Achlya bisexualis | |
---|---|
Scientific classification | |
Domain: | Eukaryota |
Clade: | Diaphoretickes |
Clade: | SAR |
Clade: | Stramenopiles |
Phylum: | Oomycota |
Order: | Saprolegniales |
Family: | Saprolegniaceae |
Genus: | Achlya |
Species: | A. bisexualis |
Binomial name | |
Achlya bisexualis Coker & Couch (1927) | |
Achlya bisexualis is a species of water mold. It is described as being close to Achlya flagellata , differing by it striking heterothallism and less elongated gemmae. [1]
In 1936, it was discovered that the species contains a number of hermaphrodite females, which behave as true females in the presence of strong males. [2]
Some of the protein of Achlya bisexualis have been sequenced, such as Actin, Cytochrome c oxidase subunit 1 & 2, Pyruvate kinase etc. [3]
Achlya bisexualis can be found in fresh water of many place, such as Europe, north America, Korea, [4] South Africa, [5] India [6] etc.
Achlya bisexualis as other Achlya has asexual reproduction and sexual reproduction. [7]
One kind of asexual reproduction is vegetative reproduction. Vegetative reproduction can be process when it is fragmented. Or when the environment condition is unfavor to Achlya bisexualis it will create gammae and be cut off by hyphae. [7]
Another way of asexual reproduction is sporulation. During sporulation, the hyphal tip which will become sporangium will slightly inflate. The nuclei and cytosol will flow into the tip. There will be a cross wall to separate sporangium and other parts, then a gray central vacuole occurs in sporangium. The sporangium will start cleavage and then become homogeneous and uninuclear. Then primary zoospores formed and come out from the tip. These primary zoospores will germinate and release secondary zoospores, secondary zoospores will germinate and release tertiary zoospores, finally tertiary zoospores will grow to new mycelium. [7]
Achlya bisexualis is heterothallic its sex organ antheridia and oogonia will develop on different somatic hyphae. During the sexual reproduction, the female Achlya bisexualis will release Antheridial (hormone A) to let male Achlya bisexualis grow antheridial initials. Second, the male Achlya bisexualis will release hormone B to let female Achlya bisexualis form oogonial initials. Third, oogonial initials will release hormone C to let antheridial initials grow towards the oogonial initials. When the antheridia contact with the oogonial initials, it will release hormone D to let the oogonial initials form oogonia and the eggs will start differentiation. Antheridia will give one male nucleus to each eggs in oosphere then become diploid oospore. These oospore will release when the oogonial wall be degraded. These oospores will grow zoosporangium, then it will go meiosis to create zoospores. Zoospores will grow to new mycelium. [7]
Achlya bisexualis also can cause saprolegniasis to fishes as other water molds. It can grow at any part of skin, gill etc. but mostly at head. It will cause damage to fish skin. There are some chemical treatments for saprolegniasis, such as Malachite Green, Formalin and Copper sulphate. [8]
Chytridiomycota are a division of zoosporic organisms in the kingdom Fungi, informally known as chytrids. The name is derived from the Ancient Greek χυτρίδιον (khutrídion), meaning "little pot", describing the structure containing unreleased zoospores. Chytrids are one of the earliest diverging fungal lineages, and their membership in kingdom Fungi is demonstrated with chitin cell walls, a posterior whiplash flagellum, absorptive nutrition, use of glycogen as an energy storage compound, and synthesis of lysine by the α-amino adipic acid (AAA) pathway.
Zygomycota, or zygote fungi, is a former division or phylum of the kingdom Fungi. The members are now part of two phyla: the Mucoromycota and Zoopagomycota. Approximately 1060 species are known. They are mostly terrestrial in habitat, living in soil or on decaying plant or animal material. Some are parasites of plants, insects, and small animals, while others form symbiotic relationships with plants. Zygomycete hyphae may be coenocytic, forming septa only where gametes are formed or to wall off dead hyphae. Zygomycota is no longer recognised as it was not believed to be truly monophyletic.
The Oomycetes, or Oomycota, form a distinct phylogenetic lineage of fungus-like eukaryotic microorganisms within the Stramenopiles. They are filamentous and heterotrophic, and can reproduce both sexually and asexually. Sexual reproduction of an oospore is the result of contact between hyphae of male antheridia and female oogonia; these spores can overwinter and are known as resting spores. Asexual reproduction involves the formation of chlamydospores and sporangia, producing motile zoospores. Oomycetes occupy both saprophytic and pathogenic lifestyles, and include some of the most notorious pathogens of plants, causing devastating diseases such as late blight of potato and sudden oak death. One oomycete, the mycoparasite Pythium oligandrum, is used for biocontrol, attacking plant pathogenic fungi. The oomycetes are also often referred to as water molds, although the water-preferring nature which led to that name is not true of most species, which are terrestrial pathogens.
Saprolegnia is a genus of water moulds often called cotton moulds because of the characteristic white or grey fibrous patches they form. Current taxonomy puts Saprolegnia as a genus of the heterokonts in the order Saprolegniales.
An oogonium is a small diploid cell which, upon maturation, forms a primordial follicle in a female fetus or the female gametangium of certain thallophytes.
