Allomyces macrogynus | |
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Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Fungi |
Division: | Blastocladiomycota |
Class: | Blastocladiomycetes |
Order: | Blastocladiales |
Family: | Blastocladiaceae |
Genus: | Allomyces |
Species: | A. macrogynus |
Binomial name | |
Allomyces macrogynus (R.Emers.) R.Emers. & C.M.Wilson (1954) | |
Synonyms [1] | |
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Allomyces macrogynus is a species of fungus in the family Blastocladiaceae. It was first described by mycologist Ralph Emerson in 1941 as a variety of Allomyces javanicus , [2] and later given distinct species status in 1954. [3] Its genome has been sequenced by the Broad Institute. [4]
The genome of Allomyces macrogynus has been sequenced [2] and this makes it desirable to review an organism of interesting structure and one which is responsive to environmental changes in easily observable ways. In Seattle 1969, at an informal meeting of Emerson, Machlis, Olson, Seale and Youatt, Youatt agreed to study chemical aspects of the fungus so that when the genome was known gene activity could be related to what the genes governed.
Allomyces macrogynus features defined by Emerson [3] and Emerson and Wilson [1] were of immediate interest for research and teaching because the organism had such clear and interesting structures. The vegetative growth showed the formation of rhizoids, hyphae and branching and then in the diploid cultures two kinds of fruiting body, zoosporangia ZS that reproduced the diploid organisms and resting or resistant sporangia RS that led to the haploid organism. Then on the haploid hyphae gametangia were produced with small terminal male gametangia containing carotene and larger female gametangia below.
Olson reviewed studies to 1984 that included chemotaxis of male gametes to female gametes, the identification of the hormone sirenin, studies of the chemistry of walls and discharge plugs and methods for classroom demonstrations. His comprehensive monograph also compares Allomyces with other fungi in detail. [5]
The organism which lives in tropical ditchwater has a range of survival mechanisms which can be studied in the laboratory. These include chemotaxis of zoospores to amino acids, especially leucine and lysine [6] and to some peptides and to oxygen, [7] and a minicycle where a germinated spore, deprived of nutrients, can produce another zoospore to move on to better conditions. [8] Allomyces macrogynus also shows chemotropism in the growing hyphal organisms by which the rhizoids can grow towards amino acid sources [9] and the hyphae to a better oxygen supply. [10] The diploid organisms can produce zoosporangia ZS when conditions are good and the resistant or resting sporangia RS when they are unfavourable. [11] The RS can survive desiccation for years.
Study requires synchronous culture in defined media. [11] Allomyces macrogynus is commonly grown in media with casein hydrolysate and yeast extracts as the source of nitrogen and growth factors but can be grown in a variety of chemically defined media. The simplest of these had ammonium salt as the only source of nitrogen. [11] Defined media allow selection of ZS or RS in diploid plants and male or female gametangia in haploid plants, the chief factor being the ratio of amino acids to glucose.
Interpretation of results is always easier if organisms are grown in chemically defined media and media could be very simple as would be expected for a saprophytic organism first isolated from ditch water. [11] In this context it is worth noting that, although methionine is supplied in all culture media, the organisms can synthesise methionine and in their natural environment they probably use sulfide available at low concentration. [12] Methionine is required for branching and, if added just before branching of a growing culture, hydrogen sulfide, cysteine and homocysteine can all be used. [13]
Methods based on vortex mixing and osmotic shock cause death of many spores. Casein hydrolysate CH or mixtures of leucine and lysine can also be used. [6] Small peptides in hydrolysed CH were also effective. [7]
Casein hydrolysate CH was good for producing synchronous germination. Zoospores encysted and attached to the unshaken glass vessel and the CH could then be removed and replaced with defined medium. As wall development began the organisms detached from glass and with suitable shaking grew as suspensions of single organisms, ideal for observation. [14] With new ways to produce RS synchronous cultures of haploid organisms could now be grown in the same way from selectively produced mature RS. [15] For chemically defined induction of germination mixtures of leucine and lysine or phenylpyruvate were the best of many compounds tested.
The synchronously growing hyphae showed development at the hyphal tip in G1 of the growth cycle and widening at the base in G2. [16] This study used time lapse photography because the alternating pattern seemed unusual. However, from the earliest descriptions of spore germination the same pattern was present. [3] After rhizoids had emerged the cysts developed first at a 180° angle to the rhizoids but then widened at the base to give the typical tubular hyphae.
