this species has a large rhizome system. The small contribution of overwintering leaves during the short-term period of this study may be explained by the significant storage ability of rhizomes in this long-living species. Other ecological functions of overwintering leaves, such as suppression of neighbouring plants in spring, are suggested. (+info)Phenolic constituents from the rhizomes of Dryopteris crassirhizoma. (4/13)
A new phenolic glycoside, dryopteroside (1), was isolated from the rhizomes of Dryopteris crassirhizoma (Dryopteridaceae), together with five known compounds, 4beta-carboxymethyl-(-)-epicatechin (2), isobiflorin (3), biflorin (4), 1-beta-D-glucopyranosyloxy-3-methoxy-5-hydroxybenzene (5) and (+)-catechin-6-C-beta-D-glucopyranoside (6). The new compound was elucidated to be 1-butanoyl-3-C-beta-D-glucopyranosyl-5-methyl-phloroglucinyl-6-O-beta-D-glucopyra noside (1) by chemical and various spectroscopic analyses. The known compounds 2-6 were first reported from the genus Dryopteris. (+info)Spore fitness components do not differ between diploid and allotetraploid species of Dryopteris (Dryopteridaceae). (5/13)
BACKGROUND AND AIMS: Although allopolyploidy is a prevalent speciation mechanism in plants, its adaptive consequences are poorly understood. In addition, the effects of allopolyploidy per se (i.e. hybridization and chromosome doubling) can be confounded with those of subsequent evolutionary divergence between allopolyploids and related diploids. This report assesses whether fern species with the same ploidy level or the same altitudinal distribution have similar germination responses to temperature. The effects of polyploidy on spore abortion and spore size are also investigated, since both traits may have adaptive consequences. METHODS: Three allotetraploid (Dryopteris corleyi, D. filix-mas and D. guanchica) and three related diploid taxa (D. aemula, D. affinis ssp. affinis and D. oreades) were studied. Spores were collected from 24 populations in northern Spain. Four spore traits were determined: abortion percentage, size, germination time and germination percentage. Six incubation temperatures were tested: 8, 15, 20, 25 and 32 degrees C, and alternating 8/15 degrees C. KEY RESULTS: Allotetraploids had bigger spores than diploid progenitors, whereas spore abortion percentages were generally similar. Germination times decreased with increasing temperatures in a wide range of temperatures (8-25 degrees C), although final germination percentages were similar among species irrespective of their ploidy level. Only at low temperature (8 degrees C) did two allotetraploid species reach higher germination percentages than diploid parents. Allotetraploids showed faster germination rates, which would probably give them a competitive advantage over diploid parents. Germination behaviour was not correlated with altitudinal distribution of species. CONCLUSIONS: The results of this study suggest that (i) relative fitness of allopolyploids at sporogenesis does not differ from that of diploid parents and (ii) neither does allopolyploidization involve a change in the success of spore germination. (+info)Two new triterpenes from the Rhizome of Dryopteris crassirhizoma, and inhibitory activities of its constituents on human immunodeficiency virus-1 protease. (6/13)
Two new hopane type triterpenes, named dryopteric acids A (1) and B (2), were isolated from the Rhizome of Dryopteris crassirhizoma (Aspiadaceae) together with sixteen known compounds (3-18). Of isolated compounds, ursolic acid (15), and dryopteric acid A (1) and B (2) showed potent inhibitory activities against HIV-1 protease with IC50 values of 8.9-44.5 microM. In addition, acetylated compounds 1 and 2 appreciably increased inhibitory activities with their IC50 values of 1.7 and 10.8 microM, respectively. (+info)Reproductive and competitive interactions among gametophytes of the allotetraploid fern Dryopteris corleyi and its two diploid parents. (7/13)
(+info)Microsatellites reveal substantial among-population genetic differentiation and strong inbreeding in the relict fern Dryopteris aemula. (8/13)
(+info)"Dryopteris" is a genus of ferns in the family Dryopteridaceae. It includes many species commonly known as wood ferns or buckler ferns. These ferns are characterized by their tough, leathery fronds and their ability to tolerate dry conditions better than some other ferns. They are found in a variety of habitats around the world, including forests, mountains, and rocky areas. Some species of Dryopteris have been used in traditional medicine, but it is important to note that the use of wild plants as medicine should only be done under the guidance of a qualified healthcare professional.
Dryopteridaceae is a family of ferns in the order Polypodiales, also known as the "wood fern" family. It includes several genera of terrestrial and epiphytic ferns, characterized by having typically large, divided fronds with sori (spore cases) protected by an indusium on the underside of the leaf. Examples of genera in this family include Dryopteris, Polystichum, and Athyrium. These ferns are found in a variety of habitats around the world, including temperate and tropical forests.