Sporogenesis is the production of spores in biology. The term is also used to refer to the process of reproduction via spores. Reproductive spores were found to be formed in eukaryotic organisms, such as plants, algae and fungi, during their normal reproductive life cycle. Dormant spores are formed, for example by certain fungi and algae, primarily in response to unfavorable growing conditions. Most eukaryotic spores are haploid and form through cell division, though some types are diploid sor dikaryons and form through cell fusion.we can also say this type of reproduction as single pollination
Aphanomyces euteiches is a water mould, or oomycete, plant pathogen responsible for the disease Aphanomyces root rot. The species Aphanomyces euteiches can infect a variety of legumes. Symptoms of the disease can differ among hosts but generally include reduced root volume and function, leading to stunting and chlorotic foliage. Aphanomyces root rot is an important agricultural disease in the United States, Europe, Australia, New Zealand, and Japan. Management includes using resistant crop varieties and having good soil drainage, as well as testing soil for the pathogen to avoid infected fields.
Phytophthora cactorum is a fungal-like plant pathogen belonging to the Oomycota phylum. It is the causal agent of root rot on rhododendron and many other species, as well as leather rot of strawberries.
Phytophthora medicaginis is an oomycete plant pathogen that causes root rot in alfalfa and chickpea. It is a major disease of these plants and is found wherever they are grown. P. medicaginis causes failure of stand establishment because of seedling death. Phytophthora medicaginis is part of a species complex with Phytophthora megasperma.
Pythium irregulare is a soil borne oomycete plant pathogen. Oomycetes, also known as "water molds", are fungal-like protists. They are fungal-like because of their similar life cycles, but differ in that the resting stage is diploid, they have coenocytic hyphae, a larger genome, cellulose in their cell walls instead of chitin, and contain zoospores and oospores.
Pythium aphanidermatum is a soil borne plant pathogen. Pythium is a genus in the class Oomycetes, which are also known as water molds. Oomycetes are not true fungi, as their cell walls are made of cellulose instead of chitin, they are diploid in their vegetative state, and they form coenocytic hyphae. Also, they reproduce asexually with motile biflagelette zoospores that require water to move towards and infect a host. Sexually, they reproduce with structures called antheridia, oogonia, and oospores.
Pythium aristosporum is a species of pythium under the class oomycota that causes root dysfunction in creeping bentgrass.
Sclerophthora macrospora is a protist plant pathogen of the class Oomycota. It causes downy mildew on a vast number of cereal crops including oats, rice, maize, and wheat as well as varieties of turf grass. The common names of the diseases associated with Sclerophthora macrospora include "crazy top disease" on maize and yellow tuft disease on turf grass. The disease is present all over the world, but it is especially persistent in Europe.
Peronospora is a genus of oomycetes that are obligate plant pathogens of many eudicots. Most species in this group produce a downy mildew disease, which can cause severe damage to many different cultivated crops, as well as wild and ornamental plants. There are 19 genera that produce downy mildew, and Peronospora has been placed alongside Pseudoperonospora in the group of downy mildews with coloured conidia. Peronospora has far more species than any other genus of the downy mildews. However, many species have been moved from this genus to be reclassified to other or new genera. Among these was the most famous Peronospora species, formerly known as Peronospora parasitica, and now known as Hyaloperonospora parasitica. Now, the Peronospora species of most importance is likely the Peronospora tabacina. Peronospora tabacina causes blue mold on tobacco plants and can severely reduce yields of this economically important crop to the point where it has been classified as a bioweapon.
Alma Joslyn Whiffen-Barksdale was an American mycologist who discovered cycloheximide. She was born in Hammonton, New Jersey. She received a bachelor's degree from Maryville College (1937). Her Masters and Ph.D. were earned at the University of North Carolina. In 1941–42. She was a Carnegie Fellow, and in 1951, she was a Guggenheim Fellow. Barksdale worked at the Department of Antibiotic Research of the Upjohn Company of Kalamazoo, Michigan (1943–52) and at the New York Botanical Garden. Barksdale became a foundational figure in the study of Achlya, a genus of aquatic fungi with a unique reproductive system, while working at the New York Botanical Garden; The Mycological Society of America and the Achlya Newsletter, a publication of continuing research on Achlya, both published retrospectives on her life and work following her death in 1981.
Globisporangium sylvaticum is a plant pathogen, an oomycete known to cause root rot and damping off in a multitude of species. These species include apples, carrot, cherry laurel, cress, cucumber, garlic, lettuce, pea, rhododendron, and spinach. Symptoms of infection include stunting, wilt, chlorosis, and browning and eventual necrosis of roots. The pathogen can by identified by the presence of thick, microscopic, round spores within the cells of the root.
Pythium porphyrae, is a parasitic species of oomycete in the family Pythiaceae. It is the cause of red rot disease or red wasting disease, also called akagusare (赤ぐされ) in Japanese. The specific epithet porphyrae (πορφυρα) stems from the genus of one of its common hosts, Porphyra, and the purple-red color of the lesions on the thallus of the host. However, many of its hosts have been moved from the genus Porphyra to Pyropia.
Black rot on orchids is caused by Pythium and Phytophthora species. Black rot targets a variety of orchids but Cattleya orchids are especially susceptible. Pythium ultimum and Phytophthora cactorum are known to cause black rot in orchids.
This glossary of mycology is a list of definitions of terms and concepts relevant to mycology, the study of fungi. Terms in common with other fields, if repeated here, generally focus on their mycology-specific meaning. Related terms can be found in glossary of biology and glossary of botany, among others. List of Latin and Greek words commonly used in systematic names and Botanical Latin may also be relevant, although some prefixes and suffixes very common in mycology are repeated here for clarity.