Variations in the angle of emergence of hyphae were related to oxygen gradients. A further departure from apical growth was observed if hyphal organisms, growing on the surface of solid media, were covered with a microscope slide to create an oxygen gradient. The hyphal response involved growth towards the oxygen of thin unbranched hyphae which, when they reached open access to the air, widened back to the hyphal base to give hyphae of normal diameter. [17]
Synchronous germination and the chemotropism for oxygen were used to orient growing organisms suitably for measurements with a delicate vibrating probe electrode to measure currents along the hyphae during the backward and forward growth [18] and also to identify the ions involved. [9] The latter study also showed effects of growth in applied voltages and chemotropism of the rhizoids to casein hydrolysate. The ions leaving the hyphal tip were protons, which confirmed Turian's observations of acidification of the hyphal tips. [19]
In the experiments with oxygen and hyphal development there was no requirement for calcium and no inhibition by EGTA. [18] At the time of these studies many mycologists thought that calcium played a role in fungal morphology and were disinclined to believe that the labelling of agents such as the chelator EGTA and the ionophore A23187 could have been incorrectly said to be specific for calcium in many studies. Indeed, it is still not clear how the error occurred because stability constants for EGTA chelated with Fe, Zn and Mn had been published [20] before any claim of specificity for Ca. Calculations of the availability of free ions of essential divalent cations like Fe and Zn showed that experiments with EGTA were better explained as having caused deficiencies in these essential ions. [21] Classical demonstration of the requirements for trace metals requires careful cleaning of all glassware or plastic dishes and the use of very pure distilled water, and AR grade chemicals. By this method A.macrogynus and Achlya species were shown to require Fe, and Zn but not Ca. [22] The traditional supply of calcium salts to fungal cultures may have met the need for trace elements as even A.R. calcium salts always contain other divalent cations.
Basidiomycota is one of two large divisions that, together with the Ascomycota, constitute the subkingdom Dikarya within the kingdom Fungi. Members are known as basidiomycetes. More specifically, Basidiomycota includes these groups: agarics, puffballs, stinkhorns, bracket fungi, other polypores, jelly fungi, boletes, chanterelles, earth stars, smuts, bunts, rusts, mirror yeasts, and Cryptococcus, the human pathogenic yeast.
Ascomycota is a phylum of the kingdom Fungi that, together with the Basidiomycota, forms the subkingdom Dikarya. Its members are commonly known as the sac fungi or ascomycetes. It is the largest phylum of Fungi, with over 64,000 species. The defining feature of this fungal group is the "ascus", a microscopic sexual structure in which nonmotile spores, called ascospores, are formed. However, some species of Ascomycota are asexual and thus do not form asci or ascospores. Familiar examples of sac fungi include morels, truffles, brewers' and bakers' yeast, dead man's fingers, and cup fungi. The fungal symbionts in the majority of lichens such as Cladonia belong to the Ascomycota.
In biology, a spore is a unit of sexual or asexual reproduction that may be adapted for dispersal and for survival, often for extended periods of time, in unfavourable conditions. Spores form part of the life cycles of many plants, algae, fungi and protozoa.
Alternation of generations is the predominant type of life cycle in plants and algae. In plants both phases are multicellular: the haploid sexual phase – the gametophyte – alternates with a diploid asexual phase – the sporophyte.
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.
Gametogenesis is a biological process by which diploid or haploid precursor cells undergo cell division and differentiation to form mature haploid gametes. Depending on the biological life cycle of the organism, gametogenesis occurs by meiotic division of diploid gametocytes into various gametes, or by mitosis. For example, plants produce gametes through mitosis in gametophytes. The gametophytes grow from haploid spores after sporic meiosis. The existence of a multicellular, haploid phase in the life cycle between meiosis and gametogenesis is also referred to as alternation of generations.
Neurospora crassa is a type of red bread mold of the phylum Ascomycota. The genus name, meaning 'nerve spore' in Greek, refers to the characteristic striations on the spores. The first published account of this fungus was from an infestation of French bakeries in 1843.
Heterothallic species have sexes that reside in different individuals. The term is applied particularly to distinguish heterothallic fungi, which require two compatible partners to produce sexual spores, from homothallic ones, which are capable of sexual reproduction from a single organism.
Chemotropism is defined as the growth of organisms navigated by chemical stimulus from outside of the organism. It has been observed in bacteria, plants and fungi. A chemical gradient can influence the growth of the organism in a positive or negative way. Positive growth is characterized by growing towards a stimulus and negative growth is growing away from the stimulus.
