Monocellular, mononuclear phase Spores '' sp. (
Stemonitales) The spores of Myxogastria are
haploid, mainly round and measure between 5
μm and 20 μm, rarely up to 24 μm in diameter. Their surface is generally reticular, sharp, warty or spiky and very rarely smooth. The typical colour of the spore mass becomes visible through the structure, since the spores themselves are not pigmented. In some species, especially of the genus
Badhamia, the spores produce lumps. The colour, shape and diameter of spores are important characteristics for identifying species. Important factors for the germination of spores are mainly moisture and temperature. The spores usually remain germinable after several years; there were even spores preserved in
herbarium specimens which germinated after 75 years. After the spores' development, they first receive a diploid nucleus, and the
meiosis takes place in the spore. At the germination, the spore shells open either alongside special germinal pores or chinks, or rip irregularly and then release one to four haploid
protoplasts.
Myxamoebae and Myxoflagellates ) and opened spores In those species which reproduce sexually, haploid cells bud from the spores. Depending on the environmental conditions, either a myxamoeba or a myxoflagellate buds from the spore. Myxamoebae move like
amoebae – that is, crawling on the substrate – and are produced in dry conditions. Myxoflagellates, which are
peritrichous and can swim, develop in moist to wet environments. Myxoflagellates almost always have two flagella; one is generally shorter than the other and sometimes only vestigial. The flagella are used for locomotion and to help to move food particles closer. If the humidity changes, cells can switch between the two manifestations. Neither form has a cell wall. This developmental stage (and the next one) serves as a nourishment provider and is also known as the first trophic phase (nourishment phase). In this monocellular phase, the Myxogastria consume bacteria and fungus spores, and probably dissolved substances, and they reproduce through simple
cell division. If the environmental conditions change adversely in this phase, for example extreme temperature, extreme dryness or food shortage, the Myxogastria may switch to very long-lived, thin-shelled quiescent states – the so-called micro
cysts. For that to happen, the myxamoebae assume a round shape and secrete a thin cell wall. In this state they can easily survive one year or longer. If living conditions improve, they become active again.
Zygogenesis If two cells of the same type meet in this phase, they cross-fertilise to a diploid zygote through the fusion of
protoplasms and
nuclei. The conditions which trigger this are not known. The diploid zygote becomes a multinucleated
plasmodium through multiple nuclear divisions without further cell division. If the resulting cells were peritrichous, they change their shape before the fusion from the peritrichous form to the myxamoeba. The production of a zygote requires two cells of different
mating types (
heterothallic).
Plasmodium The second trophic phase begins with the development of the
plasmodium. The multinucleated organism now absorbs via
phagocytosis as many nutrients as possible. These are bacteria,
protists, dissolved substances, moulds, higher fungi and small particles of organic material. This enables the cell to undergo enormous growth. The nucleus divides multiple times, and the cell soon becomes visible to the naked eye and usually has a surface area – depending on the species – up to one square metre; however, in 1987 one artificially cultivated cell of
Physarum polycephalum attained a surface area of 5.5 sq m. Myxogastria species have numerous nuclei in their trophic plasmodium phase; the small, non-veined proto-plasmodia have between 8–100 nuclei, while large, veined meshworks have between 100 and 10 million nuclei. All of these remain part of a single cell, which has a viscous, slimy consistency, and may be transparent, white, or brightly coloured in orange, yellow, or pink. The cell has
chemotactic and negative
phototactic capabilities in this phase, meaning that it is able to move towards nutrients and away from dangerous substances and light. The movements originate in the grainy cytoplasm, which streams by pulsation in one direction within the cell. In this way the cell reaches a speed of up to 1000 μm per second – the speed in plant cells is 2–78 μm per second. A resting state, the so-called
sclerotium, may occur in this phase. The sclerotium is a hardened, resistant form composed of numerous "macrocysts", which enable the myxogastria to survive in adverse conditions, for example during winter or dry periods, in this phase. File:Trichia decipiens (Pers.)Macbr.jpg|Sporangia (pediculated) of
Trichia decipiens (
Trichiales) File:Hemitrichia serpula 57955.jpg|Plasmodiocarp of
Hemitrichia serpula (
Trichiales) File:Enteridium lycoperdon 4.jpg|Aethalium of
Enteridium lycoperdon (
Liceales)
Fructification Mature plasmodia can produce fruit bodies under appropriate circumstances. The exact triggers for this process are unknown. According to laboratory researchers, changes in humidity, temperature or
pH value as well as starvation periods were thought to be the triggers in some species. The plasmodia abandon their nutrient intake and crawl, attracted by light – a positive phototaxis – towards a dry, light area, to get an optimal spread of the spores. Once the fructification begins, it cannot be stopped. If disturbances occur, malformed spore-bearing fruit bodies are often produced. The plasmodium or parts of the fruit bodies can be smaller than one millimetre, in extreme cases they are up to a square metre and weigh up to (
Brefeldia maxima). Their shape is often pediculated or unstiped sporangia with non-cellular stems, but can also appear as veined or netted
plasmodiocarps, pincushion-shaped aethaliae or seemingly pincushion-shaped pseudo-aethaliae. The fruit bodies almost always have a hypothallus on the edge. The abundantly produced spores are stored in a reticular or filamentous structure – the so-called
capillitium – and are found on nearly all species except
Liceida and other species from the genus
Echinostelium. When the open fruit bodies have dried, the spores are dispersed by wind or by small animals such as woodlice, mites or beetles, which either pick up the spores through contact with the fruit bodies or ingest and then excrete them. Dispersal by running water is also possible, but it plays a minor role.
Asexual forms Some Myxogastria species may produce
asexually. These are continuously diploid. There is no meiosis before the germination of the spores and the production of the plasmodium proceeds without germination of two cells. == Distribution and ecology ==