Chloroplast DNA (cpDNA) refers to the genetic material present in the chloroplasts, which are organelles found in the cells of photosynthetic organisms such as plants, algae, and some bacteria. Chloroplasts are responsible for capturing sunlight energy and converting it into chemical energy through the process of photosynthesis.
Chloroplast DNA is circular and contains a small number of genes compared to the nuclear genome. It encodes for some of the essential components required for chloroplast function, including proteins involved in photosynthesis, transcription, and translation. The majority of chloroplast proteins are encoded by the nuclear genome and are imported into the chloroplast after being synthesized in the cytoplasm.
Chloroplast DNA is inherited maternally in most plants, meaning that it is passed down from the maternal parent to their offspring through the egg cell. This mode of inheritance has been used in plant breeding and genetic engineering to introduce desirable traits into crops.
An ecotype is a population of a species that is adapted to specific environmental conditions and exhibits genetic differences from other populations of the same species that live in different environments. These genetic adaptations allow the ecotype to survive and reproduce more successfully in its particular habitat compared to other populations. The term "ecotype" was first introduced by botanist John Gregor Mendel in 1870 to describe the variation within plant species due to environmental factors.
Ecotypes can be found in various organisms, including plants, animals, and microorganisms. They are often studied in ecology and evolutionary biology to understand how genetic differences arise and evolve in response to environmental pressures. Ecotypes can differ from each other in traits such as morphology, physiology, behavior, and life history strategies.
Examples of ecotypes include:
* Desert and coastal ecotypes of the lizard Uta stansburiana, which show differences in body size, limb length, and reproductive strategies due to adaptation to different habitats.
* Arctic and alpine ecotypes of the plant Arabis alpina, which have distinct flowering times and cold tolerance mechanisms that help them survive in their respective environments.
* Freshwater and marine ecotypes of the copepod Eurytemora affinis, which differ in body size, developmental rate, and salinity tolerance due to adaptation to different aquatic habitats.
It is important to note that the concept of ecotype is not always clearly defined or consistently applied in scientific research. Some researchers use it to describe any population that shows genetic differences related to environmental factors, while others reserve it for cases where there is strong evidence of local adaptation and reproductive isolation between populations.
I'm sorry for any confusion, but "Seed Dispersal" is not a term typically used in medical definitions. It is a concept from botany and ecology, referring to the various methods by which plants distribute their seeds away from the parent plant. This can occur through mechanisms such as wind, water, or animal dispersal. If you have any questions related to medical topics, I'd be happy to help with those instead!
In the context of medicine, spores are typically discussed in relation to certain types of infections and diseases caused by microorganisms such as bacteria or fungi. Spores are a dormant, resistant form of these microorganisms that can survive under harsh environmental conditions, such as extreme temperatures, lack of nutrients, and exposure to chemicals.
Spores can be highly resistant to heat, radiation, and disinfectants, making them difficult to eliminate from contaminated surfaces or medical equipment. When the conditions are favorable, spores can germinate and grow into mature microorganisms that can cause infection.
Some examples of medically relevant spores include those produced by Clostridioides difficile (C. diff), a bacterium that can cause severe diarrhea and colitis in hospitalized patients, and Aspergillus fumigatus, a fungus that can cause invasive pulmonary aspergillosis in immunocompromised individuals.
It's worth noting that spores are not unique to medical contexts and have broader relevance in fields such as botany, mycology, and biology.
Plastids are membrane-bound organelles found in the cells of plants and algae. They are responsible for various cellular functions, including photosynthesis, storage of starch, lipids, and proteins, and the production of pigments that give plants their color. The most common types of plastids are chloroplasts (which contain chlorophyll and are involved in photosynthesis), chromoplasts (which contain pigments such as carotenoids and are responsible for the yellow, orange, and red colors of fruits and flowers), and leucoplasts (which do not contain pigments and serve mainly as storage organelles). Plastids have their own DNA and can replicate themselves within the cell.
Plastocyanin is a small, copper-containing protein that plays a crucial role in the photosynthetic electron transport chain. It functions as an electron carrier, facilitating the movement of electrons between two key protein complexes (cytochrome b6f and photosystem I) located in the thylakoid membrane of chloroplasts. Plastocyanin is a soluble protein found in the lumen of the thylakoids, and its copper ion serves as the site for electron transfer. The oxidized form of plastocyanin accepts an electron from cytochrome b6f and then donates it to photosystem I, helping to maintain the flow of electrons during light-dependent reactions in photosynthesis.