Physarum polycephalum

From MicrobeWiki, the student-edited microbiology resource

Introduction

Close-up of P. polycephalum creeping over a pine bark in a Norfolk pine forest. This single-celled organism with multiple nuclei forages for food by sending out branches (plasmodia) from a central location. Photograph was taken by Nigel Downer on August 3rd, 2016.[1].

Physarum polycephalum is a species of acellular slime molds, or Myxomycetes. Despite having a similar name to fungi, these organisms are protists. They are most commonly found in soil, moist vegetation, and the forest floor where it is cool, damp, and dark, where they contribute to the decomposition of dead vegetation. P. polycephalum have very diverse forms of life in a single cycle, as they can range from being a microscopic single-celled amoeba, a multinucleated cell, or plasmodium, that can span several feet, morphing into a hardened mass known as a sclerotium, or forming small, delicate fruiting bodies that produce haploid spores.

Due to its unique life cycle and large plasmodium stage, P. polycephalum is used as a model organism for the studies of cell cycle regulation, cell differentiation, and cellular motility. A multitude of studies have been done on this species of slime mold in order to research and comprehend its methods of communication and apparent intelligence. It is currently unknown as to what the molecular and genetic properties of this organism are that make it capable of having awareness and decision making, as further studies are currently in the process of obtaining conclusive results.

Life Cycle

Plasmodial slime mold life cycle.[2].

P. Polycephalum undergoes many changes during its life. The formation of its cycles is dependent upon environmental stressors and the presence or absence of other Physarum{3}

Plasmodium
The most commonly observed form of the Physarum polycephalum is its plasmodial form. The plasmodium is a large, singular cell with multiple diploid nuclei, each nuclei which undergo synchronous mitotic divisions, and the absence of cytokines.[1] These single cells can grow to a diameter of over a foot long as they continue to consume bacteria, fungal spores, and dead organic matter in its wild environment. When in nutrient-rich agar or other liquid cultures, plasmodium cells will readily grow axenically, no longer needing to engulf microbes to aid in the decomposition of organic matter.

Sclerotium of P. physarum after being exposed to insufficient moisture and inadequate nutrients.[3].



Sclerotium
In unfavorable conditions and in the absence of light, the plasmodium will revert into a temporary and reversible dormant state known as a sclerotium. Many nuclei in the starved plasmodium will degenerate, but those that persist will undergo mitotic division at a slowed rate. [1] In this form, they are dry and hardened until favorable conditions return.

Sporangium of P. physarum.[4].

Sporulation
If a starving plasmodium is in the presence of light, it will differentiate into sporangia; clusters of spores atop the tips of stalks. In its natural environment, this would be when the Physarum emerges from under organic matter such as leaf litter on the forest floor.[2][3] The organism can survive for much longer in this formation, because of the spores' higher resistance to environmental stress because of its layered cell wall. Many types of organisms across the tree of life undergo sporulation, especially plants and fungi. The spores of many Myxomycetes, such as P. polycephalum, have smooth spore walls covered with protectives spikes.[4] Unlike the dormant state of the sclerotium, sporangia is an irreversible pathway that the plasmodium transitions into. Haploid spores are created by the process of meiosis during sporulation, these spores remain dormant until agitated and in the recurrence of favorable conditions. The haploid spores will break away from the tip of the stalk and, upon germination with sufficient moisture, develop into haploid amoeba cells.

Amoebae and Flagellates
The germination of haploid spores gives rise to uninucleate amoeba cells.

Behavioral Characteristics

Physarum polycephalum are unique organisms that undergo various life-forms for the purpose of maintaining survival in the most efficient ways possible. The plasmodium form of these Physarum are heavily experimented on due to their fascinating behavior. P. polycephalum has shown remarkable attributes of memory, communication, and even intelligence within the plasmodium.

Memory

Communication

intelligence

Optimal Foraging

“Intake” regulation of P. polycephalum physarum when faced with multiple foods varying in protein and carbohydrate content.[5].


Slime molds have been shown to solve complex nutritional challenges. An experiment on a P. polycephalum plasmodia has shown the organism's ability to extend foraging arms to patches of varied nutrient composition in the precise proportions to compose an optimal diet.[5] Social insects, such as ants, bees, and termites, have shown this pattern of optimal foraging. For these congregate insects, however, the process involves specialized foragers to obtain food for the colony as a whole. The P. polycephalum plasmodia do not undergo optimal foraging via the same process as a plasmodium is a singular cell. Despite not having a centralized system, the plasmodia were still able to maximize their benefit from the nutrient complexes they were to choose from.[5] The mechanism that allows the organisms to respond precisely to these nutritional cues remains unknown as future studies have yet to be concluded.

Conclusion

Physarum polycephalum appear to exhibit communication and intelligence, unlike most organisms.

References

  1. 1.0 1.1 Guttes, E., Guttes, S., & Rusch, H. P. (1961). Morphological observations on growth and differentiation of Physarum polycephalum grown in pure culture. Developmental Biology, 3(5), 588-614. doi:10.1016/0012-1606(61)90034-3
  2. Think Single-Celled Organisms Are Simple? Think Again! The Slime Mold Physarum polycephalum, a Single-Celled Organism for Student Investigations. (n.d.). Retrieved December 05, 2020, from https://www.carolina.com/teacher-resources/Interactive/think-single-celled-organisms-are-simple-think-again-the-slime-mold-physarum-polycephalum-a-single-celled-organism-for-student-investigations/tr41405.tr
  3. Introduction to the "Slime Molds". (n.d.). Retrieved December 05, 2020, from https://ucmp.berkeley.edu/protista/slimemolds.html
  4. Alexopoulos, C. J. (1963). The Myxomycetes II. The Botanical Review, 29(1), 1-78. doi:10.1007/bf02860818
  5. 5.0 5.1 Dussutour, A., Latty, T., Beekman, M., & Simpson, S. J. (2010). Amoeboid organism solves complex nutritional challenges. Proceedings of the National Academy of Sciences, 107(10), 4607-4611. doi:10.1073/pnas.0912198107


Edited by Freya Beinart, student of Joan Slonczewski for BIOL 116 Information in Living Systems, 2020, Kenyon College.