Fungi are a diverse group of organisms that employ a huge variety of reproductive strategies, ranging from fully asexual to almost exclusively sexual species. Most species can reproduce both sexually and asexually, alternating between haploid and diploid forms. This contrasts with most multicellular eukaryotes such as mammals, where the adults are usually diploid and produce haploid gametes which combine to form the next generation. In fungi, both haploid and diploid forms can reproduce – haploid individuals can undergo asexual reproduction while diploid forms can produce gametes that combine to give rise to the next generation.
In botany, a zoid or zoïd is a reproductive cell that possesses one or more flagella, and is capable of independent movement. Zoid can refer to either an asexually reproductive spore or a sexually reproductive gamete. In sexually reproductive gametes, zoids can be either male or female depending on the species. For example, some brown alga (Phaeophyceae) reproduce by producing multi-flagellated male and female gametes that recombine to form the diploid sporangia. Zoids are primarily found in some protists, diatoms, green alga, brown alga, non-vascular plants, and a few vascular plants. The most common classification group that produces zoids is the heterokonts or stramenopiles. These include green alga, brown alga, oomycetes, and some protists. The term is generally not used to describe motile, flagellated sperm found in animals. Zoid is also commonly confused for zooid which is a single organism that is part of a colonial animal.
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.
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 aristosporum is a species of pythium under the class oomycota that causes root dysfunction in creeping bentgrass.
Blastocladiomycota is one of the currently recognized phyla within the kingdom Fungi. Blastocladiomycota was originally the order Blastocladiales within the phylum Chytridiomycota until molecular and zoospore ultrastructural characters were used to demonstrate it was not monophyletic with Chytridiomycota. The order was first erected by Petersen for a single genus, Blastocladia, which was originally considered a member of the oomycetes. Accordingly, members of Blastocladiomycota are often referred to colloquially as "chytrids." However, some feel "chytrid" should refer only to members of Chytridiomycota. Thus, members of Blastocladiomyota are commonly called "blastoclads" by mycologists. Alternatively, members of Blastocladiomycota, Chytridiomycota, and Neocallimastigomycota lumped together as the zoosporic true fungi. Blastocladiomycota contains 5 families and approximately 12 genera. This early diverging branch of kingdom Fungi is the first to exhibit alternation of generations. As well, two (once) popular model organisms—Allomyces macrogynus and Blastocladiella emersonii—belong to this phylum.
Chara is a genus of charophyte green algae in the family Characeae. They are multicellular and superficially resemble land plants because of stem-like and leaf-like structures. They are found in freshwater, particularly in limestone areas throughout the northern temperate zone, where they grow submerged, attached to the muddy bottom. They prefer less oxygenated and hard water and are not found in waters where mosquito larvae are present. They are covered with calcium carbonate (CaCO3) deposits and are commonly known as stoneworts. Cyanobacteria have been found growing as epiphytes on the surfaces of Chara, where they may be involved in fixing nitrogen, which is important to plant nutrition.
Allomyces is a genus of fungi in the family Blastocladiaceae. It was circumscribed by British mycologist Edwin John Butler in 1911. Species in the genus have a polycentric thallus and reproduce sexually or asexually by zoospores that have a whiplash-like flagella. They are mostly isolated from soils in tropical countries, commonly in ponds, rice fields, and slow-moving rivers.
Cunninghamella bertholletiae is a species of zygomycetous fungi in the order Mucorales. It is found globally, with increased prevalence in Mediterranean and subtropical climates. It typically grows as a saprotroph and is found in a wide variety of substrates, including soil, fruits, vegetables, nuts, crops, and human and animal waste. Although infections are still rare, C. betholletiae is emerging as an opportunistic human pathogen, predominantly in immunocompromised people, leukemia patients, and people with uncontrolled diabetes. Cunninghamella bertholletiae infections are often highly invasive, and can be more difficult to treat with antifungal drugs than infections with other species of the Mucorales, making prompt and accurate recognition and diagnosis of mycoses caused by this fungus an important medical concern.
Actinomucor elegans was originally described by Schostakowitsch in Siberia in 1898 and reevaluated by Benjamin and Hesseltine in 1957. Commonly found in soil and used for the commercial production of tofu and other products made by soy fermentation. Its major identifying features are its spine-like projections on the sporangiophore and its ribbon-like hyphal structure when found in the tissue of